JP2018020017A - Game machine - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a game machine permitting suitable soldering when mounting an electronic component, a connector, and the like onto a printed wiring board.SOLUTION: A first operation hole detection sensor 951 for detecting entry into a first operation hole is connected to a main control board 61 via a first harness 951a, and a second operation hole detection sensor 952 for detecting entry into a second operation hole is connected to the main control board 61 via a second harness 952a. The main control board 61 includes: a first via hole 793s for inserting a first pin 784s used for connection of the second harness 952a, and a second via hole 793t for inserting a second pin 784t. Short-circuiting prevention holes 761, which suppress formation of a solder bridge between the first pin 784s and the second pin 784t, are provided around the first via hole 793s and the second via hole 793t each.SELECTED DRAWING: Figure 103

Description

  The present invention relates to a gaming machine.

  Pachinko machines and slot machines are known as gaming machines. For example, a pachinko gaming machine includes a main control device that controls the main control of a game, a sound emission control device that outputs sound and light for production based on commands received from the main control device, and the like. These main control devices, sound emission control devices, and the like have a board inside, and the board is configured by mounting electronic components such as ICs and resistors, connectors, and the like on a printed wiring board. Electronic parts, connectors, and the like are fixed in a state where they are electrically connected to wiring formed on a printed wiring board by soldering (see, for example, Patent Document 1).

JP 2014-004102 A

  Here, in a gaming machine such as the above-described example, it is necessary to suitably perform soldering when mounting electronic components and connectors on a printed wiring board, and there is still room for improvement in this respect.

  The present invention has been made in view of the above-mentioned circumstances and the like, and provides a gaming machine capable of suitably performing soldering when mounting an electronic component, a connector, or the like on a printed wiring board. It is the purpose.

In order to solve the above-mentioned problem, the invention according to claim 1 is a launching means for launching a game ball toward a game area based on a launch operation by a player,
A starting pitching portion into which a gaming ball flowing down the gaming area can enter;
Entry detection means for detecting a game sphere that has entered the starting entrance part,
A specific control means having a specific substrate provided with a connection means to which a transmission means for transmitting information of the detection result of the entrance detection means is electrically connected;
With
As the starting pitching portion, at least a first starting pitching portion and a second starting pitching portion are provided,
As said entrance detection means, the 1st entrance detection means which detects the game ball which entered the 1st start entrance part, and the 2nd entrance which detects the game ball which entered the 2nd start entrance part And at least a ball detecting means,
As the transmission means, the first transmission means for transmitting the detection result information of the first entrance detection means, and the second transmission means for transmitting the detection result information of the second entrance detection means,
The connection means includes a first connection means to which the first transmission means is connected, and a second connection means to which the second transmission means is connected,
The first connection means and the second connection means are individually provided for the specific substrate,
The connection terminals provided in the second connection means are two, a first connection terminal and a second connection terminal,
The specific substrate is:
A first insertion hole through which the first connection terminal is inserted;
A second insertion hole through which the second connection terminal is inserted;
A first connection region provided around the first insertion hole;
A second connection region provided around the second insertion hole;
A predetermined insertion hole through which a predetermined terminal of a predetermined mounting component is inserted;
A predetermined connection area provided around the predetermined insertion hole;
With
In a state where the first connection terminal is inserted into the first insertion hole, the first connection terminal and the first connection region are electrically connected by solder,
In a state where the second connection terminal is inserted into the second insertion hole, the second connection terminal and the second connection region are electrically connected by solder,
In a state where the predetermined terminal is inserted into the predetermined insertion hole, the predetermined terminal and the predetermined connection region are electrically connected by solder,
In the game area, the first start ball entering portion is provided at a position where a game ball launched at least when the launch operation according to the first operation mode is performed can be reached,
In the game area, the second start ball entering part is a position where the game ball launched when the launch operation according to the first operation mode is being performed is not reachable or difficult to reach, and the second operation mode Is provided at a position where the game ball launched when the launch operation is performed can be reached,
The specific control means includes
First acquisition means for acquiring special information based on the fact that a game ball is detected by the first entry detection means;
First acquisition information storage means for storing the special information acquired by the first acquisition means;
Second acquisition means for acquiring special information based on the fact that a game ball is detected by the second entry detection means;
Second acquisition information storage means for storing the special information acquired by the second acquisition means;
Grant determination means for performing grant determination as to whether or not the special information stored in the first acquisition information storage means or the second acquisition information storage means corresponds to predetermined grant information;
Privilege granting means for granting a privilege to a player based on the result of the grant determination by the grant determination means being the grant correspondence result that the special information to be judged corresponds to the grant information; ,
Acceptance control capable of switching the second starting entrance part to either a first state in which a game ball is difficult to enter or cannot enter, and a second state in which a game ball is easier to enter. Means,
With
The acceptance control means has a first mode and a second mode that is more likely to be in the second state than the first mode as a control mode of the second starting and entering part,
The special information stored in the second acquisition information storage unit becomes the target of the determination of the grant rather than the case where the special information stored in the first acquisition information storage unit is the target of the determination of grant. Is a configuration in which the privilege that is advantageous to the player is given or is easily given,
The first connection region and the second connection region are formed to have a larger area than the predetermined connection region,
The first connection region is formed such that an area on a side different from the second insertion hole side is increased with the first insertion hole as a reference,
The second connection region is formed so that an area on a side different from the first insertion hole side is increased with the second insertion hole as a reference.

  ADVANTAGE OF THE INVENTION According to this invention, it becomes possible to perform suitably the soldering at the time of mounting an electronic component, a connector, etc. on a printed wiring board.

It is a perspective view which shows the pachinko machine in 1st Embodiment. It is a perspective view which decomposes | disassembles and shows the main structures of a pachinko machine. It is a front view which shows the structure of a game board. It is explanatory drawing for demonstrating the structure regarding discharge | emission of the game ball which flowed down the game area | region. It is a block diagram which shows the electric constitution of a pachinko machine. It is explanatory drawing for demonstrating the content of the various counters used for a success or failure lottery. It is a flowchart which shows the main process performed by main side CPU. It is a flowchart which shows the timer interruption process performed with the main side CPU. It is explanatory drawing for demonstrating the structure which makes the main side CPU input the detection result of a entrance detection sensor. It is a flowchart which shows the entrance detection process performed by main side CPU. It is a block diagram for demonstrating the electrical structure of the various apparatuses which communicate between a payout control apparatus and the said payout control apparatus. It is a flowchart which shows the timer interruption process performed with payout side CPU. It is a block diagram for demonstrating the electrical structure of IC for management. It is explanatory drawing for demonstrating the structure of the input port of management side I / F. It is explanatory drawing for demonstrating the structure of the memory for correspondence. It is explanatory drawing for demonstrating the structure of the memory for log | history. It is a flowchart which shows the process for recognition performed with the main side CPU. It is a flowchart which shows the management process performed with management side CPU. (A)-(d) It is a time chart which shows a mode that the information of the correspondence of the 1st-15th buffer and the kind of signal is stored in the memory for correspondence. It is a flowchart which shows the output process for management performed in main side CPU. It is a flowchart which shows the log | history setting process performed with management side CPU. (A)-(e) It is a time chart which shows a mode that log | history information is stored in the memory for log | history. It is a flowchart which shows the process for data output performed with the main side CPU. It is a flowchart which shows the process for external output performed with management side CPU. It is explanatory drawing for demonstrating the structure of the input port of the management side I / F in 2nd Embodiment. It is a flowchart which shows the process for recognition performed with the main side CPU. It is a flowchart which shows the management process performed with management side CPU. (A)-(h) It is a time chart which shows a mode that the information of the correspondence of 1st-12th buffer and the kind of signal is stored in the memory for correspondence. It is a block diagram for demonstrating the electrical structure of management IC in 3rd Embodiment. It is explanatory drawing for demonstrating the structure of the input port of management side I / F. It is a flowchart which shows the power failure information storage process performed with main side CPU. It is a flowchart which shows the power failure response process performed in management side CPU. It is a flowchart which shows the process for external output performed with management side CPU. It is a flowchart which shows the power failure response process performed in the management side CPU in 4th Embodiment. (A) It is a flowchart which shows the opportunity specific process performed in main side CPU in 5th Embodiment, (b) It is a flowchart which shows the arithmetic processing performed in management side CPU. It is a flowchart which shows the opportunity specific process performed by the main side CPU in 6th Embodiment. It is a flowchart which shows the arithmetic processing performed by the management side CPU in 7th Embodiment. It is a flowchart which shows the log | history setting process performed in the management side CPU in 8th Embodiment. It is explanatory drawing for demonstrating the structure of the memory for log | history in 9th Embodiment. It is a flowchart which shows the log | history setting process performed with management side CPU. It is a block diagram for demonstrating the electric constitution of MPU of the main controller in 10th Embodiment. It is a flowchart which shows the entrance detection process performed by main side CPU. It is a block diagram for demonstrating the electric constitution of the main controller in 11th Embodiment. It is explanatory drawing for demonstrating the structure of the input port of management side I / F. It is explanatory drawing for demonstrating the structure of the memory for log | history. It is a flowchart which shows the log | history setting process performed with management side CPU. It is a flowchart which shows the process for external output performed with management side CPU. It is a flowchart which shows the parameter management process performed with main side CPU. It is a block diagram for demonstrating the structure of the signal path | route which transmits the detection result of each entrance detection sensor in 12th Embodiment to main side CPU and management IC. It is a front view of the game board in 13th Embodiment. (A) It is a perspective view of a 1st left-right sorting nail, (b) It is a top view of a 1st left-right sorting member, (c) It is a rear view of a 1st left-right sorting member. (A) It is a perspective view of the member for fixation, (b) It is an end view of the cut surface of the 1st right-and-left distribution nail at the time of cut | disconnecting in a plane perpendicular | vertical to the surface of a game board. (A) It is an end elevation of the longitudinal section of the 1st right-and-left distribution nail which shows the game ball which collides with the 1st distribution surface, (b) The course of the game ball which falls from the upper part and collides with the 1st distribution surface It is explanatory drawing for demonstrating (c) It is explanatory drawing for demonstrating the course of the game ball which flows down from the upper left side, and collides with a 1st distribution surface. (A) End view of a longitudinal section of a first left and right sorting nail showing a game ball colliding with a second distribution surface, (b) Path of a game ball falling from above and colliding with a second distribution surface It is explanatory drawing for demonstrating (c) It is explanatory drawing for demonstrating the course of the game ball which flows down from the upper left side, and collides with a 2nd distribution surface. (A) It is a perspective view of a 2nd right-and-left distribution nail, (b) It is a top view of a 2nd left-right distribution member, (c) It is a rear view of a 2nd left-right distribution member. (A) a table indicating the direction of the drag received by the game ball colliding with the first left / right sorting nail; (b) a table indicating the direction of the drag received by the game ball colliding with the second left / right sorting nail; (C) It is a table which shows the direction of the drag which the game ball which collides with an obstruction nail receives. (A) It is explanatory drawing for demonstrating a mode that the game ball located in the back | inner side is guided to the left side guide nail group, (b) A mode that the game ball located in the near side is guided to the left side guide nail group It is explanatory drawing for demonstrating. (A) It is explanatory drawing for demonstrating a mode that the game ball located in the back | inner side is guided to the right side guide nail group, (b) A mode that the game ball located in the near side is guided to the right side guide nail group It is explanatory drawing for demonstrating. It is a front view of the game board which expands and shows the periphery of the left guide member in another form of the thirteenth embodiment. FIG. 4 is a front view of a game board in which a first left / right sorting nail and a second left / right sorting nail are provided in the vicinity of the upstream of the working port, and an enlarged view of the vicinity of the working port. (A) It is a perspective view of a 1st left-right distribution nail, (b) It is an end view of the cut surface of the 1st left-right distribution nail at the time of cut | disconnecting in a plane perpendicular | vertical to the surface of a game board. (A) It is a perspective view of an inversion nail, (b) It is an end view of a cut surface at the time of cut | disconnecting an inversion nail in the plane perpendicular | vertical to the surface of a game board, (c) The game ball which collides with a 1st inversion surface (D) It is explanatory drawing for demonstrating the course of the game ball which collides with a 2nd inversion surface. It is the front view of the game board in 14th Embodiment, and the enlarged view of the upstream part periphery of the left side guide nail group. (A) Perspective view of front / rear distribution nail, (b) Front view of front / rear distribution member, (c), (d) Front / rear distribution nail when cut along a plane perpendicular to the surface of the game board It is an end elevation of the cut surface. (A) It is a perspective view of a back nail, (b), (c) It is an end elevation of the cut surface of a back nail at the time of cut | disconnecting in a plane perpendicular | vertical to the surface of a game board. (A) It is explanatory drawing for demonstrating the course in the left guidance nail group of the game ball located in the back | inner side of a game area, (b) Course in the left guidance nail group of the game ball located in the near side of a game area It is explanatory drawing for demonstrating. (A) It is a top view of the front priority member in another form of 14th Embodiment, (b) It is explanatory drawing for demonstrating the course of the game ball in the left guide nail group containing a front priority member. It is the front view of the game board in 15th Embodiment, and the enlarged view of a rebound nail periphery. (A) It is a disassembled perspective view of a repelling nail, (b) It is a longitudinal cross-sectional view of a repelling nail. (A) is an end view of the cut surface when the repelling nail is cut in a plane perpendicular to the plane of the game board, (b) is an explanatory diagram for explaining the course of the game ball colliding with the high repulsion part, (C) It is an end view of a cut surface at the time of cut | disconnecting a repulsion nail in the plane perpendicular | vertical to the plane of a game board, (d) It is explanatory drawing for demonstrating the course of the game ball colliding with a low repulsion member. (A) It is explanatory drawing for demonstrating the course of the game ball colliding with the high repulsion part of a repulsion nail, (b) The path | route of the game ball after a collision at the time of colliding with the low repulsion member of a repulsion nail is demonstrated. It is explanatory drawing for. It is a front view of the game board in a 16th embodiment. (A) It is a perspective view of a front / rear sorting table, (b) A plan view of the front / rear sorting table, and (c), (d) When the front / rear sorting table is cut in a plane perpendicular to the surface of the game board It is an end elevation of the cut surface. It is a front view of the game board which expands and shows the left center part. It is a front view of the game board in another form of 16th Embodiment. (A), (b) It is a front view of the game board which expands and shows the back-and-forth distribution stand and the left guide nail group periphery. (A) It is a perspective view of the front-and-back sorting stand provided with the groove | channel which guide | induces the game ball of the back side to the back | inner side, and the groove | channel which guides the game ball of the front side to the front side most, (b) back side FIG. 3 is a perspective view of a front / rear sorting table provided with a groove for guiding the game ball to the frontmost side and a groove for guiding the game ball on the front side to the farthest side. It is the front view of the game board in 17th Embodiment, and the enlarged view of a position change passage periphery. (A) It is a perspective view of a channel | path formation member, (b) It is a front view of a channel | path formation member, (c), (d) The cut surface at the time of cut | disconnecting a channel | path formation member in a plane perpendicular | vertical to the surface of a game board FIG. (A), (b) It is a front view of the game board which expands and shows the downstream periphery of a position change channel | path. (A), (b) It is an end view of a cut surface at the time of cut | disconnecting the exchange channel | path formation member in a plane perpendicular | vertical to the surface of a game board. It is a front view of the game board in 18th Embodiment. (A) It is a disassembled perspective view of a guide member, (b) It is a left view of a guide member. It is an end view of a cut surface when a guide member is cut along a plane perpendicular to the surface of the game board. (A), (b) It is a front view of the game board which expands and shows the downstream periphery of a guide passage. It is an end view of the cut surface when the replacement guide member is cut along a plane perpendicular to the surface of the game board. (A) End view of the cut surface when the guide member is cut along a plane perpendicular to the surface of the game board in another form of the eighteenth embodiment, (b) Replacement with a plane perpendicular to the surface of the game board It is an end view of a cut surface when a guide member is cut. (A) It is a surface view of the main control board which expands and shows a part of main control board in 19th Embodiment, (b) It is a surface view of the main control board which expands and shows the periphery of 1 row connector. . (A) It is a perspective view of a 1 row connector, (b) It is a perspective view of a 2 pole connector, (c) It is a perspective view of a 2 row connector. (A) It is a perspective view which expands and shows a part of back surface of a printed wiring board, (b) It is a longitudinal cross-sectional view which expands and shows the circumference | surroundings of the via hole of the printed wiring board cut | disconnected by the plane perpendicular | vertical to the surface. It is a longitudinal cross-sectional view which expands and shows the surroundings of the pin of the printed wiring board cut | disconnected by the plane perpendicular | vertical to the surface. (A) It is a reverse view which expands and shows a part of main control board, (b) It is a reverse view of the printed wiring board which expands and shows the back surface area | region for 1 row before a 1 row connector is mounted | worn. (A) It is explanatory drawing for demonstrating the jet of molten solder, (b) It is explanatory drawing for demonstrating a mode that the jet is contacting the back surface of a printed wiring board. (A) It is a longitudinal cross-sectional view of the printed wiring board for a comparison shown in order to demonstrate the state which the 2nd pin of the 1 row connector, the 3rd pin, and the 4th pin are contacting the jet, (b) 1 row It is a longitudinal cross-sectional view of the printed wiring board for a comparison shown in order to demonstrate a mode that the 2nd pin of a connector slips out from a contact state with a jet, (c) The 3rd pin of a 1 row connector slips out of a contact state with a jet It is a longitudinal cross-sectional view of the printed wiring board for a comparison shown in order to demonstrate a mode. (A) It is a longitudinal cross-sectional view of the printed wiring board for a comparison shown in order to demonstrate the state which the 3rd pin of 1 row connector slipped out of the contact state with a jet, (b) 4th pin of 1 row connector is jet It is a longitudinal cross-sectional view of the printed wiring board for a comparison shown in order to demonstrate the state which pulled out from the contact state, and (c) The state in which the solder bridge is formed between the 3rd pin and the 4th pin of 1 row connector It is a longitudinal cross-sectional view of the printed wiring board for a comparison which shows this. It is a longitudinal cross-sectional view of the printed wiring board shown in order to demonstrate the solder fillet formed around the 4th pin of the 1 row connector. (A) It is a back view of the printed wiring board which expands and shows the back area for 2 poles before a 2 pole connector is mounted | worn, (b) It expands the back area for 2 rows before a 2 row connector is mounted | worn It is a reverse view of the printed wiring board shown. (A) It is a reverse view of the printed wiring board which expands and shows the back surface area | region for 1 row provided with the inclination short circuit prevention hole in another form of 19th Embodiment, (b) It expands the back surface area for 1 row. It is a back view of the printed wiring board shown, and (c) is a back view of the printed wiring board showing an enlarged back surface area for one row in the printed wiring board. (A) The back surface figure of the printed wiring board which expands and shows the back surface area | region for 1 row in 20th Embodiment, (b) The longitudinal cross-sectional view of the printed wiring board which expands and shows the periphery of the pin of 1 row connector It is. (A) It is a back view of the printed wiring board which expands and shows the back surface area | region for 1 row in which the six isolation | separation type | mold short circuit prevention holes in another form of 20th Embodiment are formed, (b) Two 3 directions It is a reverse view of the printed wiring board which expands and shows the back surface area | region for 1 row in which the separation type | mold short circuit prevention hole is formed. It is a back view of the printed wiring board which expands and shows the back region for 1 row in which the short circuit prevention hole group for suppressing generation | occurrence | production of the solder bridge in 21st Embodiment is formed. It is a front view of the game board in a 22nd embodiment. (A) It is explanatory drawing for demonstrating the connection aspect of a 1st working port detection sensor and a 2nd working port detection sensor, and a main control board, (b) 1st working port area | region and 2nd working port area | region It is a reverse view of the printed wiring board which expands and shows.

<First Embodiment>
Hereinafter, a first embodiment of a pachinko gaming machine (hereinafter referred to as “pachinko machine”), which is a type of gaming machine, will be described in detail with reference to the drawings. FIG. 1 is a perspective view of the pachinko machine 10, and FIG. 2 is an exploded perspective view showing the main configuration of the pachinko machine 10. As shown in FIG. In FIG. 2, the configuration in the game area PA of the pachinko machine 10 is omitted for convenience.

  As shown in FIG. 1, the pachinko machine 10 includes an outer frame 11 that forms an outer shell of the pachinko machine 10, and a gaming machine body 12 that is rotatably attached to the outer frame 11. Have. The outer frame 11 is configured by connecting wooden plates to four sides and has a rectangular frame shape. The pachinko machine 10 is installed in the game hall by attaching and fixing the outer frame 11 to the island facility. In the pachinko machine 10, the outer frame 11 is not an essential configuration, and may be configured such that the outer frame 11 is provided in the island facility of the game hall.

  As shown in FIG. 2, the gaming machine main body 12 includes an inner frame 13, a front door frame 14 disposed in front of the inner frame 13, and a back pack unit 15 disposed behind the inner frame 13. ing. An inner frame 13 of the gaming machine body 12 is rotatably supported by the outer frame 11. Specifically, the inner frame 13 can be rotated forward with the left side as a rotation base end side and the right side as a rotation front end side in front view.

  A front door frame 14 is rotatably supported by the inner frame 13 and can be rotated forward with the left side as a rotation base end side and the right side as a rotation front end side in a front view. Further, the back pack unit 15 is rotatably supported on the inner frame 13, and can be rotated backward with the left side as a rotation base end side and the right side as a rotation front end side in a front view.

  The gaming machine main body 12 is provided with a locking device at the rotating tip, and has a function of locking the gaming machine main body 12 to the outer frame 11 so that it cannot be opened. The door frame 14 has a function of locking the door frame 14 to the inner frame 13 so as not to be opened. Each of these locked states is released by performing an unlocking operation on the cylinder lock 17 provided exposed at the front surface of the pachinko machine 10 using an unlocking key.

  Next, the configuration of the front side of the gaming machine body 12 will be described.

  The inner frame 13 is mainly composed of a resin base 21 whose outer shape is substantially the same as that of the outer frame 11. A substantially elliptical window hole 23 is formed at the center of the resin base 21. A game board 24 is detachably attached to the resin base 21. The game board 24 is made of plywood, and the game area PA formed on the front surface of the game board 24 is exposed to the front surface side of the inner frame 13 through the window hole 23 of the resin base 21.

  Here, the structure of the game board 24 is demonstrated based on FIG. FIG. 3 is a front view of the game board 24.

  An inner rail portion 25 and an outer rail portion 26 are attached to the game board 24 so as to partition a part of the outer edge of the game area PA. The inner rail portion 25 and the outer rail portion 26 provide guidance means. As a guide rail, it is configured. A game ball launched from a game ball launching mechanism 27 (see FIG. 2) attached below the window hole 23 in the resin base 21 is guided to the upper part of the game area PA by a guide rail.

  Incidentally, the game ball launching mechanism 27 includes a launch rail 27a extending toward the guide rail, a ball feeding device 27b for supplying game balls stored in an upper plate 55a, which will be described later, onto the launch rail 27a, and the launch rail 27a. And a solenoid 27c which is an electric actuator for firing the game ball supplied to the guide rail. When the launch operation device (or operation handle) 28 provided on the front door frame 14 is rotated, the solenoid 27c is driven and controlled, and a game ball is launched.

  The game board 24 has a plurality of large and small openings penetrating in the front-rear direction. Each opening is provided with a general winning port 31, a special electricity winning device 32, a first operating port 33, a second operating port 34, a through gate 35, a variable display unit 36, a special drawing unit 37, a universal drawing unit 38, and the like. ing. A total of four general winning ports 31 are provided, and one is provided for each other.

  Even if a ball enters the through gate 35, the game ball is not paid out. On the other hand, when a ball enters the general winning port 31, the special electricity winning device 32, the first operating port 33, and the second operating port 34, a predetermined number of game balls are paid out. Specifically, when the number of prize balls is one game ball entering the first operation port 33 or one game ball entering the second operation port 34 is generated. In the case where one prize ball is paid out and one game ball is thrown into the general prize opening 31, ten prize balls are paid out and the special prize winning device 32 is paid out. When one game ball enters, 15 prize balls are paid out.

  The number of prize balls may be arbitrary. For example, the second actuation port 34 may have a smaller number of prize balls than the first actuation port 33, and the second actuation port 34 may be configured as the first actuation port. The number of prize balls may be larger than 33.

  In addition, an out port 24a is provided at the bottom of the game board 24, and game balls that have not entered various winning ports etc. are discharged from the game area PA through the out port 24a. In addition, the game board 24 is provided with a large number of nails 24b and various members such as a windmill in order to disperse and adjust the falling direction of the game ball as appropriate.

  Here, the entry ball means that the game ball passes through a predetermined opening, and not only the mode of discharging from the game area PA after passing through the opening, but also from the game area PA after passing through the opening. A mode in which the game area PA continues to flow down without being discharged is also included. However, in the following description, in order to clearly distinguish the game ball from entering the out port 24a, the general winning port 31, the special prize winning device 32, the first operating port 33, the second operating port 34, and the through gate 35 are provided. Entering a game ball into is also expressed as a prize.

  The first operating port 33 and the second operating port 34 are unitized as operating port devices and are installed in the game board 24. Both the first working port 33 and the second working port 34 are opened upward. Further, both the operation ports 33 and 34 are arranged in the vertical direction so that the first operation port 33 is located on the upper side. The second operating port 34 is provided with a general electric utility 34a as a guide piece composed of a pair of left and right movable pieces. In the closed state of the utility wire 34a, the game ball cannot win the second operating port 34, and the winning of the second operating port 34 becomes possible when the universal power 34a is opened.

  A through gate 35 is provided on the upstream side in the flow-down direction of the game ball from the second working port 34. The through gate 35 has a through hole (not shown) penetrating in the vertical direction, and the game ball that has won the through gate 35 flows down the game area PA after winning. As a result, the game ball that has won the through gate 35 can win the second working port 34.

  Based on the winning of the through gate 35, the common utility 34 a of the second operating port 34 is switched from the closed state to the open state. Specifically, an internal lottery is performed with a winning at the through gate 35 as a trigger, and a normal display of a general-purpose unit 38 provided at the lower right corner, which is a region where game balls do not pass in the game region PA, is displayed. In the part 38a, the change display of the pattern is performed. Then, when the result of the internal lottery is the electrification opening winning, the stop result corresponding to the result is displayed, and the fluctuation display of the general map display unit 38a is finished, the state shifts to the public power open state. In the public power open state, the general electric utility 34a is opened in a predetermined manner.

  The general map display unit 38a is constituted by a segment display in which a plurality of segment light emitting units are arranged in a predetermined manner, but is not limited to this, and is not limited to this. A liquid crystal display device, an organic EL display device , Or other types of display devices such as CRT or dot matrix display. In addition, as a pattern variably displayed on the general map display unit 38a, a configuration in which a plurality of types of characters are variably displayed, a configuration in which a plurality of types of symbols are variably displayed, a configuration in which a plurality of types of characters are variably displayed, or A configuration in which a plurality of colors are switched and displayed is conceivable.

  In the universal map unit 38, a universal map hold display section 38b is provided at a position adjacent to the universal map display section 38a. A maximum of four game balls won in the through gate 35 are reserved, and the number of the reserved balls is displayed by turning on the general-purpose display unit 38b.

  A lottery is performed with the winning of the first working port 33 or the second working port 34 as a trigger. The lottery result is clearly shown through display effects in the symbol display device 41 of the special figure unit 37 and the variable display unit 36.

  Specifically, the special figure unit 37 is provided with a special figure display unit 37a. The display area of the special figure display unit 37 a is narrower than the display surface 41 a of the symbol display device 41. In the special figure display part 37a, a winning change to the first working port 33 or a winning to the second working port 34 is used as a trigger, and a lottery is performed to display a variation display or a predetermined display. Then, a result corresponding to the lottery result is displayed. In addition, although the special figure display part 37a is comprised by the segment display by which several segment light emission parts are arranged in the predetermined | prescribed aspect, it is not limited to this, A liquid crystal display device, an organic electroluminescence display device , Or other types of display devices such as CRT or dot matrix display. In addition, as a picture displayed on the special figure display unit 37a, a configuration in which a plurality of types of characters are displayed, a configuration in which a plurality of types of symbols are displayed, a configuration in which a plurality of types of characters are displayed, or a plurality of types of colors A configuration in which is displayed is conceivable.

  In the special figure unit 37, a special figure holding display part 37b is provided at a position adjacent to the special figure display part 37a. A maximum of four game balls won in the first operation port 33 or the second operation port 34 are reserved, and the reserved number is displayed by lighting the special figure reservation display portion 37b.

  Specifically, the symbol display device 41 is configured as a liquid crystal display device including a liquid crystal display, and the display content is controlled by a display control device described later. The symbol display device 41 is not limited to a liquid crystal display device, and may be another display device having a display screen such as a plasma display device, an organic EL display device, or a CRT, and is a dot matrix display. May be.

  In the symbol display device 41, when a special symbol display unit 37a displays a change or predetermined display of a pattern based on a winning in the first operating port 33 or a winning in the second operating port 34, the symbol is displayed accordingly. A variable display or a predetermined display is performed. For example, on the display surface 41a of the symbol display device 41, three symbol rows of upper, middle, and lower rows are set as a plurality of display areas, and numbers “1” to “9” are attached to the symbol rows. The symbols are scrolled and displayed with the symbols arranged in ascending or descending order. In this scroll display, the scroll display in all the symbol sequences is started first, and the display is switched from the scroll display to the standby display in the order of the upper symbol sequence → the lower symbol sequence → the middle symbol sequence. The process ends with the symbols still displayed. For example, in the game times in which the game result is a jackpot result, a predetermined combination of symbols is stopped and displayed on the active line set in advance on the display surface 41a of the symbol display device 41.

  In addition, the symbol display device 41 performs not only a display effect triggered by winning a prize to the first operating port 33 or the second operating port 34, but also a display effect in the opening / closing execution mode that shifts after winning the winning combination. Is called. In addition, based on the winning in one of the operation ports 33 and 34, the display is started on the special symbol display unit 37a and the symbol display device 41, and until a predetermined result is displayed and ended, the game number is 1 Equivalent to times. Further, the variation display mode of the symbol in the symbol display device 41 is not limited to the above, and is arbitrary, such as the number of symbol columns, the direction of symbol variation display in the symbol column, the number of symbols in each symbol column, etc. Can be appropriately changed. Also, the pattern that is variably displayed on the symbol display device 41 is not limited to the above-described pattern, and for example, only numbers may be variably displayed as the pattern.

  When the big win is won in the winning lottery based on the winning to the first operating port 33 or the winning to the second operating port 34, the mode shifts to an opening / closing execution mode in which the special electric winning device 32 can be won. The special electric prize winning device 32 is provided with a large winning opening (not shown) leading to the back side of the game board 24 and an open / close door 32a for opening and closing the large winning opening. The open / close door 32a is arranged in either a closed state or an open state. Specifically, the open / close door 32a is normally in a closed state in which game balls cannot be won, and can be switched to an open state in which game balls can be won when winning the transition to the open / close execution mode in the internal lottery. It has become. Incidentally, the opening / closing execution mode is a mode that shifts when a hit result is obtained. Note that, in the closed state, winning may not be impossible, but it may be configured such that winning is less likely to occur than in the open state.

  FIG. 4 is an explanatory diagram for explaining a configuration relating to the discharge of the game ball that has flowed down the game area PA.

  As already described, the game balls that have entered the general winning opening 31, the special prize winning device 32, the first operating opening 33, the second operating opening 34, and the out opening 24a are discharged from the gaming area PA. In other words, the game ball that is launched from the game ball launching mechanism 27 and flows into the game area PA is any one of the general winning port 31, the special prize winning device 32, the first operating port 33, the second operating port 34, and the out port 24a. By entering the ball, the game area PA is discharged. A game ball that has entered any of the general winning port 31, the special prize winning device 32, the first operating port 33, the second operating port 34, and the out port 24a is guided to the back side of the game board 24.

  On the back side of the game board 24, discharge passage portions 42 to 48 are formed in correspondence with the general winning port 31, the special electricity winning device 32, the first operating port 33, the second operating port 34, and the out port 24a, respectively. . The game balls that have flowed into the discharge passage portions 42 to 48 flow down through the discharge passage portions 42 to 48 that have flowed in, and are led to the lower end portion of the game board 24 on the back side of the game board 24, and become a discharge ball collection portion (not shown). Collected. Then, the game balls collected by the discharge ball collection unit are discharged to the ball circulation device of the island facility where the pachinko machine 10 is installed in the game hall.

  Various detection sensors 42a to 48a for detecting game balls are provided in the respective discharge passage portions 42 to 48. The discharge passage portions 42 to 48 and the detection sensors 42a to 48a will be described below. Since the four general winning ports 31 are provided as described above, the discharge passage portions 42 to 44 exist corresponding to each of the four. In this case, one detection sensor 42a is provided for each of the first discharge passage portion 42 corresponding to the leftmost general winning opening 31 and the second discharge passage portion 43 corresponding to the right general winning opening 31. 43a is provided. Specifically, the first winning port detection sensor 42 a is provided so that the detection range exists in the middle of the first discharge passage 42, and the detection range is in the middle of the second discharge passage 43. A second winning opening detection sensor 43a is provided so as to exist. A game ball that has entered the leftmost general winning opening 31 is detected by the first winning opening detection sensor 42a in the middle of passing through the first discharge passage portion 42, and a game that has entered the general winning opening 31 on the right side of the game is entered. The ball is detected by the second winning port detection sensor 43a while passing through the second discharge passage portion 43. Further, a third discharge passage portion 44 formed so as to join the two general winning ports 31 on the right side at a midway position is provided. The third discharge passage portion 44 has an inlet side region corresponding to each of the two general winning ports 31, and has one outlet side region by joining the inlet side regions in the middle. doing. A third winning port detection sensor 44a is provided so that a detection range exists in the middle of the exit side region in the third discharge passage portion 44. A game ball that has entered one of the two general winning ports 31 on the right side is detected by the third winning port detection sensor 44 a while passing through the third discharge passage portion 44.

  Corresponding to the special electric prize winning device 32, a fourth discharge passage portion 45 exists. A special electric detection sensor 45 a is provided so that a detection range exists in the middle of the fourth discharge passage portion 45, and a game ball that has entered the special electric prize device 32 is in the middle of passing through the fourth discharge passage portion 45. It is detected by the special electricity detection sensor 45a. A fifth discharge passage portion 46 exists corresponding to the first working port 33. A first operation port detection sensor 46a is provided so that a detection range exists in the middle of the fifth discharge passage portion 46, and a game ball that has entered the first operation port 33 passes through the fifth discharge passage portion 46. In the middle of passing, it is detected by the first working port detection sensor 46a. A sixth discharge passage portion 47 exists corresponding to the second working port 34. A second operation port detection sensor 47a is provided so that a detection range exists in the middle of the sixth discharge passage portion 47, and a game ball that has entered the second operation port 34 passes through the sixth discharge passage portion 47. In the middle of passing, it is detected by the second working port detection sensor 47a. A seventh discharge passage portion 48 exists corresponding to the out port 24a. An out-port detection sensor 48 a is provided so that a detection range exists in the middle of the seventh discharge passage portion 48, and a game ball that has entered the out-port 24 a passes through the seventh discharge passage portion 48. It is detected by the outlet detection sensor 48a.

  In addition, the game ball which became a detection target by any one detection sensor 42a-48a among the various detection sensors 42a-48a does not become a detection target of the other detection sensors 42a-48a. A gate detection sensor 49a is also provided for the through gate 35, and a game ball passing through the through gate 35 in the middle of flowing down the game area PA is detected by the gate detection sensor 49a.

  As the various detection sensors 42a to 49a, electromagnetic induction type proximity sensors are used, but any sensor can be used as long as it can individually detect game balls. The various detection sensors 42 a to 49 a are electrically connected to a main control device 60 described later, and the detection results of the various detection sensors 42 a to 49 a are output to the main control device 60. Specifically, the various detection sensors 42a to 49a output a LOW level signal in a situation where a game ball is not detected, and an HI level signal in a situation where a game ball is detected. Note that the present invention is not limited to this, and the relationship between HI and LOW may be reversed.

  As shown in FIG. 2, the front door frame 14 is provided so as to cover the entire front side of the inner frame 13 in which the game board 24 having the above configuration is attached to the resin base 21. As shown in FIG. 1, the front door frame 14 is formed with a window portion 51 so that almost the entire game area PA can be viewed from the front. The window part 51 has a substantially elliptical shape, and the window panel 52 is fitted therein. The window panel 52 is formed of colorless and transparent with glass, but is not limited to this, and may be formed of colorless and transparent with synthetic resin. The game area PA is defined through the window panel 52 from the front of the pachinko machine 10. As long as it is visible, it may be colored and transparent.

  A display light emitting unit 53 is provided above the window unit 51. In addition, a pair of left and right speaker portions 54 that output sound effects according to the gaming state are provided. Further, below the window portion 51, an upper bulging portion 55 and a lower bulging portion 56 that bulge to the near side are arranged in parallel vertically. An upper plate 55a that opens upward is provided inside the upper bulge portion 55, and a lower plate 56a that also opens upward is provided inside the lower bulge portion 56. The upper plate 55a has a function of temporarily storing game balls paid out from a payout device described later and guiding them to the game ball launching mechanism 27 side while aligning them in a row. In addition, the lower tray 56a has a function of storing game balls that are surplus in the upper tray 55a.

  Next, the configuration on the back side of the gaming machine main body 12 will be described.

  As shown in FIG. 2, a main controller 60 that controls the main game is mounted on the back of the inner frame 13 (specifically, the game board 24). The main control device 60 includes a main control board 61 accommodated in a board box 60a. In addition, you may provide the trace structure for giving the trace means for leaving the trace of the opening to the board | substrate box 60a, or leaving the trace of the open. As the trace means, a plurality of case bodies constituting the substrate box 60a are unseparably coupled, and a configuration of a coupling portion that requires destruction of a predetermined part at the time of separation, or an adhesive layer remains on an adhesion target at the time of peeling off. A configuration is conceivable in which a seal seal that leaves a trace of being peeled is pasted so as to straddle the boundaries between a plurality of case bodies. Moreover, as a trace structure, the structure which apply | coats an adhesive agent with respect to the boundary between the some case bodies which comprise the board | substrate box 60a can be considered.

  The back pack unit 15 is installed so as to cover the back side of the inner frame 13 including the main controller 60. The back pack unit 15 includes a back pack 72 formed of a synthetic resin having transparency, and a payout mechanism portion 73 and a control device assembly unit 74 are attached to the back pack 72.

  The payout mechanism unit 73 includes a tank 75 in which game balls supplied from the island equipment of the game hall are sequentially replenished, and a payout device 76 for paying out the game balls stored in the tank 75. The game balls paid out from the payout device 76 are discharged to the upper plate 55a or the lower plate 56a through a payout passage provided on the downstream side of the payout device 76. The payout mechanism unit 73 is provided with a backpack substrate having a power switch for performing ON and OFF operations of the power supply, for example, while supplying a main power of AC 24 volts.

  The control device assembly unit 74 generates and outputs predetermined power required by the payout control device 77 having a function of controlling the payout device 76 and various control devices, and is accompanied by an operation of the launch operation device 28 by the player. And a power source / launch control device 78 for controlling the launch of the game ball. The payout control device 77 and the power supply / launch control device 78 are arranged so as to overlap each other so that the payout control device 77 is behind the pachinko machine 10.

<Electric configuration of pachinko machine 10>
FIG. 5 is a block diagram showing an electrical configuration of the pachinko machine 10.

  The main control device 60 includes a main control board 61 that controls the main game and a power failure monitoring board 67 that monitors the power supply. An MPU 62 is mounted on the main control board 61. The MPU 62 incorporates a main side ROM 64, a main side RAM 65, and a management IC 66 in addition to the main side CPU 63 which is an arithmetic processing unit including a control unit and an arithmetic unit. In addition to the above elements, the MPU 62 incorporates an interrupt circuit, a timer circuit, a data input / output circuit, various counter circuits as a random number generator, and the like.

  The main ROM 64 is a memory (that is, non-volatile storage means) that does not require external power supply for storing and holding, such as a NOR flash memory and a NAND flash memory, and is used as a read-only memory. The main ROM 64 stores various control programs executed by the main CPU 63 and fixed value data.

  The main-side RAM 65 is a memory (that is, a volatile storage unit) that requires an external power supply for storage and holding such as SRAM and DRAM, and is used for both reading and writing. The main RAM 65 is capable of random access, and has a faster read time than the main ROM 64 when compared with the same data capacity. The main RAM 65 temporarily stores various data for the execution of the control program stored in the main ROM 64.

  The management IC 66 is a management device that manages the entrance mode of the game ball in the game area PA based on the information supplied from the main CPU 63. Although details will be described later, the management IC 66 grasps the history of entering the game balls into the general winning opening 31, the special prize winning device 32, the first operating opening 33, the second operating opening 34, and the out opening 24a, The frequency of entering the general winning port 31, the special prize winning device 32, the first operating port 33, and the second operating port 34 is determined in accordance with the determined winning history.

  The MPU 62 is provided with an input port and an output port. A power failure monitoring board 67 and a payout controller 77 provided in the main controller 60 are connected to the input side of the MPU 62. The power failure monitoring board 67 is connected to a power source / launch control device 78 having a function of supplying operating power, and the MPU 62 is supplied with operating power via the power failure monitoring board 67.

  Various sensors such as various entrance detection sensors 42 a to 49 a are connected to the input side of the MPU 62. As described above, the various winning detection sensors 42a to 49a are the first winning opening detection sensor 42a, the second winning opening detection sensor 43a, the third winning opening detection sensor 44a, the special electric detection sensor 45a, and the first operation opening detection sensor. 46a, second working port detection sensor 47a, out port detection sensor 48a, and gate detection sensor 49a. Based on the detection results of these entrance detection sensors 42a to 49a, the main CPU 63 determines whether or not to enter each entrance. Further, the main CPU 63 executes various lotteries based on winning in the first operating port 33 and various lotteries based on winning in the second operating port 34.

  A power failure monitoring board 67, a payout control device 77, and a sound emission control device 81 are connected to the output side of the MPU 62. For example, a prize ball command is output to the payout control device 77 based on the fact that a game ball has entered a prize ball-corresponding entrance part corresponding to the payout of a game ball in the entrance part. The Various commands such as a change command, a type command, and an opening command are output to the sound emission control device 81.

  On the output side of the MPU 62, a special electric drive unit 32 b that opens and closes the open / close door 32 a of the special electric prize winning device 32, a general electric drive unit 34 b that opens and closes the electric utility item 34 a of the second operating port 34, A figure unit 37 and a universal figure unit 38 are connected. Incidentally, the special figure unit 37 is provided with a special figure display part 37 a and a special figure holding display part 37 b, all of which are connected to the output side of the MPU 62. Similarly, the universal map unit 38 is provided with a universal map display unit 38 a and a universal map hold display unit 38 b, all of which are connected to the output side of the MPU 62. The main control board 61 is provided with various driver circuits, and the MPU 62 performs drive control of various drive units and various display units through the driver circuits.

  In other words, in the open / close execution mode, the main CPU 63 performs drive control of the special electric drive unit 32b so that the special electric prize winning device 32 is opened and closed. In addition, when the power utility 34a is opened, the main CPU 63 performs drive control of the power drive 34b so that the power utility 34a is opened and closed. In each game round, the main CPU 63 executes display control of the special figure display unit 37a. In addition, when the lottery result indicating whether or not to open the general electric utility 34a is clearly indicated, the main CPU 63 performs display control of the normal display portion 38a. In addition, when a winning in the first working port 33 or the second working port 34 occurs, or when a variable display is started in the special figure display unit 37a, the main CPU 63 performs display control of the special figure holding display unit 37b. Is executed, and when the winning display to the through gate 35 occurs, or when the variable display is started in the general map display unit 38a, the display control of the general map hold display unit 38b is executed in the main CPU 63.

  The power failure monitoring board 67 relays between the main control board 61 and the power source / launch control device 78 and monitors a DC stable voltage of 24 volts, which is the maximum voltage output from the power source / launch control device 78. The payout control device 77 performs payout control of prize balls and rental balls by the payout device 76 based on the prize ball command received from the main control device 60.

  The power / launch control device 78 is connected to, for example, a commercial power source (external power source) in a game hall or the like. And based on the external electric power supplied from the commercial power supply, necessary operating power is generated for each of the main control board 61, the payout control device 77, etc., and the generated operating power is supplied. Incidentally, the power supply / launch control device 78 is provided with a power supply unit for power interruption such as a backup capacitor. Power for storing and holding is supplied to the main side RAM 65 and the payout control device 77 of the control device 60. In addition, the power source / launch control device 78 is responsible for launch control of the game ball launch mechanism 27, and the game ball launch mechanism 27 is driven when predetermined launch conditions are met.

  The sound emission control device 81 controls the display control device 82 while driving and controlling the display light emitting portion 53 and the speaker portion 54 provided on the front door frame 14 based on various commands received from the main control device 60. It is. The display control device 82 executes display control of the symbol display device 41 based on the command received from the sound emission control device 81.

<Electrical configuration for performing various lotteries in the main CPU 63>
Next, an electrical configuration for performing various lotteries in the main CPU 63 will be described with reference to FIG.

  The main CPU 63 uses various counter information during the game to perform jackpot occurrence lottery, setting of display of the special symbol display unit 37a, setting of symbol display of the symbol display device 41, setting of display of the general symbol display unit 38a, etc. More specifically, as shown in FIG. 6, the winning random number counter C1 used for the winning lottery, the big hit type counter C2 used for determining the big hit type, and the symbol display device 41 fluctuate. The reach random number counter C3 used for the reach generation lottery, the random number initial value counter CINI used for setting the initial value of the hit random number counter C1, the display duration in the special figure display unit 37a and the symbol display device 41 are determined. The fluctuation type counter CS is used. Further, the utility power release counter C4 used for the lottery to determine whether or not the utility power item 34a of the second working port 34 is set to the utility power release state is used. The counters C1 to C3, CINI, CS, and C4 are provided in various counter areas 65b of the main RAM 65.

  Each of the counters C1 to C3, CINI, CS, and C4 is a loop counter that adds 1 to the previous value every time it is updated and returns to “0” after reaching the maximum value. Each counter is updated at short intervals. Information corresponding to the winning random number counter C1, the big hitting type counter C2 and the reach random number counter C3 is provided as acquisition information storage means in the main RAM 65 when a winning to the first operating port 33 or the second operating port 34 occurs. Stored in the reserved storage area 65a.

  The holding storage area 65a includes a holding area RE and an execution area AE. The holding area RE includes a first holding area RE1, a second holding area RE2, a third holding area RE3, and a fourth holding area RE4. In the winning history to the first operating port 33 or the second operating port 34, In addition, combinations of numerical information of the hit random number counter C1, the big hit type counter C2, and the reach random number counter C3 are stored as hold information in any of the hold areas RE1 to RE4.

  In this case, in the first reservation area RE1 to the fourth reservation area RE4, when a winning to the first operation port 33 or the second operation port 34 occurs continuously a plurality of times, the first reservation area RE1 → second Each numerical information is stored in time series in the order of the reserved area RE2 → the third reserved area RE3 → the fourth reserved area RE4. By providing the four holding areas RE1 to RE4 as described above, up to four game balls winning histories to the first operating port 33 or the second operating port 34 are stored and stored. .

  Note that the number that can be reserved and stored is not limited to four, but may be any other number such as two, three, or five or more.

  The execution area AE is an area for moving each numerical information stored in the first holding area RE1 of the holding area RE when starting the variable display of the special figure display section 37a, and starting one game round At this time, determination of success or failure is performed based on various numerical information stored in the execution area AE.

  Each of the counters will be described in detail.

  First, the general electric utility release counter C4 will be described. For example, the utility power release counter C4 is incremented by 1 in the range of 0 to 250 and returns to “0” after reaching the maximum value. The general electric utility release counter C4 is periodically updated and stored in the general electric power holding area 65c of the main RAM 65 at the timing when a game ball wins the through gate 35. Then, at a predetermined timing, a lottery is performed as to whether or not to control the general utility 34a to the open state based on the stored value of the general utility release counter C4.

  In the pachinko machine 10, a plurality of types of support modes are set so that the modes of support by the electric utility 34 a are different from each other. Specifically, in the support mode, when compared to the game area PA in a situation where the game ball is continuously being fired in the same manner, the utility object 34a of the second working port 34 is released per unit time. The high frequency support mode and the low frequency support mode are set so that the frequency of the state becomes relatively high and low.

  In the high frequency support mode and the low frequency support mode, the probability of winning the electric power open state in the electric power open lottery using the electric power utility opening counter C4 is the same (for example, both 4/5). In the high frequency support mode, the number of times that the power utility 34a is in the open state is set more frequently than in the low frequency support mode, and one open time is set longer. Has been. In this case, in the high frequency support mode, when the open state of the public electric power is selected and the open state of the general electric utility 34a is generated a plurality of times, from the end of one open state to the start of the next open state. The closing time is set shorter than one opening time. Furthermore, in the high frequency support mode, the minimum reserved time (i.e., the normal map) is required for the next open train lottery after the first open train lottery than in the low frequency support mode. The display duration time for the display unit 38a is set short.

  As described above, in the high frequency support mode, the probability of winning a prize to the second operating port 34 is higher than in the low frequency support mode. In other words, in the low frequency support mode, there is a higher probability of winning the first operating port 33 than in the second operating port 34, but in the high frequency support mode, the second operation is performed more than in the first operating port 33. The probability of winning a prize in the mouth 34 is increased. When a winning is made to the second operation port 34, a predetermined number of game balls are paid out. Therefore, in the high frequency support mode, the player plays a game while not reducing the number of possessed balls so much. It can be carried out.

  Note that the configuration for increasing the frequency at which the high frequency support mode is set to the normal power open state per unit time as compared to the low frequency support mode is not limited to the above, for example, in the general power open lottery It is good also as a structure which raises the probability that it will be elected in an open state of a public train. In addition, a reserved time (for example, executed in the general map display unit 38a based on a winning to the through gate 35) is secured after the next public train opening lottery is performed. In a configuration in which a plurality of types of variable display time) are prepared, the high frequency support mode is set so that a short securing time is easily selected or the average secure time is shorter than the low frequency support mode. Also good. Furthermore, increase the number of times of opening, lengthen the opening time, and shorten the reserved time that will be secured when the next public train opening lottery is performed after the first public train opening lottery is performed, the reserved time concerned The advantage of the high-frequency support mode over the low-frequency support mode may be increased by applying any one condition or any combination of conditions among shortening the average time and increasing the winning probability.

  Next, the winning random number counter C1 will be described. For example, the winning random number counter C1 is incremented by 1 within a range of 0 to 599, and returns to “0” after reaching the maximum value. In particular, when the winning random number counter C1 makes one round, the value of the initial random number counter CINI at that time is read as the initial value of the winning random number counter C1. The random number initial value counter CINI is a loop counter similar to the winning random number counter C1 (value = 0 to 599). The winning random number counter C1 is periodically updated and stored in the holding storage area 65a of the main RAM 65 at the timing when the game ball wins the first operation port 33 or the second operation port 34.

  The value of the random number for winning the jackpot is stored in the main ROM 64 as a success / failure table. As the success / failure table, a success / failure table for the low probability mode and a success / failure table for the high probability mode are set. That is, in the pachinko machine 10, the low probability mode and the high probability mode are set as the lottery modes in the success / failure lottery means.

  In the gaming state in which the winning / failing table for the low probability mode is referred to at the time of the lottery, the number of random numbers that win the jackpot is two. On the other hand, in the gaming state in which the winning / failing table for the high probability mode is referred to at the time of the lottery, the number of random numbers that will win the jackpot is 20. If the winning probability in the high probability mode is higher than that in the low probability mode, the number of random numbers to be won is arbitrary.

  The jackpot type counter C2 is incremented one by one within the range of 0 to 29, and returns to “0” after reaching the maximum value. The jackpot type counter C2 is periodically updated and stored in the holding storage area 65a at the timing when the game ball wins the first operating port 33 or the second operating port 34.

  In the pachinko machine 10, a plurality of jackpot results are set. The plurality of jackpot results are as follows: (1) a mode of opening / closing control of the special prize winning device 32 in the opening / closing execution mode, (2) a lottery mode in the winning lottery means after the opening / closing execution mode ends, and (3) a second after the opening / closing execution mode ends. A plurality of jackpot results are set by making a difference in the three conditions of the support mode in the general electric utility 34a of the two operation ports 34.

  As an aspect of the opening / closing control of the special electricity prize winning device 32 in the opening / closing execution mode, the occurrence frequency of winning in the special electricity prize winning device 32 from the start to the end of the opening / closing execution mode is relatively high. A frequency winning mode and a low frequency winning mode are set. Specifically, in any of the high-frequency winning mode and the low-frequency winning mode, the game is executed with a predetermined number of round games as an upper limit.

  Here, the round game is continued until either one of a predetermined upper limit continuation time elapses and a predetermined upper limit number of game balls win the special electric prize winning device 32 is satisfied. It is a game to play. In addition, the number of round games in the opening / closing execution mode triggered by the jackpot result is the same for a fixed number of rounds regardless of the type of jackpot result triggered by the transition. Specifically, the upper limit number of round games is set to 15 rounds regardless of which jackpot result is obtained.

  Moreover, in this pachinko machine 10, a plurality of types of opening modes of the special electricity prize winning device 32 are set with different opening durations from when the special electricity prize winning device 32 is opened until it is closed. Specifically, a long-time mode set to 29 sec, which is a long open duration, and a short-time mode set to 0.06 sec, which is a short duration shorter than the above long time, are set. Has been.

  In the pachinko machine 10, when the launch operation device 28 is operated by the player, the game ball launching mechanism 27 is driven and controlled so that one game ball is launched toward the game area PA every 0.6 sec. Is done. In the round game, the upper limit number of end conditions is set to nine. Then, in the long time mode among the above open modes, the open duration time is set longer than the product of the game ball firing period and one round game. On the other hand, in the short-time mode, an opening continuation time is set that is shorter than the product of the game ball launch cycle and one round game, more specifically, shorter than the game ball launch cycle. Therefore, when the opening is performed once in the long-time mode, it is expected that the special electric prize winning device 32 will receive the maximum number of winnings in one round game. When the number of times is released, it is expected that no prize will be given to the special electric prize winning device 32 or that there will be about one even if a prize is generated.

  In the high-frequency winning mode, the special electric prize winning device 32 is opened once in a long-time manner in each round game. On the other hand, in the low-frequency winning mode, the special prize winning device 32 is opened once in each round game in a short time mode.

  In addition, the number of times of opening / closing the special electric prize device 32 in the high frequency winning mode and the low frequency winning mode, the number of round games, the opening duration for one opening, and the upper limit number in one round game are those in the high frequency winning mode. However, the value is not limited to the above value as long as the occurrence frequency of the winning to the special electricity winning device 32 is higher than the low-frequency winning mode until the opening / closing execution mode starts and ends. It is.

  The game result distribution destination for the big hit type counter C2 is stored in the main ROM 64 as a distribution table. And as such a distribution destination, a low probability big hit result, a low winning high probability big hit result, and the most advantageous big hit result are set.

  The low probability big hit result is a big hit result in which the open / close execution mode becomes the high-frequency winning mode, and after the open / close execution mode ends, the win / fail lottery mode becomes the low probability mode and the support mode becomes the high frequency support mode. However, the high-frequency support mode shifts to the low-frequency support mode when the number of games reaches the end reference number (specifically, 100 times) after the shift.

  The low-winning high-probability jackpot result is a jackpot result in which the opening / closing execution mode becomes the low-frequency winning mode, and after the opening / closing execution mode ends, the success / failure lottery mode becomes the high probability mode and the support mode becomes the high-frequency support mode. is there. These high-probability mode and high-frequency support mode are continued until the lottery result in the success / failure lottery becomes a big hit state win and shifts to the big win state by that.

  The most advantageous jackpot result is a jackpot result in which the opening / closing execution mode becomes the high-frequency winning mode, and after the opening / closing execution mode ends, the winning / raising lottery mode becomes the high probability mode and the support mode becomes the high-frequency support mode. These high-probability mode and high-frequency support mode are continued until the lottery result in the success / failure lottery becomes a big hit state win and shifts to the big win state by that.

  Note that the normal game state in relation to each of the above-described game states refers to a state in which the success / failure lottery mode is the low probability mode and the support mode is the low frequency support mode, not the open / close execution mode. Moreover, it is good also as a structure in which the low prize-winning high probability hit result is not set as a game result. Further, in the opening / closing execution mode in the low winning and winning big hit result, the number of round games may be smaller than in the case of the low winning big hit result and the most advantageous big hit result.

  In the distribution table, among the values of the big hit type counter C2 of “0 to 29”, “0 to 9” corresponds to the low probability big hit result, and “10 to 14” corresponds to the low winning high probability big hit result. “15 to 29” corresponds to the most favorable jackpot result.

  Next, the reach random number counter C3 will be described. The reach random number counter C3 is, for example, incremented by 1 within a range of 0 to 238, and returns to “0” after reaching the maximum value. Here, in the pachinko machine 10, an expected effect is set as a kind of display effect in the symbol display device 41. The expected effect includes a symbol display device 41 that can display a variation of symbols, and in a gaming machine in which a final stop result is an assignment corresponding result in a game round that results in a predetermined jackpot result, the symbol display device 41 This is a display state for making the player think that it is a variable display state that is likely to be the above-mentioned giving correspondence result at the stage before the stop result is derived and displayed after the symbol variable display is started. In addition, about the provision corresponding | compatible result, the combination of the symbol to which the same number was attached | subjected on one of the effective lines is stopped and displayed.

  In the expected effect, two types of reach display and a notice display for expecting the occurrence of reach display and the generation of the corresponding result at the stage before the reach display occurs are set.

  In the reach display, a combination of reach symbols is displayed by displaying symbols for a part of a plurality of symbol sequences displayed on the display surface 41a of the symbol display device 41, and the remaining combinations in that state are displayed. A display state in which a variable display of symbols is displayed in the symbol row is included. In addition, in the state where the combination of reach symbols is displayed as described above, the variation of the symbols is displayed in the remaining symbol rows, and a predetermined character or the like is displayed as a moving image on the background screen, and the reach effect is performed. In addition, there are those that perform a reach effect by displaying a predetermined character or the like as a moving image on substantially the entire display surface 41a after reducing or not displaying a combination of reach symbols.

  The notice display includes a plurality of symbol strings in a situation where symbols are variably displayed in all symbol columns after the symbol variable display is started on the display surface 41a of the symbol display device 41. In the situation where the symbols are variably displayed in the symbol row, a mode in which the character is displayed separately from the symbols on the symbol row is included. Moreover, what makes a background screen the predetermined aspect different from the previous aspect, and what makes the symbol on a symbol row the predetermined aspect different from the previous aspect are also included. Such a notice display can occur in any game times when reach display is performed and when reach display is not performed, but the case where reach display is performed is higher than the case where reach display is not performed. Set to occur with probability.

  The reach display is executed regardless of the value of the reach random number counter C3 in the game times in which the combination of the same symbols is finally stopped. In addition, the game times corresponding to the jackpot result in which the same symbol combination is not stopped and displayed are not executed regardless of the value of the reach random number counter C3. Further, in the game times corresponding to the losing result, it is executed when the reach random number counter C3 acquired at a predetermined timing with reference to the reach table stored in the main ROM 64 corresponds to the occurrence of reach display. .

  On the other hand, the determination as to whether or not to perform the notice display is performed not by the main controller 60 but by the sound emission controller 81. In this case, the sound emission control device 81 is more prone to generate a notice display in the game times corresponding to any of the jackpot results than the game times corresponding to the miss results, and displays a notice display with a low appearance rate. A lottery process for displaying a notice is executed so as to satisfy at least one of the conditions of being easily generated. Incidentally, the lottery result is reflected when the game display effect is executed on the symbol display device 41.

  Next, the variation type counter CS will be described. For example, the variation type counter CS is incremented one by one within a range of 0 to 198, and returns to “0” after reaching the maximum value. The variation type counter CS is used when the main CPU 63 determines the display duration in the special symbol display section 37a and the symbol display duration in the symbol display device 41. The variation type counter CS is updated once every time a normal process to be described later is executed once, and is repeatedly updated even within the remaining time in the normal process. Then, the buffer value of the variation type counter CS is acquired when the variation pattern is determined at the start of variation display in the special symbol display unit 37a and at the time of symbol variation start by the symbol display device 41.

<About the processing configuration of the main CPU 63>
Next, each process executed in order for the main CPU 63 to advance the game will be described. The processing of the main CPU 63 is roughly divided into main processing that is started when the power is turned on, and timer interrupt processing that is started periodically (in this embodiment, at a cycle of 4 msec).

<Main processing>
First, the main process will be described with reference to the flowchart of FIG.

  First, a power-on wait process is executed (step S101). In the power-on wait process, for example, the process waits without progressing to the next process until a predetermined time for wait (specifically 1 sec) elapses after the main process is activated. The operation start and initial setting of the symbol display device 41 are completed during the execution period of the power-on wait process. Thereafter, access to the main RAM 65 is permitted (step S102), and the internal function register of the main CPU 63 is set (step S103).

  Thereafter, it is determined whether or not the RAM erasure switch provided in the power supply / launch control device 78 is manually operated (step S104), and whether or not “1” is set in the power failure flag of the main RAM 65 is determined. Determination is made (step S105). Also, a checksum calculation process for calculating a checksum is executed (step S106), and it is determined whether or not the checksum matches the checksum stored at the time of power-off, that is, the validity of the stored data ( Step S107).

  In the pachinko machine 10, for example, when RAM data is initialized when the power is turned on, such as when a game hall starts business, the power is turned on while the RAM erase switch is pressed. Therefore, if the RAM erase switch is pressed, the process proceeds to step S108. Similarly, when the information on occurrence of power shutdown is not set, or when an abnormality of data stored and held is confirmed by the checksum, the process proceeds to step S108. In step S108, the main RAM 65 is cleared. Thereafter, the process proceeds to step S109.

  On the other hand, if the RAM erase switch has not been pressed, step S109 is executed without executing step S108 on condition that the power failure flag is set to “1” and the checksum is normal. Proceed to In step S109, a power-on setting process is executed. In the power-on setting process, a predetermined area of the main RAM 65 such as initialization of a power failure flag is set to an initial value, and a command corresponding to the current gaming state is transmitted to the sound emission control device 81. In addition, after executing the process of step S109, a recognition process (step S110) for causing the management IC 66 to recognize various information, and a data output for outputting various data to the reader connected to the MPU 62 Processing is executed (step S111). Details of these recognition processing and data output processing will be described later.

  The main CPU 63 is configured to periodically execute the timer interrupt process, but the timer interrupt process is prohibited from occurring at the stage where the main process is started. The state in which the generation of the timer interrupt process is prohibited is canceled at the timing before the process of step S111 is completed and the process of step S112 is executed, and the execution of the timer interrupt process is permitted. As a result, when the supply of operating power to the main CPU 63 is started, the data output process in step S111 is completed, and the timer interrupt process is not executed until the stage before the process in step S112 is started. Therefore, the process for advancing the game in the main CPU 63 is not started until this situation is reached.

  Thereafter, the process proceeds to the remaining process of steps S112 to S115. That is, the main CPU 63 is configured to periodically execute the timer interrupt process, but a remaining time occurs between one timer interrupt process and the next timer interrupt process. The remaining time varies depending on the processing completion time of each timer interrupt process, but the remaining processes in steps S112 to S115 are repeatedly executed using such irregular time. In this regard, it can be said that the remaining processes in steps S112 to S115 are non-periodic processes that are performed irregularly.

  In the remaining process, first, in step S112, an interrupt prohibition setting is performed to prohibit the generation of the timer interrupt process. In the subsequent step S113, a random number initial value updating process for updating the random number initial value counter CINI is executed, and a fluctuation counter updating process for updating the fluctuation type counter CS is executed in step S114. In these update processes, the current numerical information is read from the corresponding counter in the main RAM 65, the process of adding 1 to the read numerical information is executed, and then the process of overwriting the reading source counter is executed. In this case, each counter value is cleared to “0” when it reaches the maximum value. Thereafter, in step S115, an interrupt permission setting for switching from a state in which the generation of timer interrupt processing is prohibited to a state in which the timer interrupt processing is permitted is performed. If the process of step S115 is performed, it will return to step S112 and will repeat the process of step S112-step S115.

<Timer interrupt processing>
Next, timer interrupt processing will be described with reference to the flowchart of FIG. The timer interrupt process is executed periodically (for example, at a cycle of 4 msec).

  First, a power failure information storage process is executed (step S201). In the power failure information storage process, it is monitored whether or not a power failure signal corresponding to the occurrence of power interruption has been received from the power failure monitoring board 67. Become. In the power failure process, “1” is set to the power failure flag of the main RAM 65, and a checksum is calculated and the calculated checksum is stored.

  Thereafter, a lottery random number update process is executed (step S202). In the lottery random number update process, the winning random number counter C1, the big hit type counter C2, the reach random number counter C3, and the universal utility release counter C4 are updated. Specifically, the current numerical information is sequentially read from the hit random number counter C1, the big hit type counter C2, the reach random number counter C3, and the general electric utility release counter C4, and a process of adding 1 to each of the read numerical information is executed. Later, a process of overwriting the reading source counter is executed. In this case, each counter value is cleared to “0” when it reaches the maximum value. Thereafter, in step S203, the random number initial value updating process is executed in the same manner as in step S113, and in step S204, the variation counter updating process is executed in the same manner as in step S114.

  Thereafter, a fraud detection process for monitoring whether or not a predetermined event set as a fraud monitoring target has occurred is executed (step S205). In the fraud detection process, occurrence of a plurality of types of events is monitored, and by confirming that a predetermined event has occurred, “1” is set in the game stop flag provided in the main RAM 65. In the subsequent step S206, it is determined whether or not the progress of the game is stopped by determining whether or not “1” is set in the game stop flag. If a negative determination is made in step S206, the processing after step S207 is executed.

  In step S207, port output processing is executed. In the port output process, when output information is set in the previous timer interrupt process, a process for performing output corresponding to the output information to the various drive units 32b and 34b is executed. For example, when the information for switching the special electric prize winning device 32 to the open state is set, the output of the drive signal to the special electric drive unit 32b is started, and when the information to be switched to the closed state is set. Stops the output of the drive signal. In addition, when the information for switching the general utility 34a of the second working port 34 to the open state is set, output of the drive signal to the general power drive unit 34b is started, and the closed state should be switched to. When the information is set, the output of the drive signal is stopped.

  Thereafter, a reading process is executed (step S208). In the reading process, signals other than the power failure signal and the winning signal are read, and the read information is stored for use in future processing.

  Thereafter, the incoming ball detection process is executed (step S209). In the entrance detection process, signals received from the entrance detection sensors 42a to 49a are read, and based on the read results, the out port 24a, the general winning port 31, the special prize winning device 32, and the first operation port 33 are read. The presence / absence of a ball entering the second working port 34 and the through gate 35 is specified. The details of the incoming ball detection process will be described later.

  Thereafter, a timer update process for updating the numerical information of a plurality of types of timer counters provided in the main RAM 65 is executed (step S210). In this case, the timer counter that is updated by subtracting the stored numerical information is handled in an integrated manner. However, both the updating of the subtracting timer counter and the updating of the adding timer counter are performed collectively. It is good also as a structure.

  Thereafter, a launch control process for controlling the launch of the game ball is executed (step S211). In a situation where the firing operation to the firing operation device 28 is continued, one game ball is fired at 0.6 seconds which is a predetermined firing cycle. In the subsequent step S212, as the input state monitoring process, based on the information read in the reading process in step S208, the disconnection confirmation of each of the ball detection sensors 42a to 49a and the opening confirmation of the gaming machine main body 12 and the front door frame 14 are performed. I do.

  After that, special figure special electric control processing for performing execution control of the game times and execution control of the opening / closing execution mode is executed (step S213). In the special figure special electric control process, when a winning to the first operating port 33 or the second operating port 34 occurs in a situation where the number of the holding information stored in the holding storage area 65a is less than the upper limit number, A process of storing the numerical information of the hit random number counter C1, the big hit type counter C2 and the reach random number counter C3 at the time as the hold information in the hold storage area 65a in time series is executed. Also, in the special figure special electric control process, whether or not the hold information corresponds to the big win is determined on the condition that the hold information is not stored during the game rotation and the opening / closing execution mode and is stored. If it corresponds to the process and the jackpot winning, a distribution determination process for determining which jackpot result the hold information corresponds to is executed. In addition, in the special figure special power control process, not only the success / failure determination process and the distribution determination process, but if the hold information does not correspond to the big win, whether the hold information corresponds to the occurrence of reach. A reach determination process is performed, and a process of selecting a game time duration using the numerical information of the variation type counter CS at that time is executed. Then, the change command including the duration information according to the result of each process and the type command including the game result information are transmitted to the sound emission control device 81, and the pattern in the special figure display unit 37a is displayed. Start the variable display. The sound emission control device 81 receives the change command and the type command, and causes the display light emission unit 53 and the speaker unit 54 to start the effect for game play corresponding to the contents of these commands. Also, the sound emission control device 81 transmits a change pattern command corresponding to the contents of the change command and the type command to the display control device 82. When the display control device 82 receives the variation pattern command, the symbol display device 41 starts the variation display of the symbol corresponding to the content of the variation pattern command. As a result, one game is started.

  In the special figure special electric control process, whether or not it is the end timing of the game time by determining whether or not the duration of the game time determined at the start of the game time has elapsed during the execution of one game time. Determine. When it is the end timing, a process for ending the game round is executed in a state where the display corresponding to the game result is performed. In this case, if the current game time corresponds to the occurrence of any jackpot result, the pattern corresponding to the type of the jackpot result is stopped and displayed on the special figure display unit 37a. When the game times correspond to the losing result, the pattern corresponding to the losing result is stopped and displayed on the special figure display unit 37a. In addition, a final stop command indicating that the game times should be ended is transmitted to the sound emission control device 81. Upon receiving the final stop command, the sound emission control device 81 ends the effect for the current game round in the display light emitting unit 53 and the speaker unit 54. Further, the sound emission control device 81 transmits a final stop command to the display control device 82. The display control device 82 receives the final stop command, and ends the effect for the current game round on the symbol display device 41.

  In the special figure special electric control process, when the result of the game times is a result corresponding to the shift to the opening / closing execution mode, a process for starting the opening / closing execution mode is executed. At the start, an opening command indicating that the opening / closing execution mode is started is transmitted to the sound emission control device 81. In the special figure special electric control process, a process for starting each round game and a process for ending each round game are executed. When the round game is started, the special electricity prize device 32 is opened, and when the round game is finished, the special electricity prize device 32 is closed. In each of these processes, an open command indicating that the round game is started is transmitted to the sound emission control device 81, and a close command indicating that the round game is ended is transmitted to the sound light control device 81. Further, in the special figure special electric control process, when the open / close execution mode is ended, an ending command indicating that is transmitted to the sound emission control device 81. The sound emission control device 81 causes the display light emitting unit 53 and the speaker unit 54 to execute an effect for the opening / closing execution mode in a manner corresponding to various commands received during the opening / closing execution mode. Also, the sound emission control device 81 transmits a command corresponding to the command received during the opening / closing execution mode to the display control device 82. The display control device 82 causes the symbol display device 41 to execute an effect for the opening / closing execution mode in a manner corresponding to various commands received during the opening / closing execution mode. Also, in the special figure special electric control process, when the opening / closing execution mode is ended, the success / failure lottery mode and the support mode after the opening / closing execution mode ends correspond to the type of jackpot result that triggered the execution of the opening / closing execution mode. Execute the process for setting the mode.

  After executing the special figure special electric control process of step S213 in the timer interruption process, the ordinary figure electric power control process is executed (step S214). In the ordinary map / electric power control process, when a winning to the through gate 35 is generated, a process for acquiring the retained information on the ordinary map side is executed and the retained information on the ordinary map side is stored. In addition, a release determination is performed on the hold information, and a process for performing an effect for a normal diagram is executed using the release determination as a trigger. Further, based on the result of the opening determination, a process for opening and closing the utility wire 34a of the second working port 34 is executed. In this case, if the support mode is the low frequency support mode, the corresponding process is executed, and if the support mode is the high frequency support mode, the corresponding process is executed. In the case of the opening / closing execution mode, even if the immediately preceding support mode is the high frequency support mode, the low frequency support mode is set.

  In the subsequent step S215, based on the processing results of the immediately preceding steps S213 and S214, output information is set for reflecting the increase / decrease number of the hold information related to the special figure display unit 37a in the special figure hold display unit 37b. The output information for reflecting the increase / decrease number of the hold information related to the general map display unit 38a to the general map hold display unit 38b is set. In step S215, the output information for updating the display content of the special figure display unit 37a is set based on the processing results of the immediately preceding steps S213 and S214, and the display content of the general map display unit 38a is set. Set the output information to be updated.

  Thereafter, the contents of the command and signal received from the payout control device 77 are confirmed, and a payout state receiving process for performing a process corresponding to the check result is executed (step S216). In addition, a payout output process for setting a prize ball command as an output target is executed (step S217). Further, an external information setting process for controlling the start and end of the output of the external signal according to the processing results of the various processes executed in the current timer interrupt process is executed (step S218). Thereafter, a management output process for outputting information corresponding to the result of entering the game ball in the game area PA to the management IC 66 is executed (step S219). Details of the management output process will be described later.

  Next, in the main CPU 63, based on the detection results of the respective ball detection sensors 42a to 49a, the out port 24a, the general winning port 31, the special prize winning device 32, the first operating port 33, the second operating port 34, and the through A configuration for specifying whether or not a game ball has entered the gate 35 will be described. FIG. 9 is an explanatory diagram for explaining a configuration in which detection results of the entrance detection sensors 42 a to 49 a are input to the main CPU 63.

  The main CPU 63 is provided with an input port 63a. The input port 63a is configured as an 8-bit parallel interface so that eight types of signals can be handled simultaneously. An area for storing “0” or “1” information according to the voltage of each signal is provided in a one-to-one correspondence with each terminal. That is, the area includes 0th bit D0 to 7th bit D7. Further, more than eight types of signals are input to the input port 63a. In order to limit the number of simultaneously input targets to eight types, a signal group to be input to the input port 63a depends on the driver IC. It is switched through switching control.

  In the ball entry detection process (step S209) of the timer interrupt process (FIG. 8), a signal group to be input to the input port 63a is set as a signal group from each of the ball entry detection sensors 42a to 49a. In such a situation, the 0th bit D0 stores information corresponding to the detection signal from the first winning port detection sensor 42a, and the first bit D1 corresponds to the detection signal from the second winning port detection sensor 43a. The second bit D2 stores information corresponding to the detection signal from the third prize opening detection sensor 44a, and the third bit D3 stores information corresponding to the detection signal from the special electric detection sensor 45a. The fourth bit D4 stores information corresponding to the detection signal from the first working port detection sensor 46a, and the fifth bit D5 stores information corresponding to the detection signal from the second working port detection sensor 47a. The 6 bit D6 stores information corresponding to the detection signal from the outlet detection sensor 48a, and the seventh bit D7 stores information corresponding to the detection signal from the gate detection sensor 49a. It is.

  Each of the entrance detection sensors 42a to 49a outputs a LOW level signal indicating non-detection as a detection signal when the passage of the game ball is not detected, and detects the passage of the game ball. In this case, an HI level signal indicating that the detection is being performed is output as the detection signal. The input port 63a stores "0" information for the corresponding bit when the LOW level signal is received, and "1" for the corresponding bit when the HI level signal is received. Stores the information. That is, in the situation where the passing of the game ball is not detected in the entrance detection sensors 42a to 49a, information “0” corresponding to the information indicating non-detection is stored for the corresponding bit, and the passing of the game ball is detected. In the detected state, information “1” corresponding to the information indicating that the bit is being detected is stored.

  FIG. 10 is a flowchart showing the incoming ball detection process executed in step S209 of the timer interrupt process (FIG. 8).

  When it is confirmed that the situation in which the information “0” is stored in the 0th bit D0 is switched to the situation in which the information “1” is stored, the first winning opening detection sensor 42a It is determined that a game ball has been detected (step S301: YES). In this case, “1” is set to the first output flag provided in the main RAM 65 (step S302), and the value of the 10 prize ball counter provided in the main RAM 65 is incremented by 1 (step S303). . The first output flag is for the main CPU 63 to specify that information output indicating that one game ball has been detected by the first winning opening detection sensor 42a should be executed to the management IC 66. Flag. The 10 award ball counter is a counter for the main CPU 63 to specify the number of times that 10 game balls should be paid out. When the value of the 10 prize ball counter is 1 or more, 10 prize ball commands are output to the payout control device 77 in the payout output process of step S217 in the timer interrupt process (FIG. 8), and 10 prize balls are given. When the command is output once, the value of the 10 prize ball counter is decremented by 1. When the payout control device 77 receives the 10 prize ball commands, the payout control device 77 drives and controls the payout device 76 so that 10 game balls are paid out.

  When it is confirmed that the situation in which the information of “0” is stored in the first bit D1 is switched to the situation in which the information of “1” is stored, the second winning opening detection sensor 43a receives one It is determined that a game ball has been detected (step S304: YES). In this case, “1” is set to the second output flag provided in the main RAM 65 (step S305), and 1 is added to the value of the 10 prize ball counter provided in the main RAM 65 (step S306). . The second output flag is used for the main CPU 63 to specify that information output indicating that one game ball has been detected by the second prize opening detection sensor 43a should be executed to the management IC 66. Flag.

  When it is confirmed that the situation in which the information of “0” is stored in the second bit D2 is switched to the situation in which the information of “1” is stored, the third winning opening detection sensor 44a It is determined that a game ball has been detected (step S307: YES). In this case, “1” is set to the third output flag provided in the main RAM 65 (step S308), and 1 is added to the value of the 10 prize ball counter provided in the main RAM 65 (step S309). . The third output flag is used for the main CPU 63 to specify that information output indicating that one game ball is detected by the third prize opening detection sensor 44a should be executed to the management IC 66. Flag.

  When it is confirmed that the situation in which the information “0” is stored in the third bit D3 is switched to the situation in which the information “1” is stored, one game ball is detected by the special electricity detection sensor 45a. It determines with having been detected (step S310: YES). In this case, “1” is set to the special electricity prize flag provided in the main RAM 65 (step S311), “1” is set to the fourth output flag provided in the main RAM 65 (step S312), and further The value of the 15 prize ball counters provided in the main RAM 65 is incremented by 1 (step S313). The special power prize flag is a flag for the main CPU 63 to specify that one game ball has entered the special power prize device 32 in the round game in the open / close execution mode. In the special figure special electric control process (step S213) of the timer interruption process (FIG. 8), it is confirmed that “1” is set in the special electric prize winning flag, so that one game ball enters the special electric prize device 32. It is determined that a ball has been generated, and 1 is subtracted from the remaining number of balls that can be entered into the special electric prize device 32 in the round game. When the process of subtracting 1 from the number of balls that can be entered is executed, the special electricity prize flag is cleared to “0”. The fourth output flag is a flag for the main CPU 63 to specify that the information output indicating that one game ball is detected by the special electric detection sensor 45a should be executed to the management IC 66. . The 15 award ball counter is a counter for the main CPU 63 to specify the number of times to pay out 15 game balls. When the value of the counter for 15 prize balls is 1 or more, 15 prize balls are output to the payout control device 77 in the payout output process in step S217 in the timer interrupt process (FIG. 8), and 15 prize balls are given. When the command is output once, the counter value for 15 prize balls is decremented by 1. When the payout control device 77 receives 15 prize ball commands, the payout control device 77 drives and controls the payout device 76 so that 15 game balls are paid out.

  When it is confirmed that the situation in which the information “0” is stored in the fourth bit D4 is switched to the situation in which the information “1” is stored, the first operating port detection sensor 46a detects one It is determined that a game ball has been detected (step S314: YES). In this case, “1” is set to the first operation winning flag provided in the main RAM 65 (step S315), and “1” is set to the fifth output flag provided in the main RAM 65 (step S316). Further, 1 is added to the value of the single prize ball counter provided in the main RAM 65 (step S317). The first operation winning flag is a flag for the main CPU 63 to specify that one game ball has entered the first operation port 33. In the special signal special control process (step S213) of the timer interrupt process (FIG. 8), it is stored in the holding area RE of the holding storage area 65a by confirming that “1” is set in the first operation winning flag. On the condition that the number of reserved information being held is less than the upper limit number of four, processing for newly storing the reserved information is executed. In the special electric special electric control process (step S213), it is confirmed that “1” is set in the first operation winning flag, and when the processing corresponding to the confirmation is executed, the first operation winning flag is cleared to “0”. To do. The fifth output flag is used for the main CPU 63 to specify that the information output indicating that one game ball is detected by the first working port detection sensor 46a should be executed to the management IC 66. Flag. The single prize ball counter is a counter for the main CPU 63 to specify the number of times one game ball should be paid out. When the value of the single prize ball counter is 1 or more, a single prize ball command is output to the payout control device 77 in the payout output process of step S217 in the timer interrupt process (FIG. 8) and one prize ball is obtained. When the command is output once, the value of one prize ball counter is decremented by one. When the payout control device 77 receives a single prize ball command, the payout control device 77 drives and controls the payout device 76 so that one game ball is paid out.

  When it is confirmed that the situation in which the information “0” is stored in the fifth bit D5 is switched to the situation in which the information “1” is stored, the second working port detection sensor 47a It is determined that a game ball has been detected (step S318: YES). In this case, “1” is set to the second operation winning flag provided in the main RAM 65 (step S319), and “1” is set to the sixth output flag provided in the main RAM 65 (step S320). Further, 1 is added to the value of the single prize ball counter provided in the main RAM 65 (step S321). The second operation winning flag is a flag for the main CPU 63 to specify that one game ball has entered the second operation port 34. In the special signal special control process (step S213) of the timer interrupt process (FIG. 8), it is stored in the holding area RE of the holding storage area 65a by confirming that the second operation winning flag is set to “1”. On the condition that the number of reserved information being held is less than the upper limit number of four, processing for newly storing the reserved information is executed. In the special electric special electric control process (step S213), it is confirmed that “1” is set in the second operation winning flag, and when the processing corresponding to the confirmation is executed, the second operation winning flag is cleared to “0”. To do. The sixth output flag is for the main CPU 63 to specify that the information output indicating that one game ball is detected by the second working port detection sensor 47a should be executed to the management IC 66. Flag.

  When it is confirmed that the situation in which the information “0” is stored in the sixth bit D6 is switched to the situation in which the information “1” is stored, one game ball is detected by the out port detection sensor 48a. Is detected (step S322: YES). In this case, “1” is set to the seventh output flag provided in the main RAM 65 (step S323). The seventh output flag is a flag for the main CPU 63 to specify that information output indicating that one game ball has been detected by the outlet detection sensor 48a should be executed to the management IC 66. is there.

  When it is confirmed that the situation in which the information “0” is stored in the seventh bit D7 is switched to the situation in which the information “1” is stored, one game ball is detected by the gate detection sensor 49a. It is determined that it has been detected (step S324: YES). In this case, “1” is set to the gate winning flag provided in the main RAM 65 (step S325). The gate winning flag is a flag for the main CPU 63 to specify that one game ball has entered the through gate 35. In the ordinary power transmission control process (step S214) of the timer interruption process (FIG. 8), it is confirmed that “1” is set in the gate winning flag, so that the normal power stored in the general power reservation area 65c is stored. Processing for storing the current numerical value information of the general utility release counter C4 in the general electric power reservation area 65c as general information holding information on condition that the number of reserved information on the side is less than the upper limit number of four. Execute. It is confirmed that “1” is set in the gate winning flag in the ordinary power control process (step S214), and the gate winning flag is cleared to “0” when the processing corresponding to the confirmation is executed.

  Since the timer interrupt process (FIG. 8) is started at a cycle of 4 msec as described above, when one game ball is detected by one ball detection sensor 42a to 49a, In the situation where the detection of the one game ball is continued by the detection sensors 42a to 49a, the main CPU 63 specifies that one game ball has been detected by the entry detection sensors 42a to 49a. Done. Therefore, it is sufficient to provide one each of the first to seventh output flags.

  Next, processing contents executed by the payout control device 77 will be described. First, the electrical configuration of the payout control device 77 and various devices that communicate with the payout control device 77 will be described with reference to the block diagram of FIG.

  The payout control device 77 includes an MPU 91. The MPU 91 incorporates a payout-side ROM 93, a payout-side RAM 94, an interrupt circuit, a timer circuit, a data input / output circuit and the like in addition to a payout-side CPU 92 that is an arithmetic processing unit including a control unit and a calculation unit.

  The payout-side ROM 93 is a memory (that is, a non-volatile storage unit) that does not require external power supply for storing and holding, such as a NOR flash memory and a NAND flash memory, and is used as a read only. The payout-side ROM 93 stores various control programs executed by the payout-side CPU 92 and fixed value data.

  The payout-side RAM 94 is a memory (that is, a volatile storage unit) that requires an external power supply for storage and holding such as SRAM and DRAM, and is used for both reading and writing. The payout side RAM 94 can be randomly accessed, and when compared with the same data capacity, the payout side RAM 94 requires a faster time for reading than the payout side ROM 93. The payout-side RAM 94 temporarily stores various data for execution of the control program stored in the payout-side ROM 93.

  The payout side CPU 92 can perform bidirectional communication with the main side CPU 63. When the payout side CPU 92 receives a prize ball command from the main side CPU 63, the payout side CPU 92 drives and controls the payout device 76 so that the number of game balls corresponding to the prize ball command is paid out. Further, the payout side CPU 92 monitors whether or not the game ball can be normally paid out, and if the payout side CPU 92 specifies that the game ball cannot be normally discharged, The payout device 76 is stopped even in a situation where the information on the number of unpaid prize balls is stored. Further, the payout side CPU 92 transmits a payout limit command indicating that the payout is not normally possible to the main CPU63. When the main CPU 63 receives the payout restriction command, the symbol display device 41, the display light emitting unit 53, and the speaker unit 54 perform notification indicating that it is not possible to pay out the game balls normally. In this manner, a notification command is transmitted to the sound emission control device 81. As a state where it is not possible to normally pay out game balls, a full state where the lower plate 56a is filled with game balls, a state where no balls are refilled in the tank 75, a state where no balls are replenished, and a payout device 76 There are a payout abnormal state in which the machine does not operate normally, a main body open state in which the gaming machine main body 12 is opened from the outer frame 11, and a front door open state in which the front door frame 14 is opened from the inner frame 13. .

  A full tank detection sensor (not shown) is provided in the middle of the game ball passage leading from the payout device 76 to the lower tray 56a, and the detection result of the full tank detection sensor is input to the payout side CPU 92. The payout side CPU 92 specifies that the game ball is fully filled when the game ball is continuously detected by the full tank detection sensor, and the state where the game ball is continuously detected by the full tank detection sensor is released. In this case, it is determined that the full tank state has been released.

  A ball non-detection sensor (not shown) is provided in the middle of the game ball passage leading from the tank 75 to the payout device 76, and the detection result of the ball non-detection sensor is input to the payout side CPU 92. The payout-side CPU 92 specifies that the game ball is not detected when the game ball is not continuously detected by the ball non-detection sensor, and when the game ball is not continuously detected by the ball detection sensor is released. Identifies that the ballless state has been released.

  The payout device 76 is provided with a payout detection sensor (not shown) for detecting a game ball paid out from the payout device 76, and a detection result of the payout detection sensor is input to the payout side CPU 92. The payout side CPU 92 specifies that one game ball has been paid out from the payout device 76 when a game ball is detected by the payout detection sensor. In addition, the payout side CPU 92 specifies that the payout detection sensor is in a payout abnormal state when the payout detection sensor 76 does not continuously detect the game ball in spite of the drive control of the payout device 76 so that the game ball is paid out. When the state where the game ball is not continuously detected by the payout detection sensor is released, it is determined that the payout abnormality state is released.

  A front door opening sensor 95 is provided on the front surface of the inner frame 13 (see FIG. 2), and the detection result of the front door opening sensor 95 is input to the payout side CPU 92. In this case, when the front door frame 14 is in a closed state with respect to the inner frame 13, the front door opening sensor 95 transmits a closing detection signal to the payout side CPU 92, and the front door frame 14 is in an open state with respect to the inner frame 13. In this case, the front door opening sensor 95 transmits an opening detection signal to the payout side CPU 92. The payout-side CPU 92 specifies that the front door frame 14 is in the closed state when receiving the closing detection signal from the front door opening sensor 95 and receives the opening detection signal from the front door opening sensor 95. It specifies that the front door frame 14 is an open state. The payout side CPU 92 transmits a front door opening command to the main side CPU 63 at the timing when the front door frame 14 is determined to be in the open state from the closed state, and specifies that the front door frame 14 is in the closed state from the open state. At this timing, a front door closing command is transmitted to the main CPU 63. The main CPU 63 specifies that the front door frame 14 has been opened when the front door opening command is received, and specifies that the front door frame 14 has been closed when the front door closing command is received.

  A main body opening sensor 96 is provided on the front surface of the back pack unit 15 (see FIG. 2), and the detection result of the main body opening sensor 96 is input to the payout side CPU 92. In this case, when the gaming machine main body 12 is closed with respect to the outer frame 11, the main body opening sensor 96 transmits a closing detection signal to the payout side CPU 92, and the gaming machine main body 12 is open with respect to the outer frame 11. In some cases, the main body opening sensor 96 transmits an opening detection signal to the payout side CPU 92. The payout-side CPU 92 specifies that the gaming machine main body 12 is in a closed state when a closing detection signal is received from the main body opening sensor 96, and a gaming machine when the opening detection signal is received from the main body opening sensor 96. It is specified that the main body 12 is in an open state. Further, the payout side CPU 92 transmits a main body opening command to the main side CPU 63 at the timing when it is determined that the gaming machine main body 12 is in the open state from the closed state, and specifies that the gaming machine main body 12 is in the closed state from the open state. A main body closing command is transmitted to the main CPU 63 at the timing. The main CPU 63 specifies that the gaming machine main body 12 is in an open state when receiving a main body opening command, and specifies that the gaming machine main body 12 is in a closed state when receiving a main body closing command.

  The timer interrupt process executed by the payout side CPU 92 will be described with reference to the time chart of FIG. The timer interrupt process is repeatedly started at a predetermined cycle (for example, 2 msec).

  First, a full tank process is executed (step S401). In the full tank process, as described above, it is determined whether or not the tank is full based on the detection result of the full tank detection sensor. And a command indicating that the tank is full is transmitted to the main CPU 63. When the full tank state is released, a process for enabling the game ball to be paid out is executed, and a command indicating that the full tank state has been released is transmitted to the main CPU 63.

  Thereafter, a ball useless process is executed (step S402). In the ball-free process, as described above, it is determined whether or not the ball is in the non-ball state based on the detection result of the ball-free detection sensor. At the same time, a command indicating that there is no ball is transmitted to the main CPU 63. In addition, when the no-ball state is released, a process for enabling the game ball to be paid out is executed, and a command indicating that the no-ball state is released is transmitted to the main CPU 63.

  Thereafter, a payout abnormality monitoring process is executed (step S403). In the payout abnormality monitoring process, as described above, it is determined whether or not the payout abnormality state is based on the detection result of the payout detection sensor. At the same time, a command indicating a payout abnormality state is transmitted to the main CPU 63. In addition, when the payout abnormal state is canceled, a process for enabling payout of the game ball is executed, and a command indicating that the payout abnormal state has been canceled is transmitted to the main CPU 63.

  Thereafter, a front door opening monitoring process is executed (step S404). In the front door opening monitoring process, as described above, it is determined whether or not the front door frame 14 is in the open state based on the detection result of the front door opening sensor 95. When the front door frame 14 is in the open state, A process for stopping the payout of game balls is executed, and a front door opening command is transmitted to the main CPU 63. In addition, when the front door frame 14 is closed, a process for allowing the game ball to be paid out is executed, and a front door closing command is transmitted to the main CPU 63.

  Thereafter, the main body opening monitoring process is executed (step S405). In the main body opening monitoring process, as described above, it is determined whether or not the gaming machine main body 12 is in the open state based on the detection result of the main body opening sensor 96. If the gaming machine main body 12 is in the open state, the game ball Is executed, and a main body release command is transmitted to the main CPU 63. Further, when the gaming machine main body 12 is closed, a process for enabling the payout of the game ball is executed, and a main body closing command is transmitted to the main CPU 63.

  Thereafter, a command reading process is executed (step S406). In the command reading process, a process of reading a prize ball command transmitted by the main CPU 63 is executed. Then, the prize ball command is stored in the payout side RAM 94. Then, after executing a prize ball setting process for adding the number corresponding to the received prize ball command to the unpaid prize ball number information in the payout side RAM 94 (step S407), the payout device 76 pays out game balls. The payout control process for performing the execution control is executed (step S408). In the payout control process, when the unpaid prize ball number information stored in the payout side RAM 94 is a value of 1 or more, the payout device 76 is driven and one paying ball is detected by the payout detection sensor. In this case, 1 is subtracted from the value of the prize ball number information. When the value of the prize ball number information becomes “0”, the drive control of the payout device 76 is stopped. Thereafter, an external information setting process for controlling the start and end of the output of the external signal according to the processing results of the various processes executed in the current timer interrupt process is executed (step S409).

  Next, a configuration for externally outputting information from the pachinko machine 10 to the hall computer HC provided in the game hall will be described.

  As shown in FIG. 2, the back pack unit 15 is provided with an external terminal plate 97. The external terminal plate 97 is provided with a large number of external terminals, which are some external terminals and a plurality of external terminals are electrically connected to the main CPU 63 and some external terminals. A plurality of external terminals are electrically connected to the payout side CPU 92. Since the main CPU 63 and the payout CPU 92 are electrically connected to the external terminal plate 97 as described above, the main CPU 63 and the payout CPU 92 send information to the hall computer HC as shown in FIG. It is possible to output.

  One external terminal of the external terminal plate 97 is electrically connected to the front door opening sensor 95, and one external terminal of the external terminal plate 97 is electrically connected to the main body opening sensor 96. In detail, the signal connection board 98 is provided in the middle of the signal path from the front door opening sensor 95 to the payout CPU 92 with regard to the configuration of this electrical connection. The signal relay board 98 is provided with a branch path SL2 branched from the signal path SL1 from the front door opening sensor 95 to the payout CPU 92. The branch path SL2 is connected to an external terminal for opening the front door in the external terminal plate 97. Therefore, an electrical signal corresponding to the detection result of the front door opening sensor 95 is input not only to the payout-side CPU 92 but also to an external terminal for opening the front door on the external terminal plate 97. Thus, a signal indicating whether or not the front door frame 14 is in an open state can be externally output to the hall computer HC without being controlled by the payout side CPU 92.

  In detail, the signal relay board 98 is provided with a branch path SL4 that branches from the signal path SL3 from the main body open sensor 96 to the payout CPU 92. The branch path SL4 is connected to an external terminal for opening the main body of the external terminal plate 97. Therefore, the electrical signal corresponding to the detection result in the main body opening sensor 96 is not only input to the payout side CPU 92 but also input to the external terminal for opening the main body on the external terminal plate 97. As a result, a signal indicating whether or not the gaming machine main body 12 is in an open state can be externally output to the hall computer HC without being controlled by the payout side CPU 92.

  Next, the contents of information output from the main CPU 63 and the payout CPU 92 to the hall computer HC will be described. First, the contents of information output from the main CPU 63 to the hall computer HC will be described.

  In the external information setting process (step S218) in the timer interrupt process (FIG. 8), the main CPU 63 performs output setting of information to each external terminal assigned to the main CPU 63 on the external terminal board 97. As information output from the main CPU 63 to the external terminal board 97, information indicating that the opening / closing execution mode is in progress, information indicating that the support mode is in the high frequency support mode, and one game round is completed. And a predetermined number (for example, 100) of game balls from the game area PA through one of the out port 24a, the general winning port 31, the special winning device 32, the first operating port 33, and the second operating port 34. Information indicating that the game ball has been discharged, information indicating that a game ball has entered the first operation port 33, and information indicating that a game ball has entered the second operation port 34 are included. .

  In the external information setting process (step S409) in the timer interruption process (FIG. 12), the payout side CPU 92 performs output setting of information to each external terminal assigned to the payout side CPU 92 on the external terminal board 97. The information output from the payout side CPU 92 to the external terminal board 97 includes information indicating that 10 game balls have been paid out.

In the hall computer HC, in accordance with various information received from the pachinko machine 10 through the external terminal board 97, it is possible to grasp the execution mode of the game ball payout in the pachinko machine 10. For example,
-A payout rate that is the ratio of the number of game balls paid out until 100 game balls are discharged from the game area PA of the pachinko machine 10-A game play state that is not in the opening / closing execution mode and the high frequency support mode Ball ratio (hereinafter referred to as “B”)
-Number of games played in the opening / closing execution mode-Number of games played in the high frequency support mode-Number of game times executed until 100 game balls are discharged from the game area PA of the pachinko machine 10 "S")
B-S × “the number of winning balls for winning in the first operating port 33 and the second operating port 34”
-Number of game balls that enter the first operating port 33 before 100 game balls are discharged from the game area PA of the pachinko machine 10 (hereinafter, this ratio is referred to as "S1")
The number of game balls that have entered the second operating port 34 before 100 game balls are discharged from the game area PA of the pachinko machine 10 (hereinafter, this ratio is referred to as “S2”).
B- (S1 × “the number of winning balls for winning in the first operating port 33” + S2 × “the number of winning balls for winning in the second operating port 34”)
Etc. are calculated. Thereby, it becomes possible to manage the entrance mode of the game ball in the game area PA of the pachinko machine 10 in the hall computer HC. The number of prize balls is the number of game balls to be paid out when one game ball enters the corresponding entrance part.

<Configuration for managing the winning mode of game balls>
Next, a configuration for managing the winning mode of the game ball using the management IC 66 will be described. First, the electrical configuration of the management IC 66 will be described with reference to the block diagram of FIG.

  As described above, the MPU 62 of the main control device 60 includes the main CPU 63, the main ROM 64, the main RAM 65, and the management IC 66. The MPU 62 includes an I / F 101 and a reading terminal 102 in addition to these.

  The I / F 101 is an interface for transmitting / receiving a signal to / from an external device of the MPU 62. The I / F 101 is electrically connected to the main CPU 63 via the internal bus 103. The detection results from the sensors such as the ball entry detection sensors 42a to 49a and the commands from the payout side CPU 92 are input to the MPU 62 through the input port of the I / F 101, and based on the input detection results and the contents of the commands. As described above, the main CPU 63 executes various processes. As a result of executing various processes by the main CPU 63, when a signal is output to a device such as the special electric drive unit 32b, the signal output is performed through the output port of the I / F 101 and the main side As a result of executing various processes by the CPU 63, when a command output is performed to the payout side CPU 92 and the sound emission control device 81, the command output is performed through the output port of the I / F 101.

  The reading terminal 102 is a terminal for electrically connecting a reading device that is an external device of the pachinko machine 10 to the MPU 62, and is provided so that a connecting terminal portion is exposed on the surface of the MPU 62. . However, as described above, the main control board 61 on which the MPU 62 is mounted is accommodated in the board box 60a, and the reading terminal 102 faces the wall of the board box 60a so as not to be exposed to the outside of the main control apparatus 60. ing. Therefore, in order to electrically connect the reading device to the reading terminal 102, it is necessary to open the substrate box 60a to expose the MPU 62. Thereby, it is possible to prevent the electrical connection of the reading device to the reading terminal 102 from being performed illegally. However, the present invention is not limited to this, and an opening for exposing the reading terminal 102 to the outside of the main controller 60 is formed in the substrate box 60a. The reader 102 may be electrically connected to the terminal 102.

  The management IC 66 includes a management-side I / F 111, a management-side CPU 112, a management-side ROM 113, a management-side RAM 114, an RTC 115, a correspondence relationship memory 116, and a history memory 117. Each of these devices is connected to be capable of bidirectional communication through an internal bus 66a provided in the management IC 66.

  The management-side I / F 111 receives various signals from the main CPU 63 via the signal path group 118 for unidirectional communication built in the MPU 62, and uses the signal path group 119 for unidirectional communication built in the MPU 62. An interface for transmitting various signals to the reading terminal 102 via the interface. Various signals from the main CPU 63 are input to the input port of the management side I / F 111, and various signals to the reading terminal 102 are output from the output port of the management side I / F 111. The main CPU 63 is electrically connected to the reading terminal 102 via a bidirectional signal path group 120 built in the MPU 62.

  The management side CPU 112 is an arithmetic processing device including a control unit and an arithmetic unit. The management ROM 113 is a memory (that is, non-volatile storage means) that does not require external power supply for storing and holding, such as a NOR flash memory and a NAND flash memory, and is used as a read-only memory. The management ROM 113 stores various control programs executed by the management CPU 112 and fixed value data. The management-side RAM 114 is a memory (that is, a volatile storage unit) that requires an external power supply for storing and holding, such as SRAM and DRAM, and is used for both reading and writing. The management-side RAM 114 can be accessed at random, and when compared with the same data capacity, the management-side RAM 114 requires a faster time for reading than the management-side ROM 113. The management-side RAM 114 temporarily stores various data for the execution of the control program stored in the management-side ROM 113.

  The RTC 115 is a real-time clock, and is configured to always measure date information and time information and output the date information and time information being measured in accordance with an instruction from the management CPU 112. The RTC 115 is provided with a backup power source, and it is possible to measure date information and time information even while the pachinko machine 10 is powered off.

  The correspondence relationship memory 116 is a memory (that is, a volatile storage unit) that requires an external power supply for storage retention such as SRAM and DRAM, and is used for both reading and writing. The correspondence memory 116 stores information on the correspondence between the buffers 122a to 122p provided in the input port 121 of the management-side I / F 111 and the types of signals input to the buffers 122a to 122p. Used for Details of the contents of the correspondence memory 116 will be described later.

  The history memory 117 is a memory that does not require external power supply for storing and holding, such as a NOR flash memory and a NAND flash memory (that is, nonvolatile storage means), and is used for both reading and writing. The history memory 117 is used for storing information related to the entry of game balls received from the main CPU 63 through the management-side I / F 111. Details of the contents of the history memory 117 will be described later.

  Next, the configuration of the input port 121 provided in the management side I / F 111 will be described. FIG. 14 is an explanatory diagram for explaining the configuration of the input port 121 of the management-side I / F 111.

  The input port 121 is provided with a plurality of buffers 122a to 122p. Specifically, first to sixteenth buffers 122a to 122p are provided. One type of signal can be input to each of the first to sixteenth buffers 122a to 122p through the signal paths 118a to 118p, and each of the first to sixteenth buffers 122a to 122p is an input target signal. “0” is stored as the first data when the signal is at the LOW level, and “1” information is stored as the second data when the signal to be input is at the HI level. The relationship between LOW and HI and the first data and the second data may be reversed.

  A first signal corresponding to the detection result of the first winning port detection sensor 42a is input to the first buffer 122a. In this case, the main CPU 63 outputs a first signal at the LOW level when no new game ball is detected by the first winning opening detection sensor 42a, and one game is output by the first winning opening detection sensor 42a. When a sphere is detected, a HI level first signal is output for a specific period. This specific period is a period sufficient for the management CPU 112 to specify that the HI level first signal is input to the first buffer 122a.

  A second signal corresponding to the detection result of the second prize opening detection sensor 43a is input to the second buffer 122b. In this case, the main CPU 63 outputs a second signal of the LOW level in a situation where a new game ball is not detected by the second prize opening detection sensor 43a, and one game is outputted by the second prize opening detection sensor 43a. When a sphere is detected, the second signal at the HI level is output for a specific period. This specific period is a period sufficient for the management CPU 112 to specify that the HI level second signal is input to the second buffer 122b.

  A third signal corresponding to the detection result of the third prize opening detection sensor 44a is input to the third buffer 122c. In this case, the main CPU 63 outputs a third signal of the LOW level in a situation where a new game ball is not detected by the third prize opening detection sensor 44a, and one game is outputted by the third prize opening detection sensor 44a. When a sphere is detected, a third signal of HI level is output for a specific period. This specific period is a period sufficient for the management-side CPU 112 to specify that the HI level third signal is input to the third buffer 122c.

  A fourth signal corresponding to the detection result of the special electricity detection sensor 45a is input to the fourth buffer 122d. In this case, the main CPU 63 outputs the fourth signal at the LOW level in a situation where a new game ball is not detected by the special electricity detection sensor 45a, and one game ball is detected by the special electricity detection sensor 45a. HI level fourth signal is output for a specific period. This specific period is a period sufficient for the management CPU 112 to specify that the HI level fourth signal is input to the fourth buffer 122d.

  A fifth signal corresponding to the detection result of the first working port detection sensor 46a is input to the fifth buffer 122e. In this case, the main CPU 63 outputs a fifth signal at the LOW level in a situation where a new game ball is not detected by the first operation port detection sensor 46a, and one game is output by the first operation port detection sensor 46a. When a sphere is detected, the fifth signal at the HI level is output for a specific period. This specific period is a period sufficient for the management-side CPU 112 to specify that the HI level fifth signal is input to the fifth buffer 122e.

  A sixth signal corresponding to the detection result of the second working port detection sensor 47a is input to the sixth buffer 122f. In this case, the main CPU 63 outputs a sixth signal at the LOW level when no new game ball is detected by the second operation port detection sensor 47a, and one game is output by the second operation port detection sensor 47a. When a sphere is detected, a HI level sixth signal is output for a specific period. This specific period is a period sufficient for the management CPU 112 to specify that the HI level sixth signal is input to the sixth buffer 122f.

  A seventh signal corresponding to the detection result of the out-port detection sensor 48a is input to the seventh buffer 122g. In this case, the main CPU 63 outputs a seventh signal at the LOW level when no new game ball is detected by the out port detection sensor 48a, and one game ball is detected by the out port detection sensor 48a. In this case, the seventh signal at the HI level is output over a specific period. This specific period is a period sufficient for the management side CPU 112 to specify that the HI level seventh signal is input to the seventh buffer 122g.

  An eighth signal corresponding to whether or not the open / close execution mode is in progress is input to the eighth buffer 122h. In this case, the main CPU 63 continuously outputs the eighth signal at the LOW level in the situation that is not in the opening / closing execution mode, and continuously outputs the eighth signal at the HI level in the situation that is in the opening / closing execution mode.

  A ninth signal corresponding to whether or not the high frequency support mode is in progress is input to the ninth buffer 122i. In this case, the main CPU 63 continuously outputs the ninth signal at the LOW level when the high frequency support mode is not set, and continuously outputs the ninth signal at the HI level when the high frequency support mode is set.

  A tenth signal corresponding to whether or not the front door frame 14 is being opened is input to the tenth buffer 122j. In this case, the main CPU 63 continuously outputs the LOW level tenth signal when the front door frame 14 is in the closed state, and continues the HI level tenth signal when the front door frame 14 is in the open state. And output.

  The sixteenth buffer 122p receives an output instruction signal for causing the management side CPU 112 to recognize when the history information stored in the history memory 117 is output to the reading terminal 102. In this case, the main CPU 63 outputs a LOW level output instruction signal in a situation where it is not necessary to output history information, and outputs a HI level output instruction signal for a specific period when it is necessary to output history information. To do. This specific period is a period sufficient for the management side CPU 112 to specify that the HI level output instruction signal is input to the sixteenth buffer 122p.

  The eleventh buffer 122k, the twelfth buffer 122l, the thirteenth buffer 122m, the fourteenth buffer 122n, and the fifteenth buffer 122o can receive signals from the main CPU 63, but the pachinko machine 10 does not receive normal signals. It is blank. As described above, by providing a larger number of buffers 122a to 122p than the types of signals output from the main CPU 63 to the management IC 66 in the pachinko machine 10 as the input port 121 of the management I / F 111, It is possible to divert the management IC 66 to a different model from the pachinko machine 10. Thereby, the versatility of the management IC 66 can be enhanced. Incidentally, signal paths 118a to 118p are formed between the main CPU 63 and the first to sixteenth buffers 122a to 122p so as to correspond to the first to sixteenth buffers 122a to 122p on a one-to-one basis. However, the present invention is not limited to this, and the signal paths 118k to 118o may not be formed between the buffers 122k to 122o to be blanked.

  It is determined in the design stage of the management IC 66 that the output instruction signal is input to the sixteenth buffer 122p in the input port 121 of the management-side I / F 111. The management-side CPU 112 receives no instruction from the main-side CPU 63. Can specify that an output instruction signal is input to the sixteenth buffer 122p. On the other hand, what type of signal is input to the first to fifteenth buffers 122a to 122o is not determined at the design stage of the management IC 66, and the type of these signals receives an instruction from the main CPU 63. This is specified by the management CPU 112. Although the details of the types of these signals in the management side CPU 112 will be described later, when control is started in the main side CPU 63 and the management side CPU 112 in accordance with the supply of operating power to the MPU 62, the main side CPU 63 changes to the management side CPU 112. This is done by sending a type identification command. In this case, the information on the types of various signals provided by the type identification command is stored in the correspondence memory 116, and when the various types of signals are specified by the management CPU 112 in a situation where operating power is supplied. Information stored in the correspondence relationship memory 116 is referred to.

  FIG. 15 is an explanatory diagram for explaining the configuration of the correspondence memory 116. The correspondence relationship memory 116 has first to fifteenth correspondence relationship areas 123a to 123o in a one-to-one correspondence with the first to fifteenth buffers 122a to 122o provided in the input port 121 of the management-side I / F 111. Is provided.

  In the first correspondence relationship area 123a, information indicating the general winning opening 31 is stored as information for the management CPU 112 to specify the type of signal input to the first buffer 122a. In addition, information indicating the number of game balls to be paid out when one game ball enters the general prize opening 31 is included in the first correspondence area 123a together with information indicating that the game is a general prize opening 31 (10 pieces). Stored. In the second correspondence area 123b, information indicating the general winning opening 31 is stored as information for specifying the type of signal input to the second buffer 122b by the management CPU 112. The second correspondence area 123b also includes information indicating the number of game balls to be paid out when one game ball enters the general prize opening 31 together with information indicating that the game is a general prize opening 31 (10 pieces). Stored. In the third correspondence area 123c, information indicating the general winning opening 31 is stored as information for the management CPU 112 to specify the type of signal input to the third buffer 122c. In addition, in the third correspondence area 123c, information indicating the number of game balls to be paid out when one game ball enters the general prize opening 31 is included along with information indicating that it is the general prize opening 31 (10 pieces). Stored.

  In the fourth correspondence area 123d, information indicating the special prize winning device 32 is stored as information for the management CPU 112 to specify the type of signal input to the fourth buffer 122d. The fourth correspondence area 123d also includes information indicating that the game is a special prize winning device 32, and information on the number of game balls to be paid out when one game ball enters the special prize winning device 32 (15). Stored. In the fifth correspondence area 123e, information indicating the first working port 33 is stored as information for the management CPU 112 to specify the type of signal input to the fifth buffer 122e. In addition, information indicating the number of game balls to be paid out when one game ball enters the first operation port 33 together with information indicating the first operation port 33 in the fifth correspondence area 123e (one) ) Is also stored. In the sixth correspondence area 123f, information indicating the second working port 34 is stored as information for specifying the type of signal input to the sixth buffer 122f by the management CPU 112. In addition, in the sixth correspondence area 123f, information indicating the number of game balls to be paid out when one game ball enters the second operation port 34 together with information indicating the second operation port 34 (one piece). ) Is also stored. In the seventh correspondence area 123g, information indicating the out port 24a is stored as information for specifying the type of signal input to the seventh buffer 122g by the management CPU 112.

  In the eighth correspondence area 123h, information indicating the open / close execution mode is stored as information for the management CPU 112 to specify the type of signal input to the eighth buffer 122h. In the ninth correspondence area 123i, information indicating the high-frequency support mode is stored as information for the management CPU 112 to specify the type of signal input to the ninth buffer 122i. In the tenth correspondence area 123j, information indicating the front door frame 14 is stored as information for the management CPU 112 to specify the type of signal input to the tenth buffer 122j.

  In the eleventh corresponding relationship area 123k, information indicating a blank that does not correspond to any of them is stored as information for specifying the type of signal input to the eleventh buffer 122k by the management CPU 112. In the twelfth correspondence area 123l, information indicating a blank that does not correspond to any of them is stored as information for specifying the type of signal input to the twelfth buffer 122l by the management CPU 112. In the thirteenth correspondence area 123m, information indicating a blank that does not correspond to any of them is stored as information for specifying the type of signal input to the thirteenth buffer 122m by the management CPU 112. In the fourteenth correspondence area 123n, information indicating a blank that does not correspond to any of them is stored as information for specifying the type of signal input to the fourteenth buffer 122n by the management CPU 112. In the fifteenth corresponding relationship area 123o, information indicating a blank that does not correspond to any of them is stored as information for specifying the type of signal input to the fifteenth buffer 122o by the management CPU 112.

  As described above, the type of signal input to the first to fifteenth buffers 122a to 122o is specified by the management CPU 112 by receiving an instruction from the main CPU 63. The management IC 66 can be used for a different model from the pachinko machine 10. Thereby, the versatility of the management IC 66 can be enhanced.

  In addition, every time a signal corresponding to storage of history information is output to the first to fifteenth buffers 122a to 122o, information for recognizing the signal type is not output, but the signal type is recognized in advance. Information for specifying the type of signal input to the first to fifteenth buffers 122a to 122o based on the output information in the management CPU 112 is stored in the correspondence memory 116. This is a configuration. As a result, each time a signal is output, the first to fifteenth buffers 122a to 122o output information for recognizing the type of the signal each time a signal corresponding to the storage of history information is output. The amount of information output from the side CPU 63 to the management side CPU 112 can be suppressed.

  In addition, the output of information for specifying the type of signal input to the first to fifteenth buffers 122a to 122o by the management CPU 112 is performed when the supply of operating power is started. Thereby, in the situation where a game is started in the pachinko machine 10, the type of signal input to the first to fifteenth buffers 122a to 122o can be specified by the management CPU 112.

  Further, information setting that the output instruction signal is input to the sixteenth buffer 122p is performed at the design stage of the management IC 66. As a result, the type of signal input to the sixteenth buffer 122p is specified for the output instruction signal that is surely used not only for the pachinko machine 10 but also for other types of pachinko machines that use the management IC 66. Therefore, it is possible to omit the processing for this. Therefore, it is possible to suppress the processing load of processing for specifying the type of such signal.

  Next, the history memory 117 of the management IC 66 will be described. FIG. 16 is an explanatory diagram for explaining the configuration of the history memory 117.

  The history memory 117 is provided with a history area 124 for sequentially storing history information. In the history area 124, a plurality of pointer information is set in serial numbers, and a history information storage area 125 is set in correspondence with each pointer information on a one-to-one basis. In the history information storage area 125, a combination of RTC information and correspondence information can be stored. In this case, each history information storage area 125 has a data capacity of 2 bytes, and a 1-byte data capacity is allocated as an area for storing RTC information, and is used as an area for storing correspondence information. A data capacity of 1 byte is allocated. When it becomes necessary to store correspondence information according to the signals input to the first to fifteenth buffers 122a to 122o (actually the first to tenth buffers 122a to 122j of the pachinko machine 10) First, the date information and time information measured in the current RTC 115 are stored in the area for storing the RTC information in the history information storage area 125 corresponding to the pointer information that is the current write target. Thereafter, the corresponding relationship information corresponding to the buffers 122a to 122o that triggered the information storage this time is read from the corresponding relationship areas 123a to 123o corresponding to the buffers 122a to 122o in the corresponding relationship memory 116, and the read corresponding relationship information. Are stored in the area for storing the correspondence information in the history information storage area 125 corresponding to the pointer information that is currently written.

  Specifically, regarding the correspondence information stored in the history information storage area 125, the first to seventh buffers 122a to 122g receive signals corresponding to the detection results of the incoming ball detection sensors 42a to 48a as described above. Therefore, information corresponding to the types of the incoming detection sensors 42a to 48a is stored in the first to seventh correspondence areas 123a to 123g in the correspondence memory 116. More specifically, information corresponding to the type of the entrance portion corresponding to each of the entrance detection sensors 42a to 48a is stored in the first to seventh correspondence areas 123a to 123g. As already described in the pachinko machine 10, the first to third winning opening detection sensors 42 a to 44 a detect game balls that have entered the general winning opening 31. The first to third correspondence areas 123a to 123c corresponding to the detection sensors 42a to 44a each store information indicating that it is the general winning opening 31. The fourth correspondence area 123d stores information indicating that it is the special prize winning device 32, and the fifth correspondence area 123e stores information indicating that it is the first operation port 33. In the sixth correspondence area 123f, information indicating the second operation port 34 is stored, and in the seventh correspondence area 123g, information indicating the out port 24a is stored. When the buffer 122a to 122o that triggered the information storage this time is any one of the first to seventh buffers 122a to 122g, the information on the type of the entrance part corresponding to the buffers 122a to 122g is the first to first buffers 122a to 122g. The information is read from any one of the seventh correspondence relationship areas 123a to 123g, and the read information on the type of the ball-entry part is stored as it is in the area for storing the correspondence information in the history information storage area 125.

  On the other hand, a signal indicating whether or not the eighth buffer 122h is in the open / close execution mode is input, a signal indicating whether or not the ninth buffer 122i is in the high frequency support mode is input, and the tenth buffer 122j is A signal indicating whether or not the front door frame 14 is being opened is input. Therefore, information indicating the open / close execution mode is stored in the eighth correspondence area 123h, information indicating the high frequency support mode is stored in the ninth correspondence area 123i, and the tenth correspondence area Information indicating the front door frame 14 is stored in 123j.

  As described above, the main CPU 63 continuously outputs the eighth signal at the LOW level in the situation that is not in the opening / closing execution mode, and continuously outputs the eighth signal at the HI level in the situation in the opening / closing execution mode. The side CPU 112 specifies that the opening / closing execution mode has started when the eighth signal changes from the LOW level to the HI level, and specifies that the opening / closing execution mode has ended when the eighth signal changes from the HI level to the LOW level. It becomes possible. Then, in both cases where the eighth signal changes from the LOW level to the HI level and when the eighth signal changes from the HI level to the LOW level, the management CPU 112 is triggered to store the correspondence information in the history information storage area 125. Identifies That is, when the eighth signal changes from the LOW level to the HI level, the history information storage area 125 includes not only the information indicating the opening / closing execution mode read from the eighth correspondence area 123h but also the start information. Is stored in the area for storing the correspondence information. Further, when the eighth signal changes from the HI level to the LOW level, not only the information indicating that it is the opening / closing execution mode read from the eighth correspondence area 123h but also the end information together with the history information storage area 125 Is stored in the area for storing the correspondence information.

  As described above, the main CPU 63 continuously outputs the ninth signal at the LOW level in the situation that is not the high frequency support mode, and continuously outputs the ninth signal at the HI level in the situation that is the high frequency support mode. The management CPU 112 identifies that the high frequency support mode has started when the ninth signal changes from LOW level to HI level, and ends the high frequency support mode when the ninth signal changes from HI level to LOW level. It is possible to specify that Then, in both cases where the ninth signal changes from the LOW level to the HI level and when the ninth signal changes from the HI level to the LOW level, the management CPU 112 is triggered to store the correspondence information in the history information storage area 125. Identifies That is, when the ninth signal changes from the LOW level to the HI level, not only the information indicating the high-frequency support mode read from the ninth correspondence area 123i but also the start information together with the history information storage area It stores in the area for storing 125 correspondence information. When the ninth signal changes from the HI level to the LOW level, the history information storage area includes not only the information indicating the high frequency support mode read from the ninth correspondence area 123i but also the end information. It stores in the area for storing 125 correspondence information.

  As described above, the main CPU 63 continuously outputs the LOW level tenth signal when the front door frame 14 is in the closed state, and outputs the HI level tenth signal when the front door frame 14 is in the open state. In order to continuously output, the management side CPU 112 specifies that the front door frame 14 is opened when the tenth signal changes from the LOW level to the HI level, and when the tenth signal changes from the HI level to the LOW level. However, it is possible to specify that the front door frame 14 is closed. The management CPU 112 is triggered to store the corresponding information in the history information storage area 125 both when the tenth signal changes from the LOW level to the HI level and when the tenth signal changes from the HI level to the LOW level. Identifies That is, when the tenth signal changes from the LOW level to the HI level, the history information is stored together with not only the information indicating that it is the front door frame 14 read from the tenth correspondence area 123j but also the opening start information. The correspondence information of the area 125 is stored in the area for storing. Further, when the tenth signal changes from the HI level to the LOW level, history information is stored together with not only the information indicating that it is the front door frame 14 read from the tenth correspondence area 123j but also the opening end information. The correspondence information of the area 125 is stored in the area for storing.

  The history information storage area 125 can store all the history information generated during the ten consecutive business days when game balls are continuously fired in the pachinko machine 10 from opening to closing. It is provided for several minutes. For example, if history information is generated 60000 times a day, 600000 or more history information storage areas 125 are provided. As a result, all history information can be stored and retained in the history memory 117 for at least 10 days.

  The history memory 117 includes a pointer area 126 in addition to the history area 124. The pointer area 126 stores information for the management CPU 112 to specify pointer information that is currently written in the history memory 117. Specifically, at the shipping stage of the pachinko machine 10, information for designating pointer information of “0” as a write target is set in the pointer area 126. Each time one piece of history information is newly stored in the history information storage area 125, the information in the pointer area 126 is updated so that the value of the pointer information to be written is incremented by one. When the history information is stored in the history information storage area 125 corresponding to the last-order pointer information and the last-order pointer information is to be written, the pointer is set so that the pointer information “0” becomes the write-target. The information in the service area 126 is updated. As a result, when there is an opportunity to store history information exceeding the number of storable history information, new history information is overwritten in order from the history information storage area 125 in which old history information is stored. Become.

  Further, when history information is read from the history memory 117 by the reading device, all the history information storage areas 125 are cleared to “0” and pointer information “0” is to be written. The information in the pointer area 126 is updated. As a result, it is possible to prevent history information that has been read once from becoming read again.

  Next, a specific processing configuration for managing the winning mode of the game ball using the management IC 66 will be described. First, a processing configuration for storing information on the correspondence between the first to fifteenth buffers 122a to 122o provided in the input port 121 of the management-side I / F 111 and the signal type in the correspondence memory 116 will be described. FIG. 17 is a flowchart showing the recognition process executed by the main CPU 63. The recognition process is executed in step S110 in the main process (FIG. 7).

  First, “15” is set in the recognition output counter provided in the main RAM 65 (step S501). The recognizing output counter indicates the remaining necessary number of information outputs for causing the management side CPU 112 to recognize which type of signal each buffer 122a to 122p of the input port 121 in the management side I / F 111 corresponds to. This is a counter for the main CPU 63 to specify. As already described, since 15 of the first to fifteenth buffers 122a to 122o are to be recognized as signal types, “15” is set in the recognition output counter.

  Thereafter, an identification start command output process is executed (step S502). The main CPU 63 outputs various commands to the management CPU 112 in order for the management CPU 112 to recognize which type of signal the first to fifteenth buffers 122a to 122o correspond to. When this command is output, the first to eighth signals input to the first to eighth buffers 122a to 122h are used. That is, the first to fifteenth buffers 122a using the first to eighth signals (that is, the first to eighth signal paths 118a to 118h) that are used to instruct the management CPU 112 to store the history information. A command output for causing the management CPU 112 to recognize which kind of signal corresponds to .about.122o is performed. As a result, the number of signal paths can be reduced compared to a configuration in which signal paths for performing the command output are provided separately from the signal paths 118a to 118p for outputting signals to the first to sixteenth buffers 122a to 122p. This makes it possible to simplify the configuration. The identification start command has a data capacity of 8 bits, and data of each bit is input to the first to eighth buffers 122a to 122h as the first to eighth signals, respectively. Further, in the output process of the identification start command, the output state of the ninth signal is switched to the HI level at the timing of starting the output of the identification start command in order to make the management CPU 112 recognize that the new command has been transmitted. The output period of the identification start command and the period of maintaining the output state of the ninth signal at the HI level are set to a period sufficient for the management CPU 112 to recognize the output state of the identification start command and the ninth signal Has been. By receiving the identification start command, the management-side CPU 112 should start processing for storing information on the correspondence relationship between the first to fifteenth buffers 122a to 122o and the signal type in the correspondence relationship memory 116. Identify.

  Thereafter, the type identification command corresponding to the current value of the recognition output counter of the main RAM 65 is read from the main ROM 64 (step S503). In this case, the first buffer 122a becomes the signal type setting target first, and the n + 1th buffer becomes the signal type setting target next to the nth buffer, and then corresponds to the first to fifteenth buffers 122a to 122o. The signal type recognition setting is performed. Accordingly, if the recognition output counter is “15” to “13”, the type identification command indicating the general winning opening 31 and the number of the winning balls is read. If the recognition output counter is “12”, the special electric prize is received. The type identification command indicating the device 32 and the number of prize balls is read. If the recognition output counter is “11”, the type identification command indicating the first operating port 33 and the number of prize balls is read. If the recognition output counter is “10”, it is the second operation port 34 and the type identification command indicating the number of prize balls is read. If the recognition output counter is “9”, it is determined that the output port 24a is. The type identification command is read, and if the recognition output counter is “8”, the type identification command indicating the open / close execution mode is read, and the recognition output counter is read. If “7”, the type identification command indicating the high-frequency support mode is read, and if the recognition output counter is “6”, the type identification command indicating the front door frame 14 is read and the recognition output is output. If the counter is “5” to “1”, a type identification command indicating blank is read.

  Thereafter, output processing of the read type identification command is executed (step S504). The type identification command has an 8-bit data capacity like the identification start command, and data of each bit is input to the first to eighth buffers 122a to 122h as the first to eighth signals, respectively. In the output process of the identification type command, the output state of the ninth signal is switched to the HI level at the timing when the output of the identification type command is started in order to make the management CPU 112 recognize that the new command has been transmitted. The output period of the identification type command and the period of maintaining the output state of the ninth signal at the HI level are set to a period sufficient for the management CPU 112 to recognize the output state of the identification type command and the ninth signal. Has been. By receiving the identification type command, the management-side CPU 112 corresponds to the identification type command in the corresponding relationship areas 123a to 123o corresponding to the buffer to be set this time among the first to fifteenth buffers 122a to 122o. Store information to be used.

  Thereafter, 1 is subtracted from the value of the recognition output counter in the main RAM 65 (step S505), and it is determined whether or not the value of the recognition output counter after the 1 subtraction is “0” (step S506). When the value of the recognition output counter is 1 or more (step S506: NO), a process for outputting a type identification command corresponding to the value of the recognition output counter after 1 subtraction is executed (steps S503 and S503). Step S504).

  On the other hand, when the value of the recognition output counter is “0” (step S506: YES), an output process of an identification end command is executed (step S507). The identification end command has a data capacity of 8 bits, and the data of each bit is input to the first to eighth buffers 122a to 122h as the first to eighth signals, respectively. In the output process of the identification end command, the output state of the ninth signal is switched to the HI level at the timing when the output of the identification end command is started in order to make the management CPU 112 recognize that the new command has been transmitted. The output period of the identification end command and the period for maintaining the output state of the ninth signal at the HI level are set to a period sufficient for the management CPU 112 to recognize the output state of the identification end command and the ninth signal. Has been. By receiving the identification end command, the management-side CPU 112 specifies that the processing for storing the information on the correspondence relationship between the first to fifteenth buffers 122a to 122o and the signal type in the correspondence relationship memory 116 is completed. To do.

  Next, management processing executed by the management CPU 112 will be described with reference to the flowchart of FIG. The management process is started when the supply of operating power to the management CPU 112 is started. Note that the processing speed of the management CPU 112 is faster than the processing speed of the main CPU 63, and the next timer interrupt processing (FIG. 8) after one timer interrupt processing (FIG. 8) is started in the main CPU 63. In the management process, the combination of processes after step S606 is executed 16 times or more before the process is started.

  When the identification start command is received from the main CPU 63 (step S601: YES), the value of the setting target counter provided in the management RAM 114 is cleared to “0” (step S602). The setting target counter is a counter for the management-side CPU 112 to specify the type of the buffer 122a to 122o that is the target of signal type setting. The first buffer 122a is the signal type setting target first, and then the n + 1th buffer is the signal type setting target next to the nth buffer.

  Thereafter, on the condition that the type identification command is received from the main CPU 63 (step S603: YES), the correspondence setting process is executed (step S604). In the correspondence setting process, the type identification received this time in the correspondence area corresponding to the current value in the setting target counter of the management RAM 114 among the first to fifteenth correspondence areas 123a to 123o of the correspondence memory 116. Stores information on the signal type set in the command. Thereafter, 1 is added to the value of the setting target counter in the management side RAM 114 (step S605).

  If a negative determination is made in step S603, or if the process of step S605 is executed, it is determined whether an identification end command has been received from the main CPU 63 (step S606). If the identification end command has not been received (step S606: NO), the process returns to step S603, and on condition that a type identification command is newly received from the main CPU 63 (step S603: YES), steps S604 and S605 are performed. Run the process again.

  When the identification end command is received from the main CPU 63 (step S606: YES), the processes of step S607 and step S608 are repeatedly executed. Although details will be described later in step S <b> 607, a history setting process for storing history information corresponding to the type of signal received from the main CPU 63 in the history memory 117 is executed. In step S608, although details will be described later, an external output process for outputting the history information stored in the history memory 117 to the reading terminal 102 is executed.

  FIG. 19 is a time chart showing how correspondence information between the first to fifteenth buffers 122a to 122o and the types of signals input to the buffers 122a to 122o are stored in the correspondence memory 116. FIG. 19A shows a period in which a command is output from the main CPU 63 to the management CPU 112 using the first to eighth signals (that is, the first to eighth signal paths 118a to 118h). b) shows a period in which the output state of the ninth signal is at the HI level, and FIG. 19C shows the first to fifteenth buffers 122a to 122o and the types of signals inputted to these buffers 122a to 122o. FIG. 19D shows the timing at which the correspondence setting process (step S604) is executed in the management CPU 112. FIG. 19D shows the execution period of the identification state in which the process for identifying the correspondence is executed.

  By starting the operation power supply to the main CPU 63 and the management CPU 112, the output of the identification start command using the first to eighth signals is started at the timing t1, as shown in FIG. The Further, as shown in FIG. 19B, the output state of the ninth signal is changed from the LOW level to the HI level at the timing t1. Thereafter, at the timing t2, which is the situation where the output of the identification start command is continued, the output state of the ninth signal is changed from the HI level to the LOW level as shown in FIG. The management CPU 112 identifies that the command is transmitted from the main CPU 63 by confirming that the output state of the ninth signal has been changed from the HI level to the LOW level, and the first to eighth buffers 122a to 122h. The contents of the command received from the main CPU 63 are grasped by confirming the above information. In this case, since the identification start command has been received, the management-side CPU 112 enters an identification state by making an affirmative determination in step S601 of the management process (FIG. 18). Thereafter, the output of the identification start command is stopped at the timing of t3 as shown in FIG.

  Thereafter, as shown in FIG. 19A, the output of the first type identification command using the first to eighth signals is started at the timing of t4. Further, at the timing t4, as shown in FIG. 19B, the output state of the ninth signal is changed from the LOW level to the HI level. Thereafter, at the timing t5 when the output of the type identification command is continued, the output state of the ninth signal is changed from the HI level to the LOW level as shown in FIG. 19B. The management side CPU 112 identifies that the command has been transmitted from the main side CPU 63 by confirming that the output state of the ninth signal has been changed from the HI level to the LOW level. By confirming the information, the contents of the command received from the main CPU 63 are grasped. In this case, since the first type identification command is received, the management side CPU 112 executes the correspondence setting process as shown in FIG. In the correspondence setting process, information indicating the general winning opening 31 and information on the number of winning balls are stored in the first correspondence area 123a of the correspondence memory 116. Thereafter, the output of the type identification command is stopped at the timing of t6 as shown in FIG.

  After that, at the timings t7 to t9, t10 to t12, t13 to t15, and t16 to t18, respectively, Correspondence setting processing corresponding to the type identification command output from the side CPU 63 is executed by the management side CPU 112. In this case, the correspondence setting process corresponding to the fifteenth type identification command is completed at the timing from t16 to t18.

  After that, at the timing of t19, as shown in FIG. 19A, the output of the identification end command using the first to eighth signals is started. Further, at the timing t19, as shown in FIG. 19B, the output state of the ninth signal is changed from the LOW level to the HI level. Thereafter, at the timing t20 when the output of the identification end command is continued, the output state of the ninth signal is changed from the HI level to the LOW level as shown in FIG. 19B. The management side CPU 112 identifies that the command has been transmitted from the main side CPU 63 by confirming that the output state of the ninth signal has been changed from the HI level to the LOW level. By confirming the information, the contents of the command received from the main CPU 63 are grasped. In this case, since the identification end command has been received, the identification state of the management side CPU 112 ends at the timing of t20 as shown in FIG. Thereafter, the output of the identification end command is stopped at the timing of t21 as shown in FIG.

  In order to instruct the management CPU 112 to store the history information, the management CPU 112 recognizes whether the command is output using the ninth signal as described above. Even if the command is output using the first to eighth signals (that is, the first to eighth signal paths) used, it is clearly shown to the management CPU 112 that the command is being output. It can be recognized.

  Next, a processing configuration for storing history information in the history memory 117 will be described. FIG. 20 is a flowchart showing management output processing executed by the main CPU 63. The management output process is executed in step S219 in the timer interrupt process (FIG. 8).

  First, “10” is set in the management target counter provided in the main RAM 65 (step S701). The management target counter specifies in the main CPU 63 whether or not there is a management target that is not specified as to whether or not the signal output state to the management CPU 112 should be changed in the current management output process. At the same time, it is a counter for the main CPU 63 to specify which of the management targets the signal output state to the management CPU 112 should be changed. The management target to be specified by the main CPU 63 as to whether or not the signal output state to the management CPU 112 should be changed in one management output process is seven entrance detection sensors 42a to 48a, The total number of opening / closing execution modes, whether or not the high-frequency support mode is executed, and whether or not the front door frame 14 is opened or closed. Therefore, first, “10” is set in the management target counter.

  Thereafter, it is determined whether or not the output state of the signal to the management CPU 112 for the management target corresponding to the current management target counter value is HI level (step S702). If it is not the HI level (step S702: NO), it is determined whether or not the value of the management target counter is 4 or more, whereby the number of management targets corresponding to the value of the management target counter is seven inbound detection sensors 42a. To 48a is specified (step S703).

  If an affirmative determination is made in step S703, it is determined whether or not “1” is set in the output flag of the main RAM 65 corresponding to the value of the management target counter (step S704). Specifically, if the value of the management target counter is “10” and corresponds to the first winning mouth detection sensor 42a, it is determined whether or not “1” is set in the first output flag. If the value of the management target counter is “9” and corresponds to the second prize opening detection sensor 43a, it is determined whether or not “1” is set in the second output flag, and the value of the management target counter is determined. Is “8” and corresponds to the third prize opening detection sensor 44a, it is determined whether or not “1” is set in the third output flag, and the value of the management target counter is “7”. In the case of corresponding to the special electric detection sensor 45a, it is determined whether or not “1” is set in the fourth output flag, the value of the management target counter is “6”, and the first working port detection sensor 46a. If it corresponds to "5", the fifth output flag is set to "1" Whether the management target counter is “5” and corresponds to the second operating port detection sensor 47a, is “6” set in the sixth output flag? If the value of the management target counter is “4” and corresponds to the out port 24a, it is determined whether or not “1” is set in the seventh output flag. As described above, “1” is set to the first to seventh output flags in the ball entry detection process (FIG. 10).

  When “1” is set in the output flag corresponding to the value of the management target counter (step S704: YES), the output state of the signal corresponding to the value of the management target counter among the first to seventh signals is set to the HI level. (Step S705). Thereafter, the output flag corresponding to the value of the management target counter is cleared to “0” (step S706).

  If a negative determination is made in step S703, it is determined whether or not an opportunity to switch the output state of the signal corresponding to the value of the management target counter to the HI level has occurred (step S707). Specifically, when the value of the management target counter is “3”, it is determined whether or not a transition to the opening / closing execution mode has occurred, and when the value of the management target counter is “2” It is determined whether or not the shift to the frequency support mode has occurred. When the value of the management target counter is “1”, it is determined whether or not the front door frame 14 has been opened. If an affirmative determination is made in step S707, the output state of the signal corresponding to the value of the management target counter is set to the HI level (step S708).

  If an affirmative determination is made in step S702, it is determined whether or not an opportunity to switch the output state of the signal corresponding to the value of the management target counter to the LOW level has occurred (step S709). Specifically, when the value of the management target counter is 4 or more and the current management target is any of the entrance detection sensors 42a to 48a, the value of the management target counter among the first to seventh signals is set. It is determined whether or not the HI output continuation period (specifically, 10 msec) has elapsed since the corresponding signal output state was switched from the LOW level to the HI level. This HI output continuation period is set to a period longer than the longest processing interval of the history setting process (step S607) of the management process (FIG. 18) in the management side CPU 112, and the output of the signal switched from the LOW level to the HI level. It is a period during which the state can be reliably specified by the management CPU 112. Further, when the value of the management target counter is “3” and the current management target is the opening / closing execution mode, it is determined whether the opening / closing execution mode has ended, and the value of the management target counter is “2”. If the current management target is the high-frequency support mode, it is determined whether or not the high-frequency support mode has ended, the value of the management target counter is “1”, and the current management target is the front door frame 14. In this case, it is determined whether or not the front door frame 14 is in a closed state. When an opportunity to switch the output state of the signal corresponding to the value of the management target counter to the LOW level has occurred (step S709: YES), the output state of the signal corresponding to the value of the management target counter is set to the LOW level (step S709). Step S710).

  When a negative determination is made at step S704, when a process at step S706 is executed, when a negative determination is made at step S707, when a process at step S708 is executed, when a negative determination is made at step S709, or step When the processing of S710 is executed, 1 is subtracted from the value of the management target counter in the main RAM 65 (step S711). Then, it is determined whether or not the value of the management target counter after the 1 subtraction is “0” (step S712). If the value of the management target counter is 1 or more (step S712: NO), the processing from step S702 onward is executed for the management target corresponding to the new management target counter value.

  Next, the history setting process executed by the management CPU 112 will be described with reference to the flowchart of FIG. The history setting process is executed in step S607 of the management process (FIG. 18).

  First, the number of buffers to be confirmed in the management CPU 112 among the first to fifteenth buffers 122a to 122o is set in the confirmation target counter provided in the management RAM 114 (step S801). Specifically, the number of correspondence areas in which information other than information indicating blank is stored among the first to fifteenth correspondence areas 123a to 123o in the correspondence relationship memory 116 is identified, and the identification is performed. Set the number of information to the check target counter. In this pachinko machine 10, since information other than information indicating that it is blank is stored in the first to tenth corresponding relationship areas 123a to 123j as already described, "10" is set in the check target counter in step S801. To do.

  After that, it is confirmed whether or not the numerical information stored in the buffer corresponding to the current value of the check target counter among the first to fifteenth buffers 122a to 122o has been changed from “0” to “1”. Thus, it is determined whether or not the output state of the input signal from the main CPU 63 to the buffer has been switched from the LOW level to the HI level (step S802). In addition, when the value of the confirmation target counter is “n”, the nth buffers 122a to 122o are the confirmation targets of the numerical information. For example, if the value of the check target counter is “10”, the tenth buffer 122j is a check target for numerical information, and if the value of the check target counter is “5”, the fifth buffer 122e is a check target for numerical information. .

  When an affirmative determination is made in step S802, RTC information that is year / month / day information and time information is read from the RTC 115 (step S803). Then, the writing process to the history memory 117 is executed (step S804). In the writing process, the pointer information of the history area 124 that is the current writing target is specified by referring to the pointer area 126 of the history memory 117 and corresponds to the pointer information that is the writing target. The RTC information read in step S803 is written into the history information storage area 125 of the history area 124. Also, the correspondence information is read out from the correspondence areas 123a to 123o corresponding to the current value of the check target counter, and the correspondence information is written into the history information storage area 125 corresponding to the pointer information that is the write target. In addition, when the correspondence information is any one of information indicating that it is an opening / closing execution mode, information indicating that it is a high-frequency support mode, and information indicating that it is the front door frame 14, the above In addition to the correspondence information, start information is written in the history information storage area 125 corresponding to the pointer information to be written. Note that when the value of the confirmation target counter is “n”, the n-th correspondence relationship areas 123a to 123o are the correspondence information readout targets. For example, if the value of the confirmation target counter is “10”, the tenth correspondence area 123j is a target for reading correspondence information, and if the value of the confirmation target counter is “5”, the fifth correspondence area 123e is correspondence. Information is to be read out.

  When the write process is executed as described above, the value of the confirmation target counter is one of the out port 24a, the general winning port 31, the special prize winning device 32, the first operating port 33, and the second operating port 34. In the history information storage area 125 corresponding to the pointer information to be written, the RTC information, the out port 24a, the general winning port 31, the special winning device 32, the first operating port 33 and the second operating port 34 are displayed. The combination with the corresponding relationship information indicating any of the above is stored as history information. Further, when the value of the confirmation target counter is any of the opening / closing execution mode, the high frequency support mode, and the front door frame 14, the RTC information is stored in the history information storage area 125 corresponding to the pointer information to be written. And the combination of the correspondence information indicating that it is one of the opening / closing execution mode, the high-frequency support mode, and the front door frame 14 and the start information is stored as history information.

  Thereafter, update processing of the target pointer is executed (step S805). In the update process, the numerical information stored in the pointer area 126 of the history memory 117 is read and added by one. It is determined whether the pointer information after the addition of 1 exceeds the maximum value of the pointer information in the history area 124. If the maximum value is not exceeded, the pointer information after adding 1 is overwritten in the pointer area 126 as pointer information to be newly written. If the maximum value is exceeded, the pointer area 126 is cleared to “0” so that the pointer information to be written becomes the first pointer information.

  If a negative determination is made in step S802, or if the process of step S805 is executed, whether or not the signal output has been switched to the LOW level in the corresponding relationship areas 123a to 123o corresponding to the current value of the check target counter. It is determined whether correspondence information to be confirmed is stored (step S806). Specifically, when the value of the current confirmation target counter is “8” to “10”, information indicating that it is in the open / close execution mode, the high frequency support mode is displayed in the corresponding relationship areas 123h to 123j. Since either the information indicating that it is present or the information indicating that it is the front door frame 14 is stored, an affirmative determination is made in step S806.

  If an affirmative determination is made in step S806, the numerical information stored in the buffer corresponding to the current value of the check target counter among the first to fifteenth buffers 122a to 122o is changed from “1” to “0”. It is determined whether or not the output state of the input signal from the main CPU 63 to the buffer has been switched from the HI level to the LOW level (step S807). If an affirmative determination is made in step S807, the RTC information is read (step S808) as in step S803, and the writing process to the history memory 117 is executed (step S809). In the writing process, the RTC information read in step S808 is written in the history information storage area 125 of the history area 124 corresponding to the pointer information to be written. Also, the correspondence information is read out from the correspondence areas 123a to 123o corresponding to the current value of the check target counter, and the correspondence information is written into the history information storage area 125 corresponding to the pointer information that is the write target. Further, not only the correspondence information but also the end information is written in the history information storage area 125 corresponding to the pointer information to be written. By executing the writing process in this way, when the value of the confirmation target counter is one of the opening / closing execution mode, the high frequency support mode, and the front door frame 14, it corresponds to the pointer information that is the writing target. In the history information storage area 125, the combination of the RTC information, the correspondence information indicating any one of the opening / closing execution mode, the high frequency support mode, and the front door frame 14 and the end information is stored as history information. It will be in the state. After that, the target pointer update process is executed in the same manner as in step S805 (step S810).

  When a negative determination is made at step S806, when a negative determination is made at step S807, or when the process at step S810 is executed, the value of the check target counter in the management RAM 114 is decremented by 1 (step S811). Then, it is determined whether or not the value of the confirmation target counter after the 1 subtraction is “0” (step S812). When the value of the confirmation target counter is 1 or more (step S812: NO), the processing after step S802 is executed for the confirmation target corresponding to the new value of the confirmation target counter.

  Next, how the history information is stored in the history memory 117 will be described with reference to the time chart of FIG. FIG. 22A shows a period in which an HI level signal is input to any of the first to seventh buffers 122a to 122g, and FIG. 22B shows an HI level signal input to the eighth buffer 122h. FIG. 22C shows a period during which a HI level signal is inputted to the ninth buffer 122i, and FIG. 22D shows a HI level signal inputted to the tenth buffer 122j. The period is shown, and FIG. 22E shows the writing timing of the history information to the history memory 117.

  At the timing t1, as shown in FIG. 22A, the output state of the signal input to any of the first to seventh buffers 122a to 122g is switched from the LOW level to the HI level. Therefore, history information is written in the history memory 117 as shown in FIG. Thereafter, at the timing of t2, as shown in FIG. 22A, the signal switched to the HI level at the timing of t1 is switched to the LOW level. However, since the signal is a signal input to any of the first to seventh buffers 122a to 122g, and switching of the LOW level is not an object for storing history information, the timing of t2 in FIG. As shown in e), writing of history information is not executed.

  Thereafter, as shown in FIG. 22A, the first to seventh buffers 122a at the timing t3, the timing t5, the timing t6, the timing t9, the timing t10, the timing t13, and the timing t14, respectively. The output state of the signal input to any of -122g is switched from the LOW level to the HI level. Accordingly, history information is written at each of these timings as shown in FIG.

  As shown in FIG. 22B, the output state of the signal input to the eighth buffer 122h becomes the HI level from the timing t4 to the timing t7. The eighth buffer 122h corresponds to the presence / absence of the opening / closing execution mode. Therefore, as shown in FIG. 22 (e), the timing t4 when the output state of the signal input to the eighth buffer 122h switches to the HI level, and the timing when the output state of the signal switches to the LOW level. The history information is written at each timing t7. In this case, the history information written at timing t4 includes start information, and the history information written at timing t7 includes end information. Thereby, it is possible to grasp the execution period of the opening / closing execution mode by checking the history information in the history memory 117.

  Also, history information is written in the history memory 117 in the order of time passage. Therefore, whether the history information indicating that a ball has entered any one of the out port 24a, the general winning port 31, the special prize winning device 32, the first operating port 33 and the second operating port 34 is in the open / close execution mode. It becomes possible to distinguish whether or not. Since the history information includes RTC information, any of the out port 24a, the general winning port 31, the special winning device 32, the first operating port 33, and the second operating port 34 can be compared by comparing the RTC information. It is possible to distinguish whether or not the history information indicating that a ball has entered the open / close execution mode.

  As shown in FIG. 22C, the output state of the signal input to the ninth buffer 122i becomes the HI level from the timing t8 to the timing t11. The ninth buffer 122i corresponds to whether or not the high frequency support mode has occurred. Therefore, as shown in FIG. 22 (e), the timing t8 when the output state of the signal input to the ninth buffer 122i switches to the HI level and the timing when the output state of the signal switches to the LOW level. The history information is written at each timing t11. In this case, the history information written at timing t8 includes start information, and the history information written at timing t11 includes end information. Accordingly, it is possible to grasp the execution period of the high frequency support mode by confirming the history information in the history memory 117.

  Also, history information is written in the history memory 117 in the order of time passage. Accordingly, the history information indicating that a ball has entered any one of the out port 24a, the general winning port 31, the special electric winning device 32, the first operating port 33, and the second operating port 34 is also in the high frequency support mode. It becomes possible to distinguish whether or not. Since the history information includes RTC information, any of the out port 24a, the general winning port 31, the special winning device 32, the first operating port 33, and the second operating port 34 can be compared by comparing the RTC information. It is possible to distinguish whether or not the history information indicating that the ball has entered the high frequency support mode.

  As shown in FIG. 22D, the output state of the signal input to the tenth buffer 122j becomes the HI level from the timing t12 to the timing t15. The tenth buffer 122j corresponds to whether or not the front door frame 14 is opened. Therefore, as shown in FIG. 22E, the timing at t12 when the output state of the signal input to the tenth buffer 122j switches to the HI level, and the timing when the output state of the signal switches to the LOW level. The history information is written at each timing t15. In this case, the history information written at the timing t12 includes start information, and the history information written at the timing t15 includes end information. As a result, it is possible to grasp the period during which the front door frame 14 is open by checking the history information in the history memory 117.

  Also, history information is written in the history memory 117 in the order of time passage. Therefore, history information indicating that a ball has entered any one of the out port 24a, the general winning port 31, the special winning device 32, the first operating port 33, and the second operating port 34 is being opened. It becomes possible to distinguish whether it is a thing. Since the history information includes RTC information, any of the out port 24a, the general winning port 31, the special winning device 32, the first operating port 33, and the second operating port 34 can be compared by comparing the RTC information. It is possible to distinguish whether or not the history information indicating that the ball has entered the door is in the state where the front door frame 14 is being opened.

  Next, a processing configuration for outputting history information stored in the history memory 117 to a reading device electrically connected to the reading terminal 102 of the MPU 62 will be described. FIG. 23 is a flowchart showing a data output process executed by the main CPU 63. The data output process is executed in step S111 in the main process (FIG. 7).

  In the data output process, first, it is determined whether or not a connection signal indicating that the reading device is electrically connected to the reading terminal 102 is received from the reading terminal 102 (step S901). The reading apparatus is configured to output a connection signal when electrically connected to the reading terminal 102, and when the connection signal is received through the reading terminal 102, an affirmative determination is made in step S901. do.

  If a negative determination is made in step S901, the data output process is terminated as it is. In this case, in order to execute the data output process, it is necessary to restart the supply of operating power to the MPU 62. Thus, in order to perform external output of history information, it is necessary to start supply of operating power to the MPU 62 in a state where the reading device is electrically connected to the reading terminal 102. . Since a power supply operation unit for performing a stop operation and a start operation of supply of operating power to the MPU 62 is provided on the back surface of the back pack unit 15, in order to perform these stop operations and start operations, the outer frame 11 is operated. Thus, it is necessary to open the gaming machine main body 12 and expose the back surface of the back pack unit 15. Under such circumstances, in order to output the history information externally, it is necessary to start supplying the operating power to the MPU 62 with the reading device electrically connected to the reading terminal 102. With this configuration, it is possible to make it difficult to perform an operation for reading history information by anyone other than the manager of the game hall.

  If an affirmative determination is made in step S901, it is determined whether or not a control information confirmation signal has been received from the reading terminal 102, whereby the current connection of the reading device to the reading terminal 102 is determined by the main ROM 64. It is determined whether or not the control information (program and data) is confirmed (step S902). The reading device is configured to be able to perform both control information confirmation and history information confirmation. When control information confirmation is selected by manual operation on the reading device, the reading device confirms control information. When a signal is transmitted and confirmation of history information is selected by a manual operation on the reading device, a signal for history confirmation is transmitted from the reading device. However, the present invention is not limited to this, and a configuration may be adopted in which the reading device for checking control information and the reading device for checking history are different. In this case, when a reading device for confirming control information is electrically connected to the reading terminal 102, a signal for confirming control information is transmitted from the reading device, and reading for history confirmation is performed to the reading terminal 102. When the apparatus is electrically connected, a history confirmation signal is transmitted from the reading apparatus.

  If an affirmative determination is made in step S902, an output process for confirming control information is executed (step S903). In the output process, a program and data are read from the main ROM 64 as control information, and the read control information is output to the reading terminal 102. As a result, the control information can be read by the reading device electrically connected to the reading terminal 102, and it is confirmed whether or not the control information is normal or normal. Can be performed.

  If a negative determination is made in step S902, an output instruction signal is transmitted to the management CPU 112 (step S904). Specifically, the output state of the output instruction signal is switched from the LOW level to the HI level. This HI level output state continues for a specific period. This specific period is a period sufficient for the management side CPU 112 to specify that the HI level output instruction signal is input to the sixteenth buffer 122p. When the output state of the output instruction signal is switched to the HI level, the management CPU 112 executes processing for outputting history information. This process will be described in detail later.

  When the process of step S903 is executed or when the process of step S904 is executed, it is determined whether or not the electrical connection of the reading device to the reading terminal 102 is continued (step S905). If it is continued (step S905: YES), the process stands by in step S905. Thereby, it is possible to prevent the processing set in the execution order after the data output processing from being executed until the electrical connection of the reading device to the reading terminal 102 is released. When the electrical connection of the reading device to the reading terminal 102 is released (step S905: NO), the data output processing is terminated.

  Next, external output processing executed by the management CPU 112 will be described with reference to the flowchart of FIG. The external output process is executed in step S608 of the management process (FIG. 18).

  When the output state of the output instruction signal received from the main CPU 63 is switched from the LOW level to the HI level (step S1001: YES), processing for outputting history information after step S1002 is executed. Specifically, first, by counting the number of history information storage areas 125 in which the corresponding relationship information indicating the outlets 24a in the history area 124 of the history memory 117 is stored, The number of balls entered is calculated (step S1002). In addition, by counting the number of history information storage areas 125 in which the correspondence information indicating that it is the general winning opening 31 is stored in the history area 124 of the history memory 117, it is possible to enter the general winning opening 31. The number is calculated (step S1003). In addition, by counting the number of history information storage areas 125 in which the correspondence information indicating that the special power prize winning device 32 is stored in the history area 124 of the history memory 117, it is possible to enter the special power prize winning device 32. The number is calculated (step S1004). Further, by counting the number of history information storage areas 125 in which the correspondence information indicating the first operating port 33 is stored in the history area 124 of the history memory 117, The number of balls entered is calculated (step S1005). In addition, by counting the number of history information storage areas 125 in which the correspondence information indicating the second operation port 34 is stored in the history area 124 of the history memory 117, The number of balls entered is calculated (step S1006).

  Thereafter, in the history area 124 of the history memory 117, the history information storage area 125 in which correspondence information and start information indicating the front door frame 14 are stored, and the correspondence relationship indicating the front door frame 14 An outlet that occurs in a situation where the front door frame 14 is open by referring to the history information storage area 125 that exists in a period between the information and the history information storage area 125 in which the end information is stored 24a, the general winning opening 31, the special electricity winning device 32, the first operating port 33, and the second operating port 34 are calculated (step S1007). The history information storage area 125 in which the correspondence information and start information indicating the front door frame 14 in the history area 124 of the history memory 117 are stored, the correspondence information indicating the front door frame 14 and A period with the history information storage area 125 in which the end information is stored is calculated from the RTC information stored in the history information storage area 125. In addition, in the entire pointer information that is a serial number, the correspondence information indicating the front door frame 14 and the history information storage area 125 in which the start information is stored, and the correspondence indicating the front door frame 14 When there are a plurality of sections with the history information storage area 125 in which information and end information are stored, the number of balls entered for the total of the sections is calculated. Further, although there is a history information storage area 125 in which correspondence information indicating start door frame 14 and start information are stored, RTC information corresponding to a time later than the history information storage area 125 Is stored in the history information storage area 125, the correspondence information indicating that it is the front door frame 14 and the start information are not stored. The history information in the history information storage area 125 in which the RTC information corresponding to the time after the history information storage area 125 is stored is treated as if the front door frame 14 is in the open state.

Thereafter, various parameters are calculated using the calculation results of steps S1002 to S1007 (step S1008). Specifically, first, the number of balls entered during the opening of the front door frame 14 calculated in step S1007 is subtracted from the number of balls calculated in steps S1002 to S1006. Then, the following parameters are calculated using the number of incoming balls after the subtraction. Note that the difference in the number of entrances of the out mouth 24a calculated in step S1007 with respect to the number of entrances calculated in step S1002 is defined as the entrance number K1, and the calculation is performed in step S1007 with respect to the number of entrances calculated in step S1003. The difference in the number of balls entered in the general winning opening 31 is set as the number K2 of balls entered, and the difference in the number of balls entered in the special electric prize winning device 32 calculated in step S1007 with respect to the number of balls entered calculated in step S1004 is set as the number K3 entered. The difference in the number of balls entered in the first operating port 33 calculated in step S1007 with respect to the number of balls calculated in step S1005 is defined as the number of balls K4, and the number calculated in step S1006 is calculated in step S1007. The difference in the number of entering balls of the second working port 34 is defined as the number of entering balls K5.
First parameter: Total number of game balls to be paid out (K2 × “the number of winning balls for winning in the general winning opening 31” + K3 × “the number of winning balls for winning in the special electric winning device 32” + K4 × “first operating port” The number of winning balls for winning 33 ”+ K5 ד the number of winning balls for winning the second operating port 34 ”) / the ratio of the total number of gaming balls discharged from the game area PA (K1 + K2 + K3 + K4 + K5) “D1”)
Second parameter: the ratio of the total number of game balls K2 entering the general winning opening 31 / the total number of game balls discharged from the game area PA (K1 + K2 + K3 + K4 + K5). Third parameter: game balls to the special prize winning device 32. The total number of balls K3 / the ratio of the total number of game balls discharged from the game area PA (K1 + K2 + K3 + K4 + K5). Fourth parameter: the total number K4 of game balls entering the first operating port 33 / discharge from the game area PA. Ratio of the total number of game balls played (K1 + K2 + K3 + K4 + K5) (hereinafter, this ratio is referred to as “D2”)
Fifth parameter: ratio of the total number of game balls entering the second operation port K5 / total number of game balls discharged from the game area PA (K1 + K2 + K3 + K4 + K5) (hereinafter, this ratio is referred to as “D3”)
Sixth parameter: D1- (D2 × “the number of winning balls for winning in the first operating port 33” + D3 × “the number of winning balls for winning in the second operating port 34”)
7th parameter: (K3 × “the number of winning balls for winning in the special electricity winning device 32” + K5 × “the number of winning balls for winning in the second operating port 34”) / total number of game balls to be paid out (K2 × “general The number of winning balls for winning at the winning opening 31 + K3 × “the number of winning balls for winning at the special electricity winning device 32” + K4 × “the number of winning balls for winning at the first operating port 33” + K5 × “the second operating port 34” Ratio / eighth parameter: K3 × “number of winning balls for winning to the special electric prize device 32” / total number of game balls to be paid out (K2 × “for winning to the general winning opening 31”) “Number of winning balls” + K3 × “Number of winning balls for winning in the special electric prize winning device 32” + K4 × “Number of winning balls for winning in the first operating port 33” + K5 × “Number of winning balls for winning in the second operating port 34” )) Percentage then history notes Using the newest RTC information oldest RTC information in the history for the area 124 of the 117, the history information being the object of this operation is to calculate the total time it took to be extracted every (step S1009). Then, the first output process is executed (step S1010). In the first output process, all history information stored in the history area 124 of the history memory 117 is sequentially output to the reading terminal 102. In addition, the various parameters calculated in step S1008 are sequentially output to the reading terminal 102, and the total time calculated in step S1009 is output to the reading terminal 102. As a result, in the reading device electrically connected to the reading terminal 102, each information to be output in the first output process is read.

  Thereafter, in the history area 124 of the history memory 117, the history information storage area 125 in which correspondence information and start information indicating the opening / closing execution mode are stored, correspondence information indicating the switching execution mode, and By referring to the history information storage area 125 existing in the period between the end information and the history information storage area 125, the out port 24a and the general winning port 31 generated in the state of the open / close execution mode are referred to. Then, the number of balls entered into each of the special electric prize winning device 32, the first operating port 33 and the second operating port 34 is calculated (step S1011). The history information storage area 125 in which the correspondence information and start information indicating the opening / closing execution mode are stored in the history area 124 of the history memory 117, and the correspondence information and end information indicating the opening / closing execution mode are stored. Is calculated from the RTC information stored in the history information storage area 125. In addition, in the entire pointer information that is a serial number, the history information storage area 125 in which correspondence information and start information indicating the opening / closing execution mode are stored, correspondence information indicating the opening / closing execution mode, and If there are a plurality of sections with the history information storage area 125 in which the end information is stored, the number of balls entered for the total of the sections is calculated. Further, although there is a history information storage area 125 in which correspondence information indicating start / close execution mode and start information are stored, RTC information corresponding to a time later than the history information storage area 125 is present. When correspondence information and start information indicating that it is in the open / close execution mode is not stored in the stored history information storage area 125, correspondence information and start information indicating that it is in the open / close execution mode is stored. Any history information in the history information storage area 125 in which RTC information corresponding to a time later than the history information storage area 125 is stored is handled in the open / close execution mode.

  Thereafter, the out port 24a, the general winning port 31, the special prize winning device 32, the first operating port 33, and the like that occurred in the situation where the front door frame 14 is in the open state during the period of the opening / closing execution mode specified in step S1011. The number of balls entering each of the second operation ports 34 is calculated (step S1012). The method of calculating the number of entered balls is the same as in the case of step S1007, except that the period is the opening / closing execution mode specified in step S1011.

Thereafter, various parameters are calculated using the calculation results of step S1011 and step S1012 (step S1013). Specifically, first, the number of balls entered while the front door frame 14 is opened calculated in step S1012 is subtracted from the number of balls entered in step S1011. Then, the following parameters are calculated using the number of incoming balls after the subtraction. Note that the difference in the number of entrances of the out mouth 24a calculated in step S1012 with respect to the number of entrances of the out mouth 24a calculated in step S1011 is defined as the number of entrances K11, and the entry of the general winning opening 31 calculated in step S1011 is performed. The difference in the number of balls entered in the general winning opening 31 calculated in step S1012 with respect to the number of balls is defined as the number K12 of balls entered, and the special prize apparatus calculated in step S1012 with respect to the number of balls entered in the special prize device 32 calculated in step S1011. The difference in the number of entering balls 32 is defined as the number of entering balls K13, and the difference in the number of entering balls in the first working port 33 calculated in step S1012 with respect to the number of entering balls in the first operating port 33 calculated in step S1011 is entered. The number K14 is calculated in step S1012 with respect to the number of balls entering the second operation port 34 calculated in step S1011. The difference between the ball entrance number of the second actuating port 34 and ball entrance number K15 was.
Eleventh parameter: Total number of game balls to be paid out (K12 × “number of winning balls for winning in the general winning opening 31” + K13 × “number of winning balls for winning in the special electric winning device 32” + K14 × “first operating port 33 The number of winning balls for winning a prize + K15 × “the number of winning balls for winning the second operating port 34”) / the ratio of the total number of gaming balls discharged from the gaming area PA (K11 + K12 + K13 + K14 + K15) D11 ”)
The twelfth parameter: the total number of game balls entered into the general winning opening 31 K12 / the ratio of the total number of game balls discharged from the game area PA (K11 + K12 + K13 + K14 + K15) The thirteenth parameter: game balls to the special prize winning device 32 The total number of balls K13 / the ratio of the total number of game balls (K11 + K12 + K13 + K14 + K15) discharged from the game area PA. Fourteenth parameter: the total number K14 of game balls entering the first operating port 33 / discharge from the game area PA. Ratio of the total number of game balls played (K11 + K12 + K13 + K14 + K15) (hereinafter, this ratio is referred to as “D12”)
Fifteenth parameter: ratio of total number of game balls K15 entering the second operating port 34 / total number of game balls discharged from the game area PA (K11 + K12 + K13 + K14 + K15) (hereinafter, this ratio is referred to as “D13”)
16th parameter: D11− (D12 × “the number of winning balls for winning in the first operating port 33” + D13 × “the number of winning balls for winning in the second operating port 34”)
17th parameter: (K13 × “the number of winning balls for winning in the special electricity winning device 32” + K15 × “the number of winning balls for winning in the second operating port 34”) / total payout of game balls (K12 × “general The number of winning balls for winning in the winning opening 31 "+ K13 ×" the number of winning balls for winning in the special electricity winning device 32 "+ K14 ×" the number of winning balls for winning in the first operating port 33 "+ K15 ×" the second operating port 34 ". Ratio / 18th parameter: K13 × “the number of winning balls for winning the special electric prize device 32” / total number of game balls to be paid out (K12 × “for winning to the general winning opening 31”) “Number of prize balls” + K13 × “Number of prize balls for winning in the special electric prize device 32” + K14 × “Number of prize balls for winning in the first operation port 33” + K15 × “Number of prize balls for winning in the second operation port 34” ") Thereafter, the second output process is executed (step S1014). In the second output process, the various parameters calculated in step S1013 are sequentially output to the reading terminal 102. Thereby, in the reading device electrically connected to the reading terminal 102, each piece of information to be output in the second output process is read.

  Thereafter, the history information storage area 125 in which the correspondence information indicating the high frequency support mode and the start information are stored in the history area 124 of the history memory 117 and the correspondence relationship indicating the high frequency support mode are stored. The out port 24a generated in the situation of the high frequency support mode by referring to the history information storage area 125 existing in the period between the information and the history information storage area 125 in which the end information is stored, The number of balls entered into each of the winning opening 31, the special prize winning device 32, the first operating opening 33 and the second operating opening 34 is calculated (step S1015). In the history area 117 of the history memory 117, the history information storage area 125 storing the correspondence information and start information indicating the high frequency support mode, the correspondence information indicating the high frequency support mode, and A period with the history information storage area 125 in which the end information is stored is calculated from the RTC information stored in the history information storage area 125. In addition, in the entire pointer information that is a serial number, the correspondence information indicating the high frequency support mode and the history information storage area 125 in which the start information is stored, and the correspondence indicating the high frequency support mode When there are a plurality of sections with the history information storage area 125 in which information and end information are stored, the number of balls entered for the total of the sections is calculated. In addition, although there is a history information storage area 125 in which correspondence information indicating the high frequency support mode and start information are stored, RTC information corresponding to a time later than the history information storage area 125 Is stored in the history information storage area 125, the correspondence information indicating the high frequency support mode and the start information are stored. The history information in the history information storage area 125 in which the RTC information corresponding to the time after the history information storage area 125 is stored is treated as being in the high frequency support mode.

  Thereafter, the out port 24a, the general winning port 31, the special winning device 32, and the first operating port 33, which are generated in the situation where the front door frame 14 is in the open state during the period of the high frequency support mode specified in step S1015. The number of balls entering each of the second working ports 34 is calculated (step S1016). The method of calculating the number of entered balls is the same as that in step S1007, except that the period of the high-frequency support mode specified in step S1015 is assumed.

Thereafter, various parameters are calculated using the calculation results of step S1015 and step S1016 (step S1017). Specifically, first, the number of balls entered during the opening of the front door frame 14 calculated in step S1016 is subtracted from the number of balls entered in step S1015. Then, the following parameters are calculated using the number of incoming balls after the subtraction. Note that the difference in the number of entrances of the out mouth 24a calculated in step S1016 with respect to the number of entrances of the out mouth 24a calculated in step S1015 is set as the number of entrances K21, and the entrance of the general winning entrance 31 calculated in step S1015 is obtained. The difference in the number of balls in the general winning opening 31 calculated in step S1016 with respect to the number of balls is defined as the number K22 of balls, and the special prize device calculated in step S1016 with respect to the number of balls in the special prize device 32 calculated in step S1015. The difference in the number of entering balls 32 is defined as the number of entering balls K23, and the difference in the number of entering balls in the first working port 33 calculated in step S1016 with respect to the number of entering balls in the first operating port 33 calculated in step S1015 is entered. Calculated in step S1016 with respect to the number of balls in the second operating port 34 calculated in step S1015, with the number K24. The difference between the ball entrance number of the second actuating port 34 and ball entrance number K25 was.
21st parameter: total number of game balls to be paid out (K22 × “the number of winning balls for winning in the general winning opening 31” + K23 × “the number of winning balls for winning in the special electric winning device 32” + K24 × “first operating port 33” The number of winning balls for winning a prize + K25 × “the number of winning balls for winning the second operating port 34”) / the ratio of the total number of gaming balls discharged from the gaming area PA (K21 + K22 + K23 + K24 + K25) D11 ”)
22nd parameter: Total number of game balls entering the general winning opening 31 K22 / Ratio of total number of game balls discharged from the game area PA (K21 + K22 + K23 + K24 + K25) 23rd parameter: Game balls to the special prize winning device 32 Total number of entered balls K23 / Ratio of the total number of game balls discharged from the game area PA (K21 + K22 + K23 + K24 + K25). Twenty-fourth parameter: Total number of game balls entered into the first working port 33 K24 / discharged from the game area PA Ratio of the total number of game balls played (K21 + K22 + K23 + K24 + K25) (hereinafter, this ratio is referred to as “D22”)
25th parameter: ratio of the total number of game balls entering the second operation port K25 / total number of game balls discharged from the game area PA (K21 + K22 + K23 + K24 + K25) (hereinafter, this ratio is referred to as “D23”)
26th parameter: D21− (D22 × “the number of winning balls for winning in the first operating port 33” + D23 × “the number of winning balls for winning in the second operating port 34”)
Thereafter, a third output process is executed (step S1018). In the third output process, the various parameters calculated in step S1017 are sequentially output to the reading terminal 102. As a result, in the reading device electrically connected to the reading terminal 102, each piece of information to be output in the third output process is read. Thereafter, a clear process is executed (step S1019). In the clear process, all the history information storage areas 125 of the history memory 117 are cleared to “0” and the pointer area 126 is cleared to “0”. As a result, the history area 124 is initialized.

  According to the embodiment described in detail above, the following excellent effects are obtained.

  Since a game ball is paid out when a game ball enters any of the general winning port 31, the special electricity winning device 32, the first operating port 33, and the second operating port 34, the player can either The game will be played while expecting a game ball to enter. In this configuration, a game ball enters any one of the out port 24a, the general winning port 31, the special electricity winning device 32, the first operating port 33, and the second operating port 34 (hereinafter also referred to as a history target entering unit). When this occurs, the history information corresponding to the occurrence is stored in the history memory 117 of the management IC 66. As a result, it becomes possible to store and hold information for managing the number or frequency of entering the game balls into each history target entrance part in the pachinko machine 10, and use this managed information. Thus, it becomes possible to appropriately manage the entrance mode of the game ball to each history target entrance section. In addition, since the history information is stored and held in the pachinko machine 10 itself, it is possible to prevent unauthorized access and unauthorized modification to the history information.

  All the entrances that discharge the game balls from the game area PA are the targets for executing the history information storage process and the targets for management using the history information. Thereby, it becomes possible to manage the pitching frequency for an arbitrary history target pitching part using the history information. In addition, it is possible to manage the ratio of the number of game balls entering each history target entrance part with respect to the number of game balls discharged from the game area PA using history information.

  The history information includes RTC information, which is information corresponding to the timing at which a game ball has entered the history target entrance portion that triggered the storage of the history information. Thereby, by using the history information, it is possible to grasp in detail the entry history of the game balls into the history target entry portion.

  In the history memory 117, not only history information corresponding to the game ball entering the history target entry portion, but also history information indicating whether or not the open / close execution mode is in progress, and in the high frequency support mode History information indicating whether or not, and history information indicating whether or not the front door frame 14 is open. Thereby, it is possible to manage whether or not the game balls have entered the history target entrance portion by distinguishing whether or not each of these situations exists.

  The history information stored in the history memory 117 can be output to a reading device that is an external device of the pachinko machine 10. As a result, the history information is read by the reading device, and it is possible to analyze the manner in which the game ball enters the history target entrance portion using the read history information.

  The MPU 62 is provided with a reading terminal 102, and a program can be read from the main ROM 64 by a reading device electrically connected to the reading terminal 102. As a result, it is possible to confirm whether or not the program is normal. In this configuration, the history information stored in the history memory 117 is output to the outside using the reading terminal 102 for externally outputting the program. As a result, the history information can be output to the outside while preventing the configuration from becoming complicated.

  It is specified whether the information to be output from the reading terminal 102 is a program or history information, and information on the side corresponding to the specifying result is externally output through the reading terminal 102. Accordingly, in the configuration in which history information is output to the outside using the reading terminal 102 for outputting the program to the outside, the pachinko machine 10 determines whether the information to be externally output is the program or the history information. The specified information is output to the outside. Therefore, only necessary information can be read out even when the reading terminal 102 is also used.

  Based on the information received from the reading device electrically connected to the reading terminal 102, it is specified which information to be output from the reading terminal 102 is the program or the history information. As a result, it is possible to prevent the configuration relating to selection of information to be externally output from becoming complicated.

  An MPU 62 having a main ROM 64 for storing a program in advance has a management IC 66 and a reading terminal 102. As a result, signal paths for the reading terminal 102 can be collected in the MPU 62. Therefore, it is possible to achieve the excellent effects as described above while making it difficult to illegally access the signal path to the reading terminal 102.

  The main CPU 63 that executes processing for paying out the game ball based on the game ball entering any of the general winning port 31, the special electricity winning device 32, the first operating port 33, and the second operating port 34. Separately, a management CPU 112 is provided, and the management CPU 112 executes processing for storing history information in the history memory 117. As a result, it is possible to manage the manner in which the game balls enter the respective history target entrance portions while preventing the processing load on the main CPU 63 from increasing extremely.

  The main CPU 63 and the management CPU 112 are provided as the MPU 62 on the same chip. This makes it possible to prevent unauthorized access to the communication path between the main CPU 63 and the management CPU 112.

  The main-side CPU 63 uses information corresponding to the detection results of the entrance detection sensors 42a to 48a using the signal paths corresponding to the entrance detection sensors 42a to 48a, and the buffers of the input port 121 of the management IC 66. It transmits to 122a-122g. As a result, the type of information transmitted from the main CPU 63 corresponds to each of the buffers 122a to 122g (that is, each signal path), and the configuration for distinguishing the type of each information on the management CPU 112 is simplified. It becomes possible to do.

  Information corresponding to whether the main CPU 63 is in the opening / closing execution mode, information corresponding to whether it is in the high frequency support mode, and information corresponding to whether the front door frame 14 is open Is transmitted to each of the buffers 122h to 122j of the input port 121 of the management IC 66 using a signal path corresponding to each of these situations. As a result, the types of information corresponding to these situations correspond to the buffers 122h to 122j (that is, the signal paths), and the configuration for distinguishing the types of information by the management CPU 112 is simplified. It becomes possible.

  The main CPU 63 transmits correspondence information indicating which type of information each buffer 122a to 122j (that is, each signal path 118a to 118j) corresponds to the management CPU 112. Thereby, it is not necessary to store the corresponding relationship information in the management IC 66 in advance. Therefore, the versatility of the management IC 66 can be improved.

  When supply of operating power to the main CPU 63 is started, correspondence information is transmitted from the main CPU 63 to the management IC 66. As a result, in a situation where a game ball can enter the history target entrance part, the correspondence between the information transmitted from the main CPU 63 and the history target entrance part can be specified by the management IC 66. It becomes possible to become.

  Correspondence information is transmitted from the main CPU 63 to the management IC 66 by using signal paths 118a to 118g for transmitting information indicating whether or not a game ball has entered the history target ball entry unit. Thereby, it becomes possible to simplify the structure regarding communication compared with the structure which provides the dedicated signal path | route for transmitting corresponding relationship information.

  The management IC 66 is provided with a correspondence memory 116, and correspondence information transmitted from the main CPU 63 to the management IC 66 is stored in the correspondence memory 116. As a result, information that enables the management target IC 66 to specify the history target entrance portion corresponding to the transmission target information is transmitted from the main CPU 63 each time detection result information of each of the entrance detection sensors 42a to 48a is transmitted. No need to provide. Therefore, it is possible to suppress the amount of information of the detection results of the respective entrance detection sensors 42a to 48a transmitted from the main CPU 63.

  When the output state of the output instruction signal output from the main CPU 63 to the management IC 66 is switched from the LOW level to the HI level, information is output from the management IC 66 to the reading terminal 102. In this case, the fact that the signal path corresponding to the sixteenth buffer 122p corresponds to the output instruction signal can be specified by the management CPU 112 without receiving correspondence information from the main CPU 63. . As a result, it is possible to prevent the configuration related to transmission of correspondence information from becoming extremely complicated.

  The management IC 66 is provided with more buffers than the types of information that need to be transmitted from the main CPU 63 to the management IC 66 as buffers 122a to 122p capable of receiving information from the main CPU 63. It has been. Thereby, even if the number of types of the information increases or decreases according to the model of the pachinko machine 10, it is possible to cope without changing the configuration regarding the buffers 122a to 122p. Therefore, the versatility of the management IC 66 can be improved.

  When history information is transmitted from the management IC 66 to the reading terminal 102, correspondence information indicating the type of the history target entrance portion corresponding to the history information is included in each history information. Thereby, it becomes possible to specify the entrance mode of the game ball into each history target entrance portion using the read history information.

  In the management IC 66, by using the history information stored in the history memory 117, various parameters (first to eighth, 11 to 18, 21 to 26 parameters) are calculated. This makes it possible to externally output various parameters that are the results of computation using history information.

  Various parameters are calculated in a state where the history information corresponding to the situation where the front door frame 14 is open is excluded. Thereby, it becomes possible to derive various parameters in a normal situation where the front door frame 14 is in the closed state. Also, various parameters corresponding to each of the situation in the opening / closing execution mode and the situation in the high frequency support mode are calculated. Thereby, the manager of the game hall or the like can grasp the entrance mode of the game ball according to each situation.

  When various parameters are calculated, the history memory 117 is initialized by executing the clear processing of the history memory 117. As a result, the history information that exceeds the storage capacity of the history memory 117 becomes an object to be stored in the history memory 117, and the history information that should originally be stored is erased by overwriting. Can be made difficult to occur.

  When various parameters are output to the reading terminal 102, history information stored in the history memory 117 is also output to the reading terminal 102. As a result, when various parameters are read out and a game ball entering mode in the game area PA is analyzed, it is possible to refer to not only the various parameters but also the history information that is the basis for the calculation of the various parameters.

  The management-side CPU 112 calculates various parameters when a reading device is electrically connected to the reading terminal 102. Thereby, it becomes possible to reduce the frequency which calculates various parameters.

  When the main CPU 63 specifies that the reading device is electrically connected to the reading terminal 102, and when the output instruction information is transmitted from the main CPU 63, various parameters are calculated by the management IC 66. The various parameters of the calculation result are output to the reading terminal 102. Accordingly, various parameters can be output to a reading device outside the pachinko machine 10 based on an instruction from the main CPU 63.

  Whether or not the reading device is electrically connected to the reading terminal 102 is specified by the process at the start of supplying the operating power executed by the main CPU 63, and the reading device is electrically connected. Is specified, output instruction information is transmitted from the main CPU 63 to the management IC 66. Thereby, in the situation where the processing at the start of supply of operating power is being executed by the main CPU 63 or the like, that is, in the situation before the normal processing for proceeding the game is started by the main CPU 63, The calculation of parameters and the external output of various parameters of the calculation results are completed. Therefore, it is possible to prevent the calculation of various parameters and the external output of the calculation results in a situation where a game ball can enter the history target ball entry part, and the processing load of the management IC 66 is reduced. It becomes possible to reduce.

  In a configuration in which when a game ball enters the first operation port 33 or the second operation port 34, an external output corresponding to the game ball is generated through the external terminal plate 97, history information is stored in the history memory 117. . Thus, by using information output externally through the external terminal plate 97, the number of game balls entering the first operation port 33 and the second operation port 34 and the frequency of entering the game ball can be easily grasped. By using the history information stored in the memory 117 for use, it is possible to accurately grasp the number and frequency of entering the game balls into the history target entry portion.

<Second Embodiment>
In the present embodiment, among the first to sixteenth buffers 122a to 122p of the input port 121 in the management-side I / F 111, the type of buffer that has been determined at the design stage of the management IC 66 is the type of buffer that is described above. This is different from the first embodiment. Further, the processing configuration executed by the main CPU 63 to make the management CPU 112 specify the type of input signal is different from that of the first embodiment. Hereinafter, a configuration different from that of the first embodiment will be described. The description of the same configuration as that of the first embodiment is basically omitted.

  FIG. 25 is an explanatory diagram for explaining the configuration of the input port 121 of the management-side I / F 111 in the present embodiment.

  The first to seventh buffers 122a to 122g and the sixteenth buffer 122p receive the same types of signals as in the first embodiment. Specifically, the first buffer 122a receives a first signal corresponding to the detection result of the first winning opening detection sensor 42a, and the second buffer 122b receives the first signal corresponding to the detection result of the second winning opening detection sensor 43a. The second signal is input, the third signal corresponding to the detection result of the third prize opening detection sensor 44a is input to the third buffer 122c, and the fourth signal corresponding to the detection result of the special electricity detection sensor 45a is input to the fourth buffer 122d. The fifth buffer 122e receives a fifth signal corresponding to the detection result of the first working port detection sensor 46a, and the sixth buffer 122f corresponds to the detection result of the second working port detection sensor 47a. The sixth signal is input, the seventh buffer 122g is input with the seventh signal corresponding to the detection result of the out port detection sensor 48a, and the sixteenth buffer 122p is instructed to output. No. is input.

  On the other hand, in the first embodiment, a signal corresponding to the opening / closing execution mode is input as the eighth signal to the eighth buffer 122h, and a signal corresponding to the high frequency support mode is input as the ninth signal to the ninth buffer 122i. Although the signal corresponding to the front door frame 14 is input to the tenth buffer 122j as the tenth signal, in the present embodiment, the buffers to which these signals are input are different. Specifically, a signal corresponding to the open / close execution mode is input to the thirteenth buffer 122m as an open / close execution mode signal, and a signal corresponding to the high frequency support mode is input to the fourteenth buffer 122n as a high frequency support mode signal. The signal corresponding to the front door frame 14 is input to the fifteenth buffer 122o as a door open signal.

  An open / close execution mode signal is input to the thirteenth buffer 122m, a high frequency support mode signal is input to the fourteenth buffer 122n, a door opening signal is input to the fifteenth buffer 122o, and It is determined at the design stage of the management IC 66 that the output instruction signal is input to the 16 buffer 122p, and the management CPU 112 does not receive an instruction from the main CPU 63, and the 13th to 16th buffers 122m to 122p. It is possible to specify that each of the signals corresponding to each is input. On the other hand, what type of signal is input to the first to twelfth buffers 122a to 122l is not determined at the design stage of the management IC 66, and the type of these signals receives an instruction from the main CPU 63. This is specified by the management CPU 112. The process for specifying the type of signal is executed when the supply of operating power to the main CPU 63 and the management CPU 112 is started, as in the first embodiment.

  FIG. 26 is a flowchart showing the recognition processing of this embodiment executed by the main CPU 63. Note that the recognition process is executed in step S110 in the main process (FIG. 7) as in the first embodiment.

  First, “12”, which is the number of first to twelfth buffers 122a to 122l to be recognized as signal types, is set in the recognition output counter of the main RAM 65 (step S1101). Thereafter, an identification start signal output process is executed (step S1102). In the output processing, output states of the first signal input to the first buffer 122a, the open / close execution mode signal input to the thirteenth buffer 122m, and the high frequency support mode signal input to the fourteenth buffer 122n Is set to the HI level to start outputting the identification start signal. The period for maintaining these signals at the HI level is set to a period sufficient for the management CPU 112 to recognize the output state of these signals.

  After that, information on the number of outputs corresponding to the current value of the recognition output counter of the main RAM 65 is read from the main ROM 64, and the read information on the number of outputs is set in an output counter provided in the main RAM 65 ( Step S1103). The output counter is a counter for the main CPU 63 to specify the output count of the type identification signal.

  In the present embodiment, when the management CPU 112 recognizes the types of signals input to the first buffer 122a to the twelfth buffer 122l, the number of winning balls set for the entrance portion corresponding to the type of signals. The type identification signal is output the same number of times. The management CPU 112 stores information corresponding to the number of times of receiving the type identification signal for each of the first buffer 122a to the twelfth buffer 122l in the first to twelfth corresponding relationship areas 123a to 123l of the correspondence memory 116. . That is, the type of the signal input to the first buffer 122a to the twelfth buffer 122l is grasped as the number of winning balls set for the pitching portion corresponding to the type of signal.

  In step S1103, when the value of the recognition output counter is “12”, “11”, or “10”, “10” corresponding to the number of prize balls in the general winning opening 31 is set in the output number counter. . When the value of the recognition output counter is “9”, “15” corresponding to the number of prize balls of the special electric prize winning device 32 is set in the output number counter. When the value of the recognition output counter is “8”, “1” corresponding to the number of prize balls in the first operation port 33 is set in the output number counter. When the value of the recognition output counter is “7”, “1” corresponding to the number of prize balls in the second operation port 34 is set in the output number counter. Further, when the value of the output counter for recognition is “6”, since the game ball is not paid out even if the game ball enters the out port 24a although it corresponds to the out port 24a, the output counter Set “0” to. Further, when the value of the recognition output counter is any one of “5” to “1”, the corresponding entry portion does not exist and is blank, so “0” is set to the output number counter.

  Thereafter, a start trigger signal output process is executed (step S1104). In the output process, the output of the start trigger signal is started by setting the output state of the first signal input to the first buffer 122a to the HI level. The period for maintaining the first signal at the HI level is set to a period sufficient for the management CPU 112 to recognize the output state of the first signal.

  Thereafter, on condition that the value of the output number counter of the main RAM 65 is not “0” (step S1105: YES), that is, on condition that a value of 1 or more is set in the output number counter in step S1103. The process proceeds to step S1106. In step S1106, a type identification signal output process is executed. In the output process, the output of the type identification signal is started by setting the output state of the second signal input to the second buffer 122b to the HI level. The period for maintaining the second signal at the HI level is set to a period sufficient for the management CPU 112 to recognize the output state of the second signal.

  Thereafter, 1 is subtracted from the value of the output number counter of the main RAM 65 (step S1107), and it is determined whether or not the value of the output number counter after the 1 subtraction is “0” (step S1108). When the value of the output number counter is 1 or more (step S1108: NO), the process returns to step S1106.

  If an affirmative determination is made in step S1105 or an affirmative determination is made in step S1108, an end trigger signal output process is executed (step S1109). In this output processing, the output of the end trigger signal is started by setting the output state of the third signal input to the third buffer 122c to the HI level. The period for maintaining the third signal at the HI level is set to a period sufficient for the management CPU 112 to recognize the output state of the third signal.

  Thereafter, 1 is subtracted from the value of the recognition output counter in the main RAM 65 (step S1110), and it is determined whether or not the value of the recognition output counter after the 1 subtraction is “0” (step S1111). If the value of the recognition output counter is 1 or more (step S1111: NO), the process returns to step S1103, and processing for recognizing the type of signal corresponding to the value of the recognition output counter after 1 subtraction is executed. To do.

  On the other hand, if the value of the recognition output counter is “0” (step S1111: YES), an identification end signal output process is executed (step S1112). In the output process, the respective output states of the third signal input to the third buffer 122c, the open / close execution mode signal input to the thirteenth buffer 122m, and the high frequency support mode signal input to the fourteenth buffer 122n Is set to the HI level, the output of the identification end signal is started. The period for maintaining these signals at the HI level is set to a period sufficient for the management CPU 112 to recognize the output state of these signals.

  Next, management processing in the present embodiment executed by the management side CPU 112 will be described with reference to the flowchart of FIG. The management process is started when the supply of operating power to the management CPU 112 is started, as in the first embodiment.

  When reception of the identification start signal from the main CPU 63 is completed (step S1201: YES), the value of the setting target counter in the management RAM 114 is cleared to “0” (step S1202). Thereafter, on condition that the start trigger signal is received from the main CPU 63 (step S1203: YES), the process proceeds to step S1204. In step S1204, it is determined whether a type identification signal is received from the main CPU 63 or not. When the type identification signal is received (step S1204: YES), 1 is added to the value of the reception number counter provided in the management side RAM 114 (step S1205). The reception counter is a counter for the management CPU 112 to specify the number of times the type identification signal is received from the main CPU 63. Note that the value of the reception number counter is cleared to “0” when an affirmative determination is made in step S1203.

  If a negative determination is made in step S1204, or if the process of step S1205 is executed, it is determined whether an end trigger signal is received from the main CPU 63 (step S1206). If the end trigger signal has not been received (step S1206: NO), the process returns to step S1204. If the end trigger signal has been received (step S1206: YES), the correspondence setting process is executed (step S1207). In the correspondence setting process, the reception number counter is set in the correspondence area corresponding to the current value in the setting target counter of the management RAM 114 in the first to twelfth correspondence areas 123a to 123l of the correspondence memory 116. Stores the value that is being stored. In this case, “10” corresponding to the number of winning balls of the general winning opening 31 is set in the first corresponding relationship area 123a, the second corresponding relationship area 123b, and the third corresponding relationship area 123c, and the fourth corresponding relationship area 123d. Is set to “15” corresponding to the number of prize balls of the special electric prize winning device 32, “1” corresponding to the number of prize balls of the first operation port 33 is set to the fifth correspondence area 123e, and the sixth correspondence relation is set. In the area 123f, “1” corresponding to the number of prize balls of the second working port 34 is set. Further, “0” is set in the seventh to twelfth corresponding relation areas 123g to 123l. Thereafter, 1 is added to the value of the setting target counter in the management-side RAM 114 (step S1208).

  If a negative determination is made in step S1203, or if the process of step S1208 is executed, it is determined whether or not reception of the identification end signal from the main CPU 63 has ended (step S1209). If the reception of the identification end signal has not been completed (step S1209: NO), the process returns to step S1203, and on condition that a start trigger signal is received from the main CPU 63 (step S1203: YES), the processing after step S1204 is performed. Run. If the reception of the identification end signal from the main CPU 63 has ended (step S1209: YES), the history setting process in step S1210 and the external output process in step S1211 are repeatedly executed.

  FIG. 28 is a time chart showing how correspondence information between the first to twelfth buffers 122a to 122l and the types of signals input to the buffers 122a to 122l are stored in the correspondence memory 116. 28A shows a period in which the output state of the first signal is at the HI level, FIG. 28B shows a period in which the output state of the second signal is at the HI level, and FIG. ) Shows a period in which the output state of the third signal is at the HI level, FIG. 28D shows a period in which the output state of the signal in the opening / closing execution mode is at the HI level, and FIG. FIG. 28F shows a period in which the output state of the high frequency support mode signal is at the HI level, and FIG. 28F shows the first to twelfth buffers 122a to 122l and the types of signals input to these buffers 122a to 122l. The execution period of the identification state in which the process for identifying the correspondence relationship is executed, FIG. 28 (g) shows the timing when the value of the reception number counter of the management RAM 114 is incremented by 1, and FIG. 28 (h) Management CPU 112 Correspondence relationship setting Te processing (step S1207) shows a timing of the execution of.

  As the supply of operating power to the main CPU 63 and the management CPU 112 is started, as shown in FIGS. 28 (a), 28 (d) and 28 (e), the first signal is supplied at the timing t1. The output states of the open / close execution mode signal and the high frequency support mode signal are changed from the LOW level to the HI level. Thereby, the output of the identification start signal from the main CPU 63 to the management CPU 112 is started. Thereafter, at timing t2, the output state of the first signal, the opening / closing execution mode signal, and the high frequency support mode signal is changed from the HI level to the LOW bell. Thereby, the output of the identification start signal from the main CPU 63 to the management CPU 112 is stopped. At the timing of t2, the management-side CPU 112 makes an affirmative determination in step S1201 of the management process (FIG. 27) to enter the identification state as shown in FIG.

  Thereafter, the output state of the first signal is maintained at the HI level as shown in FIG. 28A from the timing t3 to the timing t4. As a result, a start trigger signal is output to the management CPU 112. Then, the output state of the second signal is maintained at the HI level as shown in FIG. 28B from the timing t5 to the timing t7. Thus, the type identification signal is output once to the management CPU 112. In this case, at the timing of t6, the value of the reception number counter of the management side RAM 114 is incremented by 1 as shown in FIG.

  Thereafter, the output state of the third signal is maintained at the HI level as shown in FIG. 28C from the timing t8 to the timing t10. As a result, a termination trigger signal is output to the management CPU 112. In this case, the correspondence setting process is executed by the management CPU 112 as shown in FIG. Since the value of the reception number counter is “1” at the timing when the corresponding relationship setting process is executed, “1” is set as the corresponding relationship information in the corresponding relationship areas 123 a to 123 l in the corresponding relationship memory 116. Is stored.

  Thereafter, the output state of the first signal is maintained at the HI level as shown in FIG. 28A from the timing t11 to the timing t12. As a result, a start trigger signal is output to the management CPU 112. Then, as shown in FIG. 28 (b), each of the timing t13 to timing t15, timing t16 to timing t18, timing t19 to timing t21, and timing t22 to timing t24 is shown in FIG. The output state of the signal is maintained at the HI level. As a result, the type identification signal is output once to the management CPU 112. In this case, as shown in FIG. 28G, 1 is added to the value of the reception number counter in the management side RAM 114 at each of the timing t14, the timing t17, the timing t20, and the timing t23.

  Thereafter, the output state of the third signal is maintained at the HI level as shown in FIG. 28C from the timing t25 to the timing t27. As a result, a termination trigger signal is output to the management CPU 112. In this case, the correspondence setting process is executed by the management CPU 112 as shown in FIG. Since the value of the reception number counter is “10” at the timing when the corresponding relationship setting process is executed, “10” is set as the corresponding relationship information in the corresponding relationship areas 123 a to 123 l in the corresponding relationship memory 116. Is stored.

  Thereafter, at timing t28, as shown in FIGS. 28C, 28D, and 28E, the output state of the third signal, the open / close execution mode signal, and the high frequency support mode signal is LOW. Change from level to HI level. Thereby, the output of the identification end signal from the main CPU 63 to the management CPU 112 is started. Thereafter, at timing t29, the output state of the third signal, the opening / closing execution mode signal, and the high frequency support mode signal is changed from the HI level to the LOW bell. Thereby, the output of the identification end signal from the main CPU 63 to the management CPU 112 is stopped. At the timing of t29, the management CPU 112 makes an affirmative determination in step S1209 of the management process (FIG. 27), so that the identification state is canceled as shown in FIG.

  In this embodiment, since the information on the number of prize balls is stored as the correspondence information, the history information stored in the history memory 117 includes a prize ball corresponding to the entry part that triggered the storage of the history information. Number information is included as correspondence information. In this configuration, when there are a plurality of types of pitched portions having the same number of winning balls, the pitched portions cannot be distinguished in the history information. Specifically, since the first working port 33 and the second working port 34 each have one winning ball, it is possible to distinguish the first working port 33 and the second working port 34 in the history information. Can not. Under such circumstances, the number of prize balls of the first working port 33 and the second working port 34 may be different. Thereby, even if it is the structure where history information is stored like the 2nd embodiment, it becomes possible to distinguish the 1st operation mouth 33 and the 2nd operation mouth 34 in history information.

  In this embodiment, “15” is set in the confirmation target counter of the management side RAM 114 in step S801 of the history setting process. As a result, all of the first to fifteenth buffers 122a to 122o are to be confirmed.

  According to the present embodiment described in detail above, not only the output instruction signal but also information corresponding to whether or not the opening / closing execution mode is being performed, information corresponding to whether or not the high frequency support mode is being performed, and the front door With respect to information corresponding to whether or not the frame 14 is open, the management side CPU 112 can specify that the signal path corresponds to these pieces of information without receiving correspondence information from the main CPU 63. It has become. In this case, only information corresponding to the detection results of the respective ball detection sensors 42a to 48a is information that requires the management CPU 112 to recognize the correspondence between the information and the signal paths 118a to 118g from the main CPU 63. Become. When the management side CPU 112 is made to recognize the correspondence information, the same number of pulse signals as the number of winning balls corresponding to each of the entrance detection sensors 42a to 48a are transmitted from the main CPU 63 to the management CPU 112 using the second signal. Is output. Thereby, it becomes possible to simplify the structure regarding transmission of correspondence information.

<Third Embodiment>
The present embodiment is different from the first embodiment in that the calculation of various parameters using history information is executed. Hereinafter, a configuration different from that of the first embodiment will be described. The description of the same configuration as that of the first embodiment is basically omitted.

  FIG. 29 is a block diagram for explaining the electrical configuration of the management IC 66 in the present embodiment. As in the first embodiment, the management IC 66 includes a management side I / F 111, a management side CPU 112, a management side ROM 113, a management side RAM 114, an RTC 115, a correspondence relationship memory 116, and a history memory 117. These functions are the same as those in the first embodiment.

  In addition to the above, the management IC 66 is provided with a calculation result memory 131. In the present embodiment, when a calculation trigger occurs as will be described in detail later, various parameters are calculated by the management CPU 112 using history information stored in the history memory 117 at that time. The calculated various parameters are sequentially stored in the calculation result memory 131. Various parameters stored in the calculation result memory 131 are output to a reading device electrically connected to the reading terminal 102.

  Various parameters are triggered before the timing at which the reading device is electrically connected to the reading terminal 102. As a result, it is possible to vary the timing for calculating various parameters and the timing for externally outputting the parameters to the reading device, and the processing load can be distributed.

  In addition, since the calculation result memory 131 for storing calculation results of various parameters is provided, not only various parameters for one calculation trigger but also various parameters for a plurality of calculation triggers are collected. It becomes possible to memorize. As a result, it is possible to shorten the time required to calculate various parameters at each calculation opportunity.

  FIG. 30 is an explanatory diagram for explaining the configuration of the input port 121 of the management-side I / F 111 in the present embodiment.

  The first to tenth buffers 122a to 122j and the sixteenth buffer 122p receive the same types of signals as in the first embodiment. Specifically, the first buffer 122a receives a first signal corresponding to the detection result of the first winning opening detection sensor 42a, and the second buffer 122b receives the first signal corresponding to the detection result of the second winning opening detection sensor 43a. The second signal is input, the third signal corresponding to the detection result of the third prize opening detection sensor 44a is input to the third buffer 122c, and the fourth signal corresponding to the detection result of the special electricity detection sensor 45a is input to the fourth buffer 122d. The fifth buffer 122e receives a fifth signal corresponding to the detection result of the first working port detection sensor 46a, and the sixth buffer 122f corresponds to the detection result of the second working port detection sensor 47a. The sixth signal is input, the seventh buffer 122g is input with the seventh signal corresponding to the detection result of the out port detection sensor 48a, and the eighth buffer 122h is opened and closed. A signal corresponding to the high frequency support mode is input to the ninth buffer 122i, a signal corresponding to the front door frame 14 is input to the tenth buffer 122j, and a signal corresponding to the high frequency support mode is input to the sixteenth buffer 122p. Is supplied with an output instruction signal.

  In the present embodiment, in addition to the above various signals, a calculation instruction signal is input to the fifteenth buffer 122o. The calculation instruction signal is a signal output from the main CPU 63 to provide the calculation CPU of various parameters to the management CPU 112. The fact that the calculation instruction signal is input to the fifteenth buffer 122o is determined at the design stage of the management IC 66 in the same manner as the output instruction signal is input to the sixteenth buffer 122p. The management CPU 112 can specify that the signals corresponding to the fifteenth to sixteenth buffers 122o to 122p are input, respectively. On the other hand, what kind of signal is input to the first to fourteenth buffers 122a to 122n is not determined at the design stage of the management IC 66, and the type of these signals receives an instruction from the main CPU 63. This is specified by the management CPU 112. The process for specifying the type of signal is executed when the supply of operating power to the main CPU 63 and the management CPU 112 is started, as in the first embodiment.

  Next, a description will be given of a processing configuration for causing the management-side CPU 112 to perform various parameter calculations in response to occurrence of a calculation trigger. FIG. 31 is a flowchart showing a power failure information storage process executed by the main CPU 63. The power failure information storage process is executed in step S201 in the timer interrupt process (FIG. 8).

  In the power failure information storage process, when a power failure signal corresponding to the occurrence of power interruption is received from the power failure monitoring board 67 (step S1301: YES), a calculation instruction signal output process is executed (step S1302). In the output process, the output state of the calculation instruction signal input to the fifteenth buffer 122o in the input port 121 of the management-side I / F 111 is maintained at the HI level for a specific period. This specific period is sufficient for the management CPU 112 to recognize that the output state of the calculation instruction signal is at the HI level. Thereafter, after the power failure process is executed in step S1303, an infinite loop is established, and the process waits until the supply of operating power to the main CPU 63 is completely stopped. In the power failure process, “1” is set to the power failure flag of the main RAM 65, and a checksum is calculated and the calculated checksum is stored.

  FIG. 32 is a flowchart showing a power failure response process executed by the management CPU 112. The power failure handling process is executed after the external output process in the management process (FIG. 18). In the management process, after receiving an identification end command from the main CPU 63 (step S606: YES), step S607 is performed. The history setting process, the external output process in step S608, and the power failure handling process are repeatedly executed in this order.

  In the power failure response process, when the output state of the calculation instruction signal received from the main CPU 63 becomes the HI level (step S1401: YES), the external output in the first embodiment is performed in steps S1402 to S1406. As in steps S1002 to S1006 of the processing (FIG. 24), the number of balls entered for each of the out port 24a, the general winning port 31, the special winning device 32, the first operating port 33, and the second operating port 34 is calculated. . Further, in step S1407, as in step S1007 of the external output processing (FIG. 24) in the first embodiment, the number of various entering balls in the situation where the front door frame 14 is open is calculated. In step S1408, various parameters are calculated in the same manner as in step S1008 of the external output processing (FIG. 24) in the first embodiment. In step S1409, the external output in the first embodiment is calculated. Similar to step S1009 of the process (FIG. 24), the total time is calculated. Then, the calculation result information in step S1408 and the calculation result information in step S1409 are written in the calculation result memory 131 (step S1410). In this case, when other calculation result information is already stored in the calculation result memory 131, the calculation result information is written so as not to overwrite the already stored calculation result information. Do. Further, the current date information and time information are read from the RTC 115, and the read date information and time information are attached to the information of the operation result written this time. As a result, it is possible to specify when the information of the calculation result written this time corresponds to the timing.

  Thereafter, in step S1411, similarly to step S1011 of the external output process (FIG. 24) in the first embodiment, the number of various balls entered during the open / close execution mode is calculated, and in step S1412, the first number is entered. Similarly to step S1012 of the external output processing (FIG. 24) in the embodiment, the number of various entering balls in the open / close execution mode and the front door frame 14 being opened is calculated. In step S1413, various parameters are calculated in the same manner as in step S1013 of the external output process (FIG. 24) in the first embodiment. Then, the calculation result information in step S1414 is written in the calculation result memory 131 (step S1414). In this case, the calculation result information is written so as not to overwrite other calculation result information already stored in the calculation result memory 131. Further, the current date information and time information are read from the RTC 115, and the read date information and time information are attached to the information of the operation result written this time. As a result, it is possible to specify when the information of the calculation result written this time corresponds to the timing.

  Thereafter, in step S1415, as in step S1015 of the external output processing (FIG. 24) in the first embodiment, various numbers of incoming balls in the high frequency support mode are calculated. In step S1416, Similar to step S1016 of the external output processing (FIG. 24) in the first embodiment, the number of various entering balls is calculated in the high frequency support mode and the front door frame 14 is open. In step S1417, various parameters are calculated in the same manner as in step S1017 of the external output processing (FIG. 24) in the first embodiment. Then, the calculation result information in step S1417 is written in the calculation result memory 131 (step S1418). In this case, the calculation result information is written so as not to overwrite other calculation result information already stored in the calculation result memory 131. Further, the current date information and time information are read from the RTC 115, and the read date information and time information are attached to the information of the operation result written this time. As a result, it is possible to specify when the information of the calculation result written this time corresponds to the timing. Thereafter, an infinite loop is entered, and the system waits until supply of operating power to the management CPU 112 is completely stopped.

  FIG. 33 is a flowchart showing an external output process executed by the management CPU 112. The external output process is executed in step S608 of the management process (FIG. 18).

  When the output state of the output instruction signal from the main CPU 63 becomes the HI level (step S1501: YES), the calculation result output process is executed (step S1502). In the output process, various calculation results stored in the calculation result memory 131 are output to the reading terminal 102. Thereby, in the reading device electrically connected to the reading terminal 102, various calculation results stored in the calculation result memory 131 are read. In this case, when only various calculation results corresponding to the occurrence of one calculation trigger are stored in the calculation result memory 131, only various calculation results corresponding to the occurrence of the one calculation trigger are stored in the reading device. When various calculation results corresponding to occurrence of a plurality of calculation triggers are stored in the calculation result memory 131, various calculation results corresponding to the occurrence of the plurality of calculation triggers are read by the reading device. .

  Thereafter, a history information output process is executed (step S1503). In the output process, all the history information stored in the history area 124 of the history memory 117 is sequentially output to the reading terminal 102. As a result, the various history information stored in the history area 124 is read by the reading device electrically connected to the reading terminal 102. Thus, by outputting not only various calculation results but also history information, it becomes possible for a worker using the reading apparatus to perform detailed analysis on various calculation results.

  Thereafter, a clear process is executed (step S1504). In the clear process, all the history information storage areas 125 of the history memory 117 are cleared to “0” and the pointer area 126 is cleared to “0”. As a result, the history area 124 is initialized. In the clear process, all areas of the calculation result memory 131 are cleared to “0”. As a result, the calculation result memory 131 is initialized.

  According to the embodiment described in detail above, the following excellent effects are obtained.

  When the supply of operating power to the main CPU 63 is stopped, the management CPU 112 calculates various parameters. This makes it possible to manage various parameters for each business day.

  When it is specified that the supply of operating power is stopped in the main CPU 63, the management instruction CPU 112 calculates various parameters by changing the output state of the calculation instruction signal to the HI level. As a result, various parameters can be calculated by the management CPU 112 based on an instruction from the main CPU 63.

  Various parameters calculated by the management CPU 112 are sequentially written in the calculation result memory 131. As a result, various parameters can be accumulated in the management IC 66, and various parameters for a plurality of business days can be read together when the various parameters are read by the reading device.

  When various parameters are written in the calculation result memory 131, information that can specify the time when the various parameters are calculated is written in the calculation result memory 131 along with the various parameters. Thereby, it is possible to analyze various parameter information while grasping the time when various parameters are calculated.

  It should be noted that the history memory 117 may be cleared to “0” when a calculation trigger occurs and the calculation results of various parameters corresponding to the calculation trigger are written in the calculation result memory 131. This makes it difficult to generate an event in which new history information becomes a write target to the history memory 117 in a situation where the maximum number of history information that can be stored is already stored in the history memory 117.

  Further, the information to be externally output to the reading device is only information on various parameters stored in the calculation result memory 131, and the history information stored in the history memory 117 may not be output externally. . As a result, the amount of information output to the outside can be suppressed.

<Fourth Embodiment>
In the present embodiment, the processing configuration of the power failure response process executed by the management CPU 112 is different from that of the third embodiment. Hereinafter, a configuration different from the third embodiment will be described. The description of the same configuration as that of the third embodiment is basically omitted.

  FIG. 34 is a flowchart showing a power failure response process executed by the management CPU 112 in this embodiment.

  When the output state of the calculation instruction signal received from the main CPU 63 becomes HI level (step S1601: YES), various calculation processes are executed (step S1602). In various arithmetic processes, the processes of steps S1402 to S1409, steps S1411 to S1413, and steps S1415 to S1417 of the power failure response process (FIG. 32) in the third embodiment are executed.

Thereafter, it is determined whether or not a predetermined parameter among the various parameters calculated in step S1602 is within the reference range (step S1603). In particular,
7th parameter: (K3 × “the number of winning balls for winning in the special electricity winning device 32” + K5 × “the number of winning balls for winning in the second operating port 34”) / total number of game balls to be paid out (K2 × “general The number of winning balls for winning at the winning opening 31 + K3 × “the number of winning balls for winning at the special electricity winning device 32” + K4 × “the number of winning balls for winning at the first operating port 33” + K5 × “the second operating port 34” Ratio / eighth parameter: K3 × “number of winning balls for winning to the special electric prize device 32” / total number of game balls to be paid out (K2 × “for winning to the general winning opening 31”) “Number of winning balls” + K3 × “Number of winning balls for winning in the special electric prize winning device 32” + K4 × “Number of winning balls for winning in the first operating port 33” + K5 × “Number of winning balls for winning in the second operating port 34” )) Percentage of the two parameters It is set as a parameter to be determined whether or not it is within the reference range. If the value of the seventh parameter is 0.7 or less and the value of the eighth parameter is 0.6 or less, an affirmative determination is made in step S1603 as the predetermined parameter is in the reference range.

The predetermined parameters are not limited to the seventh parameter and the eighth parameter, and instead of or in addition to these, other parameters may be set as the predetermined parameters. For example,
Second parameter: The ratio of the total number of game balls entering the general winning opening 31 K2 / the total number of game balls discharged from the game area PA (K1 + K2 + K3 + K4 + K5) may be set as a predetermined parameter. . In this case, for example, when the value of the second parameter is 0.1 or more and 0.2 or less, the predetermined parameter may be determined to be in the reference range. Further, only a predetermined parameter to be determined in step S1603 may be calculated by various calculation processes in step S1602.

  If the predetermined parameter is not within the reference range (step S1603: NO), the various parameters calculated in step S1602 are written in the calculation result memory 131 (step S1604). In this case, when other calculation result information is already stored in the calculation result memory 131, the calculation result information is written so as not to overwrite the already stored calculation result information. Do. Further, the current date information and time information are read from the RTC 115, and the read date information and time information are attached to the information of the operation result written this time. As a result, it is possible to specify when the information of the calculation result written this time corresponds to the timing.

  On the other hand, when the predetermined parameter is within the reference range (step S1603: YES), the process of step S1604 is not executed. As a result, only the various parameters when the predetermined parameter is not within the reference range are written in the calculation result memory 131. Therefore, when an abnormal situation occurs, it is possible to suppress the storage capacity necessary for the calculation result memory 131 while leaving the history in the calculation result memory 131.

  When an affirmative determination is made in step S1603, or when the process of step S1604 is executed, a clear process for the history memory 117 is executed (step S1605). In the clear process, all the history information storage areas 125 of the history memory 117 are cleared to “0” and the pointer area 126 is cleared to “0”. As a result, the history area 124 is initialized. After executing the process of step S1605, an infinite loop is entered, and the process waits until the supply of operating power to the management CPU 112 is completely stopped.

  According to the present embodiment described above in detail, it is determined whether or not the contents of the calculated various parameters are included in the reference range, and only the various parameters determined to be included in the reference range are stored in the calculation result memory 131. Written. As a result, the amount of various parameters to be stored in the calculation result memory 131 can be suppressed, and the necessary storage capacity in the calculation result memory 131 can be suppressed.

<Fifth Embodiment>
In the present embodiment, the contents of the calculation trigger that causes the management-side CPU 112 to execute various parameter calculations are different from those in the third embodiment. Hereinafter, a configuration different from the third embodiment will be described. The description of the same configuration as that of the third embodiment is basically omitted.

  FIG. 35 (a) is a flowchart showing the trigger identification process executed by the main CPU 63. The trigger identification process is executed as a process when an affirmative determination is made in step S712 in the management output process (FIG. 20).

  It is determined whether or not a game ball has entered any one of the out port 24a, the general winning port 31, the special electricity winning device 32, the first operating port 33, and the second operating port 34 (step S1701). If an affirmative determination is made in step S1701, an addition process for a pitching counter provided in the main RAM 65 is executed (step S1702). In the addition process, the number of game balls that have entered any one of the out port 24a, the general winning port 31, the special winning device 32, the first operating port 33, and the second operating port 34 is determined as the number of processing balls this time. The management output process (FIG. 20) specifies the number of times step S705 has been executed. Then, the specified number of game balls is added to the entrance counter.

  Thereafter, it is determined whether or not the value of the entrance counter is equal to or greater than the trigger reference number “500” (step S1703). If it is “500” or more (step S1703: YES), the entrance counter subtraction process of the main RAM 65 is executed (step S1704). In the subtraction process, “500” is subtracted from the value of the entrance counter. Thereafter, a calculation instruction signal output process is executed (step S1705). In the output process, the output state of the calculation instruction signal input to the fifteenth buffer 122o in the input port 121 of the management-side I / F 111 is maintained at the HI level for a specific period. This specific period is sufficient for the management CPU 112 to recognize that the output state of the calculation instruction signal is at the HI level.

  FIG. 35B is a flowchart showing the calculation process executed by the management CPU 112. The arithmetic process is a process executed instead of the power failure response process in the third embodiment. Therefore, the calculation process is executed after the external output process in the management process (FIG. 18). In the management process, after receiving the identification end command from the main CPU 63 (step S606: YES), the process of step S607 is performed. The history setting process, the external output process in step S608, and the calculation process are repeatedly executed in this order.

  When the output state of the calculation instruction signal received from the main CPU 63 becomes the HI level (step S1801: YES), various calculation processes are executed (step S1802). In various arithmetic processes, the same processes as steps S1402 to S1418 of the power failure handling process (FIG. 32) in the third embodiment are executed.

  According to the present embodiment described in detail above, each time the total number of game balls discharged from the game area PA is equal to or greater than the trigger reference number, the management CPU 112 calculates various parameters. In this case, since various parameters are calculated every time a calculation trigger occurs repeatedly in a situation where the operating power is supplied to the main CPU 63, the game balls enter the game area PA within one business day. It becomes possible to manage the mode in detail.

  In addition, since various parameters are calculated based on whether or not the total number of game balls discharged from the game area PA is greater than or equal to the trigger reference number, the various parameters are set on condition that the game is being executed. Is calculated. This makes it possible to prevent various parameters from being calculated meaninglessly in a situation where the game is not continuously executed.

<Sixth Embodiment>
In the present embodiment, the contents of the calculation trigger for causing the management CPU 112 to execute various parameter calculations are different from those in the fifth embodiment. Hereinafter, a configuration different from that of the fifth embodiment will be described. The description of the same configuration as that of the fifth embodiment is basically omitted.

  FIG. 36 is a flowchart showing a trigger identification process executed by the main CPU 63. The trigger identification process is executed as a process when an affirmative determination is made in step S712 in the management output process (FIG. 20).

  It is determined whether or not a game ball has entered any one of the out port 24a, the general winning port 31, the special electricity winning device 32, the first operating port 33, and the second operating port 34 (step S1901). If a negative determination is made in step S1901, 1 is added to the value of the continuation counter provided in the main RAM 65 (step S1902). The continuation counter is a main CPU 63 during a period in which no game ball enters any of the out port 24a, the general winning port 31, the special electric winning device 32, the first operating port 33, and the second operating port 34. It is a counter for specifying by.

  If the value of the continuation counter after adding 1 is equal to or greater than the stop reference value (step S1903: YES), the time measurement flag provided in the main RAM 65 is cleared to “0” (step S1904). If the game ball does not enter any of the out port 24a, the general winning port 31, the special prize winning device 32, the first operating port 33 and the second operating port 34 for 5 seconds, an affirmative determination is made in step S1903. The stop reference value is set to The time measurement flag is a flag for specifying whether or not the main CPU 63 should measure time for specifying the timing for switching the output state of the calculation instruction signal to the HI level. When the value of “0” is “0”, the time is not measured, and when the value of the time measurement flag is “1”, the time is measured. If an affirmative determination is made in step S1901, "1" is set in the time measurement flag (step S1905).

  When a negative determination is made in step S1903, when the process of step S1904 is executed, or when the process of step S1905 is executed, on condition that “1” is set in the time measurement flag of the main RAM 65 ( Step S1906: YES), 1 is added to the value of the measurement counter provided in the main RAM 65 (Step S1907). The measurement counter is a counter used for measuring the time for specifying the timing for switching the output state of the calculation instruction signal to the HI level.

  It is determined whether or not the value of the measurement counter after adding 1 is equal to or greater than the instruction reference value (step S1908). The instruction reference value is set so that an affirmative determination is made in step S1908 when the time measured by the measurement counter reaches 10 hours. When an affirmative determination is made in step S1908, the value of the measurement counter is cleared to “0” (step S1909), and the calculation instruction signal output process is executed (step S1910). In the output process, the output state of the calculation instruction signal input to the fifteenth buffer 122o in the input port 121 of the management-side I / F 111 is maintained at the HI level for a specific period. This specific period is sufficient for the management CPU 112 to recognize that the output state of the calculation instruction signal is at the HI level.

  According to the embodiment described in detail above, since the various parameters are calculated every time the predetermined period elapses, it is possible to easily adjust the calculation frequency of the various parameters only by adjusting the predetermined period. Become. In this case, in a situation where the game is not executed, the measurement for a predetermined period is stopped, and when the game round is started, the measurement for the predetermined period is resumed from the state before the stop. As a result, it is possible to exclude a situation in which a game is not being executed from calculation targets of various parameters, and it is possible to appropriately derive various parameters in a situation in which a game is being executed.

  In addition, it is good also as a structure measured using RTC115 instead of the structure measured using a measurement counter whether the predetermined period passed.

<Seventh Embodiment>
In the present embodiment, the contents of the calculation trigger that causes the management-side CPU 112 to execute the calculation of various parameters are different from those in the first embodiment, and the presence or absence of the calculation trigger is specified by the main CPU 63. Instead, it is performed independently by the management CPU 112. Hereinafter, a configuration different from that of the first embodiment will be described. The description of the same configuration as that of the first embodiment is basically omitted.

  FIG. 37 is a flowchart showing the calculation process executed by the management CPU 112. The calculation process is executed when an affirmative determination is made in step S812 in the history setting process (FIG. 21).

  Corresponding to a game ball having entered one of the out port 24a, the general winning port 31, the special winning device 32, the first operating port 33, and the second operating port 34 in the history setting process of the current processing time It is determined whether history information to be stored is stored in the history memory 117 (step S2001). When an affirmative determination is made in step S2001, an addition process of a ball counter provided in the management-side RAM 114 is executed (step S2002). In the addition process, the number of game balls that have entered any one of the out port 24a, the general winning port 31, the special winning device 32, the first operating port 33, and the second operating port 34 is determined as the number of processing balls this time. In the history setting process, the history information corresponding to the occurrence of the game ball entering is specified based on the number of times stored. Then, the specified number of game balls is added to the entrance counter.

  Thereafter, it is determined whether or not the value of the entrance counter is equal to or greater than the trigger reference number “500” (step S2003). If it is “500” or more (step S2003: YES), the entrance counter subtraction process of the main RAM 65 is executed (step S2004). In the subtraction process, “500” is subtracted from the value of the entrance counter. Thereafter, various arithmetic processes are executed (step S2005). In various arithmetic processes, the same processes as steps S1402 to S1418 of the power failure handling process (FIG. 32) in the third embodiment are executed.

  According to the present embodiment described in detail above, each time the total number of game balls discharged from the game area PA is equal to or greater than the trigger reference number, the management CPU 112 calculates various parameters. In this case, since various parameters are calculated every time a calculation trigger occurs repeatedly in a situation where the operating power is supplied to the main CPU 63, the game balls enter the game area PA within one business day. It becomes possible to manage the mode in detail.

  In addition, since various parameters are calculated based on whether or not the total number of game balls discharged from the game area PA is greater than or equal to the trigger reference number, the various parameters are set on condition that the game is being executed. Is calculated. This makes it possible to prevent various parameters from being calculated meaninglessly in a situation where the game is not continuously executed.

  Further, the total number of game balls discharged from the game area PA is measured by the management CPU 112, and the management CPU 112 determines whether or not the total number is equal to or greater than the trigger reference number. In other words, the management CPU 112 uniquely determines the calculation trigger of various parameters. As a result, it is not necessary for the main CPU 63 to execute a process for determining the calculation trigger of various parameters, and thus the processing load on the main CPU 63 can be reduced.

<Eighth Embodiment>
In the present embodiment, the processing configuration of the history setting process executed by the management CPU 112 is different from that of the first embodiment. Hereinafter, a configuration different from that of the first embodiment will be described. The description of the same configuration as that of the first embodiment is basically omitted.

  In the present embodiment, the calculation result memory 131 is provided in the management IC 66 as in the third embodiment (see FIG. 29). When a calculation trigger occurs, the management CPU 112 calculates various parameters using the history information stored in the history memory 117 and writes the various parameters of the calculation result in the calculation result memory 131. In the present embodiment, a signal indicating that the opening / closing execution mode has started, a signal indicating that the opening / closing execution mode has ended, a signal indicating that the high-frequency support mode has started, and a high-frequency support mode are provided. A signal indicating that the opening of the front door frame 14 has started, and a signal indicating that the opening of the front door frame 14 has ended are individually transmitted from the main CPU 63 to the management IC 66. Sent to.

  FIG. 38 is a flowchart showing history setting processing in the present embodiment, which is executed by the management CPU 112.

  First, the number of buffers to be checked by the management CPU 112 among the first to fifteenth buffers 122a to 122o is set in the check target counter of the management RAM 114 (step S2101). Specifically, the number of correspondence areas in which information other than information indicating blank is stored among the first to fifteenth correspondence areas 123a to 123o in the correspondence relationship memory 116 is identified, and the identification is performed. Set the number of information to the check target counter. In the present embodiment, the first to seventh correspondence relationship areas 123a to 123g store information indicating that it corresponds to any of the entrance parts, and the eighth correspondence relationship area 123h starts the opening / closing execution mode. Corresponding information is stored, information corresponding to the end of the opening / closing execution mode is stored in the ninth corresponding relationship area 123i, and information corresponding to the start of the high frequency support mode is stored in the tenth corresponding relationship area 123j. The information corresponding to the end of the high frequency support mode is stored in the eleventh corresponding relationship area 123k, and the information corresponding to the opening start of the front door frame 14 is stored in the twelfth corresponding relationship area 123l. In the thirteenth correspondence area 123m, information corresponding to the end of opening of the front door frame 14 is stored. Therefore, in step S2101, “13” is set in the check target counter.

  After that, it is confirmed whether or not the numerical information stored in the buffer corresponding to the current value of the check target counter among the first to fifteenth buffers 122a to 122o has been changed from “0” to “1”. Thus, it is determined whether or not the output state of the input signal from the main CPU 63 to the buffer has been switched from the LOW level to the HI level (step S2102). In addition, when the value of the confirmation target counter is “n”, the nth buffers 122a to 122o are the confirmation targets of the numerical information. For example, if the value of the check target counter is “10”, the tenth buffer 122j is a check target for numerical information, and if the value of the check target counter is “5”, the fifth buffer 122e is a check target for numerical information. .

  When an affirmative determination is made in step S2102, RTC information that is date information and time information is read from the RTC 115 (step S2103). Then, the writing process to the history memory 117 is executed (step S2104). In the writing process, the pointer information of the history area 124 that is the current writing target is specified by referring to the pointer area 126 of the history memory 117 and corresponds to the pointer information that is the writing target. The RTC information read in step S2103 is written in the history information storage area 125 of the history area 124. Also, the correspondence information is read out from the correspondence areas 123a to 123o corresponding to the current value of the check target counter, and the correspondence information is written into the history information storage area 125 corresponding to the pointer information that is the write target. Note that when the value of the confirmation target counter is “n”, the n-th correspondence relationship areas 123a to 123o are the correspondence information readout targets. For example, if the value of the confirmation target counter is “10”, the tenth correspondence area 123j is a target for reading correspondence information, and if the value of the confirmation target counter is “5”, the fifth correspondence area 123e is correspondence. Information is to be read out.

  Thereafter, 1 is added to the value of the target pointer (step S2105). Specifically, the numerical information stored in the pointer area 126 of the history memory 117 is read, and the numerical information is incremented by one. Then, it is determined whether or not the pointer information after the addition of 1 exceeds the maximum value of the pointer information in the history area 124 (step S2106).

  If the maximum value is exceeded (step S2106: YES), various arithmetic processes are executed (step S2107). In various arithmetic processes, the same processes as those in steps S1002 to S1009, steps S1011 to S1013, and steps S1015 to S1017 of the external output process (FIG. 24) in the first embodiment are executed. Then, various parameters of the calculation result and information on the total time are written in the calculation result memory 131 (step S2108). In this case, when other calculation result information is already stored in the calculation result memory 131, the calculation result information is written so as not to overwrite the already stored calculation result information. Do. Further, the current date information and time information are read from the RTC 115, and the read date information and time information are attached to the information of the operation result written this time. As a result, it is possible to specify when the information of the calculation result written this time corresponds to the timing.

  After that, state information takeover processing is executed (step S2109). In the handover process, based on the history information stored in the history memory 117, whether the current state is the open / close execution mode, whether the high-frequency support mode is being used, and the front door frame 14 is being opened. It is determined whether or not. Then, the state information is written in the management side RAM 114.

  Thereafter, the history memory 117 is cleared (step S2110). In the clear process, all the history information storage areas 125 of the history memory 117 are cleared to “0” and the pointer area 126 is cleared to “0”. As a result, the history area 124 is initialized. Further, after executing the clear process, the state information written in the management-side RAM 114 is read in step S2109. If state information indicating that the opening / closing execution mode is being stored is stored in the history information storage area 125 corresponding to the pointer information to be written, the history information indicating that the opening / closing execution mode is being stored. In addition to writing, 1 is added to the pointer information to be written. In addition, when status information indicating that the high-frequency support mode is being stored, history information storage area corresponding to the pointer information to which the history information indicating that the high-frequency support mode is being written is written In addition to writing to 125, pointer information to be written is incremented by one. When state information indicating that the front door frame 14 is open is stored, history information indicating that the front door frame 14 is open corresponds to the pointer information to be written. While writing to the history information storage area 125, the pointer information to be written is incremented by one.

  If a negative determination is made in step S2102, a negative determination is made in step S2106, or if the process of step S2110 is executed, the value of the check target counter in the management side RAM 114 is decremented by 1 (step S2111). Then, it is determined whether or not the value of the check target counter after the 1 subtraction is “0” (step S2112). When the value of the confirmation target counter is 1 or more (step S2112: NO), the processing after step S2102 is executed for the confirmation target corresponding to the new value of the confirmation target counter.

  According to the present embodiment described in detail above, various parameters are calculated when the history information stored in the history memory 117 exceeds the upper limit number that can be stored in the history memory 117. As a result, it is possible to prevent the occurrence of a situation in which the history information becomes a storage target exceeding the upper limit number that can be stored in the history memory 117 and the calculation of various parameters cannot be performed accurately.

  Further, when various parameters are calculated, the history memory 117 is initialized and all history information is erased. This makes it possible to prevent history information that has already been subject to calculation of various parameters from becoming subject to computation of various parameters again.

  Even when the history memory 117 is initialized, the state information takeover process is executed. Thereby, it becomes possible to manage state information appropriately.

<Ninth Embodiment>
In the present embodiment, the configuration of the history memory 117 and the processing configuration of the history setting process executed by the management CPU 112 are different from those in the first embodiment. Hereinafter, a configuration different from that of the first embodiment will be described. The description of the same configuration as that of the first embodiment is basically omitted.

  FIG. 39 is an explanatory diagram for explaining the configuration of the history memory 117 in the present embodiment. The history memory 117 is provided with a total area 141, a first state area 142, a second state area 143, and a third state area 144. Each of these areas 141 to 144 is provided with first to fifteenth counters 141a to 141o, 142a to 142o, 143a to 143o, and 144a to 144o. Information on the number of times the output state of the first signal input to the first buffer 122a is changed from the LOW level to the HI level is stored in the first counters 141a to 144a of the respective areas 141 to 144. Information on the number of times the output state of the second signal input to the second buffer 122b is changed from the LOW level to the HI level is stored in the second counters 141b to 144b of the respective areas 141 to 144. Information on the number of times the output state of the third signal input to the third buffer 122c is changed from the LOW level to the HI level is stored in the third counters 141c to 144c of the respective areas 141 to 144. Information on the number of times the output state of the fourth signal input to the fourth buffer 122d is changed from the LOW level to the HI level is stored in the fourth counters 141d to 144d of the respective areas 141 to 144. Information on the number of times the output state of the fifth signal input to the fifth buffer 122e is changed from the LOW level to the HI level is stored in the fifth counters 141e to 144e of the respective areas 141 to 144. Information on the number of times the output state of the sixth signal input to the sixth buffer 122f is changed from the LOW level to the HI level is stored in the sixth counters 141f to 144f of the respective areas 141 to 144. Information on the number of times the output state of the seventh signal input to the seventh buffer 122g is changed from the LOW level to the HI level is stored in the seventh counters 141g to 144g of the respective areas 141 to 144. Information on the number of times the output state of the eighth signal input to the eighth buffer 122h is changed from the LOW level to the HI level is stored in the eighth counters 141h to 144h of the respective areas 141 to 144. Information on the number of times the output state of the ninth signal input to the ninth buffer 122i is changed from the LOW level to the HI level is stored in the ninth counters 141i to 144i of the respective areas 141 to 144. Information on the number of times the output state of the tenth signal input to the tenth buffer 122j is changed from the LOW level to the HI level is stored in the tenth counters 141j to 144j of the respective areas 141 to 144. Information on the number of times the output state of the eleventh signal input to the eleventh buffer 122k is changed from the LOW level to the HI level is stored in the eleventh counters 141k to 144k of the respective areas 141 to 144. Information on the number of times the output state of the twelfth signal input to the twelfth buffer 122l is changed from the LOW level to the HI level is stored in the twelfth counters 141l to 144l of the respective areas 141 to 144. Information on the number of times the output state of the thirteenth signal input to the thirteenth buffer 122m is changed from the LOW level to the HI level is stored in the thirteenth counters 141m to 144m of the respective areas 141 to 144. Information on the number of times the output state of the fourteenth signal input to the fourteenth buffer 122n is changed from the LOW level to the HI level is stored in the fourteenth counters 141n to 144n of the respective areas 141 to 144. Information on the number of times the output state of the 15th signal input to the 15th buffer 122o is changed from the LOW level to the HI level is stored in the 15th counters 141o to 144o of the respective areas 141 to 144.

  However, the measurement targets using the first to fifteenth counters 141a to 141o, 142a to 142o, 143a to 143o, and 144a to 144o are the out port 24a, the general winning port 31, the special winning device 32, and the first operation. These are first to seventh buffers 122a to 122g to which signals corresponding to the result of entering the ball to either the mouth 33 or the second working port 34 are input. Accordingly, signals corresponding to state information such as whether the opening / closing execution mode is being used, whether the high-frequency support mode is being used, and whether the front door frame 14 is being opened are input to the eighth to eighth signals. The 10 buffers 122h to 122j are excluded from the measurement target. The distinction of whether or not these are measurement targets is performed based on the correspondence information stored in the correspondence areas 123a to 123o of the correspondence memory 116.

  FIG. 40 is a flowchart showing history setting processing in the present embodiment, which is executed by the management CPU 112.

  First, the number of buffers subject to confirmation in the management CPU 112 among the first to fifteenth buffers 122a to 122o is set in the confirmation target counter of the management RAM 114 (step S2201). Specifically, the number of correspondence areas in which information other than information indicating blank is stored among the first to fifteenth correspondence areas 123a to 123o in the correspondence relationship memory 116 is identified, and the identification is performed. Set the number of information to the check target counter. In this pachinko machine 10, since information other than information indicating blank is stored in the first to tenth corresponding relationship areas 123a to 123j as already described, in step S2201, "10" is set in the check target counter. To do.

  Thereafter, it is determined whether or not the buffers 122a to 122o corresponding to the current check target counter are buffers to which a status information signal is input (step S2202). Specifically, in the corresponding relationship areas 123a to 123o corresponding to the value of the current check target counter, as the corresponding relationship information, information indicating the open / close execution mode, information indicating the high frequency support mode, and It is determined whether any of the information indicating the front door frame 14 is stored.

  If a positive determination is made in step S2202, state information setting processing is executed (step S2203). In the setting process, when the output state of the eighth signal indicating whether or not in the opening / closing execution mode is switched from the LOW level to the HI level, information on the first state indicating that the opening / closing execution mode is in effect is displayed on the management side. When the output state of the eighth signal is switched from the HI level to the LOW level, the information on the first state is deleted from the management side RAM 114. Further, when the output state of the ninth signal indicating whether or not the high-frequency support mode is in operation is switched from the LOW level to the HI level, information on the second state indicating that the high-frequency support mode is in operation is stored in the management-side RAM 114. When the output state of the ninth signal is switched from the HI level to the LOW level, the information on the second state is erased from the management-side RAM 114. In addition, when the output state of the tenth signal indicating whether or not the front door frame 14 is open is switched from the LOW level to the HI level, information on the third state indicating that the front door frame 14 is open. Is stored in the management-side RAM 114, and when the output state of the tenth signal is switched from the HI level to the LOW level, the information on the third state is deleted from the management-side RAM 114.

  If a negative determination is made in step S2202, the buffer corresponding to the current value of the check target counter among the first to fifteenth buffers 122a to 122o is stored in a buffer to which an information signal different from the state information is input. Whether the output state of the input signal from the main CPU 63 to the buffer is switched from the LOW level to the HI level by confirming whether or not the numerical value information that has been changed from “0” to “1”. It is determined whether or not (step S2204). If an affirmative determination is made in step S2204, the corresponding sum counter is added (step S2205). In the addition process, one of the counter values corresponding to the current value of the check target counter among the first to fifteenth counters 141a to 141o for summation in the summation area 141 of the history memory 117 is added. For example, if the value of the confirmation target counter is “5”, the total fifth counter 141e is an addition target, and if the value of the confirmation target counter is “1”, the total first counter 141a is an addition target. .

  Thereafter, by referring to the state information in the management-side RAM 114, it is determined whether or not it is in the first state, that is, whether or not it is in the opening / closing execution mode (step S2206). If it is in the first state (step S2206: YES), the corresponding counter processing for the first state is added (step S2207). In the addition process, one of the counter values corresponding to the current value of the check target counter among the first to fifteenth counters 142a to 142o for the first state in the first state area 142 of the history memory 117 is added. . For example, if the value of the confirmation target counter is “5”, the fifth counter 142e for the first state is an addition target, and if the value of the confirmation target counter is “1”, the first counter 142a for the first state is Can be added.

  Thereafter, by referring to the status information in the management side RAM 114, it is determined whether or not it is in the second state, that is, whether or not it is in the high frequency support mode (step S2208). If it is in the second state (step S2208: YES), the corresponding second state counter addition processing is executed (step S2209). In the addition process, the counter value corresponding to the current value of the check target counter among the first to fifteenth counters 143a to 143o for the second state in the second state area 143 of the history memory 117 is incremented by one. . For example, if the value of the confirmation target counter is “5”, the fifth counter 143e for the second state is an addition target, and if the value of the confirmation target counter is “1”, the first counter 143a for the second state is Can be added.

  Thereafter, by referring to the state information in the management-side RAM 114, it is determined whether or not the state is the third state, that is, whether or not the front door frame 14 is open (step S2210). If it is in the third state (step S2210: YES), the corresponding third state counter addition process is executed (step S2211). In the addition process, the counter value corresponding to the current value of the check target counter among the first to fifteenth counters 144a to 144o for the third state in the third state area 144 of the history memory 117 is incremented by one. . For example, if the value of the check target counter is “5”, the fifth counter 144e for the third state is an addition target, and if the value of the check target counter is “1”, the first counter 144a for the third state is set. Can be added.

  When the process of step S2203 is executed, when a negative determination is made at step S2204, when a negative determination is made at step S2210, or when the process of step S2211 is executed, the value of the check target counter in the management side RAM 114 is set to 1. Subtraction is performed (step S2212). Then, it is determined whether or not the value of the check target counter after the 1 subtraction is “0” (step S2213). When the value of the confirmation target counter is 1 or more (step S2213: NO), the processing after step S2202 is executed for the confirmation target corresponding to the new value of the confirmation target counter.

  By executing the history setting process as described above, the game ball entry history to the out port 24a, the general winning port 31, the special prize winning device 32, the first operating port 33 and the second operating port 34 is as described above. Rather than being stored as history information as in the first embodiment, it is stored as information on the number of times a game ball has been detected by each of the incoming ball detection sensors 42a to 48a. As a result, the storage capacity required in the history memory 117 can be reduced as compared with a configuration in which each history information is stored individually.

  As described above, since the number of times that the game balls are detected by the respective ball detection sensors 42a to 48a are stored, in the external output process (FIG. 24) in the present embodiment, the out port 24a such as step S1002 is stored. A process for calculating the number of game balls that enter the game, a process for calculating the number of game balls that enter the special electric prize device 32 such as step S1004, and the number of game balls that enter the first operation port 33 such as step S1005. Processing to calculate and processing to calculate the number of game balls entering the second operation port 34 such as step S1006 are not required. Thereby, it is possible to reduce the processing load for calculating various parameters.

  In the process of calculating the number of game balls that enter the general winning opening 31 such as step S1003, the first to third counters 141a to 141c, 142a to 142c, 143a to 143c, and 144a to 144c are all general winning openings. Therefore, it is necessary to execute a process of summing the values of the first to third counters 141a to 141c, 142a to 142c, 143a to 143c, and 144a to 144c. Further, the number of balls entered in the situation where the opening / closing execution mode is in progress and the front door frame 14 is open cannot be distinguished from the number of balls entered in other situations. Therefore, the process of step S1012 is not executed in the external output process (FIG. 24) in this embodiment. Similarly, the number of balls entered in the situation where the high-frequency support mode is in progress and the front door frame 14 is open cannot be distinguished from the number of balls entered in other situations. Therefore, the process of step S1016 is not executed in the external output process (FIG. 24) in this embodiment.

<Tenth Embodiment>
In this embodiment, the storage means for storing history information is different from that in the first embodiment. Hereinafter, a configuration different from that of the first embodiment will be described. The description of the same configuration as that of the first embodiment is basically omitted.

  FIG. 41 is a block diagram for explaining the electrical configuration of the MPU 62 in the present embodiment. Similar to the first embodiment, the MPU 62 includes a main CPU 63, a main ROM 64, a main RAM 65, a management IC 66, an I / F 101, and a reading terminal 102. Further, the management IC 66 is provided with a management side I / F 111, a management side CPU 112, a management side ROM 113, and a management side RAM 114, as in the first embodiment.

  On the other hand, in the present embodiment, unlike the first embodiment, the management IC 66 is not provided with the RTC 115, the correspondence relationship memory 116, and the history memory 117. Instead, the management IC 66 is provided with a calculation result memory 131 as in the third embodiment. Since the RTC 115, the correspondence relationship memory 116, and the history memory 117 are not provided in the management IC 66, the history information is not stored in the management IC 66 in this embodiment. In the present embodiment, the entry RAM of the out port 24 a, the general winning port 31, the special electricity winning device 32, the first operating port 33 and the second operating port 34 is stored in the main RAM 65. That is, the main RAM 65 that temporarily stores information necessary for executing a program in the main CPU 63 is also used as a memory for storing the entry history. The management IC 66 can access the main side RAM 65 through the management side I / F 111. When an operation trigger of various parameters occurs, the management IC 66 accesses the main side RAM 65 to read the entry history, and reads the read history. Various parameters are calculated using the entry history. The calculated various parameters are stored in the calculation result memory 131. When a reading device is electrically connected to the reading terminal 102, various parameters are provided from the calculation result memory 131 to the reading device, while the ball entry history stored in the main RAM 65 is not provided to the reading device. .

  FIG. 42 is a flowchart showing the entrance detection process in the present embodiment which is executed by the main CPU 63. The ball entry detection process is executed in step S209 of the timer interruption process (FIG. 8).

  When it is confirmed that the situation in which the information “0” is stored for the 0th bit D0 is switched to the situation in which the information “1” is stored, the first winning opening detection sensor 42a sets 1 It is determined that one game ball has been detected (step S2301: YES). In this case, 1 is added to the value of the general winning counter provided in the main RAM 65 (step S2302). The general winning counter is a counter for storing the number of balls entered into the general winning opening 31 as a pitching history. The value of the general winning counter is cleared to “0” when a reading device is electrically connected to the reading terminal 102 and various parameters are read from the calculation result memory 131 by the reading device. Incidentally, since the backup power is supplied to the main RAM 65 even when the operating power supply to the MPU 62 is stopped, even if the pachinko machine 10 is turned off, the value of the general winning counter is Retained. Thereafter, 1 is added to the value of the ten prize ball counters in the main RAM 65 (step S2303).

  When it is confirmed that the situation in which the information “0” is stored for the first bit D1 has been switched to the situation in which the information “1” is stored, the second winning opening detection sensor 43a sets 1 It is determined that one game ball has been detected (step S2304: YES). In this case, 1 is added to the value of the general winning counter in the main RAM 65 (step S2305). Thereafter, 1 is added to the value of the ten prize ball counter in the main RAM 65 (step S2306).

  When it is confirmed that the situation in which the information “0” is stored for the second bit D2 has been switched to the situation in which the information “1” is stored, the third winning opening detection sensor 44a sets 1 It is determined that one game ball has been detected (step S2307: YES). In this case, 1 is added to the value of the general winning counter in the main RAM 65 (step S2308). Thereafter, 1 is added to the value of the ten prize ball counter in the main RAM 65 (step S2309).

  When it is confirmed that the situation in which the information “0” is stored in the third bit D3 is switched to the situation in which the information “1” is stored, the special electric power detection sensor 45a makes one game It is determined that a sphere has been detected (step S3210: YES). In this case, “1” is set in the special electricity winning flag of the main RAM 65 (step S2311). Further, 1 is added to the value of the special prize winning counter provided in the main RAM 65 (step S2312). The special electric prize winning counter is a counter for storing the number of balls entered into the special electric prize winning device 32 as a pitching history. The value of the special electric prize counter is cleared to “0” when a reading device is electrically connected to the reading terminal 102 and various parameters are read from the calculation result memory 131 by the reading device. Incidentally, since the backup power is supplied to the main RAM 65 even when the operation power supply to the MPU 62 is stopped, even if the pachinko machine 10 is turned off, the value of the special prize winning counter is Retained. Thereafter, the value of the 15 prize ball counters in the main RAM 65 is incremented by 1 (step S2313).

  When it is confirmed that the situation in which the information “0” is stored in the fourth bit D4 is switched to the situation in which the information “1” is stored, the first operating port detection sensor 46a sets 1 It is determined that one game ball has been detected (step S2314: YES). In this case, “1” is set to the first operation winning flag of the main RAM 65 (step S2315). Further, 1 is added to the value of the first operation counter provided in the main RAM 65 (step S2316). The first operation counter is a counter for storing the number of entering the first operation port 33 as an entry history. The value of the first operation counter is cleared to “0” when a reading device is electrically connected to the reading terminal 102 and various parameters are read from the calculation result memory 131 by the reading device. . Incidentally, since the backup power is supplied to the main RAM 65 even when the operation power supply to the MPU 62 is stopped, even if the pachinko machine 10 is turned off, the value of the first operation counter Is retained. Thereafter, 1 is added to the value of the single prize ball counter in the main RAM 65 (step S2317).

  When it is confirmed that the situation in which the information “0” is stored in the fifth bit D5 is switched to the situation in which the information “1” is stored, the second operating port detection sensor 47a sets 1 It is determined that one game ball has been detected (step S2318: YES). In this case, “1” is set to the second operation winning flag of the main RAM 65 (step S2319). Further, the value of the second operation counter provided in the main RAM 65 is incremented by 1 (step S2320). The second operation counter is a counter for storing the number of balls entering the second operation port 34 as a ball entry history. The value of the second operation counter is cleared to “0” when a reading device is electrically connected to the reading terminal 102 and various parameters are read from the calculation result memory 131 by the reading device. . Incidentally, since the backup power is supplied to the main RAM 65 even when the operation power supply to the MPU 62 is stopped, even if the pachinko machine 10 is turned off, the value of the second operation counter Is retained. Thereafter, 1 is added to the value of the single prize ball counter in the main RAM 65 (step S2321).

  When it is confirmed that the situation in which the information “0” is stored in the sixth bit D6 is switched to the situation in which the information “1” is stored, the out-port detection sensor 48a provides one It is determined that a game ball has been detected (step S2322: YES). In this case, 1 is added to the value of the out counter provided in the main RAM 65 (step S2323). The out counter is a counter for storing the number of balls entering the out port 24a as a ball entry history. The value of the out counter is cleared to “0” when a reading device is electrically connected to the reading terminal 102 and various parameters are read from the calculation result memory 131 by the reading device. Incidentally, since the backup power is supplied to the main RAM 65 even when the supply of the operating power to the MPU 62 is stopped, the value of the out counter is stored even if the pachinko machine 10 is turned off. Retained.

  When it is confirmed that the situation in which the information “0” is stored in the seventh bit D7 is switched to the situation in which the information “1” is stored, the gate detection sensor 49a performs one game. It is determined that a sphere has been detected (step S2324: YES). In this case, “1” is set to the gate winning flag of the main RAM 65 (step S2325).

  By performing the entry detection process as described above, the entry histories to the out port 24a, the general winning port 31, the special prize winning device 32, the first operating port 33, and the second operating port 34 are stored in the respective entrance parts. Is stored in the main side RAM 65 as the number of balls entered. As a result, every time a ball enters any one of the out port 24a, the general winning port 31, the special winning device 32, the first operating port 33, and the second operating port 34, a signal is sent from the main CPU 63 to the management CPU 112. There is no need to output. Therefore, the configuration for outputting a signal from the main CPU 63 to the management CPU 112 can be simplified.

  In the present embodiment, when a calculation opportunity occurs, the management CPU 112 reads the number of balls entered from the general winning counter of the main RAM 65 to the general winning slot 31, and transfers the special winning prize counter from the main RAM 65 to the special winning device 32. Read the number of balls entered, read the number of balls entered from the first operation counter of the main RAM 65 to the first operation port 33, read the number of balls entered from the second operation counter of the main RAM 65 to the second operation port 34, The number of balls entering the out port 24a is read from the out counter of the main RAM 65. Then, the first parameter to the eighth parameter described in the first embodiment are calculated using the read number of balls. However, the number of balls entered in a state where the number of balls entered when the front door frame 14 is open and the number of balls entered when the front door frame 14 is closed are not measured. Therefore, the first parameter to the eighth parameter are calculated in a state including the number of entered balls generated when the front door frame 14 is open. In addition, since the number of balls entered during the opening / closing execution mode and the number of balls entered during the high frequency support mode are not individually measured, the first parameter to the 18th parameter and the 21st parameter described in the first embodiment. The 26th parameter is not calculated. The calculated first to eighth parameters are written in the calculation result memory 131. When a reading device is electrically connected to the reading terminal 102, all parameters written at that time in the calculation result memory 131 are provided to the reading device. At this time, the calculation result memory 131 is cleared to “0”.

  Note that the management IC 66 does not access the main RAM 65 independently, but information on the number of balls that have been stored in the main RAM 65 as the ball entry history is transmitted to the management IC 66 by transfer control by the main CPU 63. It is good also as a structure to be. In this case, it is possible to reliably prevent an event in which the main CPU 63 and the management CPU 112 access the main RAM 65 at the same time.

<Eleventh embodiment>
In the present embodiment, the configuration of the main control board 61, the types of signals output from the main CPU 63 to the management CPU 112, and the method of storing the entry history to each entry section are different from those in the first embodiment. ing. Hereinafter, a configuration different from that of the first embodiment will be described. The description of the same configuration as that of the first embodiment is basically omitted.

  FIG. 43 is a block diagram for explaining the electrical configuration of the main control board 61 in the present embodiment. The MPU 62 is mounted on the main control board 61 as in the first embodiment. Similar to the first embodiment, the MPU 62 includes a main CPU 63, a main ROM 64, a main RAM 65, a management IC 66, an I / F 101, and a reading terminal 102. Similarly to the first embodiment, the management IC 66 is provided with a management-side I / F 111, a management-side CPU 112, a management-side ROM 113, a management-side RAM 114, a correspondence relationship memory 116, and a history memory 117.

  On the other hand, in this embodiment, the management IC 66 is not provided with the RTC 115 unlike the first embodiment. Also. In addition to the MPU 62, the main control board 61 is provided with a notification light emitting unit 151. The notification light emitting unit 151 is directly controlled to emit light by the main CPU 63. The main CPU 63 can access the history memory 117 of the management IC 66, and calculates various parameters using the information of the entry history of each entry that has been read from the history memory 117. Then, the light emitting state of the notification light emitting unit 151 is controlled according to the contents of the various parameters thus calculated. The notification light emitting unit 151 is accommodated in the accommodation space of the substrate box 60a of the main control device 60, but the substrate box 60a is formed transparent, and the light emitting state of the notification light emitting unit 151 is changed to the outside of the substrate box 60a. The light emitting part 151 for notification is provided so that it can be visually confirmed. As a result, the gaming machine main body 12 is opened with respect to the outer frame 11 so that the main control device 60 can be visually confirmed, thereby notifying the light emitting unit 151 for notification without requiring the work of opening the board box 60a. It becomes possible to visually confirm the light emission state of the.

  FIG. 44 is an explanatory diagram for explaining the configuration of the input port 121 of the management-side I / F 111 in the present embodiment.

  The first to seventh buffers 122a to 122g and the sixteenth buffer 122p receive the same types of signals as in the first embodiment. Specifically, the first signal corresponding to the detection result of the first winning mouth detection sensor 42a is input to the first buffer 122a, and the second signal corresponding to the detection result of the second winning mouth detection sensor 43a is input to the second buffer 122b. A third signal corresponding to the detection result of the third prize winning port detection sensor 44a is input to the third buffer 122c, and a fourth signal corresponding to the detection result of the special electricity detection sensor 45a is input to the fourth buffer 122d. Is input to the fifth buffer 122e, and a fifth signal corresponding to the detection result of the first operating port detection sensor 47a is input to the sixth buffer 122f. 6 signal is input, the seventh buffer 122g is input with the seventh signal corresponding to the detection result of the outlet detection sensor 48a, and the 16th buffer 122p is output with the output instruction signal. It is inputted.

  On the other hand, in the first embodiment, a signal corresponding to the opening / closing execution mode is input as the eighth signal to the eighth buffer 122h, and a signal corresponding to the high frequency support mode is input as the ninth signal to the ninth buffer 122i. Although the signal corresponding to the front door frame 14 is input to the tenth buffer 122j as the tenth signal, in the present embodiment, the signal corresponding to the opening / closing execution mode, the signal corresponding to the high frequency support mode, and the front A signal corresponding to the door frame 14 is not input to the input port 121. That is, no signal relating to the entry history is input to the eighth to fifteenth buffers 122h to 122o.

  The types of signals to be input to the first to fifteenth buffers 122a to 122o have not been determined at the design stage of the management IC 66, and the types of these signals can be obtained by receiving instructions from the main CPU 63. It is specified by the management side CPU 112. The process for specifying the type of signal is executed when the supply of operating power to the main CPU 63 and the management CPU 112 is started, as in the first embodiment. On the other hand, the fact that the output instruction signal is input to the sixteenth buffer 122p is determined at the design stage of the management IC 66, and the management CPU 112 outputs to the sixteenth buffer 122p without receiving an instruction from the main CPU 63. It is possible to specify that the instruction signal is input.

  FIG. 45 is an explanatory diagram for explaining the configuration of the history memory 117 in the present embodiment. The history memory 117 is provided with first to fifteenth buffer counters 152a to 152o. The first buffer counter 152a stores information on the number of times the output state of the first signal input to the first buffer 122a has been changed from the LOW level to the HI level. The second buffer counter 152b stores information on the number of times the output state of the second signal input to the second buffer 122b has been changed from the LOW level to the HI level. The third buffer counter 152c stores information on the number of times the output state of the third signal input to the third buffer 122c has been changed from the LOW level to the HI level. The fourth buffer counter 152d stores information on the number of times the output state of the fourth signal input to the fourth buffer 122d has been changed from the LOW level to the HI level. The fifth buffer counter 152e stores information on the number of times the output state of the fifth signal input to the fifth buffer 122e has been changed from the LOW level to the HI level. The sixth buffer counter 152f stores information on the number of times the output state of the sixth signal input to the sixth buffer 122f has been changed from the LOW level to the HI level. The seventh buffer counter 152g stores information on the number of times the output state of the seventh signal input to the seventh buffer 122g has been changed from the LOW level to the HI level. The eighth buffer counter 152h stores information on the number of times the output state of the eighth signal input to the eighth buffer 122h has been changed from the LOW level to the HI level. The ninth buffer counter 152i stores information on the number of times the output state of the ninth signal input to the ninth buffer 122i has been changed from the LOW level to the HI level. The tenth buffer counter 152j stores information on the number of times the output state of the tenth signal input to the tenth buffer 122j has been changed from the LOW level to the HI level. The eleventh buffer counter 152k stores information on the number of times the output state of the eleventh signal input to the eleventh buffer 122k has been changed from the LOW level to the HI level. The twelfth buffer counter 152l stores information on the number of times the output state of the twelfth signal input to the twelfth buffer 122l has been changed from the LOW level to the HI level. The thirteenth buffer counter 152m stores information on the number of times the output state of the thirteenth signal input to the thirteenth buffer 122m has been changed from the LOW level to the HI level. The fourteenth buffer counter 152n stores information on the number of times the output state of the fourteenth signal input to the fourteenth buffer 122n has been changed from the LOW level to the HI level. The fifteenth buffer counter 152o stores information on the number of times the output state of the fifteenth signal input to the fifteenth buffer 122o has been changed from the LOW level to the HI level.

  However, the measurement targets using the first to fifteenth buffer counters 152a to 152o are any one of the out port 24a, the general winning port 31, the special prize winning device 32, the first operating port 33, and the second operating port 34. First to seventh buffers 122a to 122g to which signals corresponding to the result of entering the car are input. Accordingly, the eighth to fifteenth buffers 122h to 122o are excluded from the measurement target. The distinction of whether or not these are measurement targets is performed based on the correspondence information stored in the correspondence areas 123a to 123o of the correspondence memory 116.

  FIG. 46 is a flowchart showing the history setting process executed by the management CPU 112. The history setting process is executed in step S607 of the management process (FIG. 18).

  First, the number of buffers to be confirmed in the management CPU 112 among the first to fifteenth buffers 122a to 122o is set in the confirmation target counter of the management RAM 114 (step S2401). Specifically, the number of correspondence areas in which information other than information indicating blank is stored among the first to fifteenth correspondence areas 123a to 123o in the correspondence relationship memory 116 is identified, and the identification is performed. Set the number of information to the check target counter. In the pachinko machine 10, since information other than information indicating blank is stored in the first to seventh relation areas 123a to 123j as already described, in step S2401, "7" is set in the check target counter. To do.

  After that, it is confirmed whether or not the numerical information stored in the buffer corresponding to the current value of the check target counter among the first to fifteenth buffers 122a to 122o has been changed from “0” to “1”. Thus, it is determined whether or not the output state of the input signal from the main CPU 63 to the buffer has been switched from the LOW level to the HI level (step S2402). In addition, when the value of the confirmation target counter is “n”, the nth buffers 122a to 122o are the confirmation targets of the numerical information. For example, if the value of the check target counter is “5”, the fifth buffer 122e is a check target for numerical information, and if the value of the check target counter is “1”, the first buffer 122a is a check target for numerical information. .

  If an affirmative determination is made in step S2402, the corresponding buffer counters 152a to 152o are added (step S2403). In the addition process, the counter value corresponding to the current value of the counter to be checked among the counters of the first to fifteenth buffer counters 152a to 152o of the history memory 117 is incremented by one. For example, if the value of the confirmation target counter is “5”, the fifth buffer counter 152e is the addition target, and if the value of the confirmation target counter is “1”, the first buffer counter 152a is the addition target.

  If a negative determination is made in step S2402, or if the process of step S2403 is executed, the value of the check target counter in the management side RAM 114 is decremented by 1 (step S2404). Then, it is determined whether or not the value of the confirmation target counter after the 1 subtraction is “0” (step S2405). When the value of the confirmation target counter is 1 or more (step S2405: NO), the processing after step S2402 is executed for the confirmation target corresponding to the new value of the confirmation target counter.

  By executing the history setting process as described above, the game ball entry history to the out port 24a, the general winning port 31, the special prize winning device 32, the first operating port 33 and the second operating port 34 is as described above. Rather than being stored as history information as in the first embodiment, it is stored as information on the number of times a game ball has been detected by each of the incoming ball detection sensors 42a to 48a. As a result, the storage capacity required in the history memory 117 can be reduced as compared with a configuration in which each history information is stored individually.

  FIG. 47 is a flowchart showing external output processing in the present embodiment, which is executed by the management CPU 112. The external output process is executed in step S608 of the management process (FIG. 18).

  When the output state of the output instruction signal received from the main CPU 63 becomes HI level (step S2501: YES), the first to fifteenth buffer counters 152a to 152a are added to the output target counter provided in the management RAM 114. Among the counters 152o, the management CPU 112 sets the number of counters for which the frequency information is to be output (step S2502). Specifically, the number of correspondence areas in which information other than information indicating blank is stored among the first to fifteenth correspondence areas 123a to 123o in the correspondence relationship memory 116 is identified, and the identification is performed. Set the number of information to the check target counter. In this embodiment, since information other than information indicating blank is stored in the first to seventh correspondence areas 123a to 123g as described above, “7” is set in the output target counter in step S2502. .

  Thereafter, the correspondence information stored in the area corresponding to the current value of the output target counter among the first to fifteenth correspondence areas 123a to 123o in the correspondence memory 116 is read (step S2503), and the history information is used. The number-of-times information stored in the counter corresponding to the current output target counter value among the first to fifteenth buffer counters 152a to 152o in the memory 117 is read (step S2504). In this case, when the value of the output target counter is “n”, the n-th corresponding relationship areas 123a to 123o are targets for reading the corresponding relationship information, and the n-th buffer counters 152a to 152o read the number-of-times information. It becomes a target. For example, if the value of the output target counter is “5”, the fifth correspondence area 123e is a target for reading the correspondence information, the fifth buffer counter 152e is a target for reading the number of times information, and the value of the output target counter is If it is “1”, the first correspondence relationship area 123a is a target for reading correspondence information, and the first buffer counter 152a is a target for reading number information.

  Thereafter, an information output process is executed (step S2505). In the information output process, the combination of the correspondence information read in step S2503 and the number-of-times information read in step S2504 is output to the reading terminal 102. As a result, in the reading device electrically connected to the reading terminal 102, the number-of-times information about the correspondence information that is the current output target is read.

  Thereafter, 1 is subtracted from the value of the output target counter of the management side RAM 114 (step S2506). Then, it is determined whether or not the value of the output target counter after the 1 subtraction is “0” (step S2507). If the value of the output target counter is 1 or more (step S2507: NO), the processing from step S2503 is executed on the output target corresponding to the new output target counter value. If an affirmative determination is made in step S2507, the values of the first to fifteenth buffer counters 152a to 152o are cleared to “0”.

  FIG. 48 is a flowchart showing parameter management processing executed by the main CPU 63. The parameter management process is executed after the management output process in step S219 is executed in the timer interrupt process (FIG. 8).

  First, it is determined whether or not an operation trigger for various parameters has occurred (step S2601). The calculation is triggered when the parameter management process is executed for the first time after the supply of operating power to the main CPU 63 is started, and in the same way as in the fifth embodiment, the out port 24a, the general winning port 31, the special power receiving award. This occurs every time the total number of game balls entering the device 32, the first operating port 33, and the second operating port 34 reaches 500 or more as the trigger reference number. Since the case where the parameter management process is first executed after the supply of operating power is started is set as a calculation trigger, the power of the pachinko machine 10 is turned off and then turned on again to calculate various parameters. An opportunity can be easily generated. When an affirmative determination is made in step S2601, notification corresponding to the calculation results of various parameters is executed as will be described later. Therefore, in the game area PA up to that point only by performing the power OFF / ON operation. It is possible to grasp the game ball entering mode. In addition, it is possible to finely manage the entrance mode of the game balls in the game area PA by generating a calculation opportunity every time the total number of game balls entered reaches the trigger reference number of 500 or more. It becomes.

  When a calculation trigger occurs (step S2601: YES), the entry history is read from the counter that is the storage target of the entry history among the first to fifteenth buffer counters 152a to 152o of the history memory 117. Specifically, the numerical information of the first to seventh buffer counters 152a to 152g is read. In this case, the main CPU 63 can recognize the buffer counters 152a to 152o from which the entry history is to be read by the program and data stored in the main ROM 64.

  Thereafter, various arithmetic processes are executed (step S2603). In the various calculation processes, various parameters are calculated using the ball entry history read in step S2602 and the information on the number of winning balls corresponding to the ball entry history. The main CPU 63 uses the programs and data stored in the main ROM 64 to store the ball entry histories read in step S2602 as the out port 24a, the general winning port 31, the special winning device 32, the first operating port 33, and the first operating port 33. It is possible to specify which one of the two operation ports 34 corresponds to, and it is possible to specify information on the number of winning balls corresponding to each entry history read in step S2602. .

Specifically, various parameters calculated in step S2603 are:
7th parameter: (K3 × “the number of winning balls for winning in the special electricity winning device 32” + K5 × “the number of winning balls for winning in the second operating port 34”) / total number of game balls to be paid out (K2 × “general The number of winning balls for winning at the winning opening 31 + K3 × “the number of winning balls for winning at the special electricity winning device 32” + K4 × “the number of winning balls for winning at the first operating port 33” + K5 × “the second operating port 34” Ratio / eighth parameter: K3 × “number of winning balls for winning to the special electric prize device 32” / total number of game balls to be paid out (K2 × “for winning to the general winning opening 31”) “Number of winning balls” + K3 × “Number of winning balls for winning in the special electric prize winning device 32” + K4 × “Number of winning balls for winning in the first operating port 33” + K5 × “Number of winning balls for winning in the second operating port 34” )) Is calculated.

  Thereafter, it is determined whether or not the calculated various parameters are within the first range (step S2604). If the value of the seventh parameter is 0.7 or less and the value of the eighth parameter is 0.6 or less, an affirmative determination is made in step S2604, assuming that the various parameters calculated are within the first range. If an affirmative determination is made in step S2604, a first notification state setting process is executed (step S2605). In the setting process, the notification light emitting unit 151 is controlled to emit light so as to be in the first notification state. In this case, the notification light emitting unit 151 is in a blue light emitting state.

  If a negative determination is made in step S2604, it is determined whether or not the calculated various parameters are in the second range (step S2606). If only one of the conditions where the value of the seventh parameter exceeds 0.7 and the value of the eighth parameter exceeds 0.6 is satisfied, In step S2606, an affirmative determination is made that there are two ranges. When an affirmative determination is made in step S2606, a second notification state setting process is executed (step S2607). In the setting process, the notification light emitting unit 151 is controlled to emit light so as to be in the second notification state. In this case, the notification light emitting unit 151 is in a yellow light emitting state.

  If a negative determination is made in step S2606, it means that the value of the seventh parameter exceeds 0.7 and the value of the eighth parameter exceeds 0.6. In this case, the third notification state setting process is executed (step S2608). In the setting process, the notification light emitting unit 151 is controlled to emit light so as to be in the third notification state. In this case, the notification light emitting unit 151 is in a red light emitting state.

  The light emission state set in step S2605, step S2607 or step S2608 is stopped until a new notification state is set for the notification light emitting unit 151, or the supply of operating power to the notification light emitting unit 151 is stopped. Continue until. In addition, the notification state of the notification light emitting unit 151 is stored and held in the main RAM 65 and backup power is supplied to the main RAM 65, so the supply of operating power to the main CPU 63 is stopped and the notification light emitting unit is stopped. Even if 151 is once turned off, when the supply of operating power to the main CPU 63 is resumed, a light emission state corresponding to the type of information in the notification state stored in the main RAM 65 is obtained. The light emission control of the notification light emitting unit 151 is executed.

  According to the embodiment described in detail above, the following excellent effects are obtained.

  The game ball entry history to the out port 24a, the general winning port 31, the special electric prize winning device 32, the first operating port 33, and the second operating port 34 is stored as history information as in the first embodiment. Instead, it is stored as information on the number of times a game ball has been detected by each of the entrance detection sensors 42a to 48a. As a result, the storage capacity required in the history memory 117 can be reduced as compared with a configuration in which each history information is stored individually.

  A notification light emitting unit 151 for notifying contents corresponding to various parameters calculated by the management side CPU 112 is provided. As a result, the contents corresponding to the various parameters are notified by the pachinko machine 10 itself, so that the manager of the game hall or the like does not need to read the information stored in the history memory 117 and the game balls in the game area PA can be read. It becomes possible to grasp the entrance mode.

  A notification light-emitting unit 151 is provided together with the MPU 62 on the main control board 61 accommodated in the board box 60a. Thereby, it is possible to make it difficult to perform unauthorized access to the communication path between the MPU 62 and the notification light emitting unit 151.

  The calculation of various parameters and the light emission control of the notification light emitting unit 151 are executed not by the management CPU 112 but by the main CPU 63. Thereby, it becomes possible to improve the reliability of the notification content in the notification light emitting unit 151.

  When the calculation results of the various parameters correspond to the first range, the first notification state is set. When the calculation results of the various parameters correspond to the second range, the second notification state is set, and the calculation results of the various parameters are displayed. The third notification state is entered when neither the first range nor the second range is supported. That is, the various parameters are not notified as they are, but the contents corresponding to the range including the various parameters are notified. Thereby, it is possible to prevent the notification patterns in the notification light emitting unit 151 from becoming excessive, and it is possible to reduce the load for controlling the notification light emitting unit 151.

  Even if the supply of the operating power to the main CPU 63 is stopped, the supply of the operating power to the main CPU 63 is stopped immediately after the power supply to the notification light emitting unit 151 is continued. It is good also as a structure by which the light emission state in is maintained. In this case, even when the supply of operating power to the main CPU 63 is stopped, it is possible to grasp the game ball entering mode in the game area PA by checking the notification light emitting unit 151. .

  Further, instead of this configuration, when the supply of operating power to the main CPU 63 is stopped, the notification light-emitting unit 151 is turned off, but the supply of operating power to the main CPU 63 is started. May be configured such that the notification light emitting unit 151 is controlled to emit light so as to be in a light emitting state corresponding to the result of various parameters calculated before the supply of operating power is stopped. In this case, for example, by confirming the notification light-emitting unit 151 before the start of business in the game hall, it is possible to grasp the game ball entry mode on the previous business day.

  The notification means for notifying the calculation results of various parameters is not limited to the configuration in which the notification light emitting unit 151 is used, and a display device having a display surface such as the symbol display device 41 may be used. It may be. In addition, a signal corresponding to the calculation result of various parameters may be output to the hall computer HC of the game hall through the external terminal board 97.

  The special figure display part 37a of the special figure unit 37 or the universal figure display part 38a of the universal figure unit 38 may be configured to also function as the notification light emitting part 151. For example, when supply of operating power to the MPU 62 is started, various parameters are calculated, and depending on whether the calculation result is included in the first range, the second range, or any other one as in the above embodiment. The notification corresponding to the calculation result may be executed in the special figure display unit 37a or the general map display unit 38a immediately after the start of the supply of the operating power. In this case, the notification may be configured to end when the start condition of the variable display of the pattern in the special figure display unit 37a or the start condition of the variable display of the pattern in the general map display unit 38a is satisfied. It may be configured to be temporarily interrupted when the start condition of the variable display is satisfied, and resumed when the variable display of the pattern is completed. According to this configuration, it is possible to use the special-figure display unit 37a or the general-purpose display unit 38a as notification means for notifying the entrance mode of the game ball in the game area PA.

  The notification light emitting unit 151 may be provided at a position where the notification light emitting unit 151 is visible from the front of the pachinko machine 10 in a state where the gaming machine main body 12 and the front door frame 14 are closed. For example, it is good also as a structure by which the alerting | reporting light emission part 151 is provided in the position which can be visually recognized from the front of the pachinko machine 10 through the window panel 52 behind the pachinko machine 10 rather than the window panel 52. In this case, the notification content corresponding to the calculation results of various parameters can be confirmed without requiring the opening operation of the gaming machine main body 12 or the front door frame 14.

<Twelfth Embodiment>
In the present embodiment, the configuration for providing information on each entry result to the management IC 66 is different from that in the first embodiment. Hereinafter, a configuration different from that of the first embodiment will be described. The description of the same configuration as that of the first embodiment is basically omitted.

  FIG. 49 is an explanatory diagram for explaining a configuration of a signal path for allowing detection results of the respective entrance detection sensors 42 a to 48 a to be input to the main CPU 63 and the management IC 66.

  The detection result of the first winning port detection sensor 42a is input to the main CPU 63 through the first signal path SL11. In addition, the detection result of the second winning prize detection sensor 43a is input to the main CPU 63 through the second signal path SL12. Further, the detection result of the third prize winning port detection sensor 44a is input to the main CPU 63 through the third signal path SL13. Further, the detection result of the special electricity detection sensor 45a is input to the main CPU 63 through the fourth signal path SL14. The detection result of the first working port detection sensor 46a is input to the main CPU 63 through the fifth signal path SL15. The detection result of the second working port detection sensor 47a is input to the main CPU 63 through the sixth signal path SL16. In addition, the detection result of the out port detection sensor 48a is input to the main CPU 63 through the seventh signal path SL17.

  A first branch path SL21 is formed so as to branch from a middle position of the first signal path SL11, and the first branch path SL21 is electrically connected to the management IC 66. Further, a second branch path SL22 is formed so as to branch from an intermediate position of the second signal path SL12, and the second branch path SL22 is electrically connected to the management IC 66. Further, a third branch path SL23 is formed so as to branch from a middle position of the third signal path SL13, and the third branch path SL23 is electrically connected to the management IC 66. Further, a fourth branch path SL24 is formed so as to branch from a middle position of the fourth signal path SL14, and the fourth branch path SL24 is electrically connected to the management IC 66. Further, a fifth branch path SL25 is formed so as to branch from a middle position of the fifth signal path SL15, and the fifth branch path SL25 is electrically connected to the management IC 66. Further, a sixth branch path SL26 is formed so as to branch from a middle position of the sixth signal path SL16, and the sixth branch path SL26 is electrically connected to the management IC 66. Further, a seventh branch path SL27 is formed so as to branch from a middle position of the seventh signal path SL17, and the seventh branch path SL27 is electrically connected to the management IC 66.

  With the above-described configuration, the detection results of the respective ball detection sensors 42a to 48a are input to the management IC 66 without any processing by the main CPU 63. As a result, the main CPU 63 executes processing for causing the management side CPU 112 to recognize the respective winning results of the out port 24a, the general winning port 31, the special prize winning device 32, the first operating port 33 and the second operating port 34. Therefore, the processing load on the main CPU 63 can be reduced.

  Further, branch points of the branch paths SL21 to SL27 from the signal paths SL11 to SL17 exist in the MPU 62. As a result, it is possible to make it difficult to access the branch location and each of the branch paths SL21 to SL27 from the outside, and it is possible to prevent an illegal act of inputting an abnormal entry result only to the management IC 66. .

<13th Embodiment>
In the present embodiment, left and right distribution nails 213, 214 that distribute the course downstream of the game ball B1 to the left and right according to the position of the game ball B1 (FIG. 53 (a)) in the depth direction on the game board 233 (FIG. 50). This embodiment is different from the first embodiment in that (FIG. 50) is provided. Hereinafter, the description of the same configuration as that of the first embodiment is basically omitted.

  The structure of the game board 233 in this embodiment is demonstrated based on FIG. FIG. 50 is a front view of the game board 233. The game board 233 in the present embodiment differs from the game board 24 in the first embodiment in that a game area PA is formed not only on the left side but also on the right side of the surface. As shown in FIG. 50, the game board 233 is formed with a plurality of large and small openings penetrating in the front-rear direction. In each opening, there are a general winning port 241, a special electricity winning device 32, a first operating port 33, a second operating port 34, a through gate 35, a variable display unit 36, a special figure display unit 225, a general figure display unit 226, and the like. Is provided. Note that a total of three general winning ports 241 are provided on the left and right sides of the game board 233, and one through gate 35 is provided on each of the left and right sides. One other opening is provided.

  Each general winning port 241, special electric winning device 32, first operating port 33, second operating port 34, and each through gate 35 are provided with detection sensors in a one-to-one correspondence. These detection sensors are all provided on the back side of the game board 233, and the detection results are output to the main controller 60 (FIG. 5). As the detection sensor, an electromagnetic induction type proximity sensor that detects a change in the magnetic field is used. However, if the winning of the game ball B1 (FIG. 53 (a)) can be detected individually, the sensor to be used is For example, an optical sensor may be used. Here, the game ball B1 is a steel sphere having a diameter of 11 mm.

  When the occurrence of a ball entering the general winning port 241, the special electric winning device 32, the first operating port 33, and the second operating port 34 is detected, a predetermined number of game balls B1 are given to the player as a winning ball. Specifically, with respect to the number of winning balls, three winning balls are generated when a ball enters the first working port 33 and when a ball enters the second working port 34. Further, the general winning opening 241 in the present embodiment plays the same role as the general winning opening 31 in the first embodiment, and when the winning to the general winning opening 241 occurs, ten winning awards. A sphere is generated. In addition, when a special ball winning device 32 is entered, 15 prize balls are generated. However, the number of prize balls is arbitrary, and the number of prize balls in the operation holes 33 and 34 is different, for example, the number of prize balls in the second action opening 34 is larger than the number of prize balls in the first action opening 33. It may be. In addition, the number of prize balls of the special electric prize winning device 32 is not limited to a configuration that is larger than the number of other prize balls. For example, the number of prize balls of the general prize opening 241 may be smaller.

  In addition, an out port 24a is provided at the bottom of the game board 233, and the game ball B1 that has not entered the various winning ports etc. is discharged from the game area PA through the out port 24a. In addition, the game board 233 is provided with a number of nails 228, 213, and 214 in order to appropriately distribute and adjust the falling direction of the game ball B1.

  The special map display unit 225 and the general map display unit 226 are provided as a display unit in a predetermined range. The area where the display unit is installed is an area inside the game area PA partitioned using the inner rail portion 25, and the game ball B1 does not flow down in front of the front of the display unit. This is the area where the inflow of B1 is restricted. And the special figure display part 225 and the common figure display part 226 are provided with respect to the front surface of the display unit. Thereby, although the various display parts 225 and 226 are provided in the game area PA, the game ball B1 is prevented from flowing down in front of the display area PA, and visibility from the front of the pachinko machine 10 is ensured.

  In the game board 233, the inner rail portion 25 and the outer rail portion 26 constitute a guide rail. A game ball launching mechanism 27 (FIG. 2) is provided below the game board 233, and the game ball B1 launched by applying force from the solenoid 27c (FIG. 2) of the game ball launching mechanism 27 is guided as described above. The rail is guided to the upper part of the game area PA. The game ball launching mechanism 27 includes an operation base provided so as to protrude forward, and an operation handle provided so as to be rotatably supported by the operation base, and the operation handle is rotated. Thus, the launch intensity of the game ball B1 from the game ball launching mechanism 27 is adjusted.

  As already described in the first embodiment, the front door frame 14 (FIG. 2) is provided so that the game board 233 covers the entire front side of the inner frame 13 (FIG. 2). The front door frame 14 is formed with a window portion 51 (FIG. 1) so that almost the entire game area PA can be viewed from the front. The window 51 has a substantially elliptical shape, and a window panel 52 (FIG. 1) is fitted therein. The window panel 52 is formed of colorless and transparent with glass, but is not limited to this, and may be formed of colorless and transparent with synthetic resin. The game area PA is defined through the window panel 52 from the front of the pachinko machine 10. As long as it is visible, it may be colored and transparent.

  A center frame 252 is disposed on the game board 233 so as to define an opening 233a that allows the display surface 41a of the symbol display device 41 (FIG. 3) to be visible from the front of the pachinko machine 10. The center frame 252 includes a roof unit 253 provided to define the upper edge and the left and right side edges of the opening 233a.

  Next, the arrangement of the nails 228, 213, and 214 provided on the game board 233 will be described with reference to FIG. As shown in FIG. 50, the game board 233 is provided with a number of nails 228, 213, and 214. Here, the nail provided in the game board 233 of the present embodiment includes a metal obstruction nail 228 which is a round nail used in a conventional pachinko machine, and a resin first left / right sorting member 215. There are three types: a first left / right sorting nail 213 having a second left / right sorting nail 214 having a second left / right sorting member 231 made of resin. Details of the left and right sorting nails 213 and 214 will be described later.

  The metal obstruction nail 228 includes a cylindrical trunk shaft portion, a head provided on the proximal end side of the trunk shaft portion, a conical pointed head formed on the distal end side of the trunk shaft portion, Consists of. The game board 233 is configured in such a manner that the pointed head is buried deeper than the surface of the game board 233 and a part of the trunk shaft part and the head protrude from the surface of the game board 233. Is provided. The length from the surface of the game board 233 to the free end of the obstacle nail 228 (the end on the near side of the pointed head) is 17 mm. Here, the near side is the window panel 52 side close to the player, and the far side is the game board 233 side far from the player.

  The distance from the front surface of the game board 233 to the back surface of the window panel 52 is 18 mm. As described above, the diameter of the game ball B1 is 11 mm. For this reason, the game area PA has a 7 mm allowance for the game ball B1 to move in the depth direction. The position in the depth direction of the game ball B1 in the game area PA is a position where the solenoid 27c contacts when the solenoid 27c (FIG. 2) of the game ball launching mechanism 27 (FIG. 2) applies a force to the game ball B1 and launches it. In addition, the game ball B1 changes when the game ball B1 collides with the roof unit 253 or the decoration member on the game board 233 in the process of flowing down the game area PA.

  The range in which the center of the game ball B1 can be located is a range from a place advanced 5.5 mm toward the window panel 52 from the surface of the game board 233 to a place advanced 12.5 mm. Hereinafter, the range in which the game ball B1 can come into contact with the nails 228, 213, and 214 on the game board 233 is referred to as a contactable range of the game ball B1. The game ball B1 flowing down the game area PA can collide with the obstacle nail 228 in the flow-down process both in the case of being located on the game board 233 side and in the case of being located on the window panel 52 side. The course after the collision of the game ball B1 is changed by the obstacle nail 228.

  Since the game area PA is formed not only on the left side but also on the right side of the game board 233 as described above, the obstacle nail 228 is provided on the entire surface of the game board 233 as shown in FIG. It has been. On the other hand, the left and right sorting nails 213 and 214 made of resin are arranged as nails constituting guide nail groups 211 and 212 for guiding the game ball B1 to the operation ports 33 and 34 on the game board 233. Here, the guide nail groups 211 and 212 include a left guide nail group 211 composed of seven first left and right sorting nails 213 arranged in a line at equal intervals in the lower left portion of the game board 233, and a game board 233. Is a general term for a right guide nail group 212 composed of seven second left / right sorting nails 214 arranged in a row at equal intervals.

  The left guide nail group 211 is a nail row in which the first left / right sorting nail 213 positioned on the right side is provided below the first left / right sorting nail 213 adjacent to the left side. The nail row is a row extending in a direction inclined downward toward the right, and the angle formed by the row direction of the left guide nail group 211 and the horizontal direction is 30 °. The angle is an angle at which the game ball B1 can be guided to the operation ports 33 and 34 while gradually decreasing the height of the game ball B1. On the extended line in the row direction of the left guide nail group 211, the operation ports 33 and 34 exist. The space above the left guide nail group 211 is wider than the diameter of the game ball B1 so that the game ball B1 can pass therethrough. In addition, since the first left and right sorting nails 213 constituting the left guide nail group 211 are arranged at a slightly wider interval than the diameter of the game ball B1, the game balls B1 are inserted from the gap between the first left and right sorting nails 213. Can fall down. When the game ball B1 loses the speed in the left-right direction on the first left / right distribution nail 213, the game ball B1 falls downward from the gap between the first left / right distribution nail 213, so It does not stop on the nail 213.

  The right guide nail group 212 is a nail row in which the second left / right sorting nail 214 located on the left side is provided below the second left / right sorting nail 214 adjacent to the right side. The nail row extends in a direction inclined downward toward the left, and the angle formed by the row direction of the right guide nail group 212 and the horizontal direction is 30 °. The angle is an angle at which the game ball B1 can be guided to the operation ports 33 and 34 while gradually decreasing the height of the game ball B1. On the extended line in the row direction of the right guide nail group 212, the operation ports 33 and 34 exist. The space above the right guide nail group 212 is wider than the diameter of the game ball B1 so that the game ball B1 can pass therethrough. In addition, since the second left and right sorting nails 214 constituting the right guide nail group 212 are arranged at a slightly wider interval than the diameter of the game ball B 1, the game balls B 1 are separated from the gap between the second left and right sorting nails 214. Can fall down. When the game ball B1 loses the speed in the left-right direction on the second left / right distribution nail 214, the game ball B1 falls downward from the gap between the second left / right distribution nail 214, so that the game ball B1 is moved to the second left / right distribution nail 214. It does not stop on the nail 214.

  Next, the structure of the 1st left-right distribution nail 213 is demonstrated based on Fig.51 (a)-(c). FIG. 51A is a perspective view of the first left / right sorting nail 213. As shown in FIG. 51 (a), the first left / right sorting nail 213 is an elongated nail formed to extend in the direction of the axis 213c. The first left / right sorting nail 213 fixes the first left / right sorting member 215 that sorts the game balls B <b> 1 falling and colliding in the left / right direction from the top, and the first left / right sorting member 215 to the surface of the game board 233. And a fixing member 216 for the purpose. The first left-right sorting member 215 is a substantially quadrangular prism-shaped resin member formed extending in the direction of the axis 213c, and has a different inclination as a surface that can collide with the game ball B1 falling from above. Two distribution surfaces 217a and 218a are provided.

  As shown in FIG. 50, the first left / right sorting nail 213 is configured such that the axis 213 c is substantially perpendicular to the surface of the game board 233 and the first left / right sorting member 215 protrudes from the surface of the game board 233. It is fixed to the game board 233. The length of the first left / right sorting member 215 in the direction of the axis 213c is 17 mm. In the first left / right sorting nail 213 fixed to the game board 233, the first left / right sorting member 215 protrudes 17mm into the game area PA. ing. The first left / right sorting nail 213 covers the contactable range of the game ball B1. For this reason, the game ball B1 located on the back side of the game area PA can collide with the first left / right sorting nail 213 and the game ball B1 located on the near side can also collide. In the following description, in the first left / right distribution nail 213 and the second left / right distribution nail 214 fixed to the game board 233, the end fixed to the game board 233 is described as a fixed end, and the game area PA The end protruding in is described as a free end.

  As shown in FIG. 51A, the first left / right sorting member 215 includes a first sorting portion 217 formed extending in the direction of the axis 213c, and a free end side of the first sorting portion 217. The second distribution part 218 is formed to extend in the direction of the axis 213c in a manner that is continuous with the side surface. In a state where the first left / right distribution nail 213 is fixed to the game board 233, the boundary surface between the first distribution part 217 and the second distribution part 218 is parallel to the surface of the game board 233.

  Since the length of the first allocating portion 217 in the direction of the axis 213c is 9 mm, the first allocating portion 217 is in the gaming area PA in a state where the first left / right allocating nail 213 is fixed to the gaming board 233. It protrudes to the back half of. Further, the length from the left end to the right end of the first allocating portion 217 is 7 mm which is longer than the radius of the game ball B1 and shorter than the diameter. The 1st distribution part 217 is provided with the 1st distribution surface 217a formed in the aspect ranging from the left end of the 1st distribution part 217 to the right end as the upper surface. The first distribution surface 217a is inclined downward toward the right, and repels the game ball B1 that falls from above and collides with the upper right side.

  Further, since the length of the second allocating portion 218 in the direction of the axis 213c is 8 mm, the second allocating portion 218 is a game in a state where the first left / right allocating nail 213 is fixed to the game board 233. It protrudes to most of the front half of the area PA. Further, the length from the left end to the right end of the second allocating portion 218 is 7 mm which is longer than the radius of the game ball B1 and shorter than the diameter. The 2nd distribution part 218 is provided with the 2nd distribution surface 218a formed in the aspect ranging from the left end of the 2nd distribution part 218 to the right end as the upper surface. The second distribution surface 218a is inclined downward toward the left, and repels the game ball B1 that falls from above and collides with the upper left.

  Here, the trunk diameter of the trunk shaft portion of the metallic obstacle nail 228 (FIG. 50) is 2 mm. As described above, the first left / right sorting member 215 is made of resin. However, by making the size around the axis 213c larger than the trunk shaft portion of the obstacle nail 228, the first left / right sorting member 215 may be broken even if the collision of the game ball B1 is repeated. Has no strength.

  The first left / right sorting member 215 has side surfaces that are vertical surfaces at the fixed end and the free end, respectively. Among these, a first fixing hole 215a for inserting and fixing the fixing member 216 is formed in the fixed end surface 215b which is a side surface on the fixed end side. The shape of the first fixing hole 215a will be described below with reference to FIGS. 51 (b) and 51 (c). FIG. 51B is a plan view of the first left / right sorting member 215, and FIG. 51C is a rear view of the first left / right sorting member 215.

  As shown in FIG. 51 (b), the first fixing hole 215a has an opening in the fixed end surface 215b of the first left / right sorting member 215, and is near the free end from the fixed end of the first left / right sorting member 215. And the depth of the first fixing hole 215a is 15 mm. As shown in FIG. 51 (c), the first fixing hole 215a is formed to be large so as to occupy more than half the volume of the first left / right sorting member 215. The first fixing hole 215a is formed at a sufficient distance from the top, bottom, left, and right side surfaces of the first left / right sorting member 215 to maintain the strength of the first left / right sorting member 215.

  Next, a state where the first left / right sorting nail 213 is fixed to the game board 233 will be described with reference to FIGS. 52 (a) and 52 (b). FIG. 52A is a perspective view of a fixing member 216 for fixing the first left / right sorting member 215 to the game board 233, and FIG. 52B is a cross-sectional view taken along a plane perpendicular to the surface of the game board 233. It is a longitudinal cross-sectional view of the 1st right-and-left distribution nail 213 in the case.

  As shown in FIG. 52 (a), the fixing member 216 includes a cylindrical fixing trunk shaft portion 216a having a length dimension in the axis 213c direction of 30 mm and a cone having a length dimension in the axis line 213c direction of 5 mm. And has a length dimension capable of stably supporting the first left / right sorting member 215 protruding from the surface of the game board 233. The body diameter of the fixing member 216 is the same as the inner diameter of the first fixing hole 215a, and the fixing member 216 can be fitted in such a manner that the surface is in close contact with the inner surface of the first fixing hole 215a.

  The first left / right sorting member 215 and the fixing member 216 constituting the first left / right sorting nail 213 can be separated. By applying an impact to the free end with a hammer or the like, the fixing member 216 is fixed to the game board 233 alone. The first left / right sorting member 215 is fixed to the fixing member 216 by fitting the protruding portion of the fixing member 216 into the first fixing hole 215a. As a result, the first left / right sorting nail 213 is fixed to the game board 233.

  As shown in FIG. 52 (b), the fixing member 216 has the whole fixing point head 216 b and a part of the fixing trunk shaft portion 216 a buried in the back side from the surface of the game board 233. At the same time, the remaining portion of the fixing trunk shaft portion 216a is fixed to the game board 233 in such a manner as to protrude from the surface of the game board 233 in a substantially vertical direction. In the fixing member 216 fixed to the game board 233, the length dimension of the protruding portion from the surface of the game board 233 is a dimension capable of stably supporting the first left / right sorting member 215, specifically Is 15 mm. The first left / right sorting member 215 fixes the surface of the protruding portion and the inner surface of the first fixing hole 215a with an adhesive so that the sorting surfaces 217a, 218a face upward. Fixed.

  Next, the course after the collision of the game ball B1 colliding with the first left / right sorting nail 213 will be described based on FIGS. 53 and 54. FIG. First, the case where the game ball B1 collides with the first distribution surface 217a will be described. FIG. 53A is an end view of the cut surface of the first left / right sorting nail 213 cut along a plane perpendicular to the surface of the game board 233. As shown in FIG. 53 (a), the game ball B1 flowing down the back side of the game area PA (game board 233 side) sandwiched between the game board 233 and the window panel 52 collides with the first distribution surface 217a. To do.

  FIG. 53 (b) is an explanatory diagram for explaining the rebound direction of the game ball B1 flowing down from above and colliding with the first distribution surface 217a, and FIG. 53 (c) flows down from the upper left side and is the first. It is explanatory drawing for demonstrating the rebound direction of game ball B1 which collides with the distribution surface 217a. As shown in FIG. 53 (b), on the back side of the game area PA, the first distribution surface 217a is inclined downward toward the right, so that it flows down from above and the first distribution surface 217a A drag force having an upward component and a right component acts on the game ball B1 that collides. Thereby, the game ball B1 after the collision rebounds upward on the right side.

  Further, as shown in FIG. 53 (c), a drag force having an upward component and a rightward component also acts on the game ball B1 that flows down from the upper left side and collides with the first distribution surface 217a. Thereby, the game ball B1 after the collision rebounds upward on the right side. In this case, since the game ball B1 before the collision already has a velocity component in the right direction, the game ball B1 that has collided by flowing down from the upper left side is more right than the game ball B1 that has collided by falling from directly above. Proceed greatly.

  Next, a case where the game ball B1 collides with the second distribution surface 218a will be described. FIG. 54A is an end view of the cut surface of the first left / right sorting nail 213 cut along a plane perpendicular to the surface of the game board 233. As shown in FIG. 54A, the game ball B1 flowing down the front side (window panel 52 side) of the game area PA sandwiched between the game board 233 and the window panel 52 collides with the second distribution surface 218a. To do.

  FIG. 54 (b) is an explanatory diagram for explaining the rebound direction of the game ball B1 flowing down from above and colliding with the second distribution surface 218a, and FIG. 54 (c) flows down from the upper left side. It is explanatory drawing for demonstrating the rebound direction of the game ball | bowl B1 which collides with the 2 distribution surface 218a. As shown in FIG. 54 (b), on the back side of the game area PA, since the second distribution surface 218a is inclined downward toward the left, the second distribution surface 218a A drag force having an upward component and a left component acts on the game ball B1 that collides. Thereby, the game ball B1 after the collision rebounds upward on the left side.

  Further, as shown in FIG. 54 (c), a drag force having an upward component and a leftward component also acts on the game ball B1 that flows down from the upper left side and collides with the second distribution surface 218a. In this case, since the velocity component in the right direction of the game ball B1 before the collision decreases due to the influence of the left component of the drag force received by the collision, the game ball B1 after the collision bounces down to the upper right.

  Next, the structure of the second left / right sorting nail 214 will be described with reference to FIGS. FIG. 55A is a perspective view of the second left / right sorting nail 214. As shown in FIG. 55A, the second left / right sorting nail 214 is an elongated nail formed to extend in the direction of the axis 214c. The second left / right sorting nail 214 fixes the second left / right sorting member 231 that sorts the game balls B1 falling and colliding in the left / right direction from the top, and the second left / right sorting member 231 to the surface of the game board 233. And a fixing member 216 for the purpose. The second left-right sorting member 231 is a substantially quadrangular prism-shaped resin member formed extending in the direction of the axis 214c, and has a different slope as a surface that can collide with the game ball B1 falling from above. Two distribution surfaces 232a and 234a are provided.

  As shown in FIG. 50, the second left / right sorting nail 214 has an axis 214c that is substantially perpendicular to the surface of the game board 233, and the second left / right sorting member 231 protrudes from the surface of the game board 233. It is fixed to the game board 233. The length of the second left / right sorting member 231 in the direction of the axis 214c is 17 mm. In the second left / right sorting nail 214 fixed to the game board 233, the second left / right sorting member 231 projects 17 mm into the game area PA. ing. The second left / right distribution nail 214 covers the contactable range of the game ball B1. Therefore, the game ball B1 located on the back side of the game area PA can collide with the second left / right sorting nail 214 and the game ball B1 located on the near side can also collide.

  As shown in FIG. 55 (a), the second left / right sorting member 231 includes a first sorting portion 232 formed to extend in the direction of the axis 214c, and the free end side of the first sorting portion 232 The second distribution part 234 is formed to extend in the direction of the axis 214c in a manner continuous with the side surface of the first distribution part. In a state where the second left / right distribution nail 214 is fixed to the game board 233, the boundary surface between the first distribution part 232 and the second distribution part 234 is parallel to the surface of the game board 233.

  Since the length of the first allocating portion 232 in the direction of the axis 214c is 9 mm, the first allocating portion 232 is in the game area PA in a state where the second left / right allocating nail 214 is fixed to the game board 233. It protrudes to the back half of. Moreover, the 1st distribution part 232 has the length dimension of 7 mm shorter than the diameter while being longer than the radius of the game ball B1 in the left-right direction. The 1st distribution part 232 is provided with the 1st distribution surface 232a formed in the aspect ranging from the left end of the 1st distribution part 232 to the right end as the upper surface. The first distribution surface 232a is inclined downward toward the left, and repels the game ball B1 that falls from above and collides with the upper left.

  In addition, since the length of the second allocating portion 234 in the direction of the axis 214c is 8 mm, the second allocating portion 234 is a game when the second left / right allocating nail 214 is fixed to the game board 233. It protrudes to most of the front half of the area PA. Further, the second allocating portion 234 has a length dimension of 7 mm that is longer than the radius of the game ball B1 and shorter than the diameter in the left-right direction. The 2nd distribution part 234 is provided with the 2nd distribution surface 234a formed in the aspect ranging from the left end of the 2nd distribution part 234 to the right end as the upper surface. The second distribution surface 234a is inclined downward toward the right, and repels the game ball B1 that falls from above and collides with the upper right side.

  The second left / right sorting member 231 is made of resin, but by making the size around the axis 214c larger than the trunk shaft portion of the metallic obstacle nail 228, the second left / right sorting member 231 does not break even if the collision of the game ball B1 is repeated. Has strength.

  The second left / right sorting member 231 has side surfaces that are vertical surfaces at the fixed end and the free end, respectively. Among these, a second fixing hole 231a for inserting and fixing the fixing member 216 is formed in the fixed end surface 231b which is a side surface on the fixed end side. The shape of the second fixing hole 231a will be described below with reference to FIGS. 55 (b) and (c). FIG. 55B is a plan view of the second left / right sorting member 231, and FIG. 55C is a rear view of the second left / right sorting member 231.

  As shown in FIG. 55 (b), the second fixing hole 231a has an opening in the fixed end surface 231b of the second left / right sorting member 231 and is near the free end from the fixed end of the second left / right sorting member 231. And the depth of the second fixing hole 231a is 15 mm. As shown in FIG. 55 (c), the second fixing hole 231a is formed so as to occupy more than half the volume of the second left / right sorting member 231. The second fixing hole 231a is formed at a sufficient distance from the top, bottom, left, and right side surfaces of the second left / right sorting member 231 to maintain the strength of the second left / right sorting member 231.

  The fixing member 216 constituting the second left / right distribution nail 214 is the same member as the fixing member 216 constituting the first left / right distribution nail 213 described above, and the second left / right distribution member 231 is the first left / right distribution member. It is fixed to the game board 233 in the same manner as the member 215. Specifically, the second left / right sorting member 231 and the fixing member 216 constituting the second left / right sorting nail 214 are separable. By applying an impact to the free end with a hammer or the like, the fixing member 216 is fixed to the game board 233 alone. And the 2nd right-and-left distribution member 231 is fixed to the fixing member 216 using an adhesive in a mode in which the protruding portion of the fixing member 216 fits into the second fixing hole 231a. As a result, the second left / right sorting nail 214 is fixed to the game board 233 with the sorting surfaces 232a, 234a facing upward.

  Next, a case where the game ball B1 collides with the second left / right sorting nail 214 will be described. The first distribution surface 232a of the second left / right distribution nail 214 has the same inclination as the second distribution surface 218a of the first left / right distribution nail 213. Specifically, on the back side of the game area PA, the first distribution surface 232a is inclined downward toward the left, so that the game ball B1 flows down from above and collides with the first distribution surface 232a. Has a drag force having an upward component and a left component. Thereby, the game ball B1 after the collision rebounds upward on the left side.

  Further, a drag force having an upward component and a leftward component also acts on the game ball B1 flowing down from the upper right side and colliding with the first distribution surface 232a. In this case, since the velocity component in the right direction of the game ball B1 before the collision decreases due to the influence of the left component of the drag force received by the collision, the game ball B1 after the collision bounces down to the upper right.

  The second distribution surface 234a of the second left / right distribution nail 214 has the same inclination as the first distribution surface 217a of the first left / right distribution nail 213. Specifically, since the second distribution surface 234a is inclined downward toward the right on the front side of the game area PA, the game ball B1 that falls from above and collides with the second distribution surface 234a. A drag having an upward component and a rightward component is applied to. Thereby, the game ball B1 after the collision rebounds upward on the right side.

  Further, a drag force having an upward component and a rightward component also acts on the game ball B1 flowing down from the upper right side and colliding with the second distribution surface 234a. Thereby, the game ball B1 after the collision rebounds upward on the right side. In this case, since the game ball B1 before the collision already has a velocity component in the right direction, the game ball B1 that has collided by flowing down from the upper left side is more right than the game ball B1 that has collided by falling from directly above. Proceed greatly.

  Next, the difference between the course of the game ball B1 after colliding with the left and right sorting nails 213 and 214 and the course of the game ball B1 after colliding with the obstacle nail 228 is based on FIGS. 56 (a) to (c). I will explain. 56 (a) is a table showing the direction of the drag force received by the game ball B1 that collides with the first left / right sorting nail 213, and FIG. 56 (b) shows the game ball B1 that strikes the second left / right sorting nail 214. FIG. 56C is a table showing the direction of the drag received by the game ball B1 that collides with the obstacle nail 228.

  First, the first left / right sorting nail 213 will be described. As shown in FIG. 56 (a), a drag force having a right component and an upward component acts on the game ball B1 that collides with the first distribution surface 217a on the back side of the game area PA, and the game area A drag having a left component and an upward component acts on the game ball B1 that collides with the second distribution surface 218a on the front side of the PA. In the first left / right sorting nail 213, when the game ball B1 collides with the left side of the first left / right sorting nail 213 and when the game ball B1 hits the right side of the first left / right sorting nail 213 The direction of the drag acting on the game ball B1 at the time of collision is the same.

  Next, the second left / right sorting nail 214 will be described. As shown in FIG. 56 (b), a drag force having a left component and an upward component acts on the game ball B1 that collides with the first distribution surface 232a on the back side of the game area PA. 2 A drag force having a right component and an upward component acts on the game ball B1 that collides with the second distribution surface 234a on the front side of the game area PA of the left / right distribution nail 214. In the second left / right sorting nail 214, when the game ball B1 collides with the left side of the second left / right sorting nail 214 and when the game ball B1 hits the right side of the second left / right sorting nail 214 The direction of the drag acting on the game ball B1 at the time of collision is the same.

  On the other hand, as shown in FIG. 56 (c), a drag force having a left component and an upward component acts on the game ball B1 that has collided with the left surface of the obstacle nail 228, and the obstacle nail 228 A drag force having a right component and an upward component acts on the game ball B1 that has collided with the right side of the game ball B1. In the obstacle nail 228, when the game ball B1 collides with the back side of the obstacle nail 228 and when the game ball B1 collides with the front side of the obstacle nail 228, the drag force acting on the game ball B1 at the time of the collision The direction is the same.

  In this way, by using the left / right distribution nails 213, 214, the direction of the drag acting on the game ball B1 that collides with the left / right distribution nails 213, 214 differs according to the position in the depth direction in the game area PA. By doing so, the course of the game ball B1 after the collision can be made different. For this reason, compared with the obstacle nail 228 in which the course after the collision of the game ball B1 does not change regardless of whether the game ball B1 is located on the front side or the back side of the game area PA, in the game area PA The distribution of the game balls B1 can be performed in a manner that increases variations in the movement of the game balls B1. Thus, by preventing the movement of the game ball B1 from becoming monotonous, it is possible to improve the interest of the game.

  The behavior pattern of the game ball B1 in the conventional game board in which only the obstacle nail 228 is arranged as a nail for distributing the course of the game ball B1 is a behavior pattern in which the game ball B1 colliding with the left side of the obstacle nail 228 rebounds to the left side. The game ball B1 that collides with the right side of the obstacle nail 228 bounces back to the right side. On the other hand, by arranging the left and right distribution nails 213 and 214 on the game board 233, the behavior pattern of the game ball B1 in which the game ball B1 colliding with the left side of the left and right distribution nails 213 and 214 rebounds to the right side, In addition, a behavior pattern of the game ball B1 in which the game ball B1 colliding with the right side of the left and right distribution nails 213 and 214 rebounds to the left side can be added as a new behavior pattern of the game ball B1. By increasing variations in the movement of the game ball B1 in the game area PA and preventing the movement of the game ball B1 from becoming monotonous, it is possible to improve the interest of the game.

  As described above, when the game ball B1 collides with the left and right sorting nails 213 and 214, the course of the game ball B1 after the collision changes according to the position of the game ball B1 in the depth direction. Further, as already described, in the game board 233 (FIG. 50) of the present embodiment, the left and right sorting nails 213 and 214 are guided nail groups provided for guiding the game ball B1 to the operation ports 33 and 34. 211 and 212 are disposed as a part.

  The behavior when the game ball B1 located on the back side of the game area PA collides with the first left / right sorting nail 213 constituting the left guide nail group 211 will be described based on FIG. 57 (a). FIG. 57 (a) is an explanatory diagram for explaining the course of the game ball B1 located on the back side on the left guide nail group 211. FIG. As described above, the seven first left and right sorting nails 213 belonging to the left guide nail group 211 are arranged in a line toward the operation ports 33 and 34.

  As described above, the interval between the first left and right sorting nails 213 constituting the left guide nail group 211 is slightly larger than the diameter of the game ball B1. As shown in FIG. 57 (a), the game ball B1 located on the far side of the game area PA receives a drag in the upper right direction due to a collision with the first distribution surface 217a of the first left / right distribution nail 213, and is on the upper right side. Bounce back and forth. After the collision, the right speed component of the game ball B1 increases, so the game ball B1 falls downward from the gap left on the right side of the colliding first left / right sorting nail 213 and is collected from the out port 24a. The possibility of being reduced. In addition, since the moving distance of the game ball B1 in the right direction after the collision increases, the number of collisions with the first left / right sorting nail 213 required until the game ball B1 reaches the operation ports 33 and 34 decreases. Then, the possibility that the game ball B1 falls downward from the gap between the two first left and right sorting nails 213 and is collected from the out port 24a is reduced. In this way, the game ball B1 located on the back side of the game area PA is guided to the operation ports 33 and 34 by the left guide nail group 211 with a high probability.

  Next, the behavior when the game ball B1 located on the front side of the game area PA collides with the first left / right sorting nail 213 constituting the left guide nail group 211 will be described based on FIG. 57 (b). . FIG. 57 (b) is an explanatory diagram for explaining the course of the game ball B <b> 1 located on the near side on the left guide nail group 211.

  As shown in FIG. 57 (b), the game ball B1 located on the front side of the game area PA receives a drag in the upper left direction due to a collision with the second distribution surface 218a of the first left / right distribution nail 213, and moves upward on the right side. Bouncing back and forth. After the collision, the velocity component in the right direction of the game ball B1 decreases due to the influence of the drag in the opposite direction. For this reason, there is a high possibility that the game ball B1 falls downward and is collected from the out port 24a through the gap provided on the right side of the colliding first left / right sorting nail 213. Further, since the speed component in the right direction of the game ball B1 is reduced due to the collision, the number of collisions with the first left / right sorting nail 213 required until the game ball B1 reaches the operation ports 33 and 34 increases. To do. Further, since the velocity component in the right direction of the game ball B1 decreases at each collision, the game ball B1 may drop downward from the gap between the two first left and right sorting nails 213 and be collected from the out port 24a. Increases with each collision. Thus, the probability that the game ball B1 located on the front side of the game area PA is guided to the operation ports 33 and 34 by the left guide nail group 211 is low.

  Next, FIG. 58 (a) shows the behavior of the game ball B1 when the game ball B1 located on the far side of the game area PA collides with the second left / right sorting nail 214 constituting the right guide nail group 212. This will be explained based on. FIG. 58 (a) is an explanatory diagram for explaining the course of the game ball B1 located on the far side on the right guide nail group 212. FIG. As described above, the seven second left / right sorting nails 214 belonging to the right guide nail group 212 are arranged in a line toward the operation ports 33 and 34.

  As described above, the interval between the second left and right sorting nails 214 constituting the right guide nail group 212 is slightly larger than the diameter of the game ball B1. As shown in FIG. 58 (a), the game ball B1 located on the back side of the game area PA receives an upper left drag due to a collision with the first distribution surface 232a of the second left / right distribution nail 214, and is on the upper left side. Bounce back and forth. After the collision, the velocity component in the left direction of the game ball B1 increases under the influence of the drag in the same direction. For this reason, the moving distance of the game ball B1 in the left direction is increased, and the game ball B1 falls downward from the gap provided on the left side of the collided second left / right sorting nail 214 and is collected from the out port 24a. Less likely to be done. In addition, since the moving distance of the game ball B1 in the left direction after the collision increases, the number of collisions with the second left / right sorting nail 214 required to reach the operation ports 33 and 34 decreases, and the game ball The possibility that B1 falls downward from the gap between the two second left and right sorting nails 214 and is recovered from the out port 24a is reduced. In this way, the game ball B1 located on the back side of the game area PA is guided to the operation ports 33 and 34 by the right guide nail group 212 with a high probability.

  Next, FIG. 58B shows the behavior of the game ball B1 when the game ball B1 located on the front side of the game area PA collides with the second left / right sorting nail 214 constituting the right guide nail group 212. This will be explained based on. FIG. 58B is an explanatory diagram for explaining the course of the game ball B1 located on the near side on the right guide nail group 212. FIG.

  As shown in FIG. 58 (b), the game ball B1 located on the front side of the game area PA receives a drag in the upper right direction due to a collision with the second distribution surface 234a of the second left / right distribution nail 214, and is on the upper left side. Bouncing back and forth. After the collision, the speed component in the left direction of the game ball B1 decreases due to the influence of the drag in the right direction, so that the game ball B1 moves downward from the gap provided on the right side of the second right / left sorting nail 214 that has collided. The possibility of being dropped and recovered from the out port 24a increases. In addition, since the moving distance of the game ball B1 in the left direction decreases after the collision, the number of times of collision with the second left / right sorting nail 214 required until the game ball B1 reaches the operation ports 33 and 34 increases. To do. Since the velocity component in the left direction of the game ball B1 decreases at each collision, the game ball B1 can fall down from the gap between the two second left and right sorting nails 214 and be collected from the out port 24a. Sexuality increases. Thus, the probability that the game ball B1 located on the front side of the game area PA is guided to the operation ports 33 and 34 by the right guide nail group 212 is low.

  In addition, as shown in FIGS. 57 (a) and 57 (b) and FIGS. 58 (a) and 58 (b), the game ball B1 that collides in the vicinity of the upstream side of the first working port 33 has a high probability of the working port 33, Four obstacle nails 228 are arranged for winning 34. The four obstacle nails 228 bounce the game ball B1 located on the back side of the game area PA and the game ball B1 located on the near side in the same manner. For this reason, even if the game ball B1 is located on the front side of the game area PA, it is operated with high probability when guided to the obstacle nail 228 near the first operation port 33 by the guide nail groups 211 and 212. Wins at the mouths 33 and 34.

  As described above, the nail provided in the vicinity of the first operation port 33 is the obstacle nail 228, so that the game ball B1 that has reached the periphery of the operation ports 33 and 34 is left with a sense of security that the player will win with a high probability. However, it is possible to make a difference in the probability that the game ball B1 wins the operation ports 33 and 34 according to the position of the game area PA in the depth direction.

  According to the embodiment described in detail above, the following excellent effects are obtained.

  The left and right sorting nails 213, 214 are provided with two sorting surfaces 217a, 218a, 232a, 234a having different inclinations, and the two sorting surfaces 217a, 218a, 232a, 234a are directed left and right so that they are directed upward. In this configuration, nails 213 and 214 are provided on the game board 233. As a result, when the game ball B1 flowing down from above collides with the first distribution surfaces 217a and 232a, the game ball B1 rebounds in a manner different from that when the game ball B1 collides with the second distribution surfaces 218a and 234a. . By using the left and right distributing nails 213 and 214, the course of the game ball B1 after the collision can be changed in a manner corresponding to the position in the depth direction of the game ball B1 in the game area PA. By increasing the pattern in which the game balls B1 are dispersed in the game area PA, it is possible to avoid the monotonous movement of the game balls B1 in the game area PA and improve the interest of the game.

  In addition, by using the left and right sorting nails 213 and 214 as the nails constituting the guide nail groups 211 and 212 for guiding the game ball B1 to the operation ports 33 and 34, the depth direction in the game area PA of the game ball B1 is increased. Differences in position can be reflected in the game results. Compared to a conventional gaming machine in which the difference in the position of the game ball B1 in the game area PA in the depth direction cannot be reflected in the game results, the variation of the movement of the game ball B1 in the game area PA is increased, thereby improving the interest of the game. be able to.

  Also, the vertical and horizontal dimensions of the resin left and right sorting members 215 and 231 constituting the left and right sorting nails 213 and 214 are larger than the vertical and horizontal dimensions of the metallic obstacle nail 228. In addition, large fixing holes 215a and 231a are formed in the left and right sorting members 215 and 231, and a metal fixing member 216 is fitted in the fixing holes 215a and 231a. As described above, since the resin member is reinforced with the metal member over the entire area, the left and right distributing nails 213 and 214 have durability that does not break even if the game ball B1 is repeatedly hit. Yes. When the pachinko machine 10 is installed in the game hall for a long time, the number of maintenance operations for the left and right sorting nails 213 and 214 can be minimized.

  In the game board 233, the left and right sorting nails 213 and 214 occupying a larger area than the obstacle nail 228 are used only for some of the nails provided in the game board 233 that are greatly related to the game result. In addition, the obstacle nail 228 is used for the remaining nails. Therefore, unlike the case where the left and right sorting nails 213 and 214 are used for all the nails provided in the game board 233, the game in the game area PA is ensured while ensuring the number of nails that can be provided in the game board 233. The game result can be different depending on the position of the sphere B1 in the depth direction.

  Further, since the right and left distribution nails 213 and 214 are provided with fixing holes 215a and 231a, the protruding portion of the fixing member 216 previously fixed to the game board 233 is fitted into the fixing holes 215a and 231a. The left and right sorting nails 213 and 214 can be fixed by the above. The left and right sorting nails 213 and 214 are fixed to the fixing member 216 with an adhesive. At this time, the right and left sorting nails 213 and 214 are rotated around the fixing member 216 until the adhesive is hardened, and the sorting surfaces 217a, 218a, 232a, and 234a of the left and right sorting nails 213 and 214 are moved upward. Since it can adjust so that it may face, the game ball | bowl B1 which flows down from upper direction can be made to collide with the distribution surfaces 217a, 218a, 232a, 234a.

<Another embodiment of the thirteenth embodiment>
-In game board 233 (Drawing 50) of a 13th embodiment mentioned above, the field where guidance nail groups 211 and 212 are arranged may be constituted by a removable member. The case where the left guide nail group 211 is configured to be detachable will be specifically described with reference to FIG. FIG. 59 is an enlarged view of the lower left part of the front of the game board 235 including the left guide member 255, which is a base on which the left guide nail group 211 can be attached and detached, and seven first left / right sorting nails 213.

  As shown in FIG. 59, the seven first left / right sorting nails 213 are fixed to the left guide member 255. The left guide member 255 is formed with three fixing protrusions 255a that allow the left guide member 255 to be screwed to the game board 233. The fixing protrusion 255a is provided with a screw for fixing. A through hole is formed. Further, the game board 235 is formed with a hole into which the left guide member 255 fits without a gap, and a recess corresponding to the fixing protrusion 255a of the left guide member 255 is formed at the edge of the hole of the game board 235. Is formed. A screw hole for screwing the left guide member 255 is formed in the recess.

  In the assembly process of the pachinko machine 10, after fixing the seven first left and right sorting nails 213 to the single left guiding member 255 that has been removed, the left guiding member 255 is attached to the game board 235, and the fixing projection The part 255a is screwed into the recessed part of the game board 233. In this way, the seven first left / right sorting nails 213 can be integrated and attached to the game board 235 at the same time, thereby fixing the first left / right sorting nails 213 to the game board 235. The working efficiency can be increased and fine adjustment of the mounting angle of the first left / right sorting nail 213 can be facilitated. In this configuration, the left guide member 255 and the first left / right sorting nail 213 fixed to the left guide member 255 may be integrally formed.

  In the thirteenth embodiment described above, the left and right sorting nails 213 and 214 may be provided as so-called life nails located in the vicinity of the upstream side of the first working port 33. A configuration in which the left and right sorting nails 213 and 214 are provided in the vicinity of the first working port 33 will be specifically described with reference to FIG. FIG. 60 is a front view of the game board 236 in which the left and right sorting nails 213 and 214 are disposed in the vicinity of the first operation port 33, and an enlarged view of the periphery of the operation ports 33 and 34 of the game board 236. Four left and right sorting nails 213 and 214 are arranged in the vicinity of the upstream side of the operation ports 33 and 34.

  Specifically, a second left / right sorting nail 214 is disposed in the vicinity of the upper left of the operation ports 33, 34, and an interval slightly larger than the diameter of the game ball B1 is located on the left side of the second left / right sorting nail 214. A first left / right sorting nail 213 is provided with a gap. Since the gap between the two left and right sorting nails 213 and 214 disposed in the vicinity of the upper left of the operation ports 33 and 34 has a width that allows the game ball B1 to pass therethrough, the game ball B1 includes the two game balls B1. It is the structure which does not pinch | interpose between the right-and-left distribution nails 213 and 214 and stops. In addition, a first left / right sorting nail 213 is disposed in the vicinity of the upper right of the operation ports 33, 34, and a space larger than the diameter of the game ball B1 is provided on the right side of the first left / right sorting nail 213. The second left / right sorting nail 214 is disposed. Since the gap between the two right and left sorting nails 213 and 214 disposed in the vicinity of the upper right of the operation ports 33 and 34 has a width that allows the game ball B1 to pass therethrough, the game ball B1 includes the two game balls B1. It is the structure which does not pinch | interpose between the right-and-left distribution nails 213 and 214 and stops.

  Most of the game balls B1 that collide with the left and right sorting nails 213 and 214 disposed in the vicinity of the upper left of the operation ports 33 and 34 are guided to the obstacle nail 228 disposed on the left side of the game area PA. A game ball B1. The game ball B1 collides with the left and right sorting nails 213 and 214 from the upper left side. The game ball B1, which is located on the far side of the game area PA and collides with the outer first left / right sorting nail 213 above the left side of the operation ports 33, 34, collides with the first sorting surface 217a. The game ball B1 receives a drag force in the upper right direction, rebounds greatly in the right direction, which is the direction toward the operation ports 33, 34, and wins the operation ports 33, 34 with a high probability.

  In addition, the game ball B1, which is located on the back side of the game area PA and collides with the inner second left / right sorting nail 214 above the left side of the operation ports 33, 34, collides with the first sorting surface 232a. The game ball B1 receives a drag force in the upper left direction, rebounds small in the right direction, which is the direction toward the operation ports 33 and 34, and wins the operation ports 33 and 34 with a high probability. Here, the outer side is a side far from the operation ports 33 and 34, and the inner side is a side closer to the operation ports 33 and 34.

  Thus, for the game ball B1 on the back side of the game area PA, the game ball B1 that collides with the first left / right sorting nail 213 relatively far from the operation ports 33 and 34 greatly advances to the right side, and the operation port The left and right sorting nails 213 and 214 are arranged so that the game ball B1 colliding with the inner second left and right sorting nail 214 relatively close to 33 and 34 advances to the right. For this reason, the game ball B1 located on the back side of the game area PA collides with the outer first left / right sorting nail 213 at the upper left side of the operation ports 33, 34 and the inner second left / right sorting nail 214. In any of the cases where there is a collision, the operating ports 33 and 34 are won with a high probability.

  In addition, the game ball B1, which is located on the front side of the game area PA and collides with the outer first left / right distribution nail 213 above the left side of the operation ports 33, 34, collides with the second distribution surface 218a. The game ball B1 receives a drag force in the upper left direction, rebounds to the right, which is the direction toward the operation ports 33, 34, and wins the operation ports 33, 34 with a low probability. In addition, the game ball B1, which is positioned on the front side of the game area PA and collides with the inner second left / right sorting nail 214 above the left side of the operation ports 33, 34, collides with the second sorting surface 234a. The game ball B1 receives a drag force in the upper right direction, greatly rebounds in the right direction, which is a direction toward the operation ports 33 and 34, and wins the operation ports 33 and 34 with a low probability.

  As described above, for the game ball B1 on the front side of the game area PA, the game ball B1 colliding with the first left / right sorting nail 213 relatively far from the operation ports 33 and 34 advances to the right side, and the operation port The left and right sorting nails 213 and 214 are arranged so that the game ball B1 colliding with the inner second left and right sorting nail 214 relatively close to 33 and 34 advances to the right. For this reason, the game ball B1 located on the front side of the game area PA collides with the outer first left / right sorting nail 213 at the upper left side of the operation ports 33, 34 and the inner second left / right sorting nail 214. In any of the cases where the collision occurs, the operation ports 33 and 34 are won with a low probability.

  On the other hand, most of the game balls B1 that collide with the left and right sorting nails 213 and 214 disposed in the vicinity of the upper right of the operation ports 33 and 34 are guided to the obstacle nail 228 disposed on the right side of the game area PA. This is the incoming game ball B1. The game ball B1 collides with the left and right sorting nails 213 and 214 from the upper right side. The game ball B1, which is located on the back side of the game area PA and collides with the outer second left / right sorting nail 214 above the right side of the operation ports 33, 34, collides with the first sorting surface 232a. The game ball B1 receives a drag force in the upper left direction, greatly rebounds to the left, which is the direction toward the operation ports 33 and 34, and wins the operation ports 33 and 34 with a high probability.

  In addition, the game ball B1, which is located on the back side of the game area PA and collides with the first left / right sorting nail 213 on the inner right side of the operation ports 33, 34, collides with the first sorting surface 217a. The game ball B1 receives a drag force in the upper right direction, rebounds to the left, which is the direction toward the operation ports 33, 34, and wins the operation ports 33, 34 with a high probability. Here, the outer side is a side far from the operation ports 33 and 34, and the inner side is a side closer to the operation ports 33 and 34.

  Thus, for the game ball B1 on the back side of the game area PA, the game ball B1 colliding with the second left / right sorting nail 214 on the outer side relatively far from the operation ports 33 and 34 greatly advances to the left side, and the operation port The left and right sorting nails 213 and 214 are arranged so that the game ball B1 colliding with the inner first left and right sorting nail 213 relatively close to 33 and 34 advances to the left. For this reason, when the game ball B1 located on the back side of the game area PA collides with the outer second left / right distribution nail 214 at the upper right side of the operation ports 33, 34, and the inner first left / right distribution nail 213. It is possible to adopt a configuration in which the operation ports 33 and 34 are won with a high probability in any of the cases of collision.

  In addition, the game ball B1, which is located on the front side of the game area PA and collides with the outer second left / right distribution nail 214 above the right side of the operation ports 33, 34, collides with the second distribution surface 234a. The game ball B1 receives a drag force in the upper right direction, rebounds to the left, which is the direction toward the operation ports 33, 34, and wins the operation ports 33, 34 with a low probability. Further, the game ball B1, which is located on the front side of the game area PA and collides with the first left / right sorting nail 213 inside the upper right side of the operation ports 33, 34, collides with the second sorting surface 218a. The game ball B1 receives a drag force in the upper left direction, greatly rebounds to the left, which is the direction toward the operation ports 33, 34, and wins the operation ports 33, 34 with a low probability.

  As described above, for the game ball B1 on the near side of the game area PA, the game ball B1 colliding with the second left / right sorting nail 214 on the outer side relatively far from the operation ports 33 and 34 advances to the left side, and the operation port The left and right sorting nails 213 and 214 are arranged so that the game ball B1 colliding with the inner first left and right sorting nail 213 relatively close to 33 and 34 advances to the left. For this reason, the game ball B1 located on the front side of the game area PA collides with the outer second left / right distribution nail 214 at the upper right side of the operation ports 33, 34 and the inner first left / right distribution nail 213. In any of the cases where the collision occurs, the operation ports 33 and 34 are won with a low probability.

  As described above, by providing the right and left distribution nails 213 and 214 in the vicinity of the upstream side of the first working port 33, the game ball B1 is in a manner corresponding to the position of the game ball B1 in the front-rear direction in the game area PA. It is possible to make the probabilities of winning the operating ports 33 and 34 different. On the other hand, in the case of the conventional pachinko machine in which the obstacle nail 228 is disposed immediately before the operation port, the probability that the game ball B1 wins the operation port is not affected by the position of the game ball B1 in the front-rear direction in the game area PA. .

  Therefore, by adopting a configuration in which the left and right sorting nails 213 and 214 are disposed immediately before the operation ports 33 and 34, compared with a conventional pachinko machine in which the obstacle nail 228 is disposed immediately before the operation ports. The variation of the movement of the game ball B1 immediately before the operation ports 33 and 34 can be enriched to improve the interest of the game.

  The left and right sorting nails 213 and 214 may be used as so-called ceiling nails arranged near the top of the game board 233. In this configuration, the game balls B1 that collide with the top nails are distributed to either the left side or the right side of the game board 233 according to the position of the game area PA in the depth direction. By using a game board in which the probability that the game ball B1 flowing down the left side wins the operating ports 33 and 34 and the probability that the game ball B1 flowing down the right side wins the operating ports 33 and 34 are different, The course of the game ball B1 after the collision can be distributed in a manner corresponding to the position in the depth direction of the game ball B1.

  In the thirteenth embodiment described above, the shape of the left and right sorting nails 213 and 214 is such that the sorting surfaces 217a, 218a, 232a and 234a are provided over the entire length of the left and right sorting nails 213 and 214. The shape is not limited. For example, instead of the first left / right sorting nail 213, the first left / right sorting nail 242 in which the sorting surfaces 244a and 245a are provided only in the collision possible range of the game ball B1 may be used.

  The first left / right sorting nail 242 will be described with reference to FIGS. 61 (a) and (b). 61 (a) is a perspective view of the first left / right sorting nail 242 and FIG. 61 (b) is an end view of the cut surface of the first left / right sorting nail 242 cut along a plane perpendicular to the game board 233. FIG. . As shown in FIG. 61 (a), the first left / right sorting nail 242 is a nail formed to extend in the direction of the axis 242a. The first left / right sorting nail 242 includes a first left / right sorting member 243 having sorting surfaces 244a, 245a for sorting the path of the game ball B1 that collides after the collision, and the first left / right sorting member 243. And a fixing member 216 for fixing to the game board 237 (FIG. 61 (b)). Here, the fixing member 216 constituting the first left / right sorting nail 242 is the same member as the fixing member 216 constituting the first left / right sorting member 215 of the thirteenth embodiment.

  The first left / right sorting member 243 is a resin member having a substantially quadrangular prism shape formed extending in the direction of the axis 242a. The first left-right sorting member 243 includes a fixed end non-contact portion 246 whose upper surface is a fixed end non-contact surface 246a that is a horizontal surface on the fixed end side that does not contact the game ball B1. On the near side of the fixed end non-contact portion 246, a first distribution portion 244 having a first distribution surface 244a inclined downward toward the right as an upper surface is connected to the fixed end non-contact portion 246. It is integrally formed in a continuous manner. In addition, on the front side of the first distribution unit 244, a second distribution unit 245 having a second distribution surface 245a inclined downward toward the left as an upper surface is connected to the first distribution unit 244. It is integrally formed in a continuous manner. A free end side non-contact portion 247 having a free end side non-contact surface 247a, which is a horizontal surface on the free end side that does not come into contact with the game ball B1, as an upper surface is provided on the front side of the second distribution portion 245. It is integrally formed in a manner that is continuous with the minute portion 245.

  As shown in FIG. 61 (b), the length dimension in the axis 242a direction of the fixed end side non-contact portion 246 located on the fixed end side of the first left / right sorting member 243 is shorter than the radius of the game ball B1. The length in the direction of the axis 242a (FIG. 61 (a)) of the first allocating portion 244 adjacent to the front side of the fixed-end-side non-contact portion 246 is 4 mm. The height dimension of the fixed end side non-contact part 246 is the same as the height dimension of the right end of the first distribution part 244.

  Further, as shown in FIG. 61 (b), the length dimension in the direction of the axis 242a (FIG. 61 (a)) of the second allocating portion 245 adjacent to the front side of the first allocating portion 244 is 4 mm. In addition, the length dimension in the direction of the axis 242a (FIG. 61 (a)) of the free end side non-contact portion 247 adjacent to the free end side of the second allocating portion 245 is shorter than the radius of the game ball B1. 4 mm. The height dimension of the free end side non-contact part 247 is the same as the height dimension of the left end of the second distribution part 245. Here, in a state where the first left / right distribution nail 242 is fixed to the game board 237, the side surface on the fixed end side, the boundary surface between the fixed end side non-contact portion 246 and the first distribution portion 244, the first distribution The boundary surface between the portion 244 and the second allocating portion 245 and the boundary surface between the second allocating portion 245 and the free end non-contact portion 247 are both surfaces parallel to the surface of the game board 237.

  As already described in the thirteenth embodiment, the contactable range of the game ball B1 is 5.5 mm from the surface of the game board 237 to the window panel 52 side, from the surface of the game board 237 to the window panel 52 side. Up to a place moved 12.5 mm. On the other hand, since the length dimension of the fixed end side non-contact portion 246 in the first left / right sorting member 243 in the direction of the axis 242a is set to be shorter than 5.5 mm, the game located on the back side of the game area PA. The ball B1 can collide only with the first distribution surface 244a, and the game ball B1 does not collide with the fixed end side non-contact surface 246a. In addition, the length dimension (4 mm) in the direction of the axis 242a of the free end side non-contact portion 247 in the first left / right sorting member 243, and the length from the free end of the first left / right sorting member 243 to the back surface of the window panel 52. Since the total of the dimensions (1 mm) is set to be shorter than 5.5 mm, the game ball B1 located on the front side of the game area PA can collide only with the second distribution surface 245a. The sphere B1 does not collide with the free end side non-contact surface 247a.

  As described above, the fixed end of the first left / right sorting nail 242 is provided with the fixed end side non-contact portion 246 whose upper surface is the fixed end side non-contact surface 246a which is a horizontal plane, and the axis 242a direction of the fixed end side non-contact portion 246 is provided. By making the length dimension of the game ball B1 shorter than the radius of the game ball B1, it is possible to eliminate the possibility that the game ball B1 located on the back side of the game area PA contacts the fixed end side non-contact surface 246a. It is possible to reduce a possibility that a large error regarding the angle occurs when the sorting nail 242 is attached. Specifically, when the first left / right distribution nail 242 is attached to the game board 237, the distribution surfaces 244a and 245a are moved upward by adjusting the rotation angle with the fixed end side non-contact surface 246a that is a horizontal plane as a guide. It becomes easy to fix the first left / right sorting nail 242 to the game board 237 in the state of facing.

  In the thirteenth embodiment described above, instead of the left and right sorting nails 213 and 214, a configuration may be used in which an inversion nail 251 that reverses the position of the game ball B1 that collides in the game area PA is used. The shape of the inversion nail 251 will be described with reference to FIGS. 62 (a) to 62 (d).

  62 (a) is a perspective view of the reversing nail 251. FIG. 62 (b) is an end view of the cut surface when the reversing nail 251 is cut along a plane perpendicular to the surface of the game board 238. FIG. FIG. 62C is an explanatory diagram for explaining the drag force received by the game ball B1 colliding with the first reversing surface 254a of the reversing nail 251. FIG. 62D is a game reciprocating with the second reversing surface 254b of the reversing nail 251. It is explanatory drawing for demonstrating the drag which sphere B1 receives.

  As shown in FIG. 62 (a), the reversing nail 251 is a nail formed extending in the direction of the axis 251a. The reversing nail 251 includes a reversing member 254 having reversing surfaces 254a and 254b that change the course of the game ball B1 that collides, and a fixing member 216 for fixing the reversing member 254 to the game board 238. Become. The fixing member 216 constituting the reversing nail 251 is the same member as the fixing member 216 constituting the first left / right sorting nail 213 in the thirteenth embodiment.

  The reversing member 254 is a substantially quadrangular prism-shaped resin member formed to extend in the direction of the axis 251a. The upper surface of the reversing member 254 has four vertices, and is constituted by a first reversing surface 254a and a second reversing surface 254b. Among these, the first inversion surface 254a is a triangular plane having vertices on the right back, left back, and right front, and the vertex on the right back is higher than the other two vertices. For this reason, the 1st inversion surface 254a inclines below toward the left and the front.

  The second inversion surface 254b is a triangular plane having vertices on the left front side, the left back side, and the right front side, and the vertex on the left front side being higher than the other two vertices. For this reason, the 2nd inversion surface 254b inclines below toward the right and back.

  The length dimension of the reversing member 254 in the direction of the axis 251a is 17 mm. As shown in FIG. 62 (b), the reversing nail 251 is formed with a fixing hole into which the fixing member 216 is fitted, and is driven into and fixed to the inner wall of the fixing hole and the game board 238. The reversing member 254 is fixed to the game board 238 by being fixed to the outer wall of the fixing member 216 with an adhesive. In a state where the reversing nail 251 is fixed to the game board 238, the entire reversing member 254 protrudes from the surface of the game board 233, so that the reversing nail 251 is positioned in front of the game ball B1 located on the far side of the game area PA. It can collide with both the game balls B1 located on the side.

  As shown in FIG. 62A, on the fixed end side of the reversing nail 251, the area of the first reversing surface 254a is larger than the area of the second reversing surface 254b. For this reason, there is a high possibility that the game ball B1 located on the back side of the game area PA will collide with the first reversal surface 254a. Since the first reversing surface 254a is inclined downward toward the left and the front, as shown in FIG. 62 (c), the game ball B1 colliding with the first reversing surface 254a has a left component and an upper In response to a drag having a directional component and a forward component, it jumps up to the left front.

  As shown in FIG. 62A, on the free end side of the reversing nail 251, the area of the second reversing surface 254b is larger than the area of the first reversing surface 254a. For this reason, the game ball B1 located on the near side of the game area PA is highly likely to collide with the second reversal surface 254b. Since the second reversing surface 254b is inclined downward toward the right and rear, as shown in FIG. 62 (d), the game ball B1 colliding with the second reversing surface 254b has a right component and an upper In response to a drag having a direction component and a back direction component, it jumps up to the right rear.

  In this way, the reversing nail 251 is a nail that has a high probability of rebounding the game ball B1 that collides on the back side to the near side and that has a high probability of rebounding the game ball B1 that collides on the near side. For this reason, for example, an inversion nail 251 is provided upstream of the left guide nail group 211 in the game board 233 of the thirteenth embodiment, and the game ball B1 that collides with the inversion nail 251 upstream of the left guide nail group 211 in the depth direction. By reversing the positional relationship, the probability that the game ball B1 located on the back side of the game area PA will win the operation ports 33 and 34, and the probability that the game ball B1 located on the near side will win the operation ports 33 and 34 Can be changed.

  By using the reversing nail 251 that greatly changes the probability of winning in the operation ports 33 and 34, variations in the movement of the game ball B1 in the game area PA can be increased, and the interest of the game can be improved. Further, by using the reversing nail 251, the position in the depth direction of the game ball B1 in the game area PA is biased to the near side or the back side due to a malfunction of the game ball launching mechanism 27 (FIG. 2). Even in such a case, it is possible to avoid a situation in which a large deviation occurs in the probability that the game ball B1 wins the operating ports 33 and 34.

<Fourteenth embodiment>
In the present embodiment, the thirteenth embodiment is that the front and rear distribution nails 262 (FIG. 63) and the rear nails 271 (FIG. 63) are provided in the game board 261 (FIG. 63) instead of the distribution nails 213 and 214. This is different from the embodiment. Hereinafter, the description of the same configuration as that of the thirteenth embodiment is basically omitted.

  FIG. 63 is a front view of the game board 261 of the present embodiment, and an enlarged view of the upstream portion of the left guide nail group 281 in the game board 261. As shown in FIG. 63, in the game board 261 of this embodiment, in order to guide the game ball B1 flowing down the left side of the game area PA to the operation ports 33, 34, the obstacle nail 228, the front / rear distribution nail 262, The left guide nail group 281 including the rear nail 271 is provided. Here, the front / rear distribution nail 262 is a nail that changes the position in the depth direction of the game ball B1 that collides in the game area PA. The rear nail 271 is a nail that can be collided only by the game ball B1 flowing down the back side (the game board 261 side) of the game area PA.

  The left guide nail group 281 is located obliquely above and to the left of the operation ports 33 and 34. Since the space above the left guide nail group 281 is wider than the diameter of the game ball B1, the game ball B1 can pass over the left guide nail group 281. A front / rear distribution nail 262 and a rear nail 271 are disposed upstream of the left guide nail group 281.

  As shown in FIG. 63, the four front / rear sorting nails 262 are arranged in a line on the most upstream side of the left guide nail group 281, so that most of the game balls B 1 guided to the left guide nail group 281 are formed. It collides with one of the front and rear distribution nails 262 in the upstream portion. The game ball B1 that has collided with the front / rear distribution nail 262 reaches the downstream side of the left guide nail group 281 with the position in the depth direction being distributed. As shown in the enlarged view of FIG. 63, a row of the front / rear distribution nails 262 formed by the four front / rear distribution nails 262 is referred to as a first guide nail row 282.

  The four front / rear sorting nails 262 constituting the first guide nail row 282 are arranged in a row in such a manner that the right front / rear sorting nail 262 is positioned below the adjacent left front / rear sorting nail 262. . The interval between the front and rear distribution nails 262 constituting the first guide nail row 282 is narrower than the diameter 11 mm of the game ball B 1, and the game ball B 1 does not fall downward from the gap between the two front and rear distribution nails 262. is there.

  Further, the upper surface of the front / rear distribution nail 262 is a flat surface that does not tilt in the left-right direction. However, as shown in FIG. 63, the front / rear distribution nail 262 is rotated approximately 20 ° clockwise when viewed from the front. It is fixed. For this reason, in the first guide nail row 282, the upper surface of the front / rear sorting nail 262 is inclined in a mode that forms a gentle downward slope toward the right. Thereby, even if the game ball B1 loses the right speed component on the first guide nail row 282, it is possible to avoid the situation where the game ball B1 stops in place.

  A gap slightly larger than the diameter of the game ball B1 is provided immediately downstream of the first guide nail row 282, and three rear nails 271 are arranged in a row downstream of the gap. A row of rear nails 271 formed by the three rear nails 271 is referred to as a second guide nail row 283. In the second guide nail row 283, the three rear nails 271 are arranged without leaving a gap, and the game ball B1 does not fall downward from the gap between the two rear nails 271.

  Further, on the downstream side of the second guide nail row 283, four obstacle nails 228 are provided without a gap, and a third guide nail row 284 is formed. Then, downstream of the four obstacle nails 228, a plurality of obstacle nails 228 are arranged in a row with a gap larger than the diameter of the game ball B1. The row of the obstacle nails 228 continues immediately before the operation ports 33 and 34, and guides the game ball B1 to the operation ports 33 and 34.

  In the present embodiment, the right guide nail group arranged on the right side of the game board 261 is composed of obstacle nails 228.

  Next, the structure of the front / rear distribution nail 262 will be described with reference to FIGS. 64 (a) is a perspective view of the front / rear distribution nail 262, and FIG. 64 (b) is a plan view of the front / rear distribution member 263 constituting the front / rear distribution nail 262. FIGS. ) Is an end view of the cut surface when the front / rear distribution nail 262 is cut in a plane perpendicular to the surface of the game board 261. As shown in FIG. 64A, the front / rear distribution nail 262 is an elongated nail formed to extend in the direction of the axis 262c. The front / rear distribution nail 262 is a front / rear distribution member 263 that distributes the game balls B1 falling and colliding from above in the depth direction, and a fixing member 216 for fixing the front / rear distribution member 263 to the surface of the game board 261. And is composed of. The front / rear sorting member 263 is a substantially quadrangular prism-shaped resin member formed to extend in the direction of the axis 262c, and is a first swing having a different inclination as a surface that can collide with the game ball B1 falling from above. A division surface 264a and a second distribution surface 265a are provided.

  As shown in FIG. 63, the front / rear distribution nail 262 has an axis 262c that is substantially perpendicular to the surface of the game board 261, and the front / rear distribution member 263 protrudes from the surface of the game board 261. It is fixed. The longitudinal dimension of the front / rear sorting member 263 in the direction of the axis 262c is 17 mm. In the front / rear sorting nail 262 fixed to the game board 261, the front / rear sorting member 263 projects 17 mm into the game area PA. Since the front / rear distribution nail 262 covers the contactable range of the game ball B1, the front / rear distribution nail 262 can collide with the game ball B1 located on the back side of the game area PA and the game is located on the front side. May collide with sphere B1. In the following description, in the state of being fixed to the game board 261, the end fixed to the game board 261 is used as the fixed end of the front / rear distribution nail 262, and the end protruding to the game area PA is used as the front / rear distribution. The free end of the nail 262 is used.

  As shown in FIG. 64 (a), the front / rear sorting member 263 includes a first sorting portion 264 on the fixed end side having the first sorting surface 264a and a first end on the free end side having the second sorting surface 265a. 2 distribution unit 265. The length dimension of the first allocating portion 264 in the direction of the axis 262c is 9 mm, and the length dimension of the second allocating portion 265 in the direction of the axis 262c is 8 mm. The first distribution surface 264a is an inclined surface that is inclined downward toward the rear, and the second distribution surface 265a is an inclined surface that is inclined downward toward the front. In the state where the front / rear distribution nail 262 is fixed to the game board 261, the boundary surface between the first distribution part 264 and the second distribution part 265 is parallel to the surface of the game board 261, and the boundary surface Is located in the center of the game area PA in the depth direction.

  As shown in FIG. 64 (b), the front-rear distribution member 263 has square side surfaces at the fixed end and the free end, respectively. Among these, a fixing hole 263a for fitting the fixing member 216 when the front / rear sorting member 263 is fixed to the game board 261 is formed in the fixed end surface 263b which is a side surface on the fixed end side. The fixing hole 263a is a cylindrical hole formed in an aspect having an opening on the side surface on the fixed end side of the front / rear sorting member 263 and extending from the fixed end of the front / rear sorting member 263 to the vicinity of the free end. The depth of the fixing hole 263a is 15 mm. As shown in FIG. 64 (b), the fixing hole 263 a is formed so as to occupy more than half the volume of the front / rear sorting member 263. The fixing hole 263a is formed at a sufficient distance from the top, bottom, left, and right side surfaces of the front / rear sorting member 263 to maintain the strength of the front / rear sorting member 263.

  Next, a state where the front / rear distribution nail 262 is fixed to the game board 261 will be described. The fixing member 216 constituting the front / rear distribution nail 262 is the same member as the fixing member 216 constituting the first left / right distribution nail 213 described in the thirteenth embodiment. As shown in FIGS. 64 (c) and 64 (d), the fixing member 216 has the whole fixing point head 216b and a part of the fixing trunk shaft portion 216a behind the surface of the game board 261. The remaining portion of the fixing trunk shaft portion 216a is fixed to the game board 261 in such a manner as to protrude in a substantially vertical direction from the surface of the game board 261. In the fixing member 216 fixed to the game board 261, the length dimension of the protrusion from the surface of the game board 261 is 15 mm. The front / rear distribution member 263 is fixed to the game board 261 in such a manner that the distribution surfaces 264a, 265a face upward by fixing the outer wall of the protrusion and the inner wall of the fixing hole 263a with an adhesive.

  As shown in FIG. 64 (c), the game ball B1 flowing down the back side (game board 261 side) of the game area PA sandwiched between the game board 261 and the window panel 52 collides with the first distribution surface 264a. To do. On the back side of the game area PA, the first distribution surface 264a is inclined downward toward the rear, so that an upward component is applied to the game ball B1 that falls from above and collides with the first distribution surface 264a. And drag with a component in the back direction. Thereby, the game ball B1 after the collision rebounds in the back direction, and flows down the back side of the game area PA in the downstream.

  In addition, the game ball B1 flowing down the front side (window panel 52 side) of the game area PA collides with the second distribution surface 265a. On the back side of the game area PA, since the second distribution surface 265a is inclined downward toward the front, the upward component is applied to the game ball B1 that falls from above and collides with the second distribution surface 265a. And a drag having a component in the front direction. As a result, the game ball B1 after the collision rebounds toward the near side, and flows down the near side of the game area PA downstream.

  Next, the relationship between the rear nail 271 and the game ball B1 in the game area PA will be described with reference to FIGS. FIG. 65A is a perspective view of the rear nail 271, and FIGS. 65B and 65C are longitudinal sectional views of the rear nail 271 when cut along a plane perpendicular to the surface of the game board 261.

  As shown in FIG. 65 (a), the rear nail 271 includes a cylindrical trunk shaft portion 271a and a conical pointed portion 271b. Both the diameter of the trunk shaft portion 271 a and the diameter of the bottom surface of the pointed head 271 b are approximately 2 mm, which is the same as the trunk diameter of the obstacle nail 228. As shown in FIG. 65 (b), the rear nail 271 is configured such that the entire pointed head 271b and a part of the trunk shaft portion 271a are buried deeper than the surface of the game board 261, and the rear shaft nail 271a The game board 261 is fixed in such a manner that a part projects from the game board 261 in a substantially vertical direction.

  In the rear nail 271 fixed to the game board 261, the length from the surface of the game board 261 to the front end of the protruding portion of the rear nail 271 is 6 mm. Here, the distance from the tip of the protruding portion of the rear nail 271 fixed to the game board 261 to the back surface of the window panel 52 is 12 mm, and a game ball B1 having a diameter of 11 mm is sandwiched between the rear nail 271 and the window panel 52. It is a configuration that does not occur.

  As shown in FIG. 65 (b), the game ball B1 having a diameter of 11 mm flowing down along the surface of the game board 261 on the back side of the game area PA collides with the rear nail 271 and changes the traveling direction. On the other hand, as shown in FIG. 65 (c), the game ball B1 flowing down the front side of the game area PA along the surface on the back side of the window panel 52 does not collide with the rear nail 271 and therefore maintains the traveling direction as it is. Then head downstream.

  Next, the movement of the game ball B1 that has entered the space above the left guide nail group 281 will be described with reference to FIGS. 66 (a) and 66 (b). FIG. 66 (a) is an explanatory diagram for explaining a course in the left guide nail group 281 of the game ball B1 located on the back side of the game area PA, and FIG. 66 (b) is a position on the front side of the game area PA. It is explanatory drawing for demonstrating the course in the left guidance nail group 281 of the game ball | bowl B1 to do.

  As shown in FIG. 66 (a), when the game ball B1 flowing down the back side of the game area PA enters the space above the left guide nail group 281, the game ball B1 forms a first guide nail row 282. It collides with one of the four front and rear distribution nails 262 and bounces back. At this time, since the game ball B1 collides with the first distribution surface 264a (FIG. 64 (a)) of the front / rear distribution nail 262, the game ball B1 flows down the back side of the game area PA with high probability.

  The game ball B1 that has bounced off the front / rear nail 262 constituting the first guide nail row 282 and bounced back is upstream of the front / rear nail 262 and the second guide nail row 283 positioned at the downstream end of the first guide nail row 282. When jumping over the gap with the rear nail 271 located at the end, the game ball B1 enters the space above the second guide nail row 283. When the game ball B1 is located on the back side of the game area PA and collides with one of the three rear nails 271 constituting the second guide nail row 283 and bounces back, the game ball B1 is returned to the third guide nail row 284. Is guided toward the operation ports 33 and 34.

  On the other hand, as shown in FIG. 66 (b), when the game ball B1 located on the front side of the game area PA enters the space above the left guide nail group 281, the game ball B1 moves through the first guide nail row 282. It collides with any one of the four front and rear distribution nails 262 and bounces back. At this time, since the game ball B1 collides with the second distribution surface 265a (FIG. 64A) of the front / rear distribution nail 262, the game ball B1 flows down along the back surface of the window panel 52 with high probability downstream. .

  The game ball B1 that collides with the second distribution surface 265a and bounces back is a front / rear distribution nail 262 located at the downstream end of the first guide nail row 282, and a rear nail 271 located at the upstream end of the second guide nail row 283, When jumping over the gap, the game ball B1 enters the space above the second guide nail row 283. When the game ball B1 is moving along the back surface of the window panel 52 and does not collide with any of the three rear nails 271 constituting the second guide nail row 283, the game ball B1 is moved to the rear nail 271 and the window. It falls through the panel 52 and is collected at the out port 24a.

  According to the embodiment described in detail above, the following excellent effects are obtained.

  The game board 261 is provided with a front / rear distribution nail 262 that distributes the path after the collision between the back side and the near side of the game area PA according to the position in the depth direction of the game ball B1 that collides. With this configuration, the path after the collision can be divided along either the game board 261 or along the window panel 52 for the game ball B1 located near the center in the depth direction of the game area PA. Further, downstream of the front / rear distribution nail 262, in each of the case where the game ball B1 is located on the game board 261 side of the game area PA and the case where it is located on the window panel 52 side of the game area PA, In this configuration, the second guide nail row 283 is set so that the path of the game ball B1 is different. For this reason, the course downstream of the game ball B1 can be made different according to the course distributed by the front / rear distribution nail 262. As described above, by arranging the second guide nail row 283 downstream of the front / rear distribution nail 262, the course of the game ball B1 downstream is changed according to the position of the game ball B1 in the front-rear direction in the game area PA. It can be configured to change. Compared with a configuration in which only the position in the left-right direction in the game area PA affects the course downstream of the game ball B1, the variation of the movement of the game ball B1 can be increased, and the interest of the game can be improved.

  Further, when the game board 261 is provided, a rear nail 271 is formed in which a space through which the game ball B1 can pass is formed between the free end of the projecting portion and the back surface of the window panel 52. Therefore, the course of the game ball B1 located on the game board 261 side is changed, and the course of the game ball B1 located on the window panel 52 side is not changed, and the course downstream of the game ball B1 is different. It can be. By using the rear nail 271 as the nail constituting the second guide nail row 283, the variation of the movement of the game ball B1 in the game area PA can be increased, and the interest of the game can be improved.

<Another embodiment of the fourteenth embodiment>
In the fourteenth embodiment described above, instead of the configuration in which the three rear nails 271 are arranged as the second guide nail row 283, the rear nails from the surface of the game board 261 to the window panel 52 side when fixed to the game board 261 One inclined member that protrudes by the same length as 271 and has the same inclined surface as the angle at which the rear nails 271 are arranged in the second guide nail row 283 may be arranged. By adopting a configuration in which the inclined member is arranged, the player moves along the surface of the game board 261 without changing the course of the game ball B1 moving along the inner surface of the window panel 52. The course of the game ball B1 can be changed. In this case, the inclined member can be fixed to the game board 261 more easily than when the three rear nails 271 are provided side by side on the game board 261.

  In the fourteenth embodiment described above, all the nails constituting the second guide nail row 283 and the third guide nail row 284 are the obstacle nails 228, and the first guide nail row 282 and the first guide nail row 282 The rear nail 271 may be disposed in the gap with the two-guide nail row 283. In this case, the conventional gaming machine that uses only the obstacle nail 228 as a nail, the probability that the game ball B1 flowing down the front side of the game area PA is guided by the left guide nail group 281 and wins the operating ports 33 and 34 is used. It is possible to increase the probability that the game ball B1 flowing down the back side of the game area PA is guided to the left guide nail group 281 and wins the operating port.

  In the fourteenth embodiment described above, the shape of the front / rear distribution nail 262 is the upper surface of the front / rear distribution nail 262, and the surface disposed on the distal end side is inclined upward from the proximal end toward the distal end In addition, the upper surface of the front / rear distribution nail 262 and the surface disposed on the base end side may be inclined downward from the base end toward the front end.

  For example, in the above-described front / rear sorting nail 262, the first sorting portion 264 located on the fixed end side is located on the free end side, and the second sorting portion 265 located on the free end side. A nail positioned on the fixed end side may be used as a front / rear sorting nail. That is, in the above-described front / rear distribution nail 262, a nail having a shape in which the first distribution unit 264 and the second distribution unit 265 are interchanged may be used as the front / rear distribution nail. The front / rear distribution nail in which the upper two inclined surfaces are inclined downward toward the center is referred to as a concave front / rear distribution nail.

  When the game ball B1 flowing down the back side of the game area PA collides with the concave front / rear distribution nail, the course downstream of the game ball B1 is changed to the front side of the game area PA. Further, when the game ball B1 flowing down the front side of the game area PA collides with the concave front / rear distribution nail, the course downstream of the game ball B1 is changed to the back side of the game area PA. That is, the position in the depth direction of the game ball B1 that collides with the concave front / rear distribution nail can be reversed. For example, when the game balls B1 that are launched toward the game area PA are all located behind the game area PA due to a malfunction of the game ball launch mechanism 27, or all the game balls B1 that are launched are all game areas PA. When the position of the game ball B1 colliding with the concave front / rear distribution nail is reversed, the position in the depth direction of the game ball B1 is reversed, so that the number of game balls B1 positioned on the back side is positioned on the front side. A situation in which the ratio of the number of game balls B1 is significantly biased can be avoided.

  Further, in the fourteenth embodiment described above, by arranging four concave front / rear distribution nails in the game board 261 instead of the four front / rear distribution nails 262 constituting the first guide nail row 282, Unlike the fourteenth embodiment described above, the game ball B1 that flows down the front side of the game area PA by the first guide nail row 282, the second guide nail row 283, and the third guide nail row 284 operates with high probability. While being guided toward the mouths 33 and 34, the game ball B1 flowing down the back side of the game area PA can be collected from the out mouth 24a with high probability.

  By adopting a configuration in which the course in the downstream of the game ball B1 changes according to the depth direction position in the game area PA of the game ball B1, only the position in the left-right direction in the game area PA affects the course in the downstream of the game ball B1. Compared to the configuration, it is possible to increase the variation of the movement of the game ball B1 and improve the interest of the game.

  In the fourteenth embodiment described above, a nail that guides the position in the depth direction of the game ball B1 in the game area PA in only one direction may be provided in the game board 261 instead of the front / rear distribution nail 262. For example, by providing the game board 261 with a front guide nail having only an inclined surface having a downward slope toward the front side of the game area PA, the position in the depth direction of the game ball B1 that collides with the front guide nail is determined. It can be guided to the near side. In addition, by disposing a back guide nail having only an inclined surface having a downward slope toward the back side of the game area PA, in the depth direction of the game ball B1 that collides with the back side guide nail. The position can be guided to the back side.

  In the game board 261 of the fourteenth embodiment described above, the first and second front / rear sorting nails 262 from the upstream side of the first guide nail row 282 are replaced with front side guide nails, and the third and fourth front / rear By replacing the distribution nail 262 with the rear guide nail, the game ball B1 that collides with the first guide nail row 282 at a relatively shallow position in the upstream portion of the left guide nail group 281 wins the operation ports 33 and 34. And the probability that the game ball B1 colliding with the first guide nail row 282 at a relatively deep position wins the operating ports 33 and 34 can be reduced. Thus, by making the winning probability different depending on the collision position of the game ball B1 in the first guide nail row 282, it is possible to prevent the movement of the game ball B1 in the game area PA from becoming monotonous, and Improvements can be made.

  -In 14th Embodiment mentioned above, the back nail 271 is good also as a structure provided with the inclined surface which gives the drag which has a component of a predetermined direction with respect to the game ball B1 which collides. For example, the rear nail 271 in the fourteenth embodiment described above may be a right guiding nail having an upper surface that is inclined downward toward the right. By providing the right guide nail on the game board 261, the game ball B1 located on the back side of the game area PA collides and accelerates to the right, and the game ball B1 located on the near side does not collide. The course of the game ball B1 can be distributed in a manner. Accordingly, the position of the game ball B1 in the depth direction is reflected in the course of the game ball B1 in the left-right direction, and the variation of the movement of the game ball B1 in the game area PA can be increased to improve the interest of the game.

  Further, for example, the rear nail 271 in the fourteenth embodiment described above may be a front guide nail having an upper surface that is inclined downward toward the front. By providing the front guide nail on the game board 261, the game ball B1 located on the back side of the game area PA moves to the near side, and the game ball B1 located on the near side does not collide. It can be set as the structure which changes the position of the depth direction of game ball B1. Thereby, in game area PA, the number of game balls B1 located in the near side can be increased. For example, by providing the first left / right sorting nail 213 in the thirteenth embodiment described above downstream of the front guide nail, there are many game balls B1 that collide with the second sorting surface 218a and are distributed to the left. can do. Further, for example, there are many game balls B1 that collide with the second distribution surface 234a and are distributed to the right by providing the second left / right distribution nail 214 in the thirteenth embodiment downstream of the front guide nail. It can be configured. Thus, by providing the front guide nail upstream of the means for distributing the course of the game ball B1 in a manner corresponding to the position of the game ball B1 in the depth direction in the game area PA, the movement of the game ball B1 in the game area PA is controlled. You can increase the variation and improve the fun of the game.

  In the fourteenth embodiment described above, instead of the rear nail 271, the shape of the game ball B1 located on the front side of the game area PA is easy to collide and the shape of the game ball B1 located on the back side is difficult to collide It is good also as a structure which arrange | positions the front priority member 291 which has this to the game board 261. FIG. The front priority member 291 will be described with reference to FIGS. 67 (a) and 67 (b). 67 (a) is a plan view of the front priority member 291 and FIG. 67 (b) is an explanatory view for explaining the course of the game ball B1 in the left guide nail group 281 including the front priority member 291. FIG.

  As shown in FIG. 67 (a), the front priority member 291 fixes a plate member 292 on which only the game ball B1 located on the front side of the game area PA can collide, and the plate member 292 to the game board 261. A first support member 293 and a second support member 294. The plate member 292 is a rectangular parallelepiped resin plate formed extending in the left-right direction. The horizontal dimension of the upper surface of the plate member 292 to which the game ball B1 can collide is 36 mm, which is longer than three times the diameter of the game ball B1, and the length dimension in the depth direction is 5.5 mm, which is the same as the radius of the game ball B1. is there. Further, the plate member 292 has a thickness of 6 mm, and has a strength that does not break even when the game ball B1 is repeatedly collided.

  A first support hole 295 having an inner diameter and a depth of 4 mm is formed in the plate member 292 at an interval of 3 mm from the left end in order to fix the first support member 293, and the second support member In order to fix 294, a second support hole 296 having an inner diameter and a depth of 4 mm is formed at an interval of 3 mm from the right end.

  The first support member 293 and the second support member 294 are the same member. The support members 293 and 294 are cylindrical support trunk shaft portions 293a and 294a having a length dimension of 28 mm in the directions of the axes 293c and 294c, and a conical support having a length dimension of 5 mm in the directions of the axes 293c and 294c. It is comprised from the pointed heads 293b and 294b for use. Since the trunk diameters of the support members 293 and 294 are 4 mm, which is the same as the inner diameters of the support holes 292a and 292b, the first support member 293 can be fitted in the first support hole 295 with no gap, The two support members 294 can be fitted in the second support hole 296 in a manner that there is no gap.

  The plate member 292 and the support members 293 and 294 constituting the front priority member 291 can be separated. The separated support members 293 and 294 are fixed to the game board 233 by applying an impact to the free end with a hammer or the like. A mode in which a part of the protrusion of the first support member 293 fits in the first support hole 295 and a mode in which a part of the protrusion of the second support member 294 fits in the second support hole 296. Thus, the plate member 292 is fixed to the support members 293 and 294, so that the front priority member 291 is fixed to the game board 233.

  As shown in FIG. 67 (b), the supporting members 293 and 294 are configured such that all of the supporting pointed heads 293b and 294b and part of the supporting trunk shaft portions 293a and 294a are more than the surface of the game board 233. While being buried in the back side, the remaining portions of the support trunk shaft portions 293a and 294a are fixed to the game board 261 in such a manner as to protrude from the surface of the game board 261 in a substantially vertical direction. In the support members 293 and 294 fixed to the game board 261, the length dimension of the protrusion from the surface of the game board 261 is 15 mm. The plate member 292 is fixed to the game board 261 by fixing the outer wall of the protrusion and the inner walls of the support holes 292a and 292b with an adhesive.

  In a state of being fixed to the game board 261, the distance between the first support member 293 and the second support member 294 is 22 mm, which is twice the diameter of the game ball B1, and the end on the far side of the plate member 292 is a game. The surface of the board 261 is 11.5 mm wider than the diameter of the game ball B1.

  In the game board 261 of the fourteenth embodiment, when the three rear nails 271 constituting the second guide nail row 283 are replaced with the front priority member 291 without changing the inclination of the upper surface, FIG. As shown in FIG. 5, the probability that the game balls B1 distributed to the back side in the upstream first guide nail row 282 fall downward from the gap between the first support member 293 and the second support member 294 is increased, and the front side The probability that the game balls B1 distributed to the side collide with the plate member 292 and enter the space above the third guide nail row 284 increases.

  Thus, by making the course of the game ball B1 located on the front side different from the course of the game ball B1 located on the back side, the variation of the movement of the game ball B1 in the game area PA is increased, and the game It is possible to improve interest.

<Fifteenth embodiment>
This embodiment is different from the thirteenth embodiment in that a repelling nail 322 (FIG. 68) is provided in the game board 321 (FIG. 68) instead of the distribution nails 213, 214. Hereinafter, the description of the same configuration as that of the thirteenth embodiment is basically omitted.

  The game board 321 of the present embodiment is provided with a repelling nail 322 in addition to the obstacle nail 228 as a nail for appropriately dispersing and adjusting the falling direction of the game ball B1. First, based on FIG. 68, the position of the rebound nail 322 in the game board 321 will be described. FIG. 68 is a front view of the game board 321 and an enlarged view of the upstream portion of the left guide nail group 323 arranged on the game board 321.

  As shown in FIG. 68, the game board 321 is provided with a guide nail group including a plurality of nails 228 and 322 in order to guide the game ball B1 to the operation ports 33 and. The guide nail group includes a left guide nail group 323 arranged to guide the game ball B1 from the left side to the operation ports 33 and 34 located at the lower center of the game board 321, and the game ball B1 from the right side. It is composed of a right guide nail group 324 arranged to guide to the operation ports 33 and 34 located at the lower center of the board 321.

  The obstruction nail 228 and the repelling nail 322 constituting the left guide nail group 323 are arranged in one direction, and the arrangement direction has an inclination of a downward inclination of 30 ° toward the right. Further, the obstacle nail 228 and the repelling nail 322 constituting the right guide nail group 324 are arranged in one direction, and the arrangement direction has an inclination that is a downward inclination of 30 ° toward the left. .

  As shown in the enlarged view of FIG. 68, the left guide nail group 323 is divided into a first nail row 331 located on the uppermost stream and a second nail row 332 located on the downstream side of the first nail row 331. . In the first nail row 331, four repelling nails 322 are arranged in a row in a direction having a downward slope of 30 ° toward the right. In the first nail row 331, the interval between the adjacent repelling nails 322 is narrower than the diameter of the game ball B1. For this reason, the game ball B1 does not fall downward from between the two repelling nails 322.

  In the second nail row 332, 13 obstacle nails 228 are arranged in a row in a direction having a downward slope of 30 ° toward the right. The gap between the repelling nail 322 located at the downstream end of the first nail row 331 and the obstacle nail 228 located at the upstream end of the second nail row 332 is set to 13 mm wider than the diameter of the game ball B1. There is a possibility that the game ball B1 falls downward from the gap. In particular, when the rebound of the game ball B1 colliding with the repelling nail 322 constituting the first nail row 331 is small, the game ball B1 falls downward from the gap between the first nail row 331 and the second nail row 332 Thus, there is a high possibility of being collected from the out port 24a provided in the lower part of the game board 321.

  Next, the shape of the repelling nail 322 will be described with reference to FIGS. 69 (a) and 69 (b). 69 (a) is an exploded perspective view of the repelling nail 322, and FIG. 69 (b) is a longitudinal sectional view of the repelling nail 322. As shown in FIG. 69 (a), the repelling nail 322 is an elongated nail formed extending in the direction of the axis 322a. The repulsion nail 322 has a low restitution coefficient, a low repulsion member 333 having a surface that repels the colliding game ball B1 and a rebound coefficient larger than the surface of the low repulsion member 333, and a high rebound of the colliding game ball B1. And a shaft member 334 having a repulsion portion 334d.

  The shaft member 334 is a metal member provided with a cylindrical free end side trunk shaft portion 334a formed on the free end side so as to extend in the direction of the axis 322a. On the back side of the free end side trunk shaft part 334a, a cylindrical fixed end side trunk shaft part 334b is integrally formed by extending in the direction of the axis 322a in a mode having a larger trunk diameter than the free end side trunk shaft part 334a. Has been. Further, a conical pointed head 334c is integrally formed on the back side of the fixed-end side trunk shaft portion 334b in such a manner that it has an apex on the axis 322a and is continuous with the fixed-end side barrel shaft portion 334b.

  The diameter of the free end side trunk shaft portion 334a is 2 mm, and the length dimension in the axial direction is 8 mm. Further, the diameter of the fixed end side trunk shaft portion 334b is 6 mm, and the length dimension in the axial direction is 22 mm. When the repelling nail 322 is fixed to the game board 321, the fixed end side trunk shaft part 334 b includes a high repulsion part 334 d that protrudes toward the front side of the surface of the game board 321, an embedded part 334 e that is embedded in the back side, Consists of. Further, the pointed head 334c has a pointed tip, and a shock is applied to the free end of the repelling nail 322 with a hammer or the like while the pointed head 334c is pressed against the surface of the game board 321. The rebound nail 322 can be fixed to the game board 321.

  The low-repulsion member 333 is a low-repulsion urethane member having a cylindrical shape that extends in the direction of the axis 322a. The diameter of the low repulsion member 333 is 6 mm, and the length dimension in the direction of the axis 322a is 8 mm. For this reason, in a state where the repelling nail 322 is fixed to the game board 321, the boundary between the low repulsion member 333 and the high repulsion portion 334 d is located at the center in the depth direction of the game area PA. The low repulsion member 333 is formed with an attachment hole 333a that penetrates the center of the low repulsion member 333 in the direction of the axis 322a. The mounting hole 333a is a cylindrical hole having an inner diameter of 2 mm. As shown in FIG. 69A, the free end side trunk shaft portion 334a of the shaft member 334 is inserted into the mounting hole 333a. As a result, as shown in FIG. 69 (b), the low repulsion member 333 is fixed to the fixed end side trunk shaft portion 334 b to become a repulsion nail 322. The low resilience member 333 is not limited to low resilience urethane as long as it is a material that reduces the rebound of the game ball B1 that collides and is durable. For example, the low resilience member 333 may be made of silicon resin.

  Next, the course of the game ball B1 that collides with the repelling nail 322 fixed to the game board 321 will be described based on FIGS. 70 (a) to (d). 70 (a) and 70 (c) are end views of the cut surface when the repelling nail 322 is cut in a plane perpendicular to the game board 321, and FIG. 70 (b) is a game ball that flows down and collides with the upper left. FIG. 70 (d) is a cross-sectional view of the high repulsion portion 334d shown for explaining the course after the collision of B1, and FIG. 70 (d) shows the course after the collision of the game ball B1 that flows down and collides from the upper left. It is a cross-sectional view of the low resilience member 333 and the free end side trunk shaft portion 334a shown.

  As shown in FIG. 70A, the repelling nail 322 is driven and fixed so that the axis 322a is substantially perpendicular to the surface of the game board 321. Here, the depth of the game area PA sandwiched between the front surface of the game board 321 and the back surface of the window panel 52 is 18 mm. As shown in FIG. 70A, the repelling nail 322 is fixed to the game board 321 in such a manner that the buried part 334 e and the pointed head part 334 c of the shaft member 334 are buried deeper than the surface of the game board 321. . In a state where the repelling nail 322 is fixed to the game board 321, the high repulsion portion 334 d is exposed on the back side of the game area PA, and the low repulsion member 333 is exposed on the front side.

  Therefore, as shown in FIG. 70 (a), the game ball B1 flowing down the back side of the game area PA collides with the high repulsion part 334d having a large restitution coefficient and rebounds greatly. Specifically, as shown in FIG. 70 (b), the game ball B1 having an initial velocity in the right direction and an initial velocity in the downward direction and having collided with one point on the upper side of the high repulsion portion 334d from the upper left side is A rightward speed slightly reduced from the initial rightward speed and an upward speed slightly reduced from the initial downward speed.

  On the other hand, as shown in FIG. 70 (c), the game ball B1 flowing down on the front side of the game area PA collides with the low repulsion member 333 having a small restitution coefficient and rebounds small. Specifically, as shown in FIG. 70 (d), the game ball B1 having the initial velocity rightward and the initial velocity downward and having collided with one point on the upper side of the low repulsion member 333 from the upper left side is A rightward speed that is greatly reduced from the initial rightward speed and an upward speed that is greatly reduced from the initial downward speed.

  Next, the course after the collision of the game ball B1 colliding with the repelling nail 322 constituting the first nail row 331 will be described based on FIGS. 71 (a) and 71 (b). FIG. 71 (a) is an explanatory diagram for explaining the course of the game ball B1 after the collision when the game ball B1 collides with the high repulsion portion 334d of the rebound nail 322, and FIG. 71 (b) is a game ball B1. FIG. 10 is an explanatory diagram for explaining a course of the game ball B1 after the collision when the ball collides with the low repulsion member 333 of the repulsion nail 322;

  As shown in FIG. 71 (a), the game ball B1 located on the back side of the game area PA collides with the high repulsion part 334d of the repulsion nail 322 constituting the first nail row 331. The game ball B1 rebounds greatly after colliding with the high repulsion part 334d having a large restitution coefficient. For this reason, the game ball B1 after the collision is guided to the operation ports 33 and 34 by the second nail row 332 without falling downward from the gap between the downstream end of the first nail row 331 and the upstream end of the second nail row 332. The probability of being done is high.

  On the other hand, as shown in FIG. 71 (b), the game ball B 1 located on the front side of the game area PA collides with the low repulsion member 333 of the repulsion nail 322 constituting the first nail row 331. The game ball B1 rebounds small after colliding with the low repulsion member 333 having a small restitution coefficient. Therefore, there is a high probability that the game ball B1 after the collision falls downward from the gap between the downstream end of the first nail row 331 and the upstream end of the second nail row 332 and is recovered from the out port 24a.

  According to the embodiment described in detail above, the following excellent effects are obtained.

  The repelling nail 322 has a high rebound portion 334d having a large restitution coefficient on the distal end side and a low repulsion member 333 having a small restitution coefficient on the proximal end side. By disposing the repelling nail 322 on the game board 321, the course of the game ball B <b> 1 after the collision can be made different according to the position in the depth direction in the game area PA. For this reason, the game board 321 is provided with only the obstacle nail 228, and the game ball B1 has a game in which the position in the depth direction in the game area PA does not affect the course of the game ball B1. It is possible to increase the variation of the movement of the game ball B1 in the area PA and improve the interest of the game.

  Further, the repelling nail 322 is used for the first nail row 331 constituting the upstream portion of the left guide nail group 323, and between the downstream end of the first nail row 331 and the upstream end of the second nail row 332. A gap having a width larger than the diameter of the game ball B1 is set. For this reason, there is a high probability that the game ball B1 located on the back side of the game area PA is guided to the operation ports 33 and 34 by the second nail row 332 after colliding with the first nail row 331. In addition, the probability that the game ball B1 located on the front side of the game area PA falls downward from the gap between the downstream end of the first nail row 331 and the upstream end of the second nail row 332 after colliding with the first nail row 331. Is expensive.

  Thus, since the probability that the game ball B1 is guided to the operation ports 33 and 34 is different in a manner corresponding to the position of the game ball B1 in the game area PA, the depth direction in the game area PA of the game ball B1 is different. Compared with the conventional pachinko machine 10 in which the position of the game ball B1 does not affect the course of the game ball B1, the variation of the movement of the game ball B1 in the game area PA can be increased and the interest of the game can be improved.

  Further, the repelling nail 322 is used for all the nails constituting the first nail row 331. By arranging a plurality of repelling nails 322 at intervals shorter than the diameter of the game ball B1, the probability that the game ball B1 is guided to the operation ports 33 and 34 due to the difference in the position in the depth direction in the game area PA of the game ball B1. It can be greatly reflected in the difference.

<Another embodiment of the fifteenth embodiment>
In the fifteenth embodiment described above, an inclined nail having a plurality of inclined surfaces inclined at different angles in the same direction may be used instead of the repelling nail 322. Specifically, the inclined nail is located on the fixed end side and has a first inclined portion having a first inclined surface having a downward slope of 30 ° toward the right, and is positioned on the free end side and on the right And a second inclined portion having a second inclined surface having a downward slope of 15 ° toward the surface. The game ball B1 that collides with the inclined nail always receives a drag force that rebounds to the right, but the velocity component in the right direction after the collision changes according to the collision position in the depth direction. Specifically, a drag force that has a large component in the right direction and a small component in the upward direction acts on the game ball B1 that collides with the first inclined surface on the back side of the game area PA. On the other hand, the game ball B1 that collides with the second inclined surface on the front side of the game area PA has a drag force that has a small component in the right direction and a large component in the upward direction.

  For this reason, in the fifteenth embodiment, by using the inclined nail instead of the repelling nail 322, the probability that the game ball B1 located on the back side of the game area PA will win the operating ports 33 and 34 is increased. The probability of winning the game ball B1 located on the near side can be reduced. By adopting a configuration in which the position in the depth direction of the game ball B1 is reflected in the game result, the interest of the game is improved as compared with the conventional pachinko machine in which only the position in the left and right direction of the game ball B1 is reflected in the game result Can be achieved.

<Sixteenth Embodiment>
The game board 341 (FIG. 72) of this embodiment is different from the thirteenth embodiment in that a front / rear distribution table 351 (FIG. 72) for distributing the game balls B1 in the depth direction of the game area PA is provided. doing. Hereinafter, the description of the same configuration as that of the thirteenth embodiment is basically omitted. Note that all the nails provided in the game board 341 of this embodiment are obstacle nails 228.

  First, the configuration of the game board 341 in the present embodiment will be described with reference to FIG. FIG. 72 is a front view of the game board 341.

  As shown in FIG. 72, the game board 341 is provided with a center frame 252 so as to define an opening 341 a that allows the display surface 41 a of the symbol display device 41 to be visually recognized from the front of the pachinko machine 10. The center frame 252 includes a roof unit 253 provided to define the upper edge and left and right side edges of the opening 341a, and a stage unit 354 provided to define the lower edge of the opening 341a. ing. At the left end of the stage unit 354, a ball inlet 363 that allows the game ball B1 existing in the game area PA to move onto the stage unit 354 is formed, and the game ball B1 that has entered the ball inlet 363 is It is guided on the stage unit 354. The stage unit 354 has a rolling surface 357 on which the game ball B1 can roll. The rolling surface 357 has a width such that two game balls B1 are arranged in the depth direction, and has a smooth streamline shape that is symmetrical about the center. Specifically, a peak portion 358 that rises upward is formed at the center of the rolling surface 357, and a valley portion 359 that is recessed downward is formed on the left and right sides thereof. Further, the left and right ends of the rolling surface 357 are located above the center portion.

  The left and right ends of the rolling surface 357 and the peak portion 358 are inclined downward toward the back side. On the other hand, the valley portion 359 has a shape inclined downward toward the front side. For this reason, the game ball B1 that has reached the top of the valley portion 359 in a sufficiently decelerated state is guided by the inclination of the valley portion 359 and discharged from the front edge of the valley portion 359 toward the lower side of the stage unit 354. .

  A guide passage 366 is formed below the peak portion 358 in the stage unit 354, and an inlet to the guide passage 366 is formed at the rear portion of the peak portion 358, and the peak portion 358 is inclined downward toward the entrance. It has become. The guide passage 366 is inclined downward toward the front, and the game ball B1 introduced into the guide passage 366 is discharged to the lower side of the stage unit 354 through the guide passage 366. The outlet of the guide passage 366 is located vertically above the first working port 33. Therefore, the game ball B <b> 1 that has passed through the guide passage 366 can easily enter the first operation port 33.

  Further, as described above, the game board 341 is provided with the front / rear sorting table 351 for distributing the game balls B1 in the depth direction of the game area PA. Specifically, as shown in FIG. 72, the front / rear sorting table 351 is disposed at a position on the left side of the ball inlet 363 formed at the left end of the stage unit 354 and above the left side of the left guide nail group 355. ing.

  Here, a detailed position in the depth direction of the game ball B1 in the game area PA is defined. In the present embodiment, the game ball B1 located on the back side of the game area PA is a game ball B1 whose center is less than 9 mm from the surface of the game board 341. Further, the game ball B1 located on the farthest side of the game area PA is a game ball B1 in a state where the game ball B1 is in contact with the surface of the game board 341 or a state equivalent thereto. The game ball B1 located on the front side of the game area PA is a game ball B1 in which the center of the game ball B1 is less than 9 mm from the back surface of the window panel 52. In addition, the game ball B1 located closest to the game area PA is a game ball B1 in a state where the game ball B1 is in contact with the back surface of the window panel 52 or a state equivalent thereto.

  The front / rear distribution table 351 is a table for distributing the game balls B1 to either the innermost side or the frontmost side of the game area PA, and the front / rear distribution table 351 is a game distributed to the innermost side. The ball B1 is fixed to the game board 341 in such a manner that the ball B1 moves on the stage unit 354 through the ball inlet 363.

  73 (a) is a perspective view of the front / rear sorting table 351, and FIG. 73 (b) is a plan view of the front / rear sorting table 351. FIG. 73 (c) and 73 (d) are end views of the cut surface when the front / rear sorting table 351 is cut along a plane perpendicular to the surface of the game board 341. FIG. As shown in FIG. 73 (a), the front / rear distribution table 351 is a plate-shaped and resin-made table, and the surface of the front / rear distribution table 351 is used to play a game ball B1 rolling on the front / rear distribution table 351. It has the inclination for distributing to either the innermost side or the foremost side. The inclination mode of the surface of the front / rear sorting table 351 will be described below with reference to FIGS. 73 (b) and 73 (c).

  As shown in FIG. 73 (b), the front / rear sorting table 351 is formed such that the length dimension from the upstream end to the downstream end is approximately three times the diameter of the game ball B1. . Further, as shown in FIG. 73 (c), the front / rear sorting table 351 has a buried portion 351a that is buried deeper than the surface of the game board 341 when the front / rear sorting board 351 is mounted on the game board 341. And a projecting portion 351b projecting to the near side of the surface of the game board 341. The game board 341 has a fixing hole for fixing the front / rear sorting table 351, and an adhesive is used in such a manner that the buried portion 351a of the front / rear sorting table 351 fits into the fixing hole. A front / back distribution table 351 is fixed to the game board 341.

  As shown in FIG. 73 (c), the protruding portion 351 b is formed from the surface of the game board 341 to the vicinity of the back surface of the window panel 52. Therefore, the protruding portion 351b can contact both the game ball B1 located on the back side of the game area PA and the game ball B1 located on the near side of the game area PA. The buried portion 351a has the same depth dimension that is substantially the same as the depth dimension of the protruding portion 351b so that it can withstand the impact even if the game ball B1 repeatedly collides with the protruding portion 351b.

  As shown in FIG. 73 (b), the front / rear sorting table 351 surface is the upstream half of the front / rear sorting table 351 surface and the rolling distribution surface 371 which is a horizontal plane, and the back side of the downstream half surface. It consists of a first downstream surface 372 that is half and a second downstream surface 373 that is the front half surface of the downstream half surface.

  Returning to FIG. 73 (a), the specific inclination of the first downstream surface 372 and the second downstream surface 373 will be described. As shown in FIG. 73 (a), in the state in which the front / back distribution table 351 is fixed to the game board 341, the first downstream surface 372 has an inclination that becomes a downward slope toward the back side, The second downstream surface 373 has an inclination that becomes a downward gradient toward the front side.

  As shown in FIG. 72, the front / back distribution table 351 is fixed to the game board 341 in a state where the rolling distribution surface 371 is slightly rotated so as to have a downward slope of 3 ° toward the right. For this reason, as shown in FIG. 73 (a), when the game ball B1 rolling on the rolling distribution surface 371 downstream is guided to the back side of the game area PA during the rolling process. In addition to being guided to the first downstream surface 372, it is guided to the second downstream surface 373 when guided to the near side during the rolling process.

  As shown in FIG. 72, the first guide nail 228a and the second guide nail 228b for guiding the game ball B1 to the rolling distribution surface 371 are provided around the upstream side of the front / rear distribution table 351 in the game board 341. Third, for preventing the game ball B1 guided to the rolling distribution surface 371 from jumping upward and rolling the game ball B1 in contact with the surface of the front / rear distribution table 351 for several seconds. Guide nails 228c are provided. The first guide nails 228a are arranged in two rows with an interval slightly wider than the diameter of the game ball B1. The two rows of the first guide nails 228a guide the game balls B1 that have entered between the rows to the rolling distribution surface 371 from the upper right, and the rows of the first guide nails 228a are separated by the front / rear distribution table 351. The game balls B1 other than the game balls B1 to be distributed are prevented from entering the space above the stage unit 354 from the ball entrance 363 opened toward the game area PA.

  When the game ball B1 guided by the first guide nail 228a collides with the upper left side of the rolling distribution surface 371 in the game board 341, the left velocity component of the game ball B1 disappears and the right direction. One second guide nail 228b for providing the speed component is provided. The second guide nail 228b is located 7 mm above the rolling distribution surface 371.

  When the second guide nail 228b is set at a position lower than the center of gravity of the game ball B1 on the rolling distribution surface 371, the game ball B1 guided on the rolling distribution surface 371 from the upper right side; The point where the second guide nail 228b collides is lower than the center of gravity of the game ball B1, and the velocity component in the left direction of the game ball B1 guided by the rolling distribution surface 371 cannot be sufficiently reduced. there is a possibility. In this case, the game ball B1 passes over the second guide nail 228b and falls to the lower left. Further, when the second guide nail 228b is set at a position higher than the height of the game ball B1 existing on the rolling distribution surface 371, the game ball B1 guided by the rolling distribution surface 371. Without colliding with the second guide nail 228b, there is a possibility that it will pass to the left through the second guide nail 228b and fall downward.

  On the other hand, the second guide nail 228b located 7 mm above the rolling distribution surface 371 has a center of gravity in the gaming ball B1 at a point where it collides with the game ball B1 guided by the rolling distribution surface 371. It is a point above. Therefore, it is possible to prevent the game ball B1 guided from the upper right to the rolling distribution surface 371 from passing over or under the second guide nail 228b and moving leftward and falling from the rolling distribution surface 371. The game ball B1 guided from the upper right can be rebounded in the right direction (downstream side).

  Further, the second guide nail 228b positioned 7 mm above the rolling distribution surface 371 is the second gaming ball in a state where the gaming ball B1 already exists on the rolling distribution surface 371. When B1 is guided to the rolling distribution surface 371, it does not come into contact with the second game ball B1. In this case, the second game ball B1 falls from the upper side of the rolling distribution surface 371 to the lower left side without reaching the rolling distribution surface 371. For this reason, it is possible to avoid the game ball B1 from staying around the front / rear sorting table 351.

  A plurality of third guide nails 228c are provided above the downstream portion of the rolling vibration distribution surface 371 and above the first downstream surface 372 and the second downstream surface 373 with a space wider than the diameter of the game ball B1. It has been. After being guided to the rolling distribution surface 371 by the first guide nail 228a, the game ball B1 colliding with the second guide nail 228b and proceeding to the right is the surface of the third guide nail 228c and the front / rear distribution table 351. Invade into a narrow space between and. On the surface of the front / rear sorting table 351, the game ball B1 collides with the third guide nail 228c a plurality of times to lose the velocity component in the vertical direction, and the surface of the front / rear sorting table 351 rolls to the right along the inclination. Move.

  As shown in FIG. 73 (c), the game ball B1 which is guided to the first downstream surface 372 by rolling on the rolling distribution surface 371 of the front / rear distribution table 351 fixed to the game board 341 is a game area. Sorted to the farthest side of the PA. Further, as shown in FIG. 73 (d), the game balls B1 rolling on the rolling distribution surface 371 and guided to the second downstream surface 373 are distributed to the foremost side of the game area PA. In this way, the game ball B1 existing at random positions in the depth direction of the game area PA rolls on the front / rear distribution table 351, thereby causing an extreme relationship that is in a pair relationship of the farthest side or the foremost side. Sorted to one of two positions.

  Next, the course of the game ball B1 after being distributed on the front / back distribution table 351 will be described with reference to FIG. FIG. 74 is an enlarged view of the left central portion of the game board 341 (FIG. 72). As already described, the game balls B1 distributed farthest in the front / rear distribution table 351 move onto the rolling surface 357 through the ball inlet 363 formed at the left end of the stage unit 354.

  Since the left and right ends of the rolling surface 357 of the stage unit 354 are provided sufficiently higher than the mountain portion 358, when the game balls B1 distributed by the front / rear distribution table 351 roll on the rolling surface 357, a game The momentum of the sphere B1 is insufficient, and the ball B1 does not fall downward from the trough 359 provided in front of the peak 358. In the rolling surface 357, the width of the valley portion 359 in which the game ball B1 can fall forward is approximately twice the diameter of the game ball B1, and the width dimension of the rolling surface 357 in the left-right direction. The ratio to is set low. Furthermore, the height difference between the bottom of the valley 359 and the top of the peak 358 on the rolling surface 357 is set to be small. That is, the configuration is such that the game ball B1 rolling on the rolling surface 357 is unlikely to fall forward from the valley portion 359.

  The game ball B1 rolls on the rolling surface 357 while accelerating from the left end of the stage unit 354 and reaches the mountain portion 358. The mountain portion 358 is inclined downward toward the rear so that the game ball B1 can easily enter the entrance of the guide passage 366 formed at the rear. For this reason, the game balls B1 distributed farthest by the front / rear distribution table 351 win the first operation port 33 with a high probability.

  On the other hand, the game balls B1 distributed to the front side in the front / rear distribution table 351 fall downward without entering the ball entrance 363. The game ball B1 can be guided to the operation ports 33 and 34 by the left guide nail group 355, but the game ball B1 is guided toward the operation ports 33 and 34 by the left guide nail group 355 while the obstacle nail 228 is in the middle. When falling downward from the gap, the game ball B1 is collected from the out port 24a without winning the operating ports 33 and 34. In the game board 341, the probability that the game ball B1 guided by the left guide nail group 355 wins the operation ports 33, 34 is the probability that the game ball B1 rolling on the rolling surface 357 of the stage unit 354 is the operation ports 33, 34. The probability of winning a prize is lower.

  According to the embodiment described in detail above, the following excellent effects are obtained.

  The front / rear sorting table 351 is configured to distribute the game balls B1 to either the farthest side or the foremost side according to the position in the depth direction of the game balls B1 on the upstream side of the front / rear sorting table 351. And it is the structure which determines whether the game ball B1 moves on the stage unit 354 through the ball | bowl entrance 363 in the aspect according to the said distribution result. The game ball B1 that has moved onto the stage unit 354 wins the operating ports 33 and 34 with a higher probability than the game ball B1 that has not moved onto the stage unit 354.

  That is, by arranging the front / rear distribution table 351 on the game board 341 in such a manner that only the game balls B1 distributed to the innermost side enter the ball entrance 363 of the stage unit 354, the upstream of the front / rear distribution table 351 is provided. The game result can be made different depending on the position of the game ball B1 in the front-rear direction. The relationship between the position of the game ball B1 in the game area PA and the game result is monotonous compared to a conventional pachinko machine in which only the position in the left-right direction of the game ball B1 in the game area PA is reflected in the game result. It can prevent and improve the interest of the game.

  Further, in the game board 341, there are two rows above the front / rear sorting table 351, with a row spacing slightly wider than the diameter of the game ball B 1 and toward the rolling distribution surface 371 of the front / rear sorting table 351. The first guide nail 228a is provided. By using the first guide nails 228a, the game balls B1 can be guided to the rolling distribution surface 371 in one row.

  In addition, a second guide nail 228b is provided above the rolling distribution surface 371 at a height higher than the center of gravity of the game ball B1 on the rolling distribution surface 371 and lower than the upper end. For this reason, it is possible to prevent the game ball B1 guided to the rolling distribution surface 371 from moving to the left, and to prevent a plurality of game balls B1 from staying above the rolling distribution surface 371. Can do.

  A third guide nail 228c is provided above the downstream portion of the rolling distribution surface 371 and above the first downstream surface 372 and the second downstream surface 373 with a gap wider than the diameter of the game ball B1. It has been. As a result, the game ball B1 guided on the front / rear distribution table 351 is rolled while being in contact with the front / rear distribution table 351, and the position in the depth direction thereof is located at the farthest side or the foremost side of the game area PA. Can be distributed to either side.

<Another embodiment of the sixteenth embodiment>
The position of the front / rear sorting table 351 in the game board 341 of the sixteenth embodiment described above is not limited to the vicinity of the upstream side of the stage unit 354. For example, the left guide nail group 382 is composed of the first left / right sorting nail 213 (FIG. 51A) already described in the thirteenth embodiment, and in the vicinity of the upstream side of the left guide nail group 382. It is good also as a structure by which the front-back distribution stand 351 is arrange | positioned. The configuration will be described below with reference to FIGS. 75 and 76.

  FIG. 75 is a front view of the game board 381 in this configuration. As shown in FIG. 75, the game board 381 is provided with a left guide nail group 382. Four first right / left sorting nails 213 are provided in the upstream portion of the left guide nail group 382 and seven obstacle nails 228 are provided in the downstream portion. In addition, the front / rear sorting table 351 described in the sixteenth embodiment is disposed upstream (left side) of the left guide nail group 382. The game balls B1 are distributed to either the farthest side or the foremost side by the front / rear sorting table 351.

  76 (a) and 76 (b) are enlarged views of the game board 341 around the front / rear sorting table 351 and the left guide nail group 382. FIG. As shown in FIG. 76 (a), the game balls B1 distributed to the farthest back side of the game area PA by the front / rear distribution table 351 come into contact with the first distribution surface 217a of the first left / right distribution nail 213 and move forward. Since the direction force is received, the game ball B1 is guided to the operation ports 33 and 34 with a high probability and wins. On the other hand, as shown in FIG. 76 (b), the game balls B1 distributed to the foremost side of the game area PA by the front / rear distribution table 351 come into contact with the second distribution surface 218a of the first left / right distribution nail 213. Therefore, the game ball B1 falls with a high probability from the gap between the first left and right sorting nails 213 and is collected from the out port 24a.

  As described above, even when the front / rear sorting table 351 is disposed in the vicinity of the upstream side of the left guide nail group 382, the game result varies depending on the position of the game ball B1 in the front / rear direction upstream of the front / rear sorting table 351. Can be. The relationship between the position of the game ball B1 in the game area PA and the game result is monotonous compared to a conventional pachinko machine in which only the position in the left-right direction of the game ball B1 in the game area PA is reflected in the game result. It can prevent and improve the interest of the game.

  As the front / rear sorting table 351 in the sixteenth embodiment described above, a front / rear sorting table 391 in which a groove for sorting the game balls B1 is formed on the upper surface may be used. The front / rear sorting table 391 having this configuration will be described with reference to FIG.

  FIG. 77 (a) shows a groove for guiding the game ball B1 located on the far side of the game area PA to the farthest side and for guiding the game ball B1 located on the near side of the game area PA to the near side. It is a perspective view of the provided front and rear sorting stand 391. As shown in FIG. 77 (a), on the upper surface of the front / rear sorting table 391, one wide groove is formed on the back side and the near side of the upstream portion 391a. The rear groove is the innermost guide groove 391b for guiding the game ball B1 to the innermost side in the downstream portion, and the front groove is for guiding the game ball B1 to the frontmost side in the downstream portion. This is the frontmost guide groove 391c.

  The game ball B1 located on the back side of the game area PA is configured to fit in the farthest side guide groove 391b of the upstream portion 391a, and the game ball B1 located on the front side of the game area PA is on the front side of the upstream portion 391a. It fits in the guide groove 391c. For this reason, by using the front / rear sorting table 391, the game ball B1 located on the back side upstream of the front / rear sort table 391 is guided to the farthest downstream side, and the game ball B1 located on the front side upstream is used. Can be guided to the most front side downstream.

  Since the path in the depth direction of the game ball B1 can be distributed in two ways in a manner corresponding to the position in the depth direction of the game ball B1, the position in the depth direction of the game ball B1 does not affect the path of the game ball B1. Compared with the configuration of the pachinko machine, the relationship between the position of the game ball B1 in the game area PA and the behavior of the game ball B1 can be prevented from becoming monotonous, and the interest of the game can be improved.

  FIG. 77 (b) shows a front / rear distribution table provided with a groove for guiding the game ball B1 located on the back side to the front side and for guiding the game ball B1 located on the front side to the back side. FIG. As shown in FIG. 77 (b), on the upper surface of the front / rear sorting table 392, one wide groove is formed on the back side and the near side of the upstream portion 392a. The groove on the back side is the most front side crossing groove 392e for guiding the game ball B1 to the most front side in the downstream portion, and the groove on the front side is for guiding the game ball B1 to the most back side in the downstream portion. It is the innermost side crossing groove 392d.

  The game ball B1 located on the back side of the game area PA is configured to fit in the foremost cross groove 392e of the upstream portion 392a, and the game ball B1 located on the front side of the game area PA is located on the farthest side of the upstream portion 392a. The configuration fits in the intersection groove 392d. For this reason, by using the front / rear sorting table 392, the game ball B1 located on the back side upstream of the front / rear sorting table 392 is guided to the most front side downstream and the game ball located on the front side upstream. B1 can be guided to the innermost side on the downstream side.

  As described above, the position of the game ball B1 in the front-rear direction can be reversed by the front-back distribution table 392. The game ball B1 rolls on the front / rear sorting table 392 by disposing a configuration that makes the game result different depending on the position of the game ball B1 in the front / rear direction, downstream of the front / rear sorting table 392. By doing so, the game result can be reversed. Thereby, the player's attention can be attracted to the behavior of the game ball B1 on the front / back distribution table 392, and the interest of the game can be improved.

<Seventeenth embodiment>
The game board 421 (FIG. 78) of this embodiment is provided with a position change passage 423 (FIG. 78) for changing the position of the game ball B1 in the depth direction in the game area PA. This is different from the embodiment. Hereinafter, the description of the same configuration as that of the sixteenth embodiment is basically omitted.

  First, the configuration of the game board 421 in the present embodiment will be described with reference to FIG.

  FIG. 78 is a front view of the game board 421 in the present embodiment and an enlarged view around the position change passage 423 in the game board 421. As shown in FIG. 78, the display surface 41a of the symbol display device 41 is located at the center of the game board 421, and the display surface 41a is visible from the opening 421a as in the sixteenth embodiment. The opening 421 a is defined by the center frame 252. The center frame 252 includes a roof unit 253 provided to define the upper edge and the left and right side edges of the opening 421a, a stage unit 354 provided to define the lower edge of the opening 421a, It has. Here, the rolling surface 357 of the stage unit 354 in the present embodiment has the same shape as the rolling surface 357 described in the sixteenth embodiment.

  In the game board 421, a position change passage 423 is provided on the left side of the display surface 41a. The position change passage 423 is a straight passage whose overall length is approximately twice the diameter of the game ball B1. The position change passage 423 is a passage that takes in the game ball B1 positioned above from the entrance, changes the position in the depth direction of the game ball B1 passing through the position change passage 423, and then releases the game ball B1 downward from the exit. . Details of the position change passage 423 will be described later.

  In the game board 421, a right guide nail 431 having a downward slope toward the right is provided in the vicinity of the position change passage 423 and on the upper left side in order to guide the game ball B 1 to the entrance of the position change passage 423. It has been. The right guide nail 431 has the same inclination of the second distribution surface 218a as that of the first distribution surface 217a in the first left / right distribution nail 213 (FIG. 51A) of the thirteenth embodiment. It is a resin nail created by changing to. When the right guide nail 431 is fixed to the game board 421, the right guide nail 431 has a protrusion that protrudes 17 mm from the surface of the game board 421 toward the window panel 52, and the protrusion is directed rightward as an upper surface. And an inclined surface inclined downward. The inclined surface is formed from the fixed end to the free end of the protrusion, and is formed from the left end to the right end of the protrusion. The game ball B1 colliding with the right guide nail 431 receives the drag in the upper right direction and is guided to the entrance of the position change passage 423.

  The structure of the right guide nail 431 is not limited to this. In short, it is only necessary to have an inclined surface having a gradient capable of repelling the game ball B1 flowing down from above and colliding to the right and guiding it to the entrance of the position change passage 423.

  In the game board 421, the first left / right sorting nail 213 is disposed immediately below the exit of the position change passage 423 with an interval of 13 mm wider than the diameter of the game ball B 1. A game area PA extends on the left side of the first left / right distribution nail 213, and a rolling surface 357 of the stage unit 354 is formed on the right side of the first left / right distribution nail 213. For this reason, the game balls B1 distributed to the right by the first left / right distribution nail 213 roll on the rolling surface 357 of the stage unit 354. In addition, the game ball B1 distributed leftward by the first left / right distribution nail 213 returns to the game area PA.

  The position changing passage 423 is formed by a transparent polycarbonate passage forming member 422 and is a passage visible from the outside. The position change passage 423 will be described with reference to FIGS. 79 (a) to 79 (d). 79A is a perspective view of the passage forming member 422, FIG. 79B is a front view of the passage forming member 422, and FIGS. 79C and 79D are perpendicular to the surface of the game board 421. FIG. It is an end view of a cut surface when the passage forming member 422 is cut in a plane.

  As shown in FIG. 79 (a), the passage forming member 422 includes a passage forming portion 424 forming a position changing passage 423, an upper fixing portion 425 for fixing the passage forming portion 424 to the game board 421, and A lower fixing portion 426. The shape of the passage forming portion 424 is a width larger than the diameter of the game ball B1, a depth that is approximately twice as long as the depth of the game area PA, and a length that is approximately twice the diameter of the game ball B1. It is a rectangular parallelepiped having a height. A plate-like upper fixing portion 425 is integrally formed on the passage forming portion 424 so as to protrude upward, and a plate-like lower fixing portion 426 is integrally formed so as to protrude downward. Yes.

  Both the fixing portions 425 and 426 are formed so as to extend from the left end to the right end of the passage forming member 422, and the shape thereof is a rectangular parallelepiped. Both the fixing portions 425 and 426 are formed in such a manner that the near-side planes of the both fixing portions 425 and 426 are located at a position 18 mm away from the near-side plane of the passage forming portion 424. As shown in FIG. 79 (b), holes 425a and 426a for screwing the passage forming member 422 to the surface of the game board 421 are penetrated in the depth direction at the center of the front side planes of both the fixing portions 425 and 426. Is formed.

  As shown in FIGS. 79 (c) and 79 (d), the passage forming member 422 is played in such a manner that a part of the back surface of the passage forming portion 424 fits into the fixing hole 421b formed on the surface of the game board 421. It is fixed to the board 421. The width and height of the fixing hole 421b are the same as the width and height of the passage forming portion 424, and the depth of the fixing hole 421b is substantially the same as the depth of the game area PA. On the surface of the game board 421, an upper fixing dent portion 421c and a lower fixing dent portion 421d having the same shape and the same size as the fixing portions 425 and 426 are formed above and below the fixing hole 421b. Has been. A screw hole corresponding to a hole 425a formed at the center of the upper fixing portion 425 is formed at the center of the upper fixing recess portion 421c, and at the center of the lower fixing recess portion 421d, A screw hole corresponding to a hole 426a formed at the center of the lower fixing portion 426 is formed.

  The passage forming member 422 can be attached and detached by screwing the upper fixing portion 425 to the upper fixing recess portion 421c and screwing the lower fixing portion 426 to the lower fixing recess portion 421d. 421 is attached. At this time, the surface of the upper fixing portion 425 and the surface of the lower fixing portion 426 are located on the same plane as the surface of the game board 421. For this reason, movement of game ball B1 does not change by passing on both fixed parts 425 and 426.

  As shown in FIG. 79A, in the passage forming member 422 attached to the game board 421, the front side of the passage forming portion 424 protrudes 18 mm toward the window panel 52 side. In the passage forming portion 424, a position changing passage 423 is formed in a portion protruding to the window panel 52 side by a through hole penetrating the passage forming portion 424 in the vertical direction. The upper opening of the position change passage 423 is an inlet, and the lower opening is an outlet.

  The position change passage 423 is a rear side wall surface 422a that is an inner wall on the back side of the passage forming member 422, a front side wall surface 422b that is a front inner wall, a left side wall surface 422c that is a left inner wall, and a right inner wall. It is defined by four surfaces, the right wall surface 422d. Among these, the width of the position change passage 423 defined by the left wall surface 422c located on the left side of the position change passage 423 and the right wall surface 422d located on the right side is constant from the entrance to the exit, and specifically, the game ball B1 It is 13 mm, which is slightly larger than the diameter. As shown in FIG. 78, the center in the left-right direction of the first left / right distribution nail 213 is directly below the center in the left-right direction of the position change passage 423. The game ball B1 passing through the position change passage 423 can move 1 mm in the left direction from the center of the position change passage 423 and can move 1 mm in the right direction from the center. On the other hand, since the lateral dimension of the first left / right sorting nail 213 is 7 mm, the game ball B1 discharged from the exit of the position change passage 423 collides with the first left / right sorting nail 213, and the course thereof is changed. Sorted to either the left or right direction.

  As shown in FIG. 79 (c), the back side wall surface 422a is a plane parallel to the surface of the game board 421, and the distance from the back surface of the window panel 52 to the back side wall surface 422a at the entrance is 18 mm, and at the exit The distance from the back surface of the window panel 52 to the back side wall surface 422a is 18 mm. Further, the front side wall surface 422b has an inclination that gradually approaches the back side wall surface 422a as it proceeds downward, and the distance from the surface of the game board 421 to the front side wall surface 422b at the entrance is 17.5 mm, and the exit The distance from the surface of the game board 421 to the front side wall surface 422b is 16 mm. As described above, the position changing passage 423 has a configuration in which the dimension in the depth direction of the passage is shortened from the entrance to the exit, and the center of the passage is moved to the back side.

  Here, the front side wall surface 422b has an inclination that advances toward the back as it goes downward, but the inclination is slight. For this reason, when the vertically falling game ball B1 collides with the front side wall surface 422b near the entrance, the path of the game ball B1 is before the game ball B1 collides with the first left / right sorting nail 213 positioned below the exit. The inner wall surface 422a and the surface of the game board 421 do not change so much. In this case, the game ball B1 changes its course to the extent that it collides with the first sorting surface 217a, which is the surface on the near side of the first left / right sorting nail 213 located 13 mm below the exit of the position change passage 423.

  Further, the inclination provided on the front side wall surface 422b is an angle that suppresses chattering in which the game ball B1 repeatedly collides with the front side wall surface 422b and the rear side wall surface 422a in the position change passage 423. is there. The inclination of the front side wall surface 422b is set to be a slope that suppresses a large rebound to the back side of the game ball B1 that falls vertically and collides with the front side wall surface 422b. It can be reflected in the course of the game ball B1 downstream in a manner that is easy for the person to understand.

  As shown in FIG. 79 (c), the boundary line between the first distribution surface 217a and the second distribution surface 218a of the first left / right distribution nail 213 is located at the center in the depth direction of the game area PA. . As shown in FIG. 79 (c), at the entrance, the game ball B1 located behind the center in the depth direction of the game area PA is discharged from the exit as it is, and the first left and right distribution nails 213 are It collides with the distribution surface 217a and is distributed in the right direction.

  Further, as shown in FIG. 79 (d), for the game ball B1 located on the near side of the center of the game area PA, the distance from the center of the game ball B1 to the back surface of the window panel 52 is 7.5 mm or less. The game ball B1 is in contact with the front side wall surface 422b of the position change passage 423, changes the course to the back side, and after being discharged from the outlet, collides with the first distribution surface 217a of the first left / right distribution nail 213. To the right. Further, the game ball B1 whose distance from the center of the game ball B1 to the back surface of the window panel 52 is longer than 7.5 mm is discharged from the exit as it is and collides with the second distribution surface 218a of the first left / right distribution nail 213. To the left.

  Thus, the position in the depth direction of the game ball B1 passing through the position change passage 423 is changed to the back side with a high probability. By combining the position change passage 423 and the first left / right distribution nail 213, the game ball B1 can be guided onto the rolling surface 357 of the stage unit 354 in a manner corresponding to the position of the game ball B1 in the depth direction. Can increase the sex.

  Next, the downstream path of the game ball B1 that collides with the first left / right sorting nail 213 provided below the position change passage 423 will be described with reference to FIGS. 80 (a) and 80 (b). 80 (a) and 80 (b) are front views of the game board 421 showing the downstream periphery of the position change passage 423 in an enlarged manner.

  As shown in FIG. 80 (a), the game balls B1 that collide with the first distribution surface 217a of the first left / right distribution nail 213 and are distributed rightward are formed on the upper surface of the stage unit 354. Guided to surface 357. As already described in the sixteenth embodiment, both the left and right ends of the rolling surface 357 of the stage unit 354 are provided sufficiently higher than the mountain portion 358, and the game ball B1 is placed forward on the rolling surface 357. The width in the left-right direction of the valley portion 359 that can fall down is approximately twice the diameter of the game ball B1, and the ratio of the rolling surface 357 to the width in the left-right direction is set low. Further, the height difference between the bottom of the valley portion 359 and the top of the peak portion 358 on the rolling surface 357 is set small. That is, the configuration is such that the game ball B1 rolling on the rolling surface 357 is unlikely to fall forward from the valley portion 359. For this reason, there is a high possibility that the game balls B1 distributed in the direction by the first left / right distribution nail 213 will win the operating ports 33,.

  On the other hand, as shown in FIG. 80 (b), the game balls B1 distributed leftward by the first left / right distribution nail 213 flow down the left game area PA. As shown in FIG. 80 (b), the game board 421 has a left guide nail group 429 for guiding the game ball B 1 flowing down the left side of the game area PA to the operation ports 33 and 34, on the left side of the operation ports 33 and 34. It is provided above. The left guide nail group 429 is constituted by obstacle nails 228.

  The game balls B1 distributed to the left by the first left / right distribution nail 213 may be guided by the left guide nail group 429 and win the operating ports 33, 34, and constitute the left guide nail group 429. There is a possibility that the obstacle nail 228 is dropped from the gap of the obstacle nail 228 and recovered from the out port 24a. In the game board 421, the probability of winning the operation ports 33 and 34 by being guided by the left guide nail group 429 is lower than the probability of winning the operation ports 33 and 34 by being guided by the rolling surface 357 of the stage unit 354.

  Next, instead of the position changing passage 423 defined by the passage forming member 422, the case of using the replacement position changing passage 442 defined by the replacement passage forming member 441 will be described with reference to FIGS. The description will be given with reference. 81 (a) and 81 (b) are end views of the cut surface when the exchange passage forming member 441 is cut along a plane perpendicular to the surface of the game board 421. FIG. Here, the replacement passage forming member 441 is a member in which the inclination of the back side wall surface 422a is changed in the passage forming portion 424 constituting the passage forming member 422, and other than the back side wall surface 422a of the replacement passage forming member 441. This structure is the same as the structure of the passage forming member 422.

  As shown in FIGS. 81A and 81B, the replacement passage forming member 441 includes an exchange passage forming portion 443 having the same outer shape as the passage forming portion 424 of the passage forming member 422, and an upper side of the passage forming member 422. The replacement upper fixing portion 444 is the same as the fixing portion 425, and the replacement lower fixing portion 445 is the same as the lower fixing portion 426 of the passage forming member 422. The replacement passage forming member 441 is fixed in such a manner that a part of the back surface of the replacement passage forming portion 443 is fitted into a fixing hole 421b formed on the surface of the game board 421. Specifically, the replacement upper fixing portion 444 is screwed to the upper fixing recess portion 421c and the replacement lower fixing portion 445 is screwed to the lower fixing recess portion 421d to be attached to and detached from the game board 421. Mounted in a possible manner.

  As shown in FIGS. 81 (a) and 81 (b), the replacement passage forming portion 443 has a passage forming portion 443 in that the inclination of the back side wall surface 443a is different from the inclination of the back side wall surface 422a of the passage forming portion 424. Different from 424. The rear side wall surface 443a has an inclination that gradually approaches the front side wall surface 443b as it advances downward, and the distance from the back surface of the window panel 52 to the rear side wall surface 443a is 17.5 mm at the entrance, and the window at the exit The distance from the back surface of the panel 52 to the back side wall surface 443a is 15 mm.

  Here, the back side wall surface 443a has an inclination that advances toward the near side as it goes downward, but the inclination is slight. Therefore, when the vertically falling game ball B1 collides with the back side wall surface 443a in the vicinity of the entrance, the path of the game ball B1 is before the game ball B1 collides with the first left / right sorting nail 213 positioned below the exit. It does not change so much that it collides with the front side wall surface 443b and the back surface of the window panel 52. The path of the game ball B1 that falls vertically and collides with the rear side wall surface 443a is the second distribution that is the surface on the near side of the first left / right distribution nail 213 located 13 mm below the exit of the replacement position changing passage 442. It changes to such an extent that it collides with the surface 218a.

  Here, the inclination provided on the rear side wall surface 443a of the replacement passage forming member 441 and the inclination provided on the front side wall surface 443b are such that the game ball B1 and the front side wall surface 443b within the replacement position change passage 442 And an angle at which chattering that repeatedly repeats the collision with the rear side wall surface 443a is suppressed. The inclination of the front side wall surface 443b is set to suppress the large rebound to the back side of the game ball B1 colliding by falling vertically, and the inclination of the back side wall surface 443a is vertically dropped to the front side of the game ball B1 colliding. By making the inclination to suppress a large rebound, the difference in the position of the game ball B1 in the depth direction can be reflected in the course of the game ball B1 downstream in a manner that is easy for the player to understand.

  As shown in FIG. 81 (a), with respect to the game ball B1 located behind the center of the game area PA, the game ball B1 that falls vertically and collides with the back side wall surface 443a changes its course to the near side. After being discharged from the outlet, it collides with the second distribution surface 218a of the first left / right distribution nail 213 and is distributed leftward. On the other hand, the game ball B1 that falls vertically and does not collide with the back side wall surface 443a is discharged as it is from the outlet, collides with the first distribution surface 217a of the first left / right distribution nail 213, and is distributed to the right.

  Also, as shown in FIG. 81 (b), for the game ball B1 located on the near side of the center of the game area PA, the game ball B1 that falls vertically and collides with the near side wall surface 443b is routed to the back side. After being discharged from the outlet, it collides with the first distribution surface 217a of the first left / right distribution nail 213 and is distributed in the right direction. On the other hand, the game ball B1 that falls vertically and does not collide with the front side wall surface 443b is discharged as it is from the outlet, collides with the second distribution surface 218a of the first left / right distribution nail 213, and is distributed leftward.

  Thus, the back side wall surface 443a that guides the game ball B1 that falls vertically and collides with the second distribution surface 218a of the first left and right distribution nail 213, and the game ball B1 that falls and collides vertically with the first right and left By using a replacement passage forming member 441 that includes a front side wall surface 443b that guides to the first distribution surface 217a of the distribution nail 213, the game ball launching mechanism 27 (FIG. 2) uses a solenoid 27c and a game When the contact mode with the ball B1 changes and only the game ball B1 located on the back side of the game area PA is supplied or only the game ball B1 located on the near side of the game area PA is supplied In addition, the number of game balls B1 guided to the rolling surface 357 of the stage unit 354 can be prevented from being extremely increased or extremely decreased.

  Further, the replacement passage forming member 441 can be mounted on the game board 421 using the same fixing hole 421b as the passage forming member 422. For this reason, by installing the replacement passage forming member 441 on the same game board 421 as the model on which the passage forming member 422 is attached, a different model is obtained by changing the probability that the game ball B1 wins the operating ports 33 and 34. Can be manufactured. Since the same game board 421 is used, a different model can be easily manufactured as compared with the case where the game board 421 is changed.

  Since the passage forming member 422 and the replacement passage forming member 441 are both attached to the game board 421 in a removable manner, the passage forming member 422 fixed to the game board 421 is removed to form a replacement passage. By changing to the member 441, the game board 421 can be recycled.

  According to the embodiment described in detail above, the following excellent effects are obtained.

  A position change passage 423 for changing the position of the game ball B1 in the depth direction in the game area PA is arranged upstream of the first left / right sorting nail 213. Then, instead of the position change passage 423, a replacement position change passage 442 for changing the position of the game ball B1 in the depth direction in a manner different from the position change passage 423 can be used. By properly using the passage forming member 422 and the replacement passage forming member 441 depending on the model, different models can be manufactured using the game board 421 having the same shape. For this reason, compared with the case where it considers and manufactures the structure of the new game board 421, the model from which the course which the game ball B1 can take easily differs in a short time and low cost can be manufactured.

  In addition, since the passage forming member 422 and the replacement passage forming member 441 are both attached to the game board 421 in a detachable manner, the passage forming member 422 attached to the game board 421 is removed and the replacement passage forming member 441 is removed. By switching to, it becomes possible to recycle the game board 421 in a manner in which the movement of the game ball B1 in the game area PA is different.

  The first left / right sorting nail 213 is provided at the left end of the rolling surface 357 of the stage unit 354, and the game ball B1 that collides with the first sorting surface 217a and is distributed to the right side is guided to the rolling surface 357. In addition, the game ball B1 that collides with the second distribution surface 218a and is distributed to the left side is guided to the operation ports 33 and 34 by a large number of nails 228 provided on the game board 421. . The rolling surface 357 having a shape in which the left and right ends and the mountain portion 358 are inclined downward toward the back has a higher probability that the game ball B1 rolling on the rolling surface 357 is higher than the nail 228 of the game board 421. The configuration leads to the operation port 33. For this reason, by installing the passage forming member 422 that easily guides the game ball B1 to the back side above the first left / right distribution nail 213, the probability that the game ball B1 wins the first operating port 33 is increased, The interest of the player can be directed to the movement of the game ball B1 around the changed passage 423, and the interest of the game can be improved.

  The position change passage 423 includes a back side wall surface 422a that is parallel to the surface of the game board 421 and a front side wall surface 422b that is inclined downward toward the back side. The inclination of the front side wall surface 422b is an angle (approximately 5 °) at which the game ball B1 that falls vertically and collides with the first distribution surface 217a of the first left / right distribution nail 213 is collided. For this reason, by attaching the position change passage 423 to the game board 421, the game ball B1 that collides with the first distribution surface 217a that is the back surface of the first left / right distribution nail 213 provided downstream is provided. You can increase the number.

  In addition, the front side wall surface 422b of the position changing passage 423 is prevented from colliding with the rear side wall surface 422a and the surface of the game board 421 until the game ball B1 colliding with falling vertically collides with the first left / right sorting nail 213. Since it is inclined at an angle (approximately 5 °), the occurrence of chattering is suppressed above the first left / right sorting nail 213, and the position of the game ball B1 in the depth direction is greatly reflected in the course of the game ball B1 downstream. be able to.

  Further, the replacement position changing passage 442 has a configuration in which the rear side wall surface 443a and the front side wall surface 443b protrude into the game area PA at the exit, and the rear side wall surface 443a takes the game ball B1 that collides by falling vertically. The left and right sorting nails 213 are inclined at an angle (approximately 5 °) to collide with the second sorting surface 218a, and the front side wall surface 443b falls vertically and causes the colliding game ball B1 to fall into the first left and right sorting nail. It is inclined at an angle (substantially 5 °) to collide with the first distribution surface 217a of 213. For this reason, instead of the position change passage 423, the replacement position change passage 442 is provided in the game board 421, so that the second distribution surface which is the front surface of the first left / right distribution nail 213 provided downstream is provided. The number of game balls B1 that collide with 218a can be increased.

  In the position change passage 423 or the replacement position change passage 442, the ratio of the game ball B1 guided to the front side and the ratio of the game ball B1 guided to the back side are determined as the rear side wall surfaces 422a and 443a and the front side wall surface 422b. , 443b can be changed according to the inclination angle, and a replacement member for guiding the game ball B1 at a desired ratio can be manufactured at a low cost.

<Another embodiment of the seventeenth embodiment>
In the seventeenth embodiment described above, the front side wall surface 443b of the replacement passage forming member 441 may be a plane parallel to the back surface of the window panel 52. Thereby, the game ball B1 located on the front side of the game area PA falls from the exit as it is, collides with the second distribution surface 218a of the first left / right distribution nail 213, and is distributed to the left side. By adopting a configuration in which the exchange passage forming member 441 can easily guide the game ball B1 to the front side, the difference from the passage formation member 422 that easily guides the game ball B1 to the back side is increased, so that the game is different between different models. The movement of the sphere B1 can be greatly changed.

  In the seventeenth embodiment described above, a game that is distributed to the left side in the first left / right sorting nail 213 by using one passage forming member 422 and changing the angle at which the passage forming member 422 is attached to the game board 421. It is good also as a structure which manufactures the model from which the ratio of the number of balls B1 and the number of game balls B1 distributed to the right side differs. For example, an angle changing member for changing the attachment angle of the passage forming member 422 is sandwiched between the fixing hole 421b of the game board 421 and the back surface of the passage forming member 422, and only the angle changing member is replaced, It is good also as a structure which changes the inclination-angle of the back side wall surface 422a and the near side wall surface 422b of the position change channel | path 423. FIG. Accordingly, different models can be manufactured using the game board 421 having the same shape and the passage forming member 422 having the same shape.

  In the seventeenth embodiment described above, the outlet of the position change passage 423 may be positioned above the rolling surface 357 of the stage unit 354. Specifically, by providing the exit of the position change passage 423 at the left end of the stage unit 354, the game ball B1 discharged from the exit of the position change passage 423 is placed on the rolling surface 357 at the left end of the stage unit 354. Fall. In the range in which the game ball B1 can fall, the rear surface area of the rolling surface 357 is inclined toward the rear side, and the front area is inclined toward the front side, thereby changing the position. The game ball B1 guided to the back side by the passage 423 wins the first operating port 33 with a high probability of being guided to the rolling surface 357 without falling to the front side, and is guided to the front side in the position change passage 423. The played game ball B1 falls to the near side.

  In this way, the exit of the position change passage 423 is provided above the rolling surface 357, and the game ball B1 positioned on the far side and the front side of the rolling surface 357 is positioned on the front side. With the configuration in which the path of the ball B1 is different, the position change path is not used without using the first left / right sorting nail 213 provided below the exit of the position change path 423 in the seventeenth embodiment. Depending on the shape of 423, the proportion of the game balls B1 that win the first operating port 33 can be changed.

<Eighteenth embodiment>
In the present embodiment, by utilizing the inclination of the guide surface 462 (FIG. 83B) in the guide passage 461 (FIG. 82), the depth of the game ball B1 when colliding with the first left / right sorting nail 213 is increased. This is different from the seventeenth embodiment in that the collision position is changed. Hereinafter, the description of the same configuration as that of the seventeenth embodiment is basically omitted.

  First, the configuration of the game board 451 in the present embodiment will be described with reference to FIG.

  FIG. 82 is a front view of the game board 451 in the present embodiment. As shown in FIG. 82, the game board 451 includes the display surface 41a of the symbol display device 41, the opening 451a, and the center frame 252 as in the seventeenth embodiment. As in the seventeenth embodiment, the center frame 252 defines the roof unit 253 provided to define the upper edge and the left and right side edges of the opening 451a, and the lower edge of the opening 451a. The stage unit 354 is provided. Here, the rolling surface 357 of the stage unit 354 in the present embodiment has the same shape as the rolling surface 357 described in the sixteenth embodiment.

  In the game board 451, a guide member 471 having a guide passage 461 (FIG. 83 (b)) for changing the position in the depth direction of the game ball B1 is mounted on the lower left side of the display surface 41a. . The guide member 471 is transparent, and the game ball B1 moving in the guide passage 461 is visible from the outside. As shown in FIG. 82, the guide passage 461 has an inlet 485 at the upper surface of the guide member 471 and is formed further toward the back than the surface of the game board 451. The outlet 522 of the guide passage 461 is formed at the lower surface of the guide member 471, and the first left / right sorting nail 213 already described in the thirteenth embodiment is provided directly below the outlet 522. .

  Below the first left / right sorting nail 213, an obstacle nail 228 constituting a left guide nail group 491 for guiding the game ball B 1 to the operation ports 33, 34 is provided, and the first left / right sorting nail A rolling surface 357 of the stage unit 354 is formed on the right side of 213. Here, in the game board 451, the left guide nail group 491 has a gap larger than the diameter of the game ball B1 between the obstacle nails 228, and the game ball B1 is likely to fall downward from the gap.

  As already described in the sixteenth embodiment, the left and right ends of the rolling surface 357 of the stage unit 354 are provided sufficiently higher than the mountain portion 358, and the game ball B1 is directed forward on the rolling surface 357. The width in the left-right direction of the valley 359 that can fall is about twice the diameter of the game ball B1, and the ratio of the rolling surface 357 to the width in the left-right direction is set low. Further, the height difference between the bottom of the valley portion 359 and the top of the peak portion 358 on the rolling surface 357 is set small. That is, the configuration is such that the game ball B1 rolling on the rolling surface 357 is unlikely to fall forward from the valley portion 359. In this way, the possibility that the game ball B1 distributed rightward by the first left / right distribution nail 213 rolls on the rolling surface 357 of the stage unit 354 and wins the first operating port 33 is the first. It is set higher than the possibility that the game balls B1 distributed to the left by one left / right distribution nail 213 are guided to the left guide nail group 491 and win the operating ports 33,.

  For this reason, the possibility that the game ball B1 distributed to the right by the first left / right distribution nail 213 rolls on the rolling surface 357 of the stage unit 354 and wins the first operating port 33 is the first. There is a higher possibility that the game balls B1 distributed to the left by the left / right distribution nails 213 are guided to the left guide nail group 491 and win the operating ports 33, 34.

  Next, the guide member 471 in which the guide passage 461 is formed will be described with reference to FIGS. 83 (a), 83 (b) and FIG. FIG. 83 (a) is an exploded perspective view of the guide member 471, and FIG. 83 (b) is a left side view. FIG. 84 is an end view of the cut surface when the guide member 471 is cut along a plane perpendicular to the surface of the game board 451. As shown in FIG. 83 (a), the guide member 471 includes an upper guide member 481 for taking in and guiding the game ball B1, a lower guide member 521 for discharging the game ball B1 while guiding the course, It is the resin-made member which consists of. The upper guide member 481 and the lower guide member 521 can be separated.

  First, the upper guide member 481 will be described. As shown in FIG. 83A, the upper guide member 481 is configured so that the main body 483 in which the upper guide passage 482 that is the upper portion of the guide passage 461 is formed and the game ball B1 does not deviate to the right side of the guide member 471. And a protrusion 484 for taking in the game ball B1 while guarding. Of these, the shape of the main body 483 is a rectangular parallelepiped, and an entrance 485 for taking in the game ball B1 is formed as an opening facing forward in the upper front portion thereof, and an upper guide is provided in the center of the lower plane. A first communication opening 486 (FIG. 83 (b)), which is an opening for discharging the game ball B1 guided by the passage 482 to the lower guide passage 525, is formed.

  The first communication opening 486 has an area through which one game ball B1 can pass with a margin of 1 mm vertically and horizontally. Further, the entrance 485 has a width that is slightly larger than the diameter of the game ball B1, and has a height that is 1.5 times the diameter of the game ball B1. In this way, the entrance 485 is formed to extend in the up-down direction, and is configured to be able to take in most of the game balls B1 that shake in the up-down direction immediately before the entrance 485.

  As shown in FIG. 83 (b), an upper guide passage 482 is formed in the main body portion 483 toward the rear lower side in a manner that is continuous with the inlet 485. Details of the upper guide passage 482 will be described later. As shown in FIG. 83 (a), fixing protrusions 487 for fixing the upper guide member 481 to the lower guide member 521 to form the guide member 471 are provided at the lower edges of the lower plane of the main body 483. Are integrally formed so as to protrude toward the surface. Further, the left side surface and the right side surface of the main body 483 are provided with elastic protrusions 531 for fixing the upper guide member 481 to the game board 451 at the upper part thereof.

  The elastic protrusion 531 is connected to a compression coil spring (not shown) fixed inside the main body 483, and the upper guide member 481 is detachable by utilizing elastic deformation of the compression coil spring. It is fixed to the game board 451 in a manner.

  The elastic protruding portion 531 is at a protruding position protruding outward from the side surface in an initial state where no force is applied to the compression coil spring. When a force is applied from the outside of the main body portion 483 toward the inside of the main body portion 483, the compression coil spring contracts and becomes a deformed state. In the deformed state of the compression coil spring, the elastic protruding portion 531 takes a deformed position in which the portion that protrudes most outward in the initial state is located on the same plane as the side surface. The elastic protruding portion 531 in the deformed position returns to the protruding position by the restoring force of the compression coil spring when the applied force is removed.

  As shown in FIG. 83 (a), the elastic protrusion 531 is located on the front side of the elastic protrusion 531 and protrudes outward with a steep slope, and the elastic protrusion 531 The rear portion 531b is located on the back side and protrudes outward with a gentle inclination.

  The protruding portion 484 of the upper guide member 481 is integrally formed so as to protrude forward from the front surface of the main body portion 483. The protrusion 484 includes a guard portion 489 for preventing the game ball B1 from moving in the right direction with respect to the upper guide member 481 on the game board 451, and a game area B1 of the game ball B1 flowing down in front of the entrance 485. The game ball B1 located on the back side of the PA is guided in the direction of the entrance 485 so as to be guided to the guide passage 461 (FIG. 83B), and the game ball B1 located on the front side is not guided to the guide passage 461. Thus, it is comprised from the distribution part 541 for guiding to the left direction.

  The guard portion 489 has a rectangular parallelepiped shape, and is formed perpendicular to the front surface of the main body portion 483 so that the left side surface thereof is positioned at the right end of the inlet 485. The guard portion 489 protrudes 17 mm forward from the main body portion 483. For this reason, in a state where the guide member 471 is mounted on the game board 451, the guard portion 489 exists from the surface of the game board 451 to the vicinity of the back surface of the window panel 52.

  In addition, the distribution unit 541 is integrally formed so as to protrude 17 mm forward from a region below the lower end of the inlet 485 on the front surface of the main body 483. The distribution part 541 exists from the left end of the main body part 483 to the left end of the guard part 489. In addition, the allocating unit 541 includes a take-in surface 541a for rebounding the game ball B1 that flows down and collides with the front of the entrance 485 as a rear upper surface, and flows down the front of the entrance 485. Thus, a left guide surface 541b for rebounding the colliding game ball B1 in the left direction is provided as an upper surface on the front side.

  The take-in surface 541a is an inclined surface that inclines downward toward the rear and repels the game ball B1 that falls from above and collides toward the entrance 485. Further, the left guide surface 541b is an inclined surface having a gentle inclination downward toward the left in order to prevent the game ball B1 falling from above from stopping on the spot.

  Next, the lower guide member 521 will be described. As shown in FIG. 83 (a), the shape of the lower guide member 521 is a rectangular parallelepiped having the same length dimension as that of the upper guide member 481 in the left-right direction and the depth direction, and one game ball is provided on the front upper portion thereof. An outlet 522 that allows B1 to be discharged with a margin of 1 mm vertically and horizontally is formed as an opening directed forward. The lower guide member 521 is formed with a lower guide passage 525 for guiding the game ball B1 discharged from the upper guide passage 482 toward the rear upper side from the outlet 522 to the outlet 522. Details of the lower guide passage 525 will be described later.

  In the center of the upper plane of the lower guide member 521, a second communication opening 523 for continuously communicating the lower guide passage 525 with the upper guide passage 482 is formed as an upward opening. The second communication opening 523 is formed at a position corresponding to the first communication opening 486 (FIG. 83 (b)) on the lower plane of the upper guide member 481 and is the same as the first communication opening 486. It has the size and shape.

  In addition, fixing receiving portions 524 are formed on the four edges of the upper plane of the lower guide member 521 so as to correspond to the fixing protrusions 487 of the upper guide member 481. When the entire fixing protrusion 487 is fitted into the fixing receiving part 524, the fixing receiving part 524 is in a state where the surface of the fixing protrusion 487 and the inner wall of the fixing receiving part 524 are in close contact with each other. The member 481 can be fixed to the lower guide member 521. Further, the left side surface and the right side surface of the lower guide member 521 are provided with elastic protrusions 531 for fixing the lower guide member 521 to the game board 451 at the lower part thereof. The elastic protrusion 531 is the same member as the elastic protrusion 531 provided on the left and right sides of the upper guide member 481.

  As described above, the upper guide member 481 is fixed to the lower guide member 521 in such a manner that the fixing protrusion 487 of the upper guide member 481 fits into the fixing receiving portion 524 of the lower guide member 521, whereby the upper guide The guide member 471 is assembled by the passage 482 and the lower guide passage 525 communicating with each other.

  In the game board 451, in a state where the upper guide member 481 is fixed to the lower guide member 521, a rectangular parallelepiped fixing hole 551 in which the main body portion 483 of the upper guide member 481 and the lower guide member 521 are accommodated without a gap. (FIG. 84) is formed. Further, the left side surface and the right side surface of the fixing hole 551 are formed with four concave portions having the same shape and the same size as the elastic protruding portion 531 in the initial state where no force is applied. The four recesses are formed on the left and right side surfaces of the upper guide member 481 and the lower guide member 521 when the main body portion 483 and the lower guide member 521 of the upper guide member 481 are accommodated in the fixing hole 551 without any gap. It is formed at a position corresponding to a total of four elastic protrusions 531 provided on the left and right side surfaces.

  In the process of mounting the guide member 471 in the fixing hole 551, the elastic protruding portion 531 is pressed from the side surface of the fixing hole 551 by the rear portion 531 b protruding outward with a gentle inclination. (Not shown) enters a deformed state, and the elastic protrusion 531 takes the deformed position. When the compression coil spring in the deformed state overlaps the recessed portion of the fixing hole 551 and the elastic protrusion 531 at the mounting position, the force applied from the rear portion 531b is removed and the compression coil spring is in the initial state. As a result, the elastic protruding portion 531 returns to the protruding position, and the guide member 471 is attached to the game board 451.

  The compression coil spring connected to the elastic protrusion 531 is detachable when the guide member 471 is pulled forward from the game board 451 and assumes a deformed position. It is fixed in a manner.

  Here, the guide member 471 is attached and detached with deformation of a compression coil spring (not shown) connected to the elastic protrusion 531. When the guide member 471 is mounted on the game board 451, the deformation of the compression coil spring is performed by applying a force from the fixing hole 551 to the rear portion 531b protruding outward with a gentle inclination. On the other hand, when the guide member 471 is removed from the game board 451, the compression coil spring is deformed by applying a force from the fixing hole 551 to the front portion 531a protruding outward with a steep slope.

  For this reason, the force required to remove the guide member 471 from the game board 451 is larger than the force required to remove the guide member 471 from the game board 451. The guide member 471 is a mode in which it is difficult to come off from the game board 451, and the guide path 461 is not easily displaced even if the game ball B1 collides with the guide member 471, and is attached to the game board 451.

  Next, the guide passage 461 formed inside the guide member 471 will be described. As shown in FIG. 83 (b), the upper guide passage 482 guides the game ball B1 taken in from the inlet 485 once in the rear and downward direction, and then guides it from the spot to the first communication opening 486 located in the front and lower direction. This is an arcuate passage. The upper guide passage 482 continuously and smoothly connects the inlet 485 to the first communication opening 486, and the height dimension of the passage gradually decreases toward the downstream in the vicinity of the inlet 485. This is a passage having a passage cross section through which one game ball B1 can pass with a margin of 1 mm in the front, rear, left and right directions. Since the cross section of the passage is set narrow, the game ball B1 is prevented from being greatly shaken in the front, rear, left and right in the guide passage 461, and the course of the game ball B1 in the guide passage 461 is limited.

  As shown in FIG. 83 (b), the game ball B1 guided to the first communication opening 486 by the upper guide passage 482 is guided from the second communication opening 523 to the outlet 522 by the lower guide passage 525. The lower guide passage 525 is continuously connected to the upper guide passage 482, and in the vicinity of the outlet 522, the probability that the discharged game ball B1 collides with the second distribution surface 218a of the first left / right distribution nail 213 is increased. For this purpose, a guide surface 462 inclined downward toward the front is provided. The guide surface 462 has a length twice as large as the diameter of the game ball B 1, and the course downstream of the game ball B 1 rolling on the guide surface 462 is greatly affected by the inclination of the guide surface 462.

  As shown in FIG. 84, the guide surface 462 is smoothly taken into the guide passage 461 at the entrance 485, and the game ball B1 passing through the guide passage 461 at a predetermined reference speed or higher is positioned on the front side of the game area PA. It has the inclination which makes it collide with the 2nd distribution surface 218a. The inclination of the guide surface 462 is repeatedly taken in with the inner wall of the guide passage 461 at the entrance 485, and the game ball B1 whose passing speed in the guide passage 461 is lower than a certain reference speed is positioned on the front side of the game area PA. The inclination is made to collide with the first distribution surface 217a. The guide passage 461 has a configuration for causing most of the game balls B1 discharged from the outlet 522 to collide with the second distribution surface 218a.

  Next, the downstream path of the game ball B1 colliding with the first left / right sorting nail 213 provided below the guide passage 461 will be described based on FIGS. 85 (a) and 85 (b). 85 (a) and 85 (b) are front views of the game board 451 showing the downstream periphery of the guide passage 461 in an enlarged manner.

  As shown in FIG. 85A, the game ball B1 that collides with the first distribution surface 217a of the first left / right distribution nail 213 and is distributed to the right is formed on the upper surface of the stage unit 354. Guided to surface 357.

  As already described in the sixteenth embodiment, the left and right ends of the rolling surface 357 of the stage unit 354 are provided sufficiently higher than the mountain portion 358, and the game ball B1 is directed forward on the rolling surface 357. The width in the left-right direction of the valley 359 that can fall is about twice the diameter of the game ball B1, and the ratio of the rolling surface 357 to the width in the left-right direction is set low. Further, the height difference between the bottom of the valley portion 359 and the top of the peak portion 358 on the rolling surface 357 is set small. That is, the configuration is such that the game ball B1 rolling on the rolling surface 357 is unlikely to fall forward from the valley portion 359. For this reason, there is a high possibility that the game balls B1 distributed in the direction by the first left / right distribution nail 213 will win the operating ports 33,.

  On the other hand, as shown in FIG. 85 (b), the game balls B1 distributed leftward by the first left / right distribution nail 213 flow down the left game area PA. In this case, there is a possibility that the game ball B1 is guided by the left guide nail group 491 and wins the operating ports 33 and 34, and falls down from the gap between the obstacle nails 228 constituting the left guide nail group 491. May be recovered from the outlet 24a. In the game board 451, the probability of winning the operation ports 33 and 34 by being guided by the left guide nail group 491 is lower than the probability of winning the operation ports 33 and 34 by being guided by the rolling surface 357 of the stage unit 354.

  Here, in the fixing hole 551 of the game board 451, instead of the guide member 471 that discharges the game ball B1 in a manner that easily collides with the second distribution surface 218a, an aspect that easily collides with the first distribution surface 217a. It is possible to mount the replacement guide member 561 for discharging the game ball B1. The replacement guide member 561 will be described below with reference to FIG. FIG. 86 is an end view of the cut surface when the replacement guide member 561 is cut along a plane perpendicular to the surface of the game board 451.

  As shown in FIG. 86, the replacement guide member 561 includes a replacement guide surface 562 that is different from the guide surface 462 in place of the lower guide member 521 when the guide member 471 is assembled. It is assembled by using the guide member 563. The lower guide member 563 for replacement differs from the lower guide member 521 only in the shape of the guide surface 462 and the shape of the outlet 522.

  As shown in FIG. 86, the lower end of the outlet 564 of the replacement lower guide member 563 is positioned below the lower end of the outlet 522 of the lower guide member 521. In addition, the replacement guide surface 562 of the replacement lower guide member 563 has a gentle arcuate shape that protrudes upward in the vicinity of the outlet 564. For this reason, the path after discharging the game ball B1 rolling on the replacement guide surface 562 of the replacement lower guide member 563 is the discharge of the game ball B1 rolling on the guide surface 462 of the lower guide member 521. There is a higher possibility that the game ball B1 discharged from the outlet 564 of the lower guide member 563 for replacement will collide with the first distribution surface 217a located on the front side of the game area PA. .

  As described above, in the game board 451, the probability of winning the operation ports 33 and 34 by being guided by the left guide nail group 491 is the probability of winning the operation ports 33 and 34 by being guided by the rolling surface 357 of the stage unit 354. Therefore, by installing the replacement guide member 561 in the game board 451 instead of the guide member 471, the game ball B1 can easily win the operating ports 33 and 34 than the model in which the guide member 471 is installed. A model can be manufactured.

  According to the embodiment described in detail above, the following excellent effects are obtained.

  The guide member 471 is formed with a guide passage 461 having an inclination for allowing the game ball B1 discharged from the outlet 522 to easily collide with the second distribution surface 218a of the first left / right distribution nail 213 provided below. Has been. Further, the first left / right sorting nail 213 positioned below the exit 522 of the guide passage 461 causes the stage unit 354 to roll the game ball B1 colliding with the first sorting surface 217a located on the back side of the game area PA. It is provided in a manner leading to the surface 357. For this reason, the player expects the game ball B1 discharged from the exit 522 of the guide passage 461 to be guided to the rolling surface 357, and collects the player's attention around the exit 522 of the guide passage 461. It is possible to improve interest.

  In the game board 451, the game ball B1 guided to the rolling surface 357 of the stage unit 354 is difficult to drop from the valley portion 359 of the rolling surface 357, so that it is guided to the rolling surface 357 and played. There is a high possibility that B1 will win the first working port 33. On the other hand, after the game ball B1 flows down the left side of the game area PA, the game ball B1 is likely to fall downward from the gap between the obstacle nails 228 constituting the left guide nail group 491. Therefore, the game ball B1 is guided to the left guide nail group 491. The possibility that the played game ball B1 wins the operating ports 33 and 34 is low. For this reason, when the game balls B1 discharged from the exit 522 of the guide passage 461 are distributed in the right direction, the player's expectation to win the first operating port 33 can be increased, and the first left and right swings can be increased. The player's attention can be attracted to the result of distribution by the nail 213, and the interest of the game can be improved.

  Further, the guide member 471 includes a take-in surface 541a for distributing the game balls B1 located on the back side of the game area PA to the back side and guiding them to the entrance 485. For this reason, the position of the game ball B1 in the game area PA in the depth direction can be largely reflected in the course of the game ball B1, and the player is focused on the vicinity of the entrance 485 of the guide passage 461 to improve the interest of the game. be able to.

  Further, a replacement guide member 561 can be attached to the game board 451 instead of the guide member 471. The replacement guide member 561 includes a replacement guide surface 562 for facilitating the collision of the game ball B1 discharged from the outlet 564 with the first distribution surface 217a of the first left / right distribution nail 213. A new model in which the game ball B1 enters the first operation port 33 can be manufactured with a different probability from the model in which the member 471 is mounted. Manufacturing costs can be reduced by using the same game board 451 for a plurality of models.

  Further, the guide member 471 takes a deformed position in the process of fitting the guide member 471 into the fixing hole 551 formed in the game board 451, and the guide member 471 is completely fitted into the fixing hole 551. Thus, it is configured to be fixed to the game board 451 in a detachable manner by the elastic protruding portion 531 that returns to the protruding position. It is also possible to attach a replacement guide member 561 using the same elastic protrusion 531 in a detachable manner to the fixing hole 551 formed in the game board 451. For this reason, by re-attaching the replacement guide member 561 to the game board 451 on which the guide member 471 is mounted, it becomes possible to recycle the game board 451 and manufacture different models.

<Another embodiment of the eighteenth embodiment>
-In 18th Embodiment mentioned above, even if the change guide 721 is provided in the exit 522 of the guide passage 461 as a structure for changing the position of the game ball B1 discharged | emitted from the exit 522 of the guide passage 461 in the depth direction. Good. A case where the guide member 571 provided with the change guide 721 is used will be described with reference to FIG.

  FIG. 87A is an end view of a cut surface when the guide member 571 is cut along a plane perpendicular to the surface of the game board 452. As shown in FIG. 87 (a), the guide member 571 is mounted in a fixing hole 552 provided in the game board 452. In the game board 452, the fixing hole 552 for fixing the guide member 571 is provided above the fixing hole 551 of the game board 451 in the eighteenth embodiment.

  The change guide 721 is an L-shaped tube having two open ends 572 and 573, and an inlet-side open end 572, which is the first open end, communicates with the outlet 522 of the guide passage 461, and the second The outlet-side opening end 573 that is the opening end is attached to the outlet 522 of the guide passage 461 in a manner toward the lower side of the game area PA.

  The shape of the outlet side opening end 573 is circular, and the center thereof is located on the back side with respect to the center of the game area PA. For this reason, the game ball B1 discharged from the center of the outlet side opening end 573 collides with the first distribution surface 217a of the first left / right distribution nail 213 provided below and is distributed to the right. However, the outlet-side opening end 573 has a space in which the game ball B1 located at the center can be crushed by 2 mm in the front-rear and left-right directions, and in the depth direction of the game ball B1 discharged from the outlet-side opening end 573 The position shifts to the back side or to the near side within a certain range.

  As shown in FIG. 87 (a), when the game ball B1 discharged from the outlet-side opening end 573 is positioned at the back side, the game ball B1 is provided directly below the outlet-side opening end 573. It collides with the first distribution surface 217a of the first left / right distribution nail 213 and is distributed in the right direction. On the other hand, when the game ball B1 that exits from the outlet-side opening end 573 is in the near side position, the game ball B1 is positioned on the first left / right sorting nail 213 disposed just below the outlet-side opening end 573. It collides with the second distribution surface 218a and is distributed leftward.

  Thus, the ratio assumed in the design stage by using the change guide 721 that limits the position in the depth direction of the game ball B1 immediately before colliding with the first left / right sorting nail 213 within a certain range. The first left / right sorting nail 213 can distribute the game ball B1 in the right direction and the left direction of the game board 452 at a rate close to. Further, since the change guide 721 is configured to guide the game ball B1 downward immediately before the outlet-side opening end 573, the game ball B1 discharged from the outlet-side opening end 573 is transferred to the first left / right distribution nail 213. It is possible to prevent a collision with the front surface of the game board 452 or the back surface of the window panel 52 by shaking in the depth direction before the collision.

  Further, in the configuration using the change guide 721, the replacement change guide 722 is used instead of the change guide 721, and the replacement guide member 561 provided at the outlet 522 of the guide member 471 of the eighteenth embodiment. Accordingly, the proportion of the game balls B1 that the first left / right sorting nail 213 sorts to the right and the proportion of the game balls B1 that the first left / right sorting nail 213 sorts to the left differ from those using the guide member 571. It is good also as a structure which can be manufactured. A case of using the replacement guide member 574 provided with the replacement change guide 722 will be described with reference to FIG.

  FIG. 87 (b) is an end view of the cut surface when the replacement guide member 574 is cut along a plane perpendicular to the surface of the game board 452. As shown in FIG. 87 (b), the replacement change guide 722 is an L-shaped tube having an inlet-side opening end 742 and an outlet-side opening end 743, similar to the change guide 721. The length of the horizontal pipe 744 which is a pipe formed by extending in the horizontal direction in the replacement change guide 722 is the horizontal pipe 745 which is a pipe formed by extending in the horizontal direction in the change guide 721. It is longer than the length dimension of FIG. 87 (a). For this reason, when the replacement change guide 722 is provided at the outlet 522 of the guide passage 461, the center of the outlet-side opening end 743 is the first left / right sorting nail 213 disposed immediately below the outlet-side opening end 743. It is located in front of the center in the depth direction.

  Further, the outlet side opening end 743 of the replacement change guide 722 has the same size and shape as the outlet side opening end 573 of the change guide 721. For this reason, the position in the depth direction of the game ball B1 discharged from the outlet side opening end 743 is shifted to the far side or to the near side within a certain range.

  Here, the position range in the depth direction that can be taken by the game ball B1 discharged from the outlet side opening end 743 in the replacement change guide 722 can be taken by the game ball B1 discharged from the outlet side opening end 573 in the change guide 721. It is shifted to the near side of the position range in the depth direction. Therefore, in the model using the replacement change guide 722, the ratio of the first left / right distribution nail 213 to distribute the game ball B1 to the left is the same as the first left / right distribution nail 213 in the model using the change guide 721. More than the ratio of distributing B1 to the left. That is, the model using the replacement change guide 722 is a model in which the game ball B1 is less likely to win the first operation port 33 than the model using the change guide 721.

  In this manner, by using the replacement change guide 722 instead of the change guide 721, it is possible to manufacture models having different probabilities that the game ball B1 wins the first operation port 33. Since it is possible to use the same game board 452 for different models, the manufacturing cost is compared with the case where a different game board 452 is manufactured in order to change the probability that the game ball B1 wins the first operation port 33. The variation of the model can be increased while restraining.

  In the eighteenth embodiment described above, the guide member 471 and the replacement guide member 561 may be fixed to the game board 451 by screwing instead of the fixing method using the elastic protrusion 531. The guide member 471 includes a screw fastening portion that protrudes from the main body portion 483 in the left-right direction. Further, the replacement guide member 561 also includes a screwing portion protruding in the left-right direction so that the replacement guide member 561 can be screwed to the game board 451. Then, around the fixing hole 551 (FIG. 84) of the game board 451, a screw that can be accommodated in such a manner that the screwing portion of the guide member 471 or the replacement guide member 561 does not protrude forward from the surface of the game board 451. A fastening recess is formed. The guide member 471 and the replacement guide member 561 are screwed to the game board 451 in a state where the screw fastening portion is fitted in the screw fastening recess. In this way, by fixing the guide member 471 and the replacement guide member 561 with screws, the guide member 471 and the guide member 471 and the guide member 471 and the replacement guide member 561 are fixed in a manner that the course of the game ball B1 to be discharged does not deviate even when the game ball B1 is repeatedly collided. The replacement guide member 561 can be firmly fixed.

  In the eighteenth embodiment described above, the guide member 471 may include an opening / closing mechanism that can open and close the inlet 485 of the guide passage 461. For example, the guide member 471 is configured to discharge the game ball B1 in a manner of colliding with the first distribution surface 217a of the first left / right distribution nail 213 with a high probability, and a predetermined lottery result is obtained in the internal lottery. In this case, the entrance 485 of the guide passage 461 may be opened. In this configuration, when a predetermined lottery result is obtained, the entrance 485 of the guide passage 461 is opened for a predetermined time, so that the first ball of the first left / right distribution nail 213 has a high probability. It collides with the distribution surface 217a and is guided to the rolling surface 357.

  Thus, in the configuration in which the path of the game ball B1 changes in a manner corresponding to the position of the game ball B1 in the depth direction in the game area PA, the ratio of the game ball B1 located in one of the depth directions according to the time zone is By adopting a configuration that increases or decreases, it becomes possible to change the flow of the game ball B1 in the same gaming machine according to the time zone, and it is possible to improve the interest of the game.

<Nineteenth embodiment>
This embodiment is different from the eleventh embodiment in that a short-circuit prevention hole 761 for preventing the occurrence of a solder bridge 751 is formed in the printed wiring board 741 constituting the main control board 61. Hereinafter, the basic description of the same configuration as that of the eleventh embodiment will be omitted.

  The main control board 61 in this embodiment is an electronic circuit mounting board configured by mounting a large number of electronic components on a printed wiring board 741. A specific configuration of the main control board 61 will be described with reference to FIGS. 88 (a) and 88 (b). 88A is an enlarged front view showing a part of the main control board 61 (FIG. 43), and FIG. 88B is an enlarged front view showing the periphery of the one-row connector 782 in the main control board 61. FIG. In FIG. 88A, the wiring pattern 776 formed on the surface of the printed wiring board 741 is not shown.

  As shown in FIG. 88 (a), the printed wiring board 741 of the main control board 61 has a one-row connector 782 having four pins 784a to 784d arranged in one row, and two pins 784e and 784f. And a two-row connector 783 having eight pins 784g to 784p arranged in two rows. The connectors 781 to 783 are attached to the via holes 793 (FIG. 90 (a)) formed in the printed wiring board 741 through the pins 784a to 784p. Here, the via hole 793 is a through hole that penetrates the front surface and the back surface of the printed wiring board 741. In the following, on the surface of the printed wiring board 741, a rectangular area around the attached one-row connector 782 is referred to as a one-row area 787, and a rectangular area around the attached two-pole connector 781 is a two-pole area. 786. Further, a rectangular area around the mounted two-row connector 783 on the surface of the printed wiring board 741 is set as a two-row area 788.

  As already described with reference to FIG. 5 in the first embodiment, the main control board 61 is connected to the payout control device 77, the sound emission control device 81, and the like. Specifically, as shown in FIG. 5, the main control board 61 provided in the main control device 60 is a payout control board provided in the payout control device 77 and a voice light emission control board provided in the voice light emission control device 81. And are electrically connected. Further, as shown in FIG. 5, the main control board 61 provided in the main control device 60 is also electrically connected to other boards such as a power failure monitoring board 67 provided in the main control device 60.

  As shown in FIG. 88A, the main control board 61 is connected to other boards using connectors 781 to 783 which are female connectors. An electric cable used to electrically connect the main control board 61 and another board has male connectors at both ends. The female connectors 781 to 783 attached to the surface of the main control board 61 are connected to the male connector at one end of the electric cable, and the male connector at the other end of the electric cable. Are connected to the female connector mounted on the other board, whereby the main control board 61 is electrically connected to the other board. Here, the other boards include a payout control board provided in the payout control apparatus 77, a sound light emission control board provided in the sound light emission control apparatus 81, a power failure monitoring board 67, and the like.

  The printed wiring board 741 is also provided with a large number of insertion mounting components such as a resistor 771, a capacitor 772, a transistor 773, and an IC 774 that are inserted through the terminals 775 into the via holes 793. As shown in FIG. 88 (b), on the surface of the printed wiring board 741, on the periphery of the one-row connector 782, pins 784 a to 784 d of the one-row connector 782 are connected to electronic components mounted on the printed wiring board 741. A copper wiring pattern 776 is formed for electrical connection. Similarly, a wiring pattern 776 (FIG. 97A) for electrically connecting the two-pole connector 781 to an electronic component on the printed wiring board 741 is formed around the two-pole connector 781. A wiring pattern 776 (FIG. 97B) for electrically connecting the two-row connector 783 to electronic components on the printed wiring board 741 is formed around the two-row connector 783. A solder resist 792 that is an insulator is formed on the wiring pattern 776, and the wiring pattern 776 is not exposed to the outside.

  Here, the structure of the connectors 781 to 783 attached to the printed wiring board 741 will be described with reference to FIGS. 88 (a) and 89 (a) to 89 (c). 89 (a) is a perspective view of the single row connector 782, FIG. 89 (b) is a perspective view of the two-pole connector 781, and FIG. 89 (c) is a perspective view of the double row connector 783. As shown in FIGS. 89 (a) to 89 (c), each of the connectors 781 to 783 is extended in the axial direction with housings 781a to 783a having hollow rectangular parallelepiped shapes whose upper planes are opened upward. The metal pins 784a to 784p are formed. The housings 781a to 783a are resin insulators. The pins 784a to 784p are male pins, and a plating film for improving electrical connectivity, corrosion resistance, and solderability is formed on the surface thereof. The plating film contains tin. In addition, it is good also as a structure by which the gold plating film is formed in the surface of pins 784a-784p.

  As shown in FIG. 88A, the connectors 781 to 783 are mounted in such a manner that the lower planes of the housings 781a to 783a are parallel to the surface of the printed wiring board 741. As shown in FIGS. 89A to 89C, the pins 784a to 784p of the connectors 781 to 783 are arranged at equal intervals in such a manner that the shafts are perpendicular to the lower planes of the housings 781a to 783a. The pins 784a to 784p protrude above and below the lower plane of the housings 781a to 783a. Among these, the upper protrusions of the pins 784a to 784p are in metal contact with female pins provided in the male connector when fitted with the male connector. Further, the lower protrusions of the pins 784a to 784p are inserted into the via holes 793 of the printed wiring board 741 and soldered when the connectors 781 to 783 are fixed to the printed wiring board 741.

  As shown in FIG. 89 (a), the one-row connector 782 includes a first pin 784a, a second pin 784b, a third pin 784c, and a fourth pin 784d in order from the right. 784a to 784d are arranged in a line in the left-right direction with an interval of 1.5 mm. The row of the pins 784a to 784d is surrounded by the side surface of the housing 782a. Further, as shown in FIG. 89 (b), the two pins 784e and 784f constituting the two-pole connector 781 are separated by a distance of 2.5 mm which is wider than the distance between the pins 784a to 784d in the one-row connector 782. The two pins 784e and 784f are surrounded by the side surface of the housing 781a.

  Further, as shown in FIG. 89 (c), the eight pins 784g to 784p constituting the two-row connector 783 are arranged in two rows of four, and the periphery of the row of the two pins 784g to 784p is as follows. It is surrounded by a housing 783a. The spacing between the pins 784g to 784p in each row is 2 mm wider than the spacing between the pins 784a to 784d in the one-row connector 782, and the spacing between the rows is 2.5 mm.

  Here, the board provided in the pachinko machine 10 includes a single row connector in which the interval between adjacent pins 784 is narrower than 1.5 mm, a single row connector in which the interval between adjacent pins 784 is wider than 1.5 mm, and pins. A two-pole connector with a spacing of 784 narrower than 2.5 mm, a two-pole connector with a spacing of pins 784 wider than 2.5 mm, a spacing between rows wider than 2.5 mm, and a spacing between pins 784 in each row Two-row connector narrower than 1.5 mm, the distance between rows is narrower than 2.5 mm, the distance between pins 784 in each row is narrower than 1.5 mm, and the distance between rows is 2.5 mm A two-row connector that is wider than the pin 784 in each row and wider than 1.5 mm is also arranged.

  Next, the configuration of the printed wiring board 741 will be described with reference to FIGS. 90 (a) and 90 (b). FIG. 90A is a perspective view of the printed wiring board 741 showing a part of the back surface side in an enlarged manner, and FIG. 90B is an enlarged view around the via hole 793 of the printed wiring board 741 cut along a plane perpendicular to the front surface. It is a longitudinal cross-sectional view shown. A base material 791 constituting the printed wiring board 741 is a paper phenol substrate manufactured by impregnating paper with a phenol resin. The printed wiring board 741 is a double-sided board in which wiring patterns 776 are formed on both the front surface and the back surface of the base material 791 that is an insulating plate.

  The base material 791 of the printed wiring board 741 is not limited to a paper phenol substrate. For example, a glass epoxy substrate manufactured by impregnating a glass cloth with an epoxy resin may be used. The printed wiring board 741 may be a single-sided board in which the wiring pattern 776 is formed only on the surface of the insulating board, or may be a multilayer board in which the wiring pattern 776 is also formed in the inner layer of the insulating board. Good.

  As shown in FIG. 90 (a), via holes 793 are formed in the printed wiring board 741 so as to pass through the terminals 775 (FIG. 88 (a)) of the insertion mounted parts or the pins 784a to 784p of the connectors 781 to 783. Yes. In order to describe the configuration of the via hole 793, a process of forming the via hole 793 will be described below. First, copper foil 779 (FIG. 90 (b)) having a thickness of 0.04 mm is attached to the front and back surfaces of base material 791 having a thickness of 1.6 mm. Thereafter, a through hole 777 (FIG. 90 (b)) that is a hole penetrating the base material 791 to which the copper foil 779 is attached in the vertical direction is formed.

  Then, copper plating is performed on the base material 791 having the through hole 777. Thereby, the copper thin film 778 (FIG. 90 (b)) is formed on the copper foil 779 (FIG. 90 (b)) stuck on the front surface and the back surface of the base material 791. Further, the through hole 777 becomes a via hole 793 by forming the copper thin film 778 on the inner wall at the timing. At this time, around the via hole 793, the copper foil 779 around the upper opening of the through hole 777 and the copper foil 779 around the lower opening are interposed via the copper thin film 778 formed on the inner wall of the through hole 777. It is in an electrically connected state.

  An etching resist thin film, which is a photosensitive material, is formed on the copper foil 779 attached to the front surface and the back surface of the base material 791 in which the via hole 793 is formed. The mask pattern is transferred and developed by irradiating light (ultraviolet rays) to the etching resist thin film. Then, unnecessary etching resist other than the mask pattern is removed, so that the mask pattern is formed on the front surface and the back surface of the substrate 791.

  Thereafter, dry etching is performed in the etching gas atmosphere to etch the copper foil 779 (FIG. 90B) and the copper thin film 778 on the base material 791 on which the mask pattern is formed using ions or the like, such as acetone. By removing the etching resist in the mask pattern portion with the organic solvent, a copper wiring pattern 776 is formed on the base 791 as shown in FIG. The wiring pattern 776 has a thickness of about 0.04 mm, which is the same as the thickness of the copper foil 779. For etching the copper foil 779 and the copper thin film 778 on the base 791, wet etching in which the base 791 is immersed in an etching solution may be used.

  The printed wiring board 741 has a solder resist 792 formed on the front and back surfaces of the base material 791 in a state where the wiring pattern 776 is formed, and is subjected to surface treatment such as solder plating, electroless gold plating, and water-soluble flux treatment. Created by. Here, the solder resist 792 is a resist that plays a role of insulating the wiring patterns 776 and preventing solder from adhering to portions other than the soldering target portion in the soldering process. Further, the surface treatment is a treatment for improving the solderability of the portion that is continuous with the wiring pattern 776 and exposed to the outside, and is a treatment for making the copper foil portion difficult to rust.

  Specifically, after a resist solution is applied by a curtain coat method to the front surface and the back surface of the base material 791 in a state where the wiring pattern 776 is formed, the pattern portion of the solder resist 792 is dried and cured. . Then, by removing the uncured portion of the resist, a printed wiring board 741 in which the wiring pattern 776 and the solder resist 792 are formed on the substrate 791 is obtained.

  As shown in FIG. 90 (a), in the printed wiring board 741, the pins 784a to 784p of the connectors 781 to 783 and the wiring pattern 776 are soldered around the upper opening and the lower opening of the via hole 793. A joint hole 762 for electrical connection is formed. The joint hole 762 is a circular hole having a diameter slightly larger than the width of the wiring pattern 776, and is formed on the front surface and the back surface of the printed wiring board 741. 90A, in the printed wiring board 741, a short-circuit prevention hole 761 having a larger area than the joint hole 762 is formed around a part of the via holes 793 instead of the joint hole 762. ing.

  In a state where the pins 784a to 784p of the connectors 781 to 783 are inserted into the via hole 793, molten solder adheres to the surface of the joint hole 762 or the short-circuit prevention hole 761 formed around the via hole 793. Then, the adhering molten solder is solidified, whereby the pins 784a to 784p of the connectors 781 to 783 are fixed to the printed wiring board 741 while being electrically connected to the wiring pattern 776.

  Here, soldering is performed in a state where the terminal 775 (FIG. 88) is inserted into the via hole 793 around which the joining hole 762 or the short-circuit prevention hole 761 is formed, so that the insertion mounting component is also attached to the printed wiring board 741. Has been.

  In the soldering process, the short-circuit prevention hole 761 is inserted into the adjacent via hole 793 with the molten solder attached around the pins 784a to 784p (FIGS. 89A to 89C) inserted into the via hole 793. It is provided for the purpose of preventing the short circuit from being formed on the printed wiring board 741 by joining the molten solder adhering around the pins 784a to 784p. In the printed wiring board 741, a short-circuit prevention hole 761 is provided around the via hole 793 that has a high probability of forming a short circuit between adjacent via holes 793 instead of the joint hole 762.

  When the amount of molten solder attached around the pins 784a to 784p inserted through the via hole 793 increases, the molten solder adheres around the pins 784a to 784p inserted through the adjacent via hole 793; The probability of joining will increase. For this reason, the short-circuit prevention hole 761 provided for suppressing the formation of the short-circuit is used even when the amount of the molten solder attached around the pins 784a to 784p inserted through the via hole 793 increases. It has a large area that can be held on the short-circuit prevention hole 761. As shown in FIG. 90A, the area of the short-circuit prevention hole 761 is set wider than the area of the joint hole 762.

  As already described in FIG. 88A, a large number of electronic components are mounted on the printed wiring board 741. For this reason, when the area of the short-circuit prevention hole 761 is set wide in all directions around the via hole 793, in addition to the via hole 793 closest to the via hole 793, a plurality of via holes 793 existing near the via hole 793 are connected. There is a possibility that a short circuit is formed between them. On the other hand, the possibility of the occurrence of a short circuit on the crowded printed wiring board 741 can be reduced by making the shape of the short-circuit prevention hole 761 an ellipse extending in one direction. .

  As shown in FIG. 90A, the short-circuit prevention hole 761 formed around the via hole 793 avoids the direction in which the via hole 793 adjacent to the via hole 793 exists, and is adjacent to the via hole 793. It is formed to extend in the opposite direction. The short-circuit prevention hole 761 is formed as an elliptical hole having a minor axis substantially the same as the diameter of the joint hole 762 and a major axis approximately twice the diameter of the joint hole 762.

  In the joint hole 762 and the short-circuit prevention hole 761, the copper foil 779 (FIG. 90 (b)) is exposed toward the upper side of the hole. On the front and back surfaces of the printed wiring board 741, since the regions excluding the joint hole 762 and the short-circuit prevention hole 761 are masked by the solder resist 792, solder is selectively attached to the joint hole 762 portion in the soldering process. be able to.

  Next, the solder fillet 798 formed around the pins 784a to 784p of the connectors 781 to 783 and around the terminals 775 of the insertion mounted component in the soldering process will be described.

  In the soldering process, the pins 784a to 784p of the connectors 781 to 783 are inserted into the via holes 793 of the printed wiring board 741. Then, molten solder adheres to the via hole 793 and solidifies. Thus, the connectors 781 to 783 are fixed in a state where they are electrically connected to the wiring pattern 776 formed on the front surface and the back surface of the printed wiring board 741.

  The solder fillet 798 will be described with reference to FIG. 91 by taking the second pin 784b of the one-row connector 782 as an example. FIG. 91 is an enlarged longitudinal sectional view showing the periphery of the pins 784 of the one-row connector 782 in the printed wiring board 741 cut along a plane perpendicular to the surface. Here, the pin 784 is the same member as the pins 784a to 784p included in the first row connector 782, the two-pole connector 781, and the second row connector 783, and is a generic name for the pins 784a to 784p.

  As shown in FIG. 91, molten solder is solidified around the pins 784 of the one-row connector 782 fixed to the printed wiring board 741 to form a solder fillet 798. The solder fillet 798 is formed on the joint hole 762, and has a substantially conical shape that extends downward from the back surface of the printed wiring board 741 along the pins 784 of the one-row connector 782. The downward length from the bottom surface to the apex of the substantially conical shape is defined as the height of the solder fillet 798. The solder fillet 798 is formed in such a manner as to include a part of the surface of the pin 784 in the single-row connector 782, the inner wall of the via hole 793, and the surface of the joint hole 762 of the printed wiring board 741. As already described, since the joint hole 762 is continuous with the wiring pattern 776 formed on the printed wiring board 741 and covered with the solder resist 792, the pin 784 of the one-row connector 782 is formed by the solder fillet 798. The wiring pattern 776 is electrically connected.

  Further, the pins 784e and 784f of the two-pole connector 781 and the pins 784g to 784p of the two-row connector 783 are also soldered in the same manner as the pins 784 of the one-row connector 782. Similarly to the connectors 781 to 783, the insertion mounting components constituting the main control board 61 are also soldered and fixed in the state where the terminals 775 of the insertion mounting components are inserted into the via holes 793 of the printed wiring board 741. Yes. Thereby, the terminal 775 (FIG. 88A) of the insertion mounted component is electrically connected to the via hole 793 and the wiring pattern 776 formed on the front surface and the back surface of the printed wiring board 741.

  FIG. 92A is an enlarged back view showing a part of the same main control board 61 as FIG. 88A. A junction hole 762 or a short-circuit prevention hole 761 is formed around the via hole 793 through which the pins 784a to 784p (FIGS. 89 (a) to (c)) of the connectors 781 to 783 are inserted on the back surface of the main control board 61. Yes. For this reason, as shown in FIG. 92A, in the back surface of the printed wiring board 741, a one-row back surface region 842, which is a peripheral region of the mounted one-row connector 782, is formed on the joint hole 762. The circular solder fillets 798 formed and the elliptical solder fillets 799 formed on the short-circuit prevention holes 761 are arranged in a line.

  Here, the configuration of the back surface region 842 for one row on the back surface of the printed wiring board 741 will be described with reference to FIG. FIG. 92 (b) is a rear view of the printed wiring board 741 showing the rear surface area 842 for one row before the one-row connector 782 is attached.

  As shown in FIG. 92 (b), in the back surface region 842 for one row, the via hole 793 through which the first pin 784a of the single row connector 782 is inserted is used as the first via hole 793a, and the second pin 784b is inserted. The via hole 793 is referred to as a second via hole 793b. The via hole 793 through which the third pin 784c of the one-row connector 782 is inserted is referred to as a third via hole 793c, and the via hole 793 through which the fourth pin 784d is inserted is referred to as a fourth via hole 793d.

  As shown in FIG. 92 (b), in the rear surface region 842 for one row, the via holes 793a to 793d are arranged in the order of the first via hole 793a, the second via hole 793b, the third via hole 793c, and the fourth via hole 793d from the right side. They are lined up in a row. In the soldering process, when the printed wiring board 741 is transported in the right direction, the fourth via hole 793d positioned at the left end of the back surface region 842 for one row is positioned at the rear end in the transport direction. Further, in the soldering process, when the printed wiring board 741 is transported in the left direction, the first via hole 793a positioned at the right end of the back surface region 842 for one row is positioned at the rear end in the transport direction.

  As shown in FIG. 92B, a wiring pattern 776 is connected to the short-circuit prevention hole 761 formed around the first via hole 793a in the back surface region 842 for one row. Further, in the back surface region 842 for one row, the short-circuit prevention hole 761, the wiring pattern 776 connected to the short-circuit prevention hole 761, and the joining hole 762 are surrounded by an insulating region made of an insulator, A GND solid 851 for grounding is provided around the insulating region. Only the joint hole 762 around the third via hole 793c is electrically connected to the GND solid 851 through the connection portion 763 having a narrower width than the long diameter of the short-circuit prevention hole 761. A solder resist 792 is formed on the wiring pattern 776 and the GND plane 851. For this reason, the wiring pattern 776 and the GND plane 851 are not exposed to the outside, and the molten solder does not adhere to the wiring pattern 776 and the GND plane 851 in the soldering process.

  Here, the GND solid 851 will be described. In addition to the wiring pattern 776 for connecting the pins 784a to 784p of the connectors 781 to 783 to the terminals 775 of the insertion mounted components mounted on the printed wiring board 741, the front and back surfaces of the printed wiring board 741 are connectors. A ground solid 851 (FIG. 92B) is provided as a ground pattern for grounding 781 to 783 and the inserted mounting component. The GND solid 851 is a copper pattern, and has a large area on the front surface and the back surface of the printed wiring board 741.

  Part of the pins 784a to 784p of the connectors 781 to 783 attached to the printed wiring board 741 is connected to the GND solid 851 for grounding. In the back surface region 842 for one row of the pachinko machine 10, as shown in FIG. 92 (b), the third via hole 793c located third from the right avoids both ends of the row of the via holes 793a to 793d, and has a GND plane. 851 is connected. As a result, in the row of four pins 784a to 784d in the one-row connector 782 (FIG. 89 (a)), the third pins 784c (FIG. 89 (a)) that are not located at both ends are grounded.

  In the soldering process, a part of the heat of the molten solder around the third pin 784c of the one-row connector 782 is transferred to the joint hole via the joint hole 762 formed around the third pin 784c. It moves to the GND solid 851 connected to 762. Since the GND solid 851 has a large area on the printed wiring board 741, it can absorb more heat than the wiring pattern 776 having a small area.

  The temperature of the molten solder around the third pin 784c of the single row connector 782 is lower than the temperature of the molten solder around the remaining pins 784a, 784b, 784d of the single row connector 782. As described above, the temperature of the molten solder around the pins 784a to 784p and the terminal 775 connected to the GND plane 851 for grounding is lowered, and the fluidity of the molten solder is lowered. For this reason, molten solder is likely to join around the pins 784a to 784p and the terminal 775 connected to the GND solid 851, and an environment in which a short circuit is likely to be formed.

  In the back surface region 842 for one row of the pachinko machine 10, the third via holes 793c connected to the GND solid 851 are set not to be positioned at both ends of the row of the via holes 793a to 793d, and the back surface region 842 for one row. The formation of a short circuit at both ends of the is suppressed.

  Next, in order to explain the mechanism in which the solder bridge 751 is generated, first, a soldering process performed for mounting the connectors 781 to 783 and the insertion mounted components on the printed wiring board 741 will be described.

  The main control board 61 shown in FIG. 88 is subjected to flow soldering in the automatic soldering apparatus 822 (FIG. 93A) after the connectors 781 to 783 and the insertion mounted parts are fixed to the printed wiring board 741. Created. Here, the flow soldering is a method of performing soldering by simultaneously supplying molten solder and heat to a target part to be soldered. FIG. 93A is an explanatory diagram for explaining the molten solder jet 821, and FIG. 93B is an explanatory diagram for explaining how the jet 821 hits the back surface of the printed wiring board 741. .

  As shown in FIG. 93A, the automatic soldering apparatus 822 includes an inclined member 822a having a gentle gradient, and the molten solder flows down on the inclined member 822a. Here, the molten solder is solder that is heated to approximately 250 ° C. and is in a molten state. When the temperature of the molten solder is low, the fluidity of the molten solder is lowered, causing a soldering failure. Specifically, the amount of molten solder adhering around the pins 784a to 784p (FIGS. 89 (a) to (c)) of the connectors 781 to 783 or the terminals 775 (FIG. 88 (a)) of the insertion mounted component increases. At the same time, the molten solder breaks down, and the molten solder around the two pins 784a to 784p or the molten solder around the two terminals 775 merge to form a solder bridge 751 (FIG. 95 (c)). This can cause a short circuit.

  The soldering process is performed by bringing the back surface of the printed wiring board 741 into contact with the molten solder flowing down on the inclined member 822a of the automatic soldering apparatus 822. As shown in FIG. 93B, in the automatic soldering apparatus 822, the printed wiring board 741 comes into contact with the molten solder while being conveyed in a state having a gentle inclination upward. The printed wiring board 741 is conveyed by the belt conveyor in the right direction.

  Here, by explaining the behavior of the molten solder when the jet 821 hits the back surface of the printed wiring board 741 conveyed by the belt conveyor, the effect of the short-circuit prevention hole 761 formed on the back surface of the printed wiring board 741 is explained. Will be explained. First, the behavior of the molten solder in the soldering process of the comparative printed wiring board 831 (FIG. 94A) in which the short-circuit prevention hole 761 is not formed will be described.

  On the back surface of the printed wiring board 831 for comparison, a plurality of pins 784a to 784p constituting the connectors 781 to 783 and a plurality of terminals 775 constituting the insertion mounted parts are arranged. For example, as shown in FIG. 93 (b), when the four pins 784a to 784d of the one-row connector 782 are soldered, the comparative printed wiring board 831 is gently inclined upward. Since it is conveyed, the start timing and the end timing of contact with the jet 821 are different for each of the four pins 784a to 784d. Here, as shown in FIG. 93 (b), in the one-row connector 782 attached to the printed wiring board 741 conveyed toward the right, the pin located on the rightmost side is set as the first pin 784a. The second pin from the right is the second pin 784b. In addition, the third pin from the right is the third pin 784c, and the fourth pin from the right is the fourth pin 784d.

  As shown in FIG. 93 (b), the four pins 784a to 784d of the one-row connector 782 are in contact with the jet 821 in order from the first pin 784a, and finally the fourth pin 784d is connected to the jet 821. It will be in contact. Then, the first pin 784a sequentially comes out of contact with the jet 821, and finally the fourth pin 784d comes out of contact with the jet 821.

  94A to 94C and FIGS. 95A to 95C regarding the behavior of the molten solder when the four pins 784a to 784d of the one-row connector 782 come out of the contact state with the jet 821. However, it will be described below. FIG. 94A is a longitudinal sectional view of a comparative printed wiring board 831 shown for explaining a state in which the second pin 784b, the third pin 784c, and the fourth pin 784d of the one-row connector 782 are in contact with the jet 821. FIG. 94 (b) is a longitudinal sectional view of a comparative printed wiring board 831 shown for explaining how the second pin 784b of the one-row connector 782 comes out of contact with the jet 821. (C) is a longitudinal cross-sectional view of the printed wiring board for comparison 831 shown for explaining the manner in which the third pin 784c of the one-row connector 782 comes out of contact with the jet 821. Here, the longitudinal cross-sectional views of FIGS. 94A to 94C are longitudinal cross-sectional views of the cut surface when the comparative printed wiring board 831 is cut along a plane perpendicular to the surface of the comparative printed wiring board 831. .

  Since the second pin 784b, the third pin 784c, and the fourth pin 784d of the one-row connector 782 are in contact with the jet 821 (FIG. 94A), only the third pin 784c and the fourth pin 784d are jets. When a transition is made to the state in contact with 821 (FIG. 94 (b)), a predetermined amount of molten solder remains around the second pin 784b, and the formation of the solder fillet 798 starts. As described above, in the initial stage in which the solder fillet 798 is formed, the amount of molten solder remaining around the second pin 784b depends on the area of the joint hole 762 formed around the second pin 784b and the printed wiring for comparison. It is influenced by the conveyance speed of the plate 831 and the like.

  As shown in FIG. 94 (b), at the formation start timing of the solder fillet 798 around the second pin 784b, the solder fillet 798 being formed around the second pin 784b and the jet 821 are continuous. is there. This state is a state where the molten solder around the second pin 784b and the molten solder of the jet 821 can go back and forth.

  Here, the static property of the molten solder will be described. The molten solder at about 250 ° C. has fluidity and surface tension. For this reason, when a small amount of molten solder lump comes into contact with a large amount of molten solder lump, the molten solder forming a small amount of lump is attracted toward the large amount of molten solder lump. As a result, the amount of molten solder forming a small amount of lump is smaller than that before contact, and the amount of molten solder forming a large amount of lump is increased as compared to before contact.

  As shown in FIG. 94 (b), when the molten solder remaining around the second pin 784b and the molten solder of the jet 821 are continuous, the molten solder around the second pin 784b is better. Since the amount is small, a part of the small amount of molten solder remaining around the second pin 784 b is drawn into the jet 821. For this reason, a small amount of molten solder remains around the second pin 784b as compared with the initially attached molten solder, and as shown in FIG. 94C, the molten solder remaining around the second pin 784b causes the second solder. A solder fillet 798 is formed on the joint hole 762 formed around the pin 784b.

  FIG. 95A is a longitudinal sectional view of a comparative printed wiring board 831 shown for explaining a state in which the third pin 784c of the one-row connector 782 has come out of the contact state with the jet 821, and FIG. FIG. 95 is a longitudinal sectional view of a comparative printed wiring board 831 for explaining a state in which the fourth pin 784d of the first row connector 782 has come out of contact with the jet 821, and FIG. 95 (c) is a first row connector 782. FIG. 10 is a longitudinal sectional view of a comparative printed wiring board 831 showing a state in which a solder bridge 751 is formed between the third pin 784c and the fourth pin 784d. Here, the longitudinal cross-sectional views of FIGS. 95A to 95C are vertical cross-sectional views of the cut surface when the comparative printed wiring board 831 is cut along a plane perpendicular to the surface of the comparative printed wiring board 831. .

  When the third pin 784 c comes out of contact with the jet 821, part of the molten solder remaining around the third pin 784 c is drawn into the jet 821 at the initial stage when the solder fillet 798 is formed. For this reason, as shown in FIG. 95A, a smaller amount of molten solder remains around the third pin 784c than the molten solder that initially adheres, and the third portion is melted by the molten solder remaining around the third pin 784c. A solder fillet 798 is formed on the joint hole 762 formed around the pin 784c.

  On the other hand, as shown in FIG. 95 (b), the fourth pin 784d located at the right end of the row constituted by the four pins 784a to 784d (FIG. 93 (b)) of the single row connector 782 is connected to the jet 821. In this case, the molten solder remaining around the fourth pin 784d and the jet 821 are not in contact with each other at the initial stage when the solder fillet 798 is formed. For this reason, the amount of molten solder remaining around the fourth pin 784d in the initial stage is maintained as it is without decreasing.

  In the comparative printed wiring board 831, the same joint hole 762 as the surroundings of the first pin 784 a to the third pin 784 c is formed around the via hole 793 through which the fourth pin 784 d of the one-row connector 782 is inserted. . Around the fourth pin 784d, an excessive amount of molten solder tends to remain with respect to the area of the joint hole 762. When excessive molten solder that does not fit around the fourth pin 784d is generated, as shown in FIG. 95 (c), the molten solder around the third pin 784c adjacent to the front side in the transport direction is most merged. Easy to do.

  When the molten solder around the fourth pin 784d and the molten solder around the third pin 784c merge and become a continuous state, the two pins 784c, 784d are between the two pins 784c, 784d. A solder bridge 751 for electrically connecting the two is formed. As a result, a short circuit is formed in the main control board using the comparative printed wiring board 831. In this case, a manual correction operation is required after the automatic soldering operation, and the manufacturing efficiency of the main control board using the comparative printed wiring board 831 decreases and the manufacturing cost increases.

  On the other hand, in the main control board 61 of the present embodiment using the printed wiring board 741, the third via hole 793c connected to the GND solid 851 is formed in the back surface region 842 for one row as already described in FIG. It is arrange | positioned so that it may not be located in both ends. In the soldering process, the third via hole 793c is not positioned at the rear end in the transport direction both when the printed wiring board 741 is transported in the right direction and when transported in the left direction.

  Printed wiring is affected by the fact that the flow of molten solder decreases with the temperature drop of the molten solder around the third pin 784c connected to the GND solid 851 and the solder bridge 751 (FIG. 95C) is likely to occur. This is a configuration that does not extend around the via holes 793a and 793d that may be located at the rear end in the transport direction of the plate 741. This reduces the possibility that the solder bridge 751 is formed around the via holes 793a and 793d located at the end of the back surface region 842 for one row due to the influence of the GND solid 851.

  Further, in the first row connector 782, the third pin 784c connected to the GND solid 851 is located inside the row of the pins 784a to 784d of the first row connector 782, so that the third pin 784c is finally formed around the third pin 784c. The amount of molten solder forming the solder fillet 798 is smaller than the amount of molten solder adhering around the third pin 784c in the initial stage. Accordingly, it is possible to prevent a short circuit due to the formation of the solder bridge 751 around the third pin 784c connected to the GND solid 851 for grounding in the one-row connector 782.

  As already described in FIG. 92B, a short-circuit prevention hole 761 is formed around the fourth via hole 793d through which the fourth pin 784d of the one-row connector 782 is inserted, instead of the joint hole 762. Accordingly, the molten solder remaining around the fourth pin 784d is prevented from joining with the molten solder remaining around the third pin 784c, and generation of the solder bridge 751 is suppressed. Returning to FIG. 92 (b), details of the short-circuit prevention hole 761 will be described below.

  As shown in FIG. 92 (b), in the rear surface region 842 for one row where the via holes 793a to 793d are arranged from right to left, the first via hole 793a located at the right end of the row of the via holes 793a to 793d and the left end. A short-circuit prevention hole 761 is formed around the fourth via hole 793d positioned, and a joint hole 762 is formed around the second via hole 793b and the third via hole 793c positioned inside the row. Thus, since the short-circuit prevention holes 761 are formed at both ends of the row of the via holes 793a to 793d parallel to the transport direction, even when the printed wiring board 741 is transported to the left in the soldering process, It is possible to suppress the generation of the solder bridge 751 around the via hole 793 located at the right end, which is the rear end in the transport direction.

  As shown in FIG. 92 (b), in the rear surface region 842 for one row, the distance LA1 from the center of the via holes 793a to 793d to the center of the adjacent via holes 793a to 793d is the adjacent pins 784a to 784d in the one row connector 782. It is 1.5 mm which is the same as the distance between (FIG. 89 (a)).

  As shown in FIG. 92B, the distance LB1 from the left end of the short-circuit prevention hole 761 around the first via hole 793a to the right end of the joint hole 762 around the second via hole 793b, and the junction hole 762 around the third via hole 793c. The distance LB1 from the left end to the right end of the short-circuit prevention hole 761 around the fourth via hole 793d is the same as the distance LB1 from the left end of the joint hole 762 around the second via hole 793b to the right end of the joint hole 762 around the third via hole 793c. is there.

  As shown in FIG. 92B, around the fourth via hole 793d, the fourth via hole 793d is positioned on the right side of the center of the short prevention hole 761, and the short prevention hole 761 is arranged in a row of the via holes 793a to 793d. It is provided near the outside. Short-circuit prevention holes 761 around the fourth via hole 793d extend outward in the row of via holes 793a to 793d. Further, around the first via hole 793a, the first via hole 793a is located on the left side of the center of the short prevention hole 761, and the short prevention hole 761 is provided on the outer side of the row of the via holes 793a to 793d. . A short-circuit prevention hole 761 around the first via hole 793a extends outward in the row of the via holes 793a to 793d.

  By providing a short-circuit prevention hole 761 having a long diameter longer than the diameter of the joint hole 762 near the outside of the row of the via holes 793a to 793d, in the soldering process, the molten solder adhering to the joint hole 762 and the short-circuit prevention hole 761 are provided. The possibility that the molten solder adhering to the solder will approach and join together is reduced. Thereby, possibility that a short circuit will be formed on the printed wiring board 741 can be reduced.

  Next, the solder fillet 799 formed around the fourth pin 784d of the one-row connector 782 by the soldering process will be described with reference to FIG. FIG. 96 is a longitudinal sectional view of a printed wiring board 741 showing a solder fillet 799 formed around the fourth pin 784d of the one-row connector 782. Here, the longitudinal sectional view of FIG. 96 is a longitudinal sectional view of a cut surface when the printed wiring board 741 is cut along a plane perpendicular to the surface of the printed wiring board 741.

  As shown in FIG. 96, the short-circuit prevention hole 761 around the fourth pin 784d in the printed wiring board 741 is larger than the area of the joint hole 762 around the fourth pin 784d in the comparative printed wiring board 831 described above. have. Therefore, a solder fillet 799 having a bottom surface larger in area than the solder fillet 798 that can be formed on the bonding hole 762 can be formed on the short-circuit prevention hole 761. As described above, the amount of the molten solder that stably fits around the fourth pin 784d of the single-row connector 782 in the printed wiring board 741 having the short-circuit prevention hole 761 is equal to the single-row connector 782 in the comparative printed wiring board 831. This is larger than the amount of molten solder that stably fits around the fourth pin 784d. By forming a short-circuit prevention hole 761 around the fourth pin 784d of the one-row connector 782 in the printed wiring board 741, it is possible to reduce the possibility that excessive molten solder is generated around the fourth pin 784d. The generation of the solder bridge 751 due to the molten solder remaining around the fourth pin 784d can be suppressed.

  As shown in FIG. 92B, the short-circuit prevention holes 761 around the fourth via hole 793d are formed to extend toward the outside of the row of the via holes 793a to 793d, and accumulate on the short-circuit prevention holes 761. The center of gravity of the molten solder is located in a direction away from the adjacent third via hole 793c in the row. For this reason, even if excessive molten solder is generated around the fourth pin 784d in the soldering process, the excessive molten solder merges with the molten solder around the third pin 784c, which is far away, and the solder bridge 751. Can be prevented from occurring.

  As already explained, in addition to the main control board 61 to which the one-row connector 782 is attached, the pachinko machine 10 is provided with a one-row connector in which the interval between the pins 784 (FIG. 91) is wider than 1.5 mm. And a board on which a single-row connector narrower than 1.5 mm is mounted. In these one-row connectors, the pins 784 connected to the GND plane 851 (FIG. 92B) for grounding are positioned at positions other than the front end and the rear end in the transport direction in the soldering process. The end of the row is removed. A part of the molten solder remaining around the pin 784 connected to the GND solid 851 at the initial stage when the solder fillet 798 (FIG. 91) is formed is drawn into the jet 821, so that the molten solder remaining around the pin 784 is retained. The amount of is reduced from the initial amount. As described above, the temperature of the molten solder around the pin 784 connected to the GND solid 851 is lowered, and the viscosity of the molten solder is increased, so that there is a probability that the solder bridge 751 is generated around the pin 784. Has been reduced.

  In the pachinko machine 10, joint holes 762 (FIG. 90 (a)) are formed around all the pins 784 of the one-line connector in which the distance between the pins 784 is larger than 1.5 mm. On the other hand, when a single-row connector having a distance between the pins 784 of 1.5 mm or less is attached to the printed wiring board, if the joint holes 762 are used around the pins 784 at both ends of the row, It is experimental that the probability that the molten solder attached around the pin 784 located at the rear end and the molten solder attached around the pin 784 adjacent to the pin 784 merge to form the solder bridge 751 increases. I know.

  On the other hand, in this pachinko machine 10, when a single-row connector in which the distance between the pins 784 is 1.5 mm or less is attached to the printed wiring board, the bonding is performed around the pins 784 located at the end of the row. A short-circuit prevention hole 761 (FIG. 90 (a)) having a larger area than the hole 762 is provided. By using the short-circuit prevention hole 761 instead of the joint hole 762, the bottom area of the solder fillet 798 that can be formed is increased, and a large amount of molten solder is stably stored around the pin 784 located at the rear end in the transport direction. Making it possible. Thereby, the probability that the solder bridge 751 is formed around the pin 784 located at the rear end in the transport direction in the one-row connector can be reduced.

  The short-circuit prevention hole 761 formed around the pin 784 located at the end of the row in the single row connector is provided in such a manner as to extend toward the outside of the row while avoiding the adjacent pin 784 existing inside the row. Yes. As described above, the center of gravity of the molten solder collected in the short-circuit prevention hole 761 is positioned in the direction opposite to the adjacent pin 784, so that the molten solder once accumulated in the short-circuit prevention hole 761 is directed in the direction of the adjacent pin 784. It is possible to prevent the solder bridge 751 from being formed by moving and joining the molten solder around the adjacent pins 784.

  In the pachinko machine 10, when mounting a single-row connector in which the distance between the pins 784 is 1.5 mm or less to the printed wiring board, not only around the pin 784 located at one end of the row but also the other end. A short-circuit prevention hole 761 having an area larger than that of the joint hole 762 and extending toward the outside of the row of the pins 784 is also provided around the pin 784 located at the center of the pin 784. Thus, in the soldering process, the probability that the solder bridge 751 is formed around the pins 784 located at both ends of the row in the single row connector can be reduced regardless of the direction in which the printed wiring board is conveyed. In the soldering process, the conveyance direction of the printed wiring board is not limited to one direction. Therefore, the conveyance direction of the printed wiring board can be determined flexibly in the soldering process, and the manufacturing efficiency can be increased.

  The reference value of the interval of the pins 784 of 1.5 mm in which the holes formed around the pins 784 located at both ends of the row are changed from the joint holes 762 to the short-circuit prevention holes 761 is one row per fixed number of printed wiring boards. When soldering for mounting the connector is performed, the probability that the solder bridge 751 is formed around the pin 784 located at the rear end in the transport direction in the one-row connector is smaller than a predetermined reference value. It is a defined value.

  As already described with reference to FIG. 89A, the interval between the pins 784a to 784d of the one-row connector 782 attached to the printed wiring board 741 (FIG. 92B) is 1.5 mm, and the short-circuit prevention hole 761 ( The conditions for setting FIG. 92 (b)) are satisfied. For this reason, as shown in FIG. 92B, a short-circuit prevention hole 761 is provided around the first via hole 793a and the fourth via hole 793d in the back surface region 842 for one row of the printed wiring board 741. The possibility that a short circuit is formed on the wiring board 741 is reduced.

  Next, a configuration around the pins 784 constituting the two-pole connector 781 attached to the printed wiring board 741 will be described. As shown in FIG. 92 (a), on the back surface of the printed wiring board 741, a two-pole back surface region 841 that is a peripheral region of the mounted two-pole connector 781 is formed on the short-circuit prevention hole 761. There are two elliptical solder fillets 799.

  Here, the configuration of the back surface area 841 for two poles on the back surface of the printed wiring board 741 will be described with reference to FIG. 97 (a). FIG. 97 (a) is a back view of the printed wiring board 741 showing an enlargement of the 2-pole back surface area 841 before the 2-pole connector 781 is attached. Two via holes 793 are formed in the back surface region 841 for two poles so as to be aligned in the left-right direction. Here, the via hole 793 positioned on the right side of the bipolar back surface region 841 is referred to as a first via hole 793e, and the via hole 793 positioned on the left side is referred to as a second via hole 793f.

  As shown in FIG. 97 (a), in the bipolar back surface region 841, both the first via hole 793e and the second via hole 793f are located at the end of the bipolar back surface region 841. For this reason, unlike the case of the back surface region 842 for one row described above (FIG. 92B), the via holes 793e and 793f connected to the GND solid 851 cannot be arranged at positions other than both ends in the transport direction. As already described, since the temperature of the molten solder decreases around the via holes 793e and 793f connected to the GND plane 851, the probability that a solder bridge 751 (FIG. 95 (c)) will occur around the via holes 793e and 793f. Is expensive. In addition, around the via holes 793e and 793f that are located at the rear end in the transport direction, excessive molten solder tends to adhere at an early stage when the solder fillet 798 is formed, and thus there is a probability that a solder bridge 751 will occur. high.

  In the printed wiring board constituting the board provided in the pachinko machine 10, the printed wiring board on which the two-pole connector is mounted has two pins 784 (FIG. 91) constituting the two-pole connector. Any of them may become a pin 784 located at the rear end in the transport direction in the soldering process. When the pin 784 connected to the GND solid 851 becomes the pin 784 positioned at the rear end in the transport direction, an environment in which the solder bridge 751 is very likely to occur is generated around the pin 784.

  For this reason, in this pachinko machine 10, the reference of the interval of the pins 784 for determining whether or not to provide the short-circuit prevention hole 761 around the pins 784 provided in the two-pole connector is the reference in the case of the single-row connector. It is set to 2.5 mm, which is longer than the value of 1.5 mm. That is, in the board provided in the pachinko machine 10, when a two-pole connector with a distance between the pins 784 of 2.5 mm or less is attached, a short-circuit prevention hole 761 around the two pins 784 (FIG. 90 (a)). ) And a joint hole 762 (FIG. 90 (a)) is formed around the two pins 784 when a two-pole connector with a gap between the pins 784 wider than 2.5 mm is attached. ing.

  Returning to the description of FIG. 97 (a), the distance LA2 between the centers of the two via holes 793e and 793f in the bipolar back surface region 841 is 2.5 mm. For this reason, as shown in FIG. 97A, a short-circuit prevention hole 761 is formed around the two via holes 793e and 793b formed in the back surface region 841 for two poles.

  As already described, in the soldering process, the short-circuit prevention hole 761 has the via holes 793e and 793f located at the rear ends in the transport direction, and the pins 784e and 784f inserted into the via holes 793e and 793f (FIG. 89 (b) Even when the amount of molten solder adhering to ()) increases, it has a large area necessary to hold the molten solder on the short-circuit prevention hole 761. For this reason, the possibility that the solder bridge 751 is formed between the two pins 784e and 784f (FIG. 89B) constituting the two-pole connector 781 is reduced.

  As shown in FIG. 97A, the short-circuit prevention hole 761 around the second via hole 793f extends in a direction opposite to the direction in which the first via hole 793e adjacent to the second via hole 793f exists. Is formed. For this reason, it can be set as the aspect in which the gravity center of the molten solder collected on the said short-circuit prevention hole 761 is located in the direction opposite to the 1st via hole 793e. As a result, even if the second via hole 793f is located at the rear end in the transport direction, the molten solder attached on the second via hole 793f is difficult to move in the direction of the adjacent first via hole 793e. Generation of the solder bridge 751 can be suppressed.

  As shown in FIG. 97A, a short-circuit prevention hole 761 that is the same as the short-circuit prevention hole 761 around the second via hole 793f is formed around the first via hole 793e. The short-circuit prevention hole 761 is formed to extend in a direction opposite to the direction in which the second via hole 793f exists. Therefore, in the soldering process, the solder bridge 751 is formed around the two pins 784e and 784f constituting the two-pole connector 781 even if the first via hole 793e is positioned at the rear end in the transport direction. The possibility of being reduced can be reduced.

  As shown in FIG. 97A, the short-circuit prevention hole 761 around the first via hole 793e located on the right side of the second via hole 793f in the bipolar back surface region 841 is the center of the short-circuit prevention hole 761. It is formed on the right side so as to be located on the left side. Further, the short-circuit prevention hole 761 around the second via hole 793f located on the left side of the first via hole 793e in the bipolar back surface region 841 is arranged such that the second via hole 793f is located on the right side of the center of the short-circuit prevention hole 761. It is formed on the left side.

  As described above, the two short-circuit prevention holes 761 are provided in such a manner that the distance LB2 from the left end of the short-circuit prevention hole 761 around the first via hole 793e to the right end of the short-circuit prevention hole 761 around the second via hole 793f is kept wide. . For this reason, it prevents that the molten solder adhering around the two pins 784e and 784f (FIG. 89 (b)) constituting the two-pole connector 781 is approaching, and the two pins 784e, It can suppress that the molten solder adhering around 784f merges and the solder bridge 751 is formed.

  Next, a configuration around the pins 784g to 784p constituting the two-row connector 783 attached to the printed wiring board 741 will be described. As shown in FIG. 92 (a), in the back surface of the printed wiring board 741, the back surface region 843 for two rows, which is the peripheral region of the mounted two-row connector 783, is formed on the joint hole 762. A circular solder fillet 798 and an elliptical solder fillet 799 formed on the short-circuit prevention hole 761 exist.

  Here, the configuration of the back surface region 843 for two rows on the back surface of the printed wiring board 741 will be described with reference to FIG. 97 (b). FIG. 97 (b) is a back view of the printed wiring board 741 showing an enlarged view of the back surface region 843 for two rows before the two-row connector 783 is mounted.

  As shown in FIG. 97 (b), two rows of via holes 793 extending in the left-right direction of the printed wiring board 741 are formed in the rear surface area 843 for two rows in the up-down direction. Here, the via holes 793 constituting the upper row are referred to as an eleventh via hole 793g, a twelfth via hole 793h, a thirteenth via hole 793i, and a fourteenth via hole 793j in order from the right side. The via holes 793 constituting the lower row are referred to as a 21st via hole 793k, a 22nd via hole 793m, a 23rd via hole 793n, and a 24th via hole 793p in order from the right side.

  Here, the two-row connector mounted on the board included in the pachinko machine 10 will be described. In the pachinko machine 10, the pins 784 (FIG. 91) constituting the two-row connector and the pins 784 connected to the GND solid 851 (FIG. 97 (b)) for grounding are connected to both ends of the upper row. And at positions other than both ends of the lower row. As described above, the configuration in which the pin 784 connected to the GND solid 851 is not disposed at the rear end in the transport direction makes it easy to generate a solder bridge 751 around the pin 784 at the rear end in the transport direction. Can be prevented.

  In the two-row connector, when determining whether or not the short-circuit prevention holes 761 are provided around the pins 784 located at both ends in the transport direction, if the distance between the upper and lower rows is sufficiently wide, The same criteria are applied to the lower row as for the single row connector. Here, the interval between the upper and lower rows refers to the distance between the center of the pin 784 located at the tip of the upper row and the center of the pin 784 located at the tip of the lower row aligned in parallel with the upper row. It is.

  In the pachinko machine 10, when the distance between the upper row and the lower row is wider than 2.5 mm, the same standard as that of the single row connector is applied. In this case, in each row, when the distance between the centers of the pins 784 is equal to or less than the distance LA1 (1.5 mm), short-circuit prevention holes 761 are formed around the pins 784 located at both ends in the transport direction, In each row, when the center-to-center distance between the pins 784 is longer than the distance LA1 (1.5 mm), joint holes 762 are formed around the pins 784 located at both ends in the transport direction.

  On the other hand, when the distance between the upper row and the lower row is 2.5 mm or less, a short-circuit prevention hole is formed around the pins 784 located at both ends in the transport direction of each row, regardless of the standard of the one-row connector. 761 is formed. As already described, around the pin 784 that will be located at the rear end in the conveying direction, more molten solder is present around the other pins 784 at the initial stage when the solder fillets 798 and 799 are formed. Adhere to. In the two-row connector, when the distance between the upper row and the lower row is 2.5 mm or less, a lot of molten solder is attached, and pins 784 that are likely to cause the solder bridge 751 are formed in each row. There is a possibility of being close at the edge. For this reason, in the case of a two-row connector in which the distance between the rows is narrow, even when the distance between the pins 784 in each row is larger than 1.5 mm, a short-circuit prevention hole is formed around the pins 784 located at both ends of each row. By forming 761, it is possible to suppress the generation of the solder bridge 751 between the pin 784 located at the end of the upper row and the pin 784 located at the end of the lower row.

  Hereinafter, the case where the short-circuit prevention holes 761 are formed around the pins 784 located at both ends in the two-row connector will be described using the two-row connector 783 provided in the main control board 61 as an example.

  As shown in FIG. 97 (b), the upper row of the two-row connector 783 (FIG. 89 (c)) constitutes the periphery of the thirteenth via hole 793i through which the pins 784i not located at both ends of the row are inserted. The joint hole 762 formed in the terminal is connected to the GND solid 851 for grounding. As described above, by preventing the pins 784g to 784p connected to the GND solid 851 from being arranged at both ends of the row, it is possible to prevent an environment in which the solder bridge 751 is likely to be generated at the end of the row of the pins 784g to 784p. Can do.

  As already described in FIG. 92B, the distance LA1 between the centers of the adjacent via holes 793a to 793d in the back surface region 842 for one row is 1.5 mm. On the other hand, as shown in FIG. 97 (b), the distance LA3 between the centers of the adjacent via holes 793g to 793p in the back surface region 843 for two rows is 2 mm longer than the distance LA1 (FIG. 92 (b)). . However, the distance LA4 from the center of the via holes 793g to 793j in the upper row to the center of the via holes 793k to 793p in the lower row is 2.5 mm. Therefore, in order to prevent the solder bridge 751 from being formed between the pins 784j and 784p (FIG. 89 (c)) of the two-row connector 783 inserted through the via holes 793j and 793p located at the left end in each row. Short prevention holes 761 are formed around the 14th via hole 793j and around the 24th via hole 793p.

  As already described, the short-circuit prevention hole 761 has the fourteenth via hole 793j and the twenty-fourth via hole 793p located at the rear end in the transport direction in the soldering process, and the pin 784j and the twenty-fourth pin inserted into the fourteenth via hole 793j. Even when the amount of molten solder adhering to the pin 784p (FIG. 89 (c)) inserted into the via hole 793p increases, a large area necessary for holding the molten solder on the short-circuit prevention hole 761 is increased. Have. Therefore, the possibility that the solder bridge 751 is formed between the pins 784j and 784p (FIG. 89 (c)) located at the left end of the row of the pins 784g to 784p in the two-row connector 783 is reduced.

  As shown in FIG. 97 (b), the short-circuit prevention hole 761 around the fourteenth via hole 793j is formed to extend toward the outside of the row in the direction opposite to the direction in which the adjacent thirteenth via hole 793i exists. Has been. For this reason, it can be set as the aspect which the gravity center of the molten solder collected on the said short-circuit prevention hole 761 is located in the direction opposite to the 13th via hole 793i. As a result, even if the 14th via hole 793j is located at the rear end in the transport direction, the molten solder attached on the 14th via hole 793j is difficult to move in the direction of the adjacent 13th via hole 793i. Generation of the solder bridge 751 can be suppressed.

  As shown in FIG. 97 (b), the short-circuit prevention hole 761 around the 24th via hole 793p is formed to extend toward the outside of the row in the direction opposite to the direction in which the adjacent 23rd via hole 793n exists. Has been. For this reason, it can be set as the aspect in which the gravity center of the molten solder collected on the said short-circuit prevention hole 761 is located in the direction opposite to the 23rd via hole 793n. As a result, even if the 24th via hole 793p is positioned at the rear end in the transport direction, the molten solder attached on the 24th via hole 793p is difficult to move in the direction of the adjacent 23rd via hole 793n. Generation of the solder bridge 751 can be suppressed.

  As shown in FIG. 97 (b), a short-circuit prevention hole 761 that is the same as the short-circuit prevention hole 761 around the fourteenth via hole 793j is formed around the eleventh via hole 793g. The short-circuit prevention hole 761 is formed to extend toward the outside of the row in the direction opposite to the direction in which the adjacent twelfth via hole 793h exists. A short-circuit prevention hole 761 that is the same as the short-circuit prevention hole 761 around the 24th via hole 793p is formed around the 21st via hole 793k. The short-circuit prevention hole 761 is formed to extend toward the outside of the row in the direction opposite to the direction in which the adjacent 22nd via hole 793m exists. For this reason, in the soldering process, the via holes 793g, 793j, and 793k positioned at both ends of the row of the via holes 793g to 793p, whether the printed wiring board 741 is conveyed rightward or leftward. , 793p, the possibility that the solder bridge 751 is formed can be reduced.

  As shown in FIG. 97 (b), the short-circuit prevention holes 761 around the via holes 793g, 793j, 793k, and 793p located at the end of the row in the back surface region 843 for the two rows are formed closer to the outside of the row. Specifically, the short-circuit prevention hole 761 around the eleventh via hole 793g is formed such that the eleventh via hole 793g is located on the left side of the center of the short-circuit prevention hole 761, and the short-circuit around the twenty-first via hole 793k. The prevention hole 761 is formed such that the 21st via hole 793k is positioned on the left side of the center of the short-circuit prevention hole 761. The short-circuit prevention hole 761 around the fourteenth via hole 793j is formed such that the fourteenth via hole 793j is located on the right side of the center of the short-circuit prevention hole 761, and the short-circuit prevention hole 761 around the twenty-fourth via hole 793p. Is formed in such a manner that the 24th via hole 793p is located on the right side of the center of the short-circuit prevention hole 761.

  In this way, it is avoided that the molten solder adhering to the short-circuit prevention hole 761 comes close to the molten solder adhering to the bonding hole 762 adjacent to the short-circuit prevention hole 761. Thereby, the possibility that the molten solder attached to the short-circuit prevention hole 761 merges with the molten solder attached to the joint hole 762 adjacent to the short-circuit prevention hole 761 to form the solder bridge 751 can be reduced.

  According to the embodiment described in detail above, the following excellent effects are obtained.

  Of the pins 784 arranged in a row on the printed wiring board 741, if the distance between adjacent pins 784 in the row is equal to or less than a reference distance, the pin 784 that is not located at the end of the row Around the pin 784 located at the end of the row, a short-circuit prevention hole 761 having an area larger than that of the joint hole 762 is formed. For this reason, compared with the case where the joining hole 762 is also formed around the pin 784 at the end of the row, a large amount of molten solder is stably placed around the pin 784 that is located at the rear end in the transport direction. The probability that a solder bridge 751 is formed around the pin 784 is reduced.

  The shape of the short-circuit prevention hole 761 is an ellipse. Therefore, the area of the short-circuit prevention hole 761 is set to a large area capable of holding the molten solder adhering around the pin 784 located at the rear end in the transport direction around the pin 784, and the short-circuit prevention hole 761. It is possible to avoid the molten solder on the upper portion of the solder from joining the molten solder adhering around the plurality of pins 784 existing in the vicinity of the pin 784.

  A short-circuit prevention hole 761 around the pin 784 located at the end of the row is formed to extend toward the outside of the row. For this reason, the center of gravity of the molten solder that accumulates on the short-circuit prevention hole 761 can be positioned in the direction in which the adjacent pin 784 does not exist. When the pin 784 located at the end of the row is located at the rear end in the transport direction, the molten solder collected around the pin 784 merges with the molten solder around the adjacent pin 784. Can be prevented. Thereby, it is possible to suppress the occurrence of the solder bridge 751 between the pin 784 at the end of the row and the pin 784 adjacent to the pin 784.

  A short-circuit prevention hole 761 is formed not only around the pin 784 located at one end of the row but also around the pin 784 located at the other end of the row so as to extend toward the outside of the row. For this reason, in the soldering process, even if the printed wiring board 741 is transported in any transport direction, the possibility that the solder bridge 751 is formed around the pin 784 located at the rear end in the transport direction is reduced. can do.

  The length that the short-circuit prevention hole 761 formed around the via hole 793 protrudes from the via hole 793 toward the inner side of the row (the adjacent pin 784 side) is a solder fillet formed on the short-circuit prevention hole 761. The minimum length necessary to maintain the strength of 799 is set. In order to secure a large area of the short-circuit prevention hole 761, if the short-circuit prevention hole 761 protrudes from the via hole 793 to the inner side of the row, the adjacent joint hole 762 from the molten solder adhering to the short-circuit prevention hole 761 or the adjacent short-circuit prevention There is a possibility that the molten solder adhering to the hole 761 becomes closer and the molten solder is likely to merge. In this case, the effect of suppressing the formation of the solder bridge 751 by securing a large area of the short-circuit prevention hole 761 is halved. On the other hand, by minimizing the length of the short-circuit prevention hole 761 protruding from the via hole 793 toward the inside of the row, the molten solder attached to the short-circuit prevention hole 761 moves toward the adjacent via hole 793. The possibility can be reduced. Thereby, it can be avoided that the effect of suppressing the formation of the solder bridge 751 by providing the short-circuit prevention hole 761 is halved.

  In the case where the interval between the pins 784 is wider than the reference value, the area of the pin 784 in the row of the pin 784 is larger than the bonding hole 762 around the pin 784 positioned at the end of the printed wiring board 741 in the transport direction. In this configuration, the large short-circuit prevention hole 761 is not used. By eliminating unnecessary short-circuit prevention holes 761 on the printed wiring board 741 having a limited area, it is possible to increase the number of insertion-mounted components that can be mounted on the printed wiring board 741 and cope with higher density of the board. it can.

  In addition, except for the case of the two-pole connector 781 in which it is unavoidable to place the pin 784 connected to the GND solid 851 at the end of the row composed of the plurality of pins 784, the pin 784 connected to the GND solid 851 The configuration is not arranged at the end. Further, the interval between the pins 784 serving as a reference for providing the short-circuit prevention hole 761 in the two-pole connector 781 is set wider than the interval between the pins 784 serving as the reference for providing the short-circuit prevention hole 761 in the first row connector 782 and the second row connector 783. ing. As a result, the possibility that the solder bridge 751 is generated due to the temperature of the molten solder decreasing around the pin 784 connected to the GND solid 851 can be reduced.

  When the printed wiring board 741 includes a plurality of rows of via holes 793, a via hole 793 located at the end of the first row and a via hole 793 located at the end of a second row different from the first row. Are arranged closer to the reference value on the printed wiring board 741 even when the distance between the centers of the adjacent via holes 793 is wider than the reference for providing the short-circuit prevention hole 761 in each row. In this configuration, a short-circuit prevention hole 761 is provided in both of the via holes 793 located at the ends of the two rows. This reduces the possibility that a solder bridge 751 is formed between the pins 784 that are located at the ends of different rows and are inserted into two via holes 793 in an environment where the amount of adhesion of molten solder increases. be able to.

<Another form of the nineteenth embodiment>
In the nineteenth embodiment described above, the direction formed by extending the short-circuit prevention holes 761 around the pins 784 located at both ends of the row is not limited to the direction opposite to the adjacent pins 784. For example, in the row of the pins 784 aligned along the left-right direction, the direction in which the short-circuit prevention hole 761 around the pin 784 located at the right end and the pin 784 located at the left end extends is formed with respect to the left-right direction. It may be inclined at a predetermined angle. The short-circuit prevention hole 761 inclined at a predetermined angle with respect to the left-right direction is referred to as an inclined short-circuit prevention hole 861, and the inclined short-circuit prevention hole 861 will be specifically described with reference to FIG.

  The printed wiring board 863 is different from the printed wiring board 741 in the nineteenth embodiment in that the printed wiring board 863 includes a one-row back surface area 862 in which an inclined short-circuit prevention hole 861 is formed. FIG. 98A is a rear view of the printed wiring board 863 showing an enlarged view of the rear surface region 862 for one row provided with the inclined short-circuit prevention holes 861. Here, in FIG. 98A, illustration of the wiring pattern 776 and the GND solid 851 (FIG. 92B) is omitted. Below, the case where the printed wiring board 863 is conveyed rightward in a soldering process is demonstrated. As shown in FIG. 98 (a), two one-row connectors 782 (FIG. 89 (a)) are mounted side by side on the one-row back surface area 862 of the printed wiring board 863.

  As shown in FIG. 98 (a), four pins 784 (FIG. 91) provided in the first connector which is the first one-row connector 782 are inserted into the first row rear surface region 862. As via holes, first via holes 864 are arranged in a line in the left-right direction at intervals of 1.5 mm. Here, the first via hole 864 has the same configuration as the via hole 793 (FIG. 90B) in the nineteenth embodiment.

  Further, in the back surface region 862 for the first row, second via holes 865 that are via holes for inserting the four pins 784 provided in the second connector which is the second first row connector 782 are spaced by 1.5 mm. Are arranged in a line in the left-right direction. Here, the second via hole 865 has the same configuration as the via hole 793 (FIG. 90B) in the nineteenth embodiment.

  The centers of the four first via holes 864 and the centers of the four second via holes 865 are aligned on the same straight line. The second via hole 865 is located to the right of the first via hole 864, and from the center of the first via hole 864 located at the right end of the four first via holes 864, to the left end of the four second via holes 865. The distance to the center of the second via hole 865 located at is 3 mm.

  Bonding holes 762 are formed around the first via holes 864 that are not located at both ends of the row of the first via holes 864 and around the second via holes 865 that are not located at both ends of the row of the second via holes 865. The four first via holes 864 around the first via hole 864 located at the right end and the four second via holes 865 around the second via hole 865 located at the right end are respectively diagonally right. An inclined short-circuit prevention hole 861 is formed extending upward. The inclined short-circuit prevention hole 861 is an ellipse having the same shape and the same size as the short-circuit prevention hole 761 in the nineteenth embodiment, and its center is located diagonally to the right of the via holes 864 and 865 located at the right end. ing.

  Further, the four first via holes 864 around the first via hole 864 positioned at the left end and the two second via holes 865 around the second via hole 865 positioned at the left end are respectively diagonally left. An inclined short-circuit prevention hole 861 is formed extending downward. The inclined short-circuit prevention hole 861 is an ellipse having the same shape and the same size as the short-circuit prevention hole 761 in the nineteenth embodiment, and its center is located obliquely below and to the left of the via holes 864 and 865 located at the left end. ing.

  As described above, in the configuration in which the pin 784 positioned at the right end of the first connector and the pin 784 positioned at the left end of the second connector are close to each other in the transport direction, the pin 784 is positioned at the right end of the first connector. An inclined short-circuit prevention hole 861 around the pin 784 extending obliquely to the right is formed, and an inclined short-circuit prevention hole 861 around the pin 784 located at the left end of the second connector is obliquely inclined to the left. It is the structure currently extended and formed. As a result, the molten solder collected in the inclined short-circuit prevention hole 861 at the right end of the first connector and the molten solder collected in the inclined short-circuit prevention hole 861 at the left end of the second connector merge to form a solder bridge 751 (FIG. 95C). ) Can be prevented.

  In the nineteenth embodiment described above, the via hole 793 is positioned at the center of the short-circuit prevention hole 761, and the distance between the short-circuit prevention hole 761 and the joint hole 762 is the same as the distance between the joint holes 762. It is good also as a certain structure. A specific example of the configuration will be described with reference to FIG.

  The printed wiring board 866 has a distance from the center of the right end via hole 793 to the center of the via hole 793 adjacent to the right end via hole 793, and from the center of the left end via hole 793 to the center of the via hole 793 adjacent to the left end via hole 793. Is different from the printed wiring board 741 in the nineteenth embodiment in that it is set wider than the distance between the centers of the via holes 793 inside the row. FIG. 98B is a rear view of the printed wiring board 866 showing the rear surface region 867 for one row in an enlarged manner. Here, in FIG. 98B, illustration of the wiring pattern 776 and the GND solid 851 (FIG. 92B) is omitted.

  As shown in FIG. 98 (b), via holes 793 for inserting the four pins 784a to 784d constituting the one-row connector 782 are formed in the left-right direction in the first-row back surface area 867 of the printed wiring board 866. Are arranged in a row. A short-circuit prevention hole 761 is formed around the via hole 793 located at the right end in such a manner that the via hole 793 at the right end is located at the center, and the via hole 793 at the left end is located around the via hole 793 located at the left end. The short-circuit prevention hole 761 is formed in a mode located at the position. Further, a joint hole 762 is formed around the via hole 793 located second from the right and around the via hole 793 located third from the right in such a manner that the via hole 793 is located at the center.

  Here, the distance LC1 is the distance between the left end of the short-circuit prevention hole 761 around the via hole 793 located at the right end and the right end of the joint hole 762 around the via hole 793 located second from the right, and the second from the right. A distance LC2 is a distance between the left end of the joint hole 762 around the via hole 793 and the right end of the joint hole 762 around the via hole 793 located third from the right. The distance between the left end of the joint hole 762 around the via hole 793 located third from the right and the right end of the short-circuit prevention hole 761 located at the left end is defined as a distance LC3.

  In this case, by adopting a configuration in which the distance LC1, the distance LC2, and the distance LC3 are the same distance, as compared with the configuration in which all the via holes 793 are equally spaced, the molten solder attached on the short-circuit prevention hole 761. The center of gravity of the solder is far from the center of the molten solder adhering to the joint hole 762, and the probability that the molten solder on the short-circuit prevention hole 761 and the molten solder on the joint hole 762 merge to form a solder bridge 751 is reduced. Can do. In addition, since the pins 784a to 784d of the one-row connector 782 are fixed to the center of the short-circuit prevention hole 761, the strength of the solder fillet 799 formed on the short-circuit prevention hole 761 is increased, so that vibration during use can be achieved. The possibility that the solder fillet 799 is damaged due to the above or the like can be reduced, and the durability of the main control board 61 can be extended.

  In the nineteenth embodiment described above, the short-circuit prevention hole 761 may be configured such that the via hole 793 located inside the short-circuit prevention hole 761 is located in the center of the short-circuit prevention hole 761. The configuration will be specifically described with reference to FIG.

  The printed wiring board 868 is different from the printed wiring board 741 in the nineteenth embodiment in that the short-circuit prevention hole 761 includes a one-row back surface region 869 formed in a manner having the via hole 793 at the center. FIG. 98 (c) is a rear view of the printed wiring board 868, showing an enlarged view of the back surface area 869 for one row in the printed wiring board 868. Here, in FIG. 98C, illustration of the wiring pattern 776 and the GND solid 851 (FIG. 92B) is omitted.

  As shown in FIG. 98 (c), the printed wiring board 868 has four via holes 793 for inserting the four pins 784a to 784d provided in the one-row connector 782 in the left-right direction at intervals of 1.5 mm. They are formed in a line-up manner. A short-circuit prevention hole 761 is formed around the right end via hole 793 around the right end via hole 793, and the left end via hole 793 is centered around the via hole 793 located at the left end. In this manner, the short-circuit prevention hole 761 is formed. In addition, a joint hole 762 is formed around the via hole 793 located second from the right, with the via hole 793 being the center, and the via hole 793 is located around the via hole 793 located third from the right. The joint hole 762 is formed in such a manner that is centered.

  As described above, the pins 784a to 784d of the one-row connector 782 are inserted into the via holes 793 formed in the center of the short-circuit prevention hole 761 and soldered, so that they are positioned at both ends of the one-row connector 782. The solder fillet 799 formed around the pins 784a and 784d is stronger in the force acting in the left-right direction than the solder fillet 799 formed when the via hole 793 is formed at the end of the short-circuit prevention hole 761. Strong against force. For this reason, the main control board 61 can be a board with a low probability of being broken even if vibration is applied.

  The interval between the four via holes 793 formed in the first row back surface region 869 is 1.5 mm, which is the same as the interval between the four via holes 793 formed in the first row rear surface region 842 in the nineteenth embodiment. Therefore, the main control board 61 can be made to be a board resistant to vibration without adjusting the interval between the pins 784a to 784d of the one-row connector 782 before the soldering process.

<20th Embodiment>
The present embodiment is different from the nineteenth embodiment in that a joining hole 762 and a separate short prevention hole 871 are formed instead of the short prevention hole 761. Hereinafter, the description of the same configuration as that of the nineteenth embodiment is omitted.

  The main control board 61 of this embodiment includes a printed wiring board 872. In the printed wiring board 872, around the pins 784a and 784d (FIG. 89 (a)) at both ends of the one-row connector 782, and around the two pins 784e and 784f (FIG. 89 (b)) of the two-pole connector 781. In addition, separate short-circuit prevention holes for suppressing the occurrence of solder bridges 751 (FIG. 95 (c)) are respectively formed around the pins 784g, 784j, 784k, and 784p at both ends in each row of the two-row connector 783. 871,874 are formed. A configuration around the one-row connector 782 of the printed wiring board 872 will be described with reference to FIGS. 99 (a) and 99 (b). FIG. 99A is a back view of the printed wiring board 872 showing the back surface area 873 for one row in an enlarged manner, and FIG. 99B is a printed wiring board showing the periphery of the pins 784 of the single row connector 782 in an enlarged manner. FIG. Here, in FIGS. 99A and 99B, the wiring pattern 776 and the GND solid 851 (FIG. 92B) are not shown.

  First, the shape of the joint hole 762 formed in the printed wiring board 872 of the main control board 61 will be described. As shown in FIG. 99A, four via holes 793 are formed in the printed wiring board 872 so as to insert the four pins 784a to 784d provided in the one-row connector 782. The via holes 793 are arranged in the left-right direction at intervals of 1.5 mm.

  In the printed wiring board 872, joint holes 762 are formed around the four via holes 793. The joint hole 762 is a circular hole that is slightly larger than the via hole 793, and the via hole 793 is formed so as to be positioned at the center of the joint hole 762.

  Regarding the four pins 784a to 784d constituting the one-row connector 782, the pin 784 arranged nth from the right is referred to as an nth pin 784. For example, the pin 784 arranged second from the right is the second pin 784b. In addition, regarding the four via holes 793 formed in the printed wiring board 872, the nth via hole 793 formed from the right is referred to as an nth via hole 793. For example, the third via hole 793 formed from the right is the third via hole 793c. Further, the joint hole 762 formed around the nth via hole 793 is referred to as an nth joint hole 762. For example, the joint hole 762 formed around the fourth via hole 793d is the fourth joint hole 762d. Here, n is a natural number of 1 to 4.

  Four via holes 793a to 793d are arranged in one row in the left-right direction in the rear surface region 873 for one row of the printed wiring board 872, and a first via hole 793a is formed at the right end of the row of the via holes 793a to 793d. In addition, a fourth via hole 793d is formed at the left end. A separation-type short-circuit prevention hole 871, which is a short-circuit prevention hole separated from the fourth joint hole 762d, is formed in the vicinity of the left side of the fourth via hole 793d located at the left end of the row of the via holes 793a to 793d. The separation-type short-circuit prevention hole 871 has a semicircular reservoir 871a having a diameter larger than that of the joint hole 762, and a contraction that continues to the reservoir 871a and gradually decreases in width toward the fourth joint hole 762d. And a width portion 871b. The reduced width portion 871b has substantially the same width as the diameter of the reservoir portion 871a in the vertical direction of the back surface region 873 for one row in a region continuous with the reservoir portion 871a. The distance LD1 from the right end of the reduced width portion 871b to the left end of the fourth joint hole 762d is shorter than the distance LD2 from the right end of the fourth joint hole 762d to the left end of the third joint hole 762c.

  Further, a separation-type short-circuit prevention hole 874 that is a short-circuit prevention hole separated from the first joint hole 762a is formed in the vicinity of the right side of the first via hole 793a located at the right end of the row of the via holes 793a to 793d. The separation-type short-circuit prevention hole 874 has a semicircular reservoir portion 874a having a diameter larger than that of the joint hole 762, and a contraction that continues to the reservoir portion 874a and gradually decreases in width toward the first joint hole 762a. And a width portion 874b. The reduced width portion 874b has a width substantially the same as the diameter of the reservoir portion 874a in the vertical direction of the back surface region 873 for one row in a region continuous with the reservoir portion 874a. Further, the distance LD1 from the left end of the reduced width portion 871b to the right end of the first joint hole 762a is shorter than the distance LD2 from the left end of the first joint hole 762a to the right end of the second joint hole 762b.

  Next, in the soldering process, when the printed wiring board 872 is conveyed rightward and the fourth pin 784d of the one-row connector 782 is positioned at the rear end in the conveying direction, the printed wiring board 872 is positioned at the rear end in the conveying direction. A mechanism for suppressing the generation of the solder bridge 751 around the fourth pin 784d will be described below with reference to FIG. In the soldering step, the fourth joint hole 762d formed around the fourth pin 784d and the rear thereof just before the fourth pin 784d of the one-row connector 782 comes out of contact with the jet 821 (FIG. 93B). A separation-type short-circuit prevention hole 871 formed in the vicinity is in contact with the jet 821.

  Immediately after the fourth pin 784d of the first row connector 782 comes out of contact with the jet 821, the molten solder attached on the fourth joint hole 762d and the molten solder attached on the separation type short prevention hole 871 are provided. As a result, the molten solder attached on the fourth joint hole 762d and the molten solder attached on the separation-type short-circuit prevention hole 871 are in an independent state via an intermediate state where the two are continuous.

  In an intermediate state before the molten solder attached on the fourth joint hole 762d becomes an independent state, the molten solder remaining around the fourth pin 784d is separated from the fourth joint hole 762d and the separate short-circuit prevention hole 871. Divided into top and bottom. For this reason, as compared with the configuration in which the separation-type short-circuit prevention hole 871 is not formed around the fourth joint hole 762d, by using the separation-type short-circuit prevention hole 871, as shown in FIG. The amount of molten solder adhering to the fourth joint hole 762d can be reduced, and the possibility that excessive molten solder that causes the solder bridge 751 to be generated on the fourth joint hole 762d can be reduced.

  As already described in FIG. 99 (a), the separation-type short-circuit prevention hole 871 is formed so as not to be continuous with the fourth joint hole 762d, and the molten solder once moved on the separation-type short-circuit prevention hole 871 The structure is difficult to move over the four joint holes 762d. With this configuration, the possibility that the molten solder cannot be accommodated on the fourth joint hole 762d and the solder bridge 751 is formed is reduced.

  Here, as shown in FIG. 99 (a), the separation-type short-circuit prevention hole 871 has an area larger than that of the fourth joint hole 762d. For this reason, it is possible to increase the amount of molten solder that moves onto the separation-type short-circuit prevention hole 871 in the intermediate state, and to decrease the amount of molten solder that moves onto the fourth joint hole 762d. Accordingly, it is possible to reduce a possibility that excessive molten solder that causes the solder bridge 751 to be generated on the fourth joint hole 762d.

  As shown in FIG. 99 (a), the reservoir portion 871a has a larger area than the reduced width portion 871b and has a large width in the vertical direction of the back surface region 873 for one row. As shown in b), most of the molten solder collected on the separation-type short-circuit prevention hole 871 moves onto the reservoir 871a due to the surface tension of the molten solder.

  As shown in FIG. 99 (a), in order to hold most of the molten solder collected on the separation-type short prevention hole 871 at a position away from the molten solder collected on the fourth joint hole 762d, 871a is provided at a position farther from the fourth joint hole 762d than the reduced width portion 871b. Thereby, the possibility that the molten solder on the separation-type short-circuit prevention hole 871 contacts the molten solder on the fourth joint hole 762d and moves toward the fourth joint hole 762d is reduced.

  As shown in FIG. 99 (a), when excess molten solder is generated on the fourth joint hole 762d, the excess molten solder is shrunk in order to move in a different direction from the third joint hole 762c. The distance LD1 from the width portion 871b to the fourth joint hole 762d is set shorter than the distance LD2 from the fourth joint hole 762d to the third joint hole 762c.

  In the soldering process, when the printed wiring board 872 is transported in the left direction, the first via hole 793a positioned at the right end of the back surface region 873 for one row is positioned at the rear end in the transport direction. As shown in FIG. 99 (a), a separation-type short-circuit prevention hole 874 is formed in the vicinity of the right side of the first joint hole 762a in order to suppress the generation of the solder bridge 751 around the first via hole 793a. ing.

  The separation-type short-circuit prevention hole 874 formed near the right side of the first joint hole 762a has the same size and shape as the separation-type short-circuit prevention hole 871 formed near the left side of the fourth joint hole 762d. doing. The separation-type short-circuit prevention hole 874 has a reservoir portion 874a that is smaller than the reduced-width portion 874b in order to hold most of the molten solder adhering to the separation-type short-circuit prevention hole 874 away from the first joint hole 762a. Is also provided in a manner located far from the first joint hole 762a.

  Here, in the substrate provided in the pachinko machine 10 of this embodiment, the pachinko machine of the nineteenth embodiment described above is used as a reference for providing the separation-type short-circuit prevention holes 871, 874 around the pins 784 (FIG. 91). 10, the same standard as that for providing a short-circuit prevention hole 761 (FIG. 92B) around the pin 784 is applied. Specifically, in the board provided in the pachinko machine 10 of the present embodiment, when a single-row connector is mounted on the board, the condition that the distance between the centers of the pins 784 is 1.5 mm or less is satisfied. Separate type short-circuit prevention holes 871, 874 (FIG. 99 (a)) are provided around the pins at both ends of the one-line connector. As a result, the possibility that the solder bridge 751 (FIG. 95C) is formed around the pin 784 located at the rear end in the transport direction is reduced. On the other hand, a joint hole 762 (FIG. 90) is provided around the pins 784 of the one-row connector in which the distance between the centers of the pins 784 is wider than 1.5 mm.

  In the board provided in the pachinko machine 10 of the present embodiment, when a two-pole connector is mounted on the board, the two-pole connector that satisfies the condition that the distance between the centers of the pins 784 is 2.5 mm or less These two pins 784 are provided with separate short-circuit prevention holes 871, 874 (FIG. 99 (a)). As a result, the possibility that the solder bridge 751 (FIG. 95C) is formed around the pin 784 located at the rear end in the transport direction is reduced. On the other hand, joint holes 762 (FIG. 90) are provided around the pins 784 of the two-pole connector in which the distance between the centers of the pins 784 is wider than 2.5 mm.

  In the board provided in the pachinko machine 10 of the present embodiment, the two-row connector is mounted on the board, and the distance between the centers of the pins 784 in each row is 1.5 mm or less, or When at least one of the conditions that the distance between the centers of the pins 784 located at the ends of each row is 2.5 mm or less is satisfied, around the pins 784 located at both ends of each row of the two-row connector Are provided with separate short-circuit prevention holes 871, 874 (FIG. 99 (a)). As a result, the possibility that the solder bridge 751 (FIG. 95C) is formed around the pin 784 located at the rear end in the transport direction is reduced. On the other hand, when the distance between the centers of the pins 784 in each row is wider than 1.5 mm and the distance between the centers of the pins 784 located at the ends of each row is wider than 2.5 mm, A joining hole 762 (FIG. 90) is provided.

  According to the embodiment described in detail above, the following excellent effects are obtained.

  In the left end of the back surface region 873 for one row, the separation-type short-circuit prevention hole 871 is provided on the left side of the fourth joint hole 762d so as not to be continuous with the fourth joint hole 762d. As a result, the amount of molten solder adhering to the fourth joint hole 762d is reduced, and the possibility that excessive molten solder that causes the solder bridge 751 to be generated on the fourth joint hole 762d is reduced. it can. Since the fourth joint hole 762d and the separation-type short-circuit prevention hole 871 are not continuous, it is possible to reduce the possibility that the molten solder once moved onto the separation-type short-circuit prevention hole 871 returns to the fourth joint hole 762d. This can reduce the possibility that excessive molten solder is generated on the fourth joint hole 762d and the solder bridge 751 is formed.

  Since the area of the separation-type short-circuit prevention hole 871 is set to be larger than the area of the fourth joint hole 762d, the molten solder moving on the separation-type short-circuit prevention hole 871 in the intermediate state where the solder fillet 798 is formed is formed. The amount can be increased to reduce the amount of molten solder that moves over the fourth joint hole 762d. Accordingly, it is possible to reduce the possibility of excessive molten solder that causes the solder bridge 751 being generated on the fourth joint hole 762d.

  In the separation-type short-circuit prevention hole 871, the reservoir 871a has a larger area than the reduced width portion 871b, and holds more molten solder than the reduced width portion 871b. The reservoir 871a is provided farther leftward from the fourth joint hole 762d than the reduced width portion 871b. For this reason, most of the molten solder collected on the separation-type short-circuit prevention hole 871 is held in a state separated from the molten solder collected on the fourth joint hole 762d. As described above, the configuration in which the amount of the molten solder existing on the fourth joint hole 762d is difficult to increase prevents the molten solder from being stored on the fourth joint hole 762d. Occurrence can be suppressed.

  The distance LD1 from the reduced width portion 871b to the fourth joint hole 762d is set shorter than the distance LD2 from the fourth joint hole 762d to the third joint hole 762c. For this reason, the excessive molten solder generated on the fourth joint hole 762d is merged with the molten solder on the separation-type short-circuit prevention hole 871, and the excessive molten solder is combined with the molten solder on the third joint hole 762c. It can be prevented from joining. Accordingly, it is possible to reduce the possibility that the solder bridge 751 is formed between the pin 784d inserted through the fourth joint hole 762d and the pin 784c inserted through the third joint hole 762c.

  In the right end of the back surface region 873 for one row, the separation-type short-circuit prevention hole 874 is provided on the right side of the first joint hole 762a so as not to be continuous with the first joint hole 762a. Thereby, even if the printed wiring board 872 is conveyed leftward in the soldering process, it is possible to suppress the generation of the solder bridge 751 around the first via hole 793a that is positioned at the rear end in the conveying direction. Can do.

<Another embodiment of the twentieth embodiment>
In the twentieth embodiment described above, the number of separation-type short-circuit prevention holes 871 formed in the vicinity of the fourth joint hole 762d is not limited to one. Further, the number of separation type short circuit prevention holes 874 formed in the vicinity of the first joint hole 762a is not limited to one. For example, a left separation type short circuit prevention hole 886, an upper left separation type short circuit prevention hole 875, and a lower left separation having the same size and shape as the separation type short circuit prevention hole 871 of the twentieth embodiment in the vicinity of the fourth joint hole 762d. The right-side separation type short-circuit prevention hole having the same size and shape as the separation-type short-circuit prevention hole 874 of the twentieth embodiment is provided near the first joint hole 762a. 887, an upper right separation type short-circuit prevention hole 877, and a lower right separation type short-circuit prevention hole 878 may be provided. The configuration will be described with reference to FIG.

  FIG. 100 (a) is a back view of the printed wiring board 879 showing an enlargement of the back surface region 885 for one row in which six separate short-circuit prevention holes 875-878, 886, 887 are formed. Here, in FIG. 100A, illustration of the wiring pattern 776 and the GND solid 851 (FIG. 92B) is omitted. As shown in FIG. 100 (a), in the vicinity of the left side of the fourth joint hole 762d, the separation-type short-circuit prevention hole 871 already described in the twentieth embodiment is formed as the left-side separation-type short-circuit prevention hole 886. Yes. In addition, an upper left separation type short-circuit prevention hole 875 is formed obliquely above and to the left of the fourth joint hole 762d, and a lower left separation type short-circuit prevention hole 876 is formed obliquely below and to the left of the fourth joint hole 762d. .

  The upper left separation type short-circuit prevention hole 875 includes an upper left reservoir portion 875a and an upper left reduced width portion 875b, and the width of the upper left reduced width portion 875b gradually decreases toward the fourth joint hole 762d. It is provided close to the joint hole 762d. In the upper left separated short-circuit prevention hole 875, the upper left reservoir 875a is provided at a position farther leftward from the fourth joint hole 762d than the upper left reduced width portion 875b. The lower left separation type short-circuit prevention hole 876 includes a lower left reservoir portion 876a and a lower left reduced width portion 876b, and the width of the lower left reduced width portion 876b gradually decreases toward the fourth joint hole 762d. It is provided close to the fourth joint hole 762d. In the lower left separation type short-circuit prevention hole 876, the lower left reservoir portion 876a is provided at a position farther left from the fourth joint hole 762d than the lower left reduced width portion 876b.

  Further, the separation-type short-circuit prevention hole 874 already described in the twentieth embodiment is formed as a right-side separation-type short-circuit prevention hole 887 near the right side of the first joint hole 762a. Further, an upper right separation type short-circuit prevention hole 877 is formed on the upper right side of the first joint hole 762a, and a lower right separation type short circuit prevention hole 878 is formed on the lower right side of the first joint hole 762a. Yes.

  The right upper separation-type short-circuit prevention hole 877 includes an upper right reservoir 877a and an upper right reduced width portion 877b. It is provided close to the joint hole 762a. In the upper right separated short-circuit prevention hole 877, the upper right reservoir 877a is set at a position farther to the upper right from the first joint hole 762a than the upper right reduced width portion 877b. The lower right separated short-circuit prevention hole 878 includes a lower right reservoir portion 878a and a lower right reduced width portion 878b, and the width of the lower right reduced width portion 878b gradually increases toward the first joint hole 762a. In a decreasing manner, it is set close to the first joint hole 762a. In the lower right separated short-circuit prevention hole 878, the lower right reservoir portion 878a is set at a position farther to the lower right from the first joint hole 762a than the lower right reduced width portion 878b.

  As described above, the left separation type short-circuit prevention hole 886, the upper left separation type short-circuit prevention hole 875, and the lower left separation type short-circuit prevention hole 876 are formed around the fourth joint hole 762d. When excessive molten solder adheres, the excess molten solder is pulled in three directions different from the third joint hole 762c adjacent to the fourth joint hole 762d, and is moved to the three reservoirs 875a, 876a, and 886a. Can be stored. For this reason, even if excessive molten solder adheres to the fourth joint hole 762d, the molten solder is prevented from joining the molten solder on the adjacent third joint hole 762c to generate the solder bridge 751. Can do.

  When the printed wiring board 879 is transported in the left direction in the soldering process, the first joint hole 762a is located at the rear end in the transport direction in the back surface region 885 for one row. When excessive molten solder adheres on the first joint hole 762a, the excess molten solder is pulled in three directions different from the second joint hole 762b adjacent to the first joint hole 762a. It can be stored in the reservoirs 877a, 878a, 887a. For this reason, even if excess molten solder adheres to the first joint hole 762a, the molten solder is prevented from joining the molten solder on the adjacent second joint hole 762b to generate the solder bridge 751. Can do.

  -It is good also as a structure which replaces with the separation-type short circuit prevention hole 871 of 20th Embodiment mentioned above, and sets the 3 direction separation-type short circuit prevention hole 881 surrounding the circumference | surroundings of the 4th joint hole 762d from 3 directions. The three-way separation type short-circuit prevention hole 881 will be described with reference to FIG.

  The printed wiring board 882 is different from the printed wiring board 872 of the twentieth embodiment in that the printed wiring board 882 includes a back surface region 883 for one row in which two three-way separation type short-circuit prevention holes 881 and 884 are formed. FIG. 100B is a rear view of the printed wiring board 882 showing an enlarged one-row rear surface area 883 in which two three-way separation type short-circuit prevention holes 881 and 884 are formed. Here, in FIG. 100B, illustration of the wiring pattern 776 and the GND solid 851 (FIG. 92B) is omitted.

  First, in the printed wiring board 882, the configuration around the fourth joint hole 762d located at the left end of the back surface region 883 for one row will be described. As shown in FIG. 100 (b), the left side having a U-shape around the fourth joint hole 762d, which surrounds the upper, left, and lower sides of the fourth joint hole 762d. A three-way separation type short-circuit prevention hole 881 is formed. The left three-way separation type short-circuit prevention hole 881 includes an upper part 881a located above the fourth joint hole 762d, a left part 881b located to the left of the fourth joint hole 762d, and a lower part of the fourth joint hole 762d. And a lower portion 881c located at the bottom. Between the fourth joint hole 762d and the upper part 881a of the left three-way separation type short-circuit prevention hole 881, between the fourth joint hole 762d and the left part 881b, and between the fourth joint hole 762d and the lower part 881c. Is shorter than the distance from the right end of the fourth joint hole 762d to the left end of the third joint hole 762c. Further, the total area of the left three-way separation type short-circuit prevention hole 881 is larger than the area of the joint hole 762.

  In the left three-way separation type short-circuit prevention hole 881, the upper portion 881a, the left portion 881b, and the lower portion 881c have a convex portion 881d extending toward the fourth joint hole 762d in a manner that is not continuous with the fourth joint hole 762d. I have.

  If excessive molten solder adheres to the fourth pin 784d of the one-row connector 782 and cannot fit in the fourth joint hole 762d, the excess molten solder has a different direction from the third joint hole 762c and the fourth By contacting the molten solder on the left three-way separation type short-circuit prevention hole 881 having a larger area than the joining hole 762, it is possible to draw excess molten solder into the left three-way separation type short-circuit prevention hole 881. it can.

  The convex part 881d of the upper part 881a, the left part 881b, and the lower part 881c approaches the fourth joint hole 762d from three directions, and the convex part 881d is a fourth joint hole rather than the third joint hole 762c. It is located near 762d. Thereby, the probability that the molten solder generated on the fourth joint hole 762d moves in three directions different from the third joint hole 762c can be increased.

  By adopting a configuration in which surplus molten solder generated on the fourth joint hole 762d is not directed to the adjacent third joint hole 762c, the surplus molten solder moves onto the third joint hole 762c and solder bridge 751 is obtained. Can be reduced.

  In addition, since the molten solder drawn in three different directions in contact with the three convex portions 881d is held in the common left three-way separation type short-circuit prevention hole 881, the generation of the solder bridge 751 in the printed wiring board 882 is prevented. The area occupied by the configuration for suppression can be minimized, and the printed wiring board 882 can be increased in density.

  Next, in the printed wiring board 882, the configuration around the first joint hole 762a located at the right end of the back surface region 883 for one row will be described. As shown in FIG. 100 (b), the right side having a U-shape surrounding the first joint hole 762a around the upper side, the right side, and the lower side around the first joint hole 762a. A three-way separation type short-circuit prevention hole 884 is formed. The right three-way separation type short-circuit prevention hole 884 includes an upper part 884a located above the first joint hole 762a, a right part 884b located right of the first joint hole 762a, and a lower part of the first joint hole 762a. And a lower portion 884c located at the bottom. Between the first joint hole 762a and the upper part 884a of the right three-way separation type short-circuit prevention hole 884, between the first joint hole 762a and the right part 884b, and between the first joint hole 762a and the lower part 884c. Is shorter than the distance from the right end of the first joint hole 762a to the right end of the third joint hole 762c. Further, the total area of the right three-way separation type short-circuit prevention hole 884 is larger than the area of the joint hole 762.

  In the right three-way separation type short-circuit prevention hole 884, the upper part 884a, the right part 884b, and the lower part 884c have a convex part 884d extending toward the first joint hole 762a in a manner not continuous with the first joint hole 762a. I have.

  When the printed wiring board 882 is transported in the left direction in the soldering process, the first joint hole 762a is positioned at the rear end in the transport direction in the back surface region 883 for one row. In the same manner as the left three-way separation type short-circuit prevention hole 881 is provided around the fourth joint hole 762d, the first joint is obtained by providing the right three-way separation type short-circuit prevention hole 884 around the first joint hole 762a. Even if excessive molten solder adheres to the hole 762a, it is possible to prevent the molten solder from joining the molten solder on the adjacent second joint hole 762b and generating the solder bridge 751.

  Since the molten solder drawn in three different directions in contact with the three protrusions 884d is held in the common right-side three-way separation type short-circuit prevention hole 884, the solder bridge 751 is formed at the right end of the back surface region 883 for one row. The area occupied by the configuration for suppressing the generation in the printed wiring board 882 can be minimized, and the density of the printed wiring board 882 can be increased.

<Twenty-first embodiment>
The present embodiment is different from the nineteenth embodiment in that short-circuit prevention hole groups 891 to 895 and 921 to 925 are formed instead of the short-circuit prevention holes 761. Hereinafter, the description of the same configuration as that of the nineteenth embodiment is omitted.

  The main control board 61 of this embodiment includes a printed wiring board 897. In the printed wiring board 897, around the pins 784a and 784d (FIG. 89 (a)) at both ends of the one-row connector 782, and around the two pins 784e and 784f (FIG. 89 (b)) of the two-pole connector 781. And a short-circuit prevention hole group 891 for suppressing the occurrence of the solder bridge 751 (FIG. 95C) around the pins 784g, 784j, 784k, and 784p at both ends in each row of the two-row connector 783. ˜895, 921 to 925 are formed. A configuration around the one-row connector 782 of the printed wiring board 897 will be described with reference to FIG. FIG. 101 is a back view of the printed wiring board 897 showing an enlarged view of the back surface region 896 for one row in which short-circuit prevention hole groups 891 to 895 and 921 to 925 for suppressing the generation of the solder bridge 751 are formed. Here, in FIG. 101, illustration of the wiring pattern 776 and the GND solid 851 (FIG. 92B) is omitted.

  As shown in FIG. 101, via holes 793a to 793d through which the four pins 784a to 784d (FIG. 89 (a)) of the one-row connector 782 are inserted are formed in the one-row rear surface region 896. In the rear surface region 896 for one row, the four via holes 793a to 793d are arranged in one row in the left-right direction, and the interval between the via holes 793a to 793d in the row is 1.5 mm.

  As shown in FIG. 101, regarding the four via holes 793a to 793d, the via hole arranged in the nth order from the right is defined as the nth via hole. For example, the via hole lined up to the right is the first via hole 793a. Here, n is a natural number of 1 to 4.

  As shown in FIG. 101, a circular bonding hole 762 is formed around the second via hole 793b and the third via hole 793c. The joint hole 762 has a larger area than the via holes 793b and 793c, and the via hole 793b and 793c are formed in a manner positioned in the center of the joint hole 762.

  Short-circuit prevention hole groups 891 to 895 are formed on the left side of the fourth via hole 793d located at the left end of the row of the via holes 793a to 793d. In addition, short-circuit prevention hole groups 921 to 925 are formed on the right side of the first via hole 793a located at the right end of the row of the via holes 793a to 793d. First, the short-circuit prevention hole group 891 to 895 formed on the left side of the fourth via hole 793d will be described.

  As shown in FIG. 101, a small short-circuit prevention hole 891 having the same size and shape as the joint hole 762 is formed around the fourth via hole 793d. The small short prevention hole 891 is formed in such a manner that the fourth via hole 793d is located at the center of the small short prevention hole 891. On the left side of the small short-circuit prevention hole 891, a large short-circuit prevention hole 892 having a larger area than the small short-circuit prevention hole 891 is formed. The small short-circuit prevention hole 891 and the large short-circuit prevention hole 892 are small-sized short-circuit prevention holes. They are connected by a first passage region 894 having a passage width smaller than the diameter of the hole 891.

  Further, an intermediate short-circuit prevention hole 893 having an area larger than that of the small short-circuit prevention hole 891 and having an area smaller than that of the large-sized short-circuit prevention hole 892 is formed on the right upper side and the lower right side of the large short-circuit prevention hole 892. The large short-circuit prevention hole 892 and the medium-sized short-circuit prevention hole 893 are connected by a second passage region 895 having a passage width wider than that of the first passage region 894.

  In the soldering process, when the printed wiring board 897 is transported in the right direction, the fourth pin 784d (FIG. 89A) located at the left end of the one-row connector 782 is located at the rear end in the transport direction. Will be. In this case, in the one-row connector 782, when the fourth pin 784d located at the rear end in the transport direction comes out of contact with the jet 821 (FIG. 93 (a)), the small short prevention hole 891 and the middle short prevention hole 893 And the molten solder adheres to the large-sized short-circuit prevention hole 892. Since a large amount of the molten solder remains on the hole having a large area, the amount of the molten solder remaining on the small short-circuit prevention hole 891 and on the medium-sized short-circuit prevention hole 893 is the amount of the molten solder remaining on the large short-circuit prevention hole 892. Less than the amount.

  The molten solder lump remaining on the small short-circuit prevention hole 891 is connected to the molten solder lump remaining on the large short-circuit prevention hole 892 by the first passage region 894. The molten solder lump remaining on the medium-sized short-circuit prevention hole 893 is connected to the molten solder lump remaining on the large-sized short-circuit prevention hole 892 by the second passage region 895.

  The molten solder has a surface tension, and when a small molten solder lump and a large molten solder lump contact, the molten solder moves from the small molten solder lump toward the large molten solder lump. Therefore, after the fourth pin 784d of the first row connector 782 (FIG. 89 (a)) comes out of contact with the jet 821, the molten solder attached around the fourth pin 784d is cooled and solidified. In the meantime, the molten solder moves from the small short prevention hole 891 and the medium short prevention hole 893 toward the large short prevention hole 892.

  In a configuration in which a small area hole is formed around the pin located at the rear end of the conveyance direction and a large area hole is formed downstream of the small area hole, the small area is caused by dynamic factors. After the molten solder moves from the hole in the large area to the hole in the large area, excess molten solder generated in the large area hole flows back toward the hole in the small area, and solders around the pin located at the rear end in the transport direction. A bridge 751 (FIG. 95 (c)) may be formed.

  On the other hand, as shown in FIG. 101, when excess molten solder is generated in the large short-circuit prevention hole 892 after the molten solder moves from the small short-circuit prevention hole 891 to the large short-circuit prevention hole 892, the second passage region The passage width of 895 is wider than the passage width of the first passage region 894, and the area of the two medium-sized short circuit prevention holes 893 is larger than the area of the small short circuit prevention hole 891, so that the back flow destination of the excess molten solder is mainly the medium size. A short-circuit prevention hole 893 is formed. As a result, the amount of molten solder that flows backward from the large short-circuit prevention hole 892 toward the small short-circuit prevention hole 891 can be reduced. The possibility that the molten solder flows backward from the large-sized short-circuit prevention hole 892 and the solder bridge 751 is formed around the fourth pin 784d of the one-row connector 782 can be reduced.

  Next, the short-circuit prevention hole group 921 to 925 formed on the right side of the first via hole 793a will be described. As shown in FIG. 101, a small short-circuit prevention hole 921 having the same size and shape as the joint hole 762 is formed around the first via hole 793a. The small short prevention hole 921 is formed in such a manner that the first via hole 793a is located at the center of the small short prevention hole 921. A large short-circuit prevention hole 922 having a larger area than the small short-circuit prevention hole 921 is formed on the right side of the small short-circuit prevention hole 921. The small short-circuit prevention hole 921 and the large short-circuit prevention hole 922 are small-sized short-circuit prevention holes. They are connected by a first passage region 924 having a passage width smaller than the diameter of the hole 921.

  In addition, an intermediate short-circuit prevention hole 923 having an area larger than that of the small short-circuit prevention hole 921 and smaller than that of the large-sized short-circuit prevention hole 922 is formed on the upper right and lower right of the large-sized short-circuit prevention hole 922. The large-sized short-circuit prevention hole 922 and the medium-sized short-circuit prevention hole 923 are connected by a second passage region 925 having a passage width wider than that of the first passage region 924.

  In the soldering process, when the printed wiring board 897 is transported in the left direction, the first pin 784a (FIG. 89A) positioned at the right end of the one-row connector 782 is positioned at the rear end in the transport direction. Will be.

  Since a short-circuit prevention hole group 921 to 925 is formed on the right side of the first via hole 793a, when the printed wiring board 897 is conveyed toward the left side in the soldering process, the small short-circuit prevention hole 921 is formed. The amount of molten solder flowing backward from the large short-circuit prevention hole 922 can be reduced. Then, the possibility that the molten solder flows backward from the large-sized short-circuit prevention hole 922 and the solder bridge 751 is formed around the first pin 784a of the one-row connector 782 can be reduced.

  Here, in the substrate provided in the pachinko machine 10 of the present embodiment, the reference for providing the short-circuit prevention hole groups 891 to 895 and 921 to 925 around the pin 784 (FIG. 91) is based on the nineteenth embodiment described above. The same standard as that for providing the short-circuit prevention hole 761 (FIG. 92B) around the pin 784 is applied to the substrate included in the pachinko machine 10. Specifically, in the board provided in the pachinko machine 10 of the present embodiment, when a single-row connector is mounted on the board, the condition that the distance between the centers of the pins 784 is 1.5 mm or less is satisfied. Short-circuit prevention hole groups 891 to 895 and 921 to 925 (FIG. 101) are provided around the pins at both ends of the one row connector. For this reason, the amount of molten solder that flows backward from the large short-circuit prevention holes 892 and 922 around the pin 784 located at the rear end in the transport direction decreases toward the small short-circuit prevention holes 891 and 921. As a result, the possibility that the solder bridge 751 (FIG. 95C) is formed around the pin 784 located at the rear end in the transport direction is reduced. On the other hand, a joint hole 762 (FIG. 90) is provided around the pins 784 of the one-row connector in which the distance between the centers of the pins 784 is wider than 1.5 mm.

  In the board provided in the pachinko machine 10 of the present embodiment, when a two-pole connector is mounted on the board, the two-pole connector that satisfies the condition that the distance between the centers of the pins 784 is 2.5 mm or less Around these two pins 784, short-circuit prevention hole groups 891 to 895, 921 to 925 (FIG. 101) are provided. For this reason, the amount of molten solder that flows backward from the large short-circuit prevention holes 892 and 922 around the pin 784 located at the rear end in the transport direction decreases toward the small short-circuit prevention holes 891 and 921. As a result, the possibility that the solder bridge 751 (FIG. 95C) is formed around the pin 784 located at the rear end in the transport direction is reduced. On the other hand, joint holes 762 (FIG. 90) are provided around the pins 784 of the two-pole connector in which the distance between the centers of the pins 784 is wider than 2.5 mm.

  In the board provided in the pachinko machine 10 of the present embodiment, the two-row connector is mounted on the board, and the distance between the centers of the pins 784 in each row is 1.5 mm or less, or When at least one of the conditions that the distance between the centers of the pins 784 located at the ends of each row is 2.5 mm or less is satisfied, around the pins 784 located at both ends of each row of the two-row connector Are provided with short-circuit prevention hole groups 891 to 895, 921 to 925 (FIG. 101). For this reason, the amount of molten solder that flows backward from the large short-circuit prevention holes 892 and 922 around the pin 784 located at the rear end in the transport direction decreases toward the small short-circuit prevention holes 891 and 921. As a result, the possibility that the solder bridge 751 (FIG. 95C) is formed around the pin 784 located at the rear end in the transport direction is reduced. On the other hand, when the distance between the centers of the pins 784 in each row is wider than 1.5 mm and the distance between the centers of the pins 784 located at the ends of each row is wider than 2.5 mm, A joining hole 762 (FIG. 90) is provided.

  According to the embodiment described in detail above, the following excellent effects are obtained.

  A small short prevention hole 891 and a large short prevention hole 892 formed around the fourth via hole 793d are connected by a first passage region 894 having a narrow passage width, and the large short prevention hole 892 and the medium short prevention hole 893. Are connected by a second passage region 895 having a wide passage width. For this reason, the molten solder remaining in the small short-circuit prevention hole 891 is likely to move to the large short-circuit prevention hole 892. In addition, since excessive molten solder that can be generated in the large short-circuit prevention hole 892 moves preferentially to the medium-sized short-circuit prevention hole 893, the occurrence of reverse flow of the molten solder from the large short-circuit prevention hole 892 to the small short-circuit prevention hole 891 is suppressed. Has been. For this reason, in the soldering process, when the fourth pin 784d of the one-row connector 782 is positioned at the rear end in the transport direction, there is a possibility that the solder bridge 751 is formed around the fourth pin 784d. Can be reduced.

  In addition, a short-circuit prevention hole group 921 to 925 is also set on the right side of the first via hole 793a. For this reason, in the soldering process, when the first pin 784a of the one-row connector 782 is located at the rear end in the transport direction, the reverse flow of the molten solder from the large short-circuit prevention hole 922 to the small short-circuit prevention hole 921 occurs. Generation | occurrence | production can be suppressed and possibility that the solder bridge 751 may be formed around the 1st pin 784a can be reduced.

<Another embodiment of the twenty-first embodiment>
The short-circuit prevention hole group 891 to 895 of the twenty-first embodiment described above includes a small short-circuit prevention hole 891, a large short-circuit prevention hole 892, a medium-sized short-circuit prevention hole 893, and a second passage region 895 excluding the first passage region 894. It may be configured. Specifically, the large short-circuit prevention hole 892 is set not as a hole continuous with the small short-circuit prevention hole 891 but as a hole not continuous with the small short-circuit prevention hole 891. In this case, until the molten solder is solidified in the soldering process, the excess molten solder adhering to the large short-circuit prevention hole 892 passes through the second passage more than the small short-circuit prevention hole 891 that is not in physical contact. It is easy to move toward the medium-sized short-circuit prevention hole 893 that is in physical contact with the region 895. For this reason, it is possible to suppress the excess molten solder attached to the large short-circuit prevention hole 892 in the initial stage from flowing back into the small short-circuit prevention hole 891 and causing the solder bridge 751 to be formed around the fourth pin 784d.

  The number of medium-sized short-circuit prevention holes 893 constituting the short-circuit prevention hole group 891 to 895 of the twenty-first embodiment described above is not limited to two. For example, the number of medium-sized short circuit prevention holes 893 constituting the short circuit prevention hole groups 891 to 895 may be one. In the soldering process, before the molten solder solidifies, the printed wiring board retains one middle-sized short-circuit prevention hole 893 that prevents excess molten solder from moving to the small-sized short-circuit prevention hole 891 on the large-sized short-circuit prevention hole 892. By suppressing the area occupied by the short-circuit prevention hole groups 891 to 895 on 741, it is possible to cope with the higher density of the main control board 61.

<Twenty-second embodiment>
The game board 931 of the present embodiment is provided with a first special figure display unit 932a corresponding to the first operation port 938, and a second special figure display unit 932b corresponding to the second operation port 939. Is provided. In the following description, differences from the first embodiment will be described, and the description of the same configuration as that of the first embodiment will be basically omitted.

  First, the configuration of the game board 931 of this embodiment will be described with reference to FIG. FIG. 102 is a front view of the game board 931 in the present embodiment. On the surface of the game board 931, as in the first embodiment, a guide rail is constituted by the inner rail portion 25 and the outer rail portion 26, and a game ball is launched when the player rotates the operation handle. The game ball B1 (FIG. 53 (a)) launched from the mechanism 27 (FIG. 2) is guided to the upper part of the game area PA by the guide rail.

  The guide rail is formed so that the exit portion thereof faces the upper center of the game area PA on one side of the game area PA. Therefore, as the amount of rotation of the operation handle by the player increases, the arrival position of the game ball B1 in the upper part of the game area PA is determined by the exit portion from the side portion where the exit portion of the guide rail is formed. It shifts to the side of the side opposite to the formed side. The exit portion of the guide rail is provided on the left side of the game area PA.

  As in the first embodiment, the game area PA is provided with a general winning opening 31, a special prize winning device 32, a variable display unit 36, and the like. Here, the game board 931 of the present embodiment is the above in that the second operating port 939 is provided at a location different from the first operating port 938 and that a pair of through gates 935 and 936 are provided. This is different from the first embodiment. These positional relationships will be described below with reference to the position of the variable display unit 36.

  The variable display unit 36 is arranged on the center side of the game area PA so that the flow area of the game ball B1 is secured on the top, bottom, left, and right. That is, in the game area PA, as the flow area of the game ball B1, the flow area 941 above the variable display unit 36, the flow area 942 below the variable display unit 36, the flow area 943 on the left side of the variable display unit 36, and A flow down area 944 on the right side of the variable display unit 36 is provided. The center frame 252 constituting a part of the variable display unit 36 is provided at the lower part of the center frame 252 because the roof unit 253 constituting the part extending from the upper part to the left and right sides extends to the front of the pachinko machine 10. Except for the game ball B1 introduced into the stage, the game ball B1 flowing down the game area PA does not cross or longitudinally cross the variable display unit 36.

  The first working port 938 which is one of the pair of workings 938 and 939 is provided in the lower flow-down region 942 as a first working port device. The first working port 938 corresponds to the first working port 33 (FIG. 3) in the first embodiment. Here, each of the flow areas 941 to 944 is provided with a dispersion member for dispersing the flow direction of the game ball B1 by the collision with the game ball B1, and the flow direction of the game ball B1 is related to the game flow. A guiding member for guiding in a predetermined direction by collision with the sphere B1 is provided. The dispersing member includes the nail 24b, the guiding member includes the roof unit 253, and the decorative member 945 disposed along the outer edge on the lower side of the game area PA. The dispersion member and the guide member can flow down toward the first operation port 938 regardless of the position of the game ball B1 launched from the game ball launching mechanism 27 at the upper part of the game area PA. It is provided as possible.

  That is, the game ball B1 that is launched from the game ball launching mechanism 27 and starts flowing down on the exit portion side of the guide rail, that is, on the left side of the game area PA in the upper part of the game area PA, the upper flow area 941 → the left flow area 943. → The game area PA flows down through the left path (first path) of the lower flow area 942. In this case, the dispersion member and the guide member are provided so that the game ball B1 that will flow down the game area PA through the left path can reach the first operation port 938 depending on the flow mode. It has been. The game ball B1, which is launched from the game ball launching mechanism 27 and starts to flow on the opposite side of the exit portion of the guide rail in the upper part of the game area PA, that is, on the right side of the game area PA, flows downward on the upper flow area 941 → right side. The game area PA flows down through the right path (second path) of the area 944 → the lower flow area 942. In this case, the dispersion member and the guide member are provided so that the game ball B1 that will flow down the game area PA through the right path can reach the first operation port 938 depending on the flow mode. It has been.

  The second working port 939, which is the other of the pair of workings 938, 939, is provided in the right flow area 944 as a second working port device. The second working port 939 corresponds to the second working port 34 (FIG. 3) in the first embodiment. That is, for the second working port 939, an electric accessory 939a is provided as a guide piece made up of a pair of left and right movable pieces. The electric accessory 939a operates between a closed state and an open state in the same manner as the general electric accessory 34a in the first embodiment. Since the trigger and the content of the operation are the same as those of the general electric utility 34a in the first embodiment, the description thereof is omitted. In this case, a nail 24b is provided above the second operation port 939, and when the electric accessory 939a is in a closed state, a winning (entering the game ball B1) to the second operation port 939 is performed by the nail 24b. Sphere) is not possible. Note that a configuration may be adopted in which winning is not difficult and winning is difficult.

  Here, as already described, since the second operation port 939 is provided in the right flow area 944, the second operation port 939 is fired from the game ball launch mechanism 27 and is opposite to the exit portion of the guide rail in the upper part of the game area PA, that is, the game The game ball B1 (FIG. 53 (a)) that has started to flow down on the right side of the area PA can flow down toward the second operation port 939, but is launched from the game ball launching mechanism 27 and is released from the game area PA. In the upper part, the game ball B1 that has started to flow down on the exit portion side of the guide rail, that is, on the left side of the game area PA cannot flow down toward the second operation port 939.

  As described above, the winning to the first operating port 938 can occur regardless of whether the game ball B1 flows on the first path side or the game ball B1 flows on the second path side. On the other hand, winning in the second operating port 939 can occur only when the game ball B1 flows on the second path side. As a result, for the player, by adjusting the amount of rotation of the operation handle, the player aims to win the first operating port 938 while avoiding the winning of the second operating port 939. In addition, the game can be performed with the aim of winning the second operating port 939.

  In the pair of through gates 935 and 936, one first through gate 935 is provided in the left flowing region 943 and the other second through gate 936 is provided in the right flowing region 944. In this case, the second through gate 936 provided in the right flow area 944 is provided on the upstream side of the second operation port 939, but is not limited to this, and from the second operation port 939. May also be provided downstream.

  An internal lottery is performed with the winning of the through gates 935 and 936 as a trigger, and the base map display unit 38a of the base map unit 38 provided in the lower left corner of the game area PA where the game ball B1 does not pass is displayed. Then, the change display of the picture is performed. Then, when the result of the internal lottery is the electrification opening winning, the stop result corresponding to the result is displayed, and the fluctuation display of the general map display unit 38a is finished, the state shifts to the electrified state. In the electric combination open state, the electric combination 939a is opened in a predetermined manner.

  In the universal map unit 38, a universal map hold display section 38b is provided at a position adjacent to the universal map display section 38a. A maximum of four game balls B1 won in the through gates 935 and 936 are reserved, and the reserved number is displayed by turning on the usual figure display unit 38b.

  The pachinko machine 10 according to the present embodiment has already been described in the first embodiment so that the frequency with which the electric accessory 939a of the second working port 939 is opened per unit time is relatively high. A high frequency support mode and a low frequency support mode are set. In the low frequency support mode, the probability of winning a prize to the first operating port 938 is higher than that of the second operating port 939. However, in the high frequency support mode, the second operating port 939 is connected to the second operating port 939. The probability of winning a prize increases.

  A lottery is performed with the winning of the first operating port 938 or the second operating port 939 as a trigger. The lottery result of the winning lottery is clearly shown through display effects in the symbol display device 41 of the special figure unit 932 and the variable display unit 36.

  The special figure unit 932 is provided with a first special figure display unit 932a and a second special figure display unit 932b. The display area of the first special symbol display unit 932a is narrower than the display surface 41a of the symbol display device 41. Similarly, the display area of the second special symbol display unit 932b is narrower than the display surface 41a of the symbol display device 41. Furthermore, the area of the display area including the first special figure display unit 932a and the second special figure display unit 932b is also narrower than the display surface 41a.

  In the first special figure display unit 932a, a winning lottery is performed with the winning of the first operating port 938 as a trigger, and thereby, a variation display or a predetermined display of the pattern is performed. Then, a result corresponding to the lottery result is displayed. In the second special figure display unit 932b, a winning lottery is performed with the winning of the second operating port 939 as a trigger, thereby performing a variation display or a predetermined display of the pattern. Then, a result corresponding to the lottery result is displayed.

  In the special figure unit 932, a first special figure hold display part 932c and a second special figure hold display part 932d are provided at positions adjacent to the first special figure display part 932a and the second special figure display part 932b. . A maximum of four game balls B1 won in the first operation port 938 are reserved, and the number of reserves is displayed when the first special figure reservation display portion 932c is turned on. In addition, the maximum number of game balls B1 won in the second operation port 939 is reserved up to four, and the reserved number is displayed when the second special figure reservation display section 932d is turned on.

  In the symbol display device 41, when the variation display or the predetermined display of the pattern is performed in the first special symbol display unit 932a based on the winning in the first operation port 938, the variation display of the symbol or the predetermined display is performed accordingly. When the second special figure display unit 932b displays a variation or predetermined display of the pattern based on the winning at the second operation port 939, the variation display or the predetermined display of the pattern is performed accordingly. .

  When the winning lottery based on the winning to the first operating port 938 is a big winning winning or a small winning winning, it shifts to the opening / closing execution mode in which the winning to the special electric winning device 32 is possible. Similarly, even when the big win or the small win is won in the winning lottery based on the winning to the second operating port 939, the mode shifts to the opening / closing execution mode in which the special electric prize winning device 32 can be won.

  On the back of the game board 931, a discharge passage portion (not shown) that guides the game ball B1 that has entered the ball to a discharge ball collection portion (not shown) corresponding to each of the first operation port 938 and the second operation port 939. ) Is formed. As shown in FIG. 102, in the discharge passage portion through which the game ball B1 entering the first operation port 938 passes, the first operation port detection sensor 951 for detecting the game ball B1 passing through the discharge passage portion. And a second operation port detection sensor 952 for detecting the game ball B1 passing through the discharge passage portion in the discharge passage portion through which the game ball B1 entering the second operation port 939 passes. Is provided.

  FIG. 103A is an explanatory diagram for explaining a connection mode between the first operation port detection sensor 951 and the second operation port detection sensor 952 and the main control board 61. As shown in FIG. 103 (a), the first working port detection sensor 951 is connected to the main control board 61 via the first harness 951a, and the second working port detection sensor 952 is the same as the first harness 951a. It is connected to the main control board 61 via a different second harness 952a. The first harness 951a is a fluorescent harness having a yellow fluorescent color, and the second harness 952a is a fluorescent harness having a green fluorescent color. The first harness 951a and the second harness 952a have a fluorescent color that can be visually identified. Here, the fluorescent yellow color used in the first harness 951a and the fluorescent green color used in the second harness 952a are not used in other harnesses used in the pachinko machine 10. Color. For this reason, the first harness 951a and the second harness 952a can be distinguished from other harnesses by visual observation.

  As shown in FIG. 103 (a), the first harness 951a is a bundle of two signal wires 958, one end of which is connected to the first working port detection sensor 951, and the other end is a male type. A two-pole connector 953 is provided. The second harness 952a is a bundle of two signal lines 958, one end of which is connected to the second working port detection sensor 952, and the other end is provided with a male two-pole connector 954. . The signal line 958 is covered with an insulator.

  The main control board 61 includes a first working port connector 955 and a second working port detection sensor 952 that are female two-pole connectors for connecting the first working port detection sensor 951 to the main control board 61. A second working port connector 956 that is a female two-pole connector for connection to the main control board 61 is provided. When the two-pole connector 953 of the first harness 951a is connected to the first operating port connector 955 of the main control board 61, the first operating port detection sensor 951 is connected to the main control board 61, and the second harness The second working port detection sensor 952 is connected to the main control board 61 by connecting the two-pole connector 954 of 952 a to the second working port connector 956 of the main control board 61.

  The first working port connector 955 has a yellow fluorescent color similarly to the first harness 951a, and the second working port connector 956 has a green fluorescent color similarly to the second harness 952a. . For this reason, when connecting the first working port detection sensor 951 and the second working port detection sensor 952 to the main control board 61, the yellow first harness 951a is connected to the yellow first working port connector 955, and the green color. The second harness 952a is connected to the green second working port connector 956. Thereby, generation | occurrence | production of the mistake which the connection point of the 1st harness 951a and the 2nd harness 952a interchanges is suppressed. Here, the yellow fluorescent color used for the first working port connector 955 and the green fluorescent color used for the second working port connector 956 are the connectors used in the pachinko machine 10 elsewhere. The color is not used. For this reason, the first working port connector 955 and the second working port connector 956 can be visually distinguished from other connectors, and the occurrence of connection errors is suppressed.

  Two signal lines 958 extending from the first working port detection sensor 951 and two signal lines 958 extending from the second working port detection sensor 952 are combined into one bundle, and four pins 784 (FIG. 91) are provided at one end thereof. A configuration in which a single-row connector is provided is also conceivable. However, in the case of adopting the configuration, it is output from the first working port detection sensor 951 and the second working port detection sensor 952 only by connecting an unauthorized substrate that transmits an unauthorized signal to the main control substrate 61 at one place. It becomes possible to manipulate the signal input to the main control board 61 illegally. On the other hand, in the present embodiment, the number of connectors that need to be connected in order to use the unauthorized board is increased to 2, thereby making it difficult to execute the unauthorized operation.

  In addition, when the signal lines 958 extending from the first working port detection sensor 951 and the second working port detection sensor 952 are configured as one bundle, there is a possibility that the unauthorized substrate cannot be found by being blocked by the bundle of signal lines 958. There is. On the other hand, in this embodiment, the signal lines 958 are subdivided into a bundle in units of the respective operation port detection sensors 951 and 952, so that an illegal substrate can be easily found between the bundles of the signal lines 958.

  The main control board 61 is an electronic circuit mounting board configured by mounting a large number of electronic components on the printed wiring board 957. A mode in which the first working port connector 955 and the second working port connector 956 are mounted on the printed wiring board 957 of the main control board 61 will be described with reference to FIG.

  FIG. 103 (b) shows an enlarged view of the first working port region 961 to which the first working port connector 955 is attached and the second working port region 962 to which the second working port connector 956 is attached. It is a reverse view of the printed wiring board 957. FIG. Here, in FIG. 103 (b), the first working port connector 955 and the second working port connector 955 and the second working port connector 955 and the second working port connector 956 are described with reference to FIG. The state where the solder for fixing the working port connector 956 to the printed wiring board 957 is removed is shown. FIG. 103B shows a state in which the main control board 61 in FIG. 103A is turned upside down. Therefore, there is no horizontal reversal between the main control board 61 in FIG. 103 (a) and the main control board 61 in FIG. 103 (b). The left side of the main control board 61 in FIG. 103 (a) is the left side of the main control board 61 in FIG. 103 (b), and the right side of the main control board 61 in FIG. 103 (a) is the main control in FIG. 103 (b). This is the right side of the substrate 61.

  As shown in FIG. 103 (b), the second working port region 962 is provided on the right side of the first working port region 961. The two-pole connector 953 (FIG. 103 (a)) of the first harness 951a (FIG. 103 (a)) includes a first pin 784q on the right side and a second pin 784r on the left side in the first working port region 961. It has. In addition, the two-pole connector 954 (FIG. 103 (a)) of the second harness 952a (FIG. 103 (a)) includes the first pin 784s on the right side in the second working port region 962 and the second on the left side. A pin 784t is provided.

  As shown in FIG. 103 (b), the printed wiring board 957 has a first via hole 793q in which the first pin 784q of the first harness 951a (FIG. 103 (a)) is inserted into the first working port region 961. And a second via hole 793r through which the second pin 784r is inserted. The printed wiring board 957 includes a first via hole 793s into which the first pin 784s of the second harness 952a (FIG. 103A) is inserted in the second working port region 962, and the second A second via hole 793t into which the pin 784t is inserted is provided. Here, the via holes 793q to 793t of the present embodiment are the same through holes as the via holes 793 (FIG. 90A) already described in the nineteenth embodiment, and penetrate the printed wiring board 957 in the vertical direction. ing.

  As shown in FIG. 103B, in the second working port region 962, the first via hole 793s and the second via hole 793t are arranged in the left-right direction, and the second via hole 793t is provided on the left side of the first via hole 793s. It has been. The distance from the center of the first via hole 793s to the center of the second via hole 793t is 2.5 mm.

  As shown in FIG. 103 (b), around the first via hole 793s, in order to connect the first via hole 793s to the electronic components on the printed wiring board 957, FIG. In FIG. 92 (b) of the nineteenth embodiment, the wiring pattern 776 already described in (1) is formed, and the second via hole 793t is grounded around the second via hole 793t. Thus, a solid GND 851 is formed. On the wiring pattern 776 and the GND plane 851, the solder resist 792 already described in FIGS. 92A and 92B of the nineteenth embodiment is formed. For this reason, molten solder does not adhere to the wiring pattern 776 and the GND plane 851 in the soldering process.

  As shown in FIG. 103 (b), in the second working port region 962, the short circuit already described in FIG. 92 (b) of the nineteenth embodiment is formed around the first via hole 793s and the second via hole 793t. A prevention hole 761 is provided. The short-circuit prevention hole 761 around the second via hole 793t is connected to the GND solid 851 by the connection portion 763 already described in FIGS. 92A and 92B of the nineteenth embodiment.

  In addition to the first working port connector 955 and the second working port connector 956, an electronic component having the terminal 775 already described in FIG. 88 (a) of the nineteenth embodiment is mounted on the printed wiring board 957. Has been. As shown in FIG. 103 (b), in the printed wiring board 957, a via hole 793 into which the electronic component terminal 775 is inserted is provided below the first working port region 961 and the second working port region 962. It has been. The via hole 793 is the through hole already described with reference to FIG. 90A of the nineteenth embodiment, and is the same through hole as the via holes 793q to 793t.

  As shown in FIG. 103 (b), the distance from the via hole 793 around the terminal 775 to the pins 784q and 784r of the first working port connector 955 and the pins 784s and 784t of the second working port connector 956 is the above-mentioned 19th. It is longer than the reference value for providing the short-circuit prevention hole 761 described in the embodiment. In the printed wiring board 957, the joint hole 762 already described in FIG. 92B of the nineteenth embodiment is provided around the via hole 793 through which the terminal 775 of the electronic component is inserted.

  In the printed wiring board 957, even if the terminal 775 exists at the shortest distance from the first via hole 793q or the second via hole 793r in the first working port region 961, from the terminal 775 to the first via hole 793q or the second via hole 793r. Is set to be longer than a reference value for providing the short-circuit prevention hole 761. Further, even if the terminal 775 exists at the shortest distance from the first via hole 793s or the second via hole 793t in the second working port region 962, the distance from the terminal 775 to the first via hole 793s or the second via hole 793t is: It is set to be longer than a reference value for providing the short-circuit prevention hole 761. For this reason, the solder bridge 751 is provided between the pins 784q and 784r of the first working port connector 955 and the pins 784s and 784t of the second working port connector 956 and the terminals 775 of other electronic components existing nearby. Formation is suppressed.

  As already described, in the game board 931, the second operation port 939 is provided in the flow-down area 944 on the right side of the variable display unit 36. The player can aim to win the second operating port 939 by adjusting the amount of rotation of the operation handle. Further, in this embodiment, the type of the jackpot result that can be selected when the jackpot is won is more to the second working port 939 than the case where the winning to the first working port 938 occurs and the winning lottery is performed. It is set so that it is more advantageous for the player when a winning prize is generated and a lottery is performed. Details of the winning lottery will be described later. In the lottery for each game round described later, the hold information acquired based on the winning to the second operating port 939 takes precedence over the holding information acquired based on the winning to the first operating port 938. Is set to For this reason, the player aims at the second operation port 939 with higher expectations than when aiming at the first operation port 938.

  As shown in FIG. 102, in the game area PA, the second operation port detection sensor 952 provided in the flow area 944 on the right side of the variable display unit 36 is configured so that the player aims at the flow area 944 on the right side. The game ball B1 (FIG. 53 (a)) is detected for the first time when the amount of rotation is adjusted. For this reason, while the player is adjusting the rotation amount of the operation handle aiming at the flow-down area 943 on the left side of the variable display unit 36, the solder bridge 751 (FIG. 95 (c)) Even if is formed, there is a possibility that it is not known that a short circuit has occurred. In this case, the malfunction of the main control board 61 is revealed only when the player raises expectation and aims at the flow area 944 on the right side of the variable display unit 36 and wins the second operating port 939. The game is interrupted in a state where the player has high expectations, which gives great disappointment to the player.

  On the other hand, in the present embodiment, as shown in FIG. 103 (b), in the second working port region 962 of the printed wiring board 957, the 19th via hole 793 s and the second via hole 793 t are arranged around the 19th via hole. The short-circuit prevention hole 761 already described in FIG. 92B of this embodiment is provided. The area of the short-circuit prevention hole 761 is set to be larger than the area of the joint hole 762 around the terminal 775 described above, and the first pin 784s inserted into the first via hole 793s in the soldering process of the printed wiring board 957 and the first pin 784s. The possibility that a solder bridge 751 is formed between the second pin 784t inserted through the second via hole 793t and short-circuited is reduced.

  As shown in FIG. 103 (b), the short-circuit prevention hole 761 has an elliptical shape in which the width in the left-right direction is wider than the width in the up-down direction. By extending the short-circuit prevention hole 761 in the left-right direction, the width in the vertical direction is widened, and the short-circuit prevention hole 761 approaches the terminal 775 (FIG. 88 (a)) possessed by the electronic components other than the second working port connector 956. The area expansion for reducing the possibility that the solder bridge 751 is formed between the first pin 784s and the second pin 784t of the second working port connector 956 is suppressed.

  As shown in FIG. 103 (b), the short-circuit prevention hole 761 around the first via hole 793s is based on the first via hole 793s and the center of the short-circuit prevention hole 761 is adjacent to the first via hole 793s. The short-circuit prevention hole 761 around the second via hole 793t is provided on the opposite side of the second via hole 793t, and the center of the short-circuit prevention hole 761 is based on the second via hole 793t. The first via hole 793s adjacent to the first via hole 793s is provided on the opposite side. The two short-circuit prevention holes 761 are provided in such a manner that the distance from the left end of the short-circuit prevention hole 761 around the first via hole 793s to the right end of the short-circuit prevention hole 761 around the second via hole 793t is kept wide. In other words, the center of gravity of the molten solder accumulated on the upper surface of the solder can be positioned in the opposite direction to the adjacent via holes 793s and 793t.

  As a result, when the first via hole 793s is positioned at the rear end in the transport direction, the molten solder around the first via hole 793s can hardly move in the direction of the adjacent second via hole 793t. When the second via hole 793t is positioned at the rear end in the transport direction, the molten solder around the second via hole 793t can hardly move in the direction of the adjacent first via hole 793s, and the solder bridge The occurrence of 751 is suppressed.

  Also, as shown in FIG. 103 (b), in the first working port region 961, the first via hole 793q and the second via hole 793r are arranged in the left-right direction, and the second via hole 793r is on the left side of the first via hole 793q. Is provided. The distance from the center of the first via hole 793q to the center of the second via hole 793r is 2.5 mm.

  As shown in FIG. 103 (b), a wiring pattern 776 is formed around the first via hole 793q in the same manner as around the first via hole 793s of the second working port region 962 described above. A GND solid 851 is formed around the two via holes 793r in the same manner as the second via holes 793r in the second working port region 962 described above. A solder resist 792 is formed on the wiring pattern 776 and the GND plane 851 in the same manner as the second working port region 962 described above. For this reason, molten solder does not adhere to the wiring pattern 776 and the GND plane 851 in the soldering process.

  As shown in FIG. 103 (b), in the first working port region 961, the first via hole 793q and the second via hole 793r are short-circuited prevention holes 761 around the first working hole region 962 as in the second working port region 962. Is provided. The short-circuit prevention hole 761 around the second via hole 793r is connected to the GND solid 851 by the connecting portion 763, similarly to the vicinity of the second via hole 793t in the second working port region 962 described above.

  As shown in FIG. 103 (b), the area of the short-circuit prevention hole 761 is set larger than the area of the joint hole 762 around the terminal 775 described above, and the first via hole 793q in the soldering process of the printed wiring board 957. The possibility of short-circuiting by forming a solder bridge 751 between the first pin 784q inserted through the second pin 784q and the second pin 784r inserted through the second via hole 793r is reduced.

  As shown in FIG. 103 (b), the short-circuit prevention hole 761 has an elliptical shape in which the width in the left-right direction is wider than the width in the up-down direction. By extending the short-circuit prevention hole 761 in the left-right direction, the width in the vertical direction is widened, and the short-circuit prevention hole 761 approaches the terminal 775 (FIG. 88 (a)) possessed by the electronic component other than the first working port connector 955. The area expansion for reducing the possibility that the solder bridge 751 is formed between the first pin 784q and the second pin 784r of the first working port connector 955 is suppressed.

  As shown in FIG. 103 (b), the short-circuit prevention hole 761 around the first via hole 793q is based on the first via hole 793q and the center of the short-circuit prevention hole 761 is adjacent to the first via hole 793q. The short-circuit prevention hole 761 around the second via hole 793r is provided on the opposite side of the second via hole 793r, and the center of the short-circuit prevention hole 761 is based on the second via hole 793r. Is provided on the side opposite to the first via hole 793q adjacent to the first via hole 793q. The two short-circuit prevention holes 761 are provided in such a manner that the distance from the left end of the short-circuit prevention hole 761 around the first via hole 793q to the right end of the short-circuit prevention hole 761 around the second via hole 793r is kept wide. It is possible to adopt a mode in which the center of gravity of the molten solder that accumulates on is located in a direction opposite to the adjacent via holes 793q and 793r.

  As a result, when the first via hole 793q is positioned at the rear end in the transport direction, it is possible to create an environment in which the molten solder around the first via hole 793q is difficult to move in the direction of the adjacent second via hole 793r. When the second via hole 793r is positioned at the rear end in the transport direction, the molten solder around the second via hole 793r can hardly move in the direction of the adjacent first via hole 793q, and the solder bridge The occurrence of 751 is suppressed.

<Electrical configuration for performing various lotteries in the main CPU 63>
Next, an electrical configuration for executing the winning lottery in the main CPU 63 (FIG. 5) will be described. In the winning lottery, the hold information acquired based on the winning of the first operating port 938 (FIG. 102) or the second operating port 939 (FIG. 102) is used.

  The main CPU 63 adds the winning random number counter C1, the big hit type counter C2, the reach random number counter C3, the random number initial value counter CINI, and the variation type counter CS to the lottery counter area 65b already described in FIG. 6 of the first embodiment. , A utility power release counter C4 is provided. The main CPU 63 includes a general electric power reservation area 65c. In addition to the execution area AE, the main CPU 63 has a first special figure reservation area as a reservation area RE corresponding to the first operation port 938. (Not shown) and a second special figure holding area (not shown) as a holding area RE corresponding to the second working port 939. In the present embodiment, the execution area AE (FIG. 6) in the reserved storage area 65a (FIG. 6) will be referred to as a special-purpose execution area AE.

  The first special figure reservation area includes a first special figure first area, a first special figure second area, a first special figure third area, and a first special figure fourth area (not shown). When a winning to the first operating port 938 occurs, the numerical information of the winning random number counter C1, the big hit type counter C2 and the reach random number counter C3 is held on the special figure side in accordance with the winning history to the first operating port 938. Information is stored in any area.

  In this case, in the first area for the first special figure to the fourth area for the first special figure, the first area for the first special figure when the winning to the first operating port 938 occurs continuously several times. The numerical information is stored in time series in the order of the second area for the first special figure, the third area for the first special figure, and the fourth area for the first special figure. By providing four areas in this way, up to four winning histories of the game ball B1 (FIG. 53 (a)) to the first operating port 938 are held and stored.

  In addition, the number that can be reserved and stored in the first special figure reservation area is not limited to four, is arbitrary, may be other plural, such as two, three, five or more, It may be singular.

  The second special figure holding area includes a first area for a second special figure, a second area for a second special figure, a third area for a second special figure, and a fourth area for a second special figure (not shown). When a winning to the second operating port 939 occurs, the numerical information of the winning random number counter C1, the big hit type counter C2 and the reach random number counter C3 is held on the special figure side according to the winning history to the second operating port 939. Information is stored in any area.

  In this case, in the second area for the second special drawing to the fourth area for the second special drawing, the first area for the second special drawing when the winning to the second operation port 939 occurs a plurality of times in succession. The numerical information is stored in time series in the order of the second area for the second special figure, the third area for the second special figure, and the fourth area for the second special figure. By providing four areas in this way, up to four winning histories of the game balls B1 to the second operating port 939 are stored on hold.

  The number that can be reserved and stored in the second special figure reservation area is not limited to four, but is arbitrary, and may be other plural such as two, three, five or more, It may be singular.

  The special figure execution area AE stores hold information to be subjected to special figure determination or distribution determination when starting the variable display in any of the special figure display units 932a and 932b. It is an area. Specifically, when the variable display of the first special figure display unit 932a is started, the hold information stored in the first special figure first area of the first special figure reservation area is the special figure execution area. Moved to AE. On the other hand, when starting the variable display of the second special figure display unit 932b, the hold information stored in the second special figure first area of the second special figure reservation area moves to the special figure execution area AE. Is done.

  Next, the determination of success / failure made using the value of the hit random number counter C1 stored in the first special figure reservation area or the second special figure reservation area will be described.

  The random number value that is won at the time of determination of success / failure is stored as a success / failure table in the main ROM 64 (FIG. 5). In the success / failure table, as the success / failure results, a jackpot result, a small hit result, and a miss result are set. The jackpot result is a success / failure result that can trigger the transition to the open / close execution mode in which the special prize winning device 32 is controlled to open / close, and can be a transition trigger for at least one of the winning / failing lottery mode and the support mode. The small hit result is a success / failure result that does not trigger the transition for both the success / failure lottery mode and the support mode, while triggering the transition to the opening / closing execution mode in which the special electricity winning device 32 is controlled to open / close. The losing result is a success / failure result that does not trigger the transition to the opening / closing execution mode and also does not trigger the transition for the success / failure lottery mode and the support mode.

  In the present embodiment, the success / failure table stored in the main ROM 64 (FIG. 5) is used for the first special figure used when determining the success / failure of the hold information acquired based on the winning to the first operating port 938. A success / failure table and a success / failure table for the second special figure used for determining the success / failure of the hold information acquired based on the winning to the second operation port 939 are set. Further, the first special figure success / failure table includes a low-accuracy acceptance table and a high-accuracy acceptance table. Similarly, the second special figure success / failure table also includes a low-probability acceptance table and a high-accuracy table. There is a success / failure table. In other words, the pachinko machine 10 according to the present embodiment has different success / failure tables for the hold information acquired based on the winning to the first operating port 938 and the hold information acquired based on the winning to the second operating port 939. In both cases, the low probability mode and the high probability mode exist as lottery modes in the winning / failing lottery.

  Specifically, each of the success / failure tables will be described. In the low-accuracy determination table for the first special figure, the value of the random number that is the jackpot result is two (for example, “5” and “305”), and the jackpot result is obtained. There are three random numbers (for example, “55”, “355”, “555”). The other values are random number values that are the result of the removal.

  In the high probability table for the first special figure, the number of random numbers resulting in the jackpot result is set to be larger than that in the low probability table for the first special figure, specifically, 20 pieces. (For example, “5”, “34”, “65”, “130”, “163”, “192”, “220”, “245”, “276”, “305”, “334”, “365”, “392”, “420”, “470”, “495”, “520”, “558”, “575”, “599”). In this case, the value group of the winning random number counter C1 that wins the big hit in the situation in the low probability mode is included in the value group of the winning random number counter C1 that wins in the situation in the high probability mode. On the other hand, the value of the random number resulting in the small hit result is the same as in the case of the low probability table for the first special figure.

  In the low probability table for the second special figure, the random value resulting in the jackpot result is the same as in the low probability table for the first special figure. On the other hand, the number of random number values resulting in the small hit result is set to be larger than that in the case of the low probability table for the first special figure, specifically 40 (for example, “3”, “8”). , “31”, “37”, “55”, “68”, “127”, “133”, “160”, “166”, “189”, “195”, “217”, “223”, “ 242 ”,“ 248 ”,“ 273 ”,“ 279 ”,“ 302 ”,“ 308 ”,“ 331 ”,“ 337 ”,“ 355 ”,“ 368 ”,“ 389 ”,“ 395 ”,“ 417 ” , “423”, “467”, “473”, “492”, “498”, “517”, “523”, “555”, “561”, “572”, “578”, “596” “598” "). It should be noted that the number of random number values resulting in the small hit result may be the same as that in the low probability table for the first special figure, and set to be smaller than in the low probability table for the first special figure. It is good also as the structure currently made.

  In the high probability table for the second special figure, the value of the random number resulting in the jackpot result is the same as that in the high probability table for the first special figure. Therefore, the number of random number values resulting in the jackpot result is larger than that in the case of the low probability table for the second special figure. On the other hand, the value of the random number resulting in the small hit result is the same as that in the low probability table for the second special figure.

  If the probability of a jackpot result is higher in the high probability mode than the low probability mode, the number and value of the winning random numbers are arbitrary, and in the situation of the low probability mode, the jackpot result In the situation where the value group of the winning random number counter C1 is in the high probability mode, only a part may be included in the value group of the winning random number counter C1 that is a big hit, or a configuration may not be included. .

  Next, the allocation determination performed using the value of the jackpot type counter C2 stored in the first special figure reservation area or the second special figure reservation area will be described.

  In the pachinko machine 10 in the present embodiment, the occurrence frequency of winning in the special prize winning device 32 (FIG. 102) from when the opening / closing execution mode is started until it is finished is relatively high. The high-frequency winning mode and the low-frequency winning mode already described in the first embodiment are set.

  In the high-frequency winning mode and the low-frequency winning mode, the number of opening / closing of the special electric prize device 32, the number of round games, the opening duration for one opening, and the upper limit number in one round game are lower in the high-frequency winning mode. It is set so that the occurrence frequency of winning in the special electric prize winning device 32 is higher than that in the frequency winning mode until the opening / closing execution mode starts and ends.

  The types of jackpot result types for the jackpot type counter C2 are stored in the main ROM 64 (FIG. 5) as a sorting table. In the allocation table, as the types of jackpot results, in addition to the low likelihood jackpot result and the most advantageous jackpot result already described in the first embodiment, an implicit high probability jackpot result and an explicit high probability jackpot result are set. ing.

  The non-explicit high-precision jackpot result is a jackpot result in which the opening / closing execution mode becomes the low-frequency winning mode, and after the opening / closing execution mode ends, the winning lottery mode before entering the opening / closing execution mode becomes any high probability mode. is there. This high-probability mode will be the next jackpot result, and will at least continue until it shifts to the opening / closing execution mode. The support mode is the high-frequency support mode if the mode before the opening / closing execution mode transition is the high-frequency support mode, and the low-frequency support mode if the mode before the opening / closing execution mode transition is the low-frequency support mode. This support mode is the next jackpot result, and at least continues until it shifts to the opening / closing execution mode.

  The explicit high-accuracy big hit result is that the opening / closing execution mode is the low-frequency winning mode, and after the opening / closing execution mode is finished, the high-probability mode is set regardless of whether the winning lottery mode before the switching to the opening / closing execution mode is performed, It is a jackpot result that becomes the high-frequency support mode regardless of the support mode before the mode transition. These high-probability mode and high-frequency support mode are the next jackpot results, and at least continue until the switching to the opening / closing execution mode is performed.

  In the main ROM 64 of the present embodiment, as a distribution table, a first special distribution table used for determination of distribution of hold information acquired based on winning to the first working port 938, A distribution table for the second special figure used when determining the distribution of the hold information acquired based on the winning to the second operation port 939 is set.

  The allocation table for the first special figure will be described in detail for each allocation table. The types of jackpot results to be distributed are the low-accuracy large hit results, the unspecified high-accuracy big hit results, and the explicit high-accuracy results. The jackpot result and the most advantageous jackpot result are all set. In the distribution table for the first special figure, out of the big hit type counter C2 of “0 to 29”, “0 to 9” corresponds to the low probability big hit result, and “10 to 14” is the unspecified high level. Corresponding to the jackpot result, “15 to 19” corresponds to the explicit high probability jackpot result, and “20 to 29” corresponds to the most advantageous jackpot result. In the case of the distribution table for the first special figure, the probability of a low probability big hit result is 1/3 when a big win is won. The probability of a highly accurate jackpot result such as a jackpot result is 2/3. In the opening / closing execution mode, the probability of becoming the high-frequency winning mode is 2/3, and the probability of becoming the low-frequency winning mode is 1/3.

  On the other hand, in the allocation table for the second special figure, only the low-accuracy big hit results and the most advantageous big hit results are set as the types of jackpot results to be distributed. The jackpot result is not set. In the distribution table for the second special figure, among the big hit type counters C2 of “0 to 29”, “0 to 9” corresponds to the low probability big hit result, and “10 to 29” is the most advantageous big hit. It corresponds to the result. In the case of the distribution table for the second special figure, when a big win is won, the probability of a low probability big hit result is 1/3, and the probability of the most advantageous big hit result is 2/3. The opening / closing execution mode is always the high-frequency winning mode.

  That is, the first special chart allocation table and the second special chart allocation table have the same probability of being in the high probability mode after the opening / closing execution mode when the big win is won. On the other hand, the probability of becoming the high-frequency winning mode in the opening / closing execution mode is higher in the distribution table for the second special figure than in the distribution table for the first special figure. More specifically, the first special chart allocation table can be in the low-frequency winning mode, whereas the second special chart allocation table cannot be in the low-frequency winning mode. Therefore, as a type of jackpot result that can be selected when a big win is won, a win to the second operating port 939 occurs rather than a case where a win to the first operating port 938 occurs and a winning lottery is performed. Therefore, it is more advantageous for the player when the winning lottery is performed.

<Special Figure Special Electric Control Process>
Next, in the special figure special electric control process of the present embodiment, which is executed to perform the execution control of the game times and the execution control of the opening / closing execution mode, the special figure special electric control process of the first embodiment (first implementation) A point different from the timer interrupt process (step S213 in FIG. 8) in the embodiment will be described.

  First, the process for acquiring the hold information on the special figure side in the special figure special electricity control process of this embodiment will be described. In the acquisition process, when the winning of the game ball B1 (FIG. 53 (a)) to the first operation port 938 has occurred, the number of the hold information stored in the first special figure hold area is read out, When the number of the hold information is less than the upper limit value (specifically “4”), the winning random number counter C1 (FIG. 6), the big hit type counter C2 (FIG. 6), and the reach random number counter C3 (FIG. 6) Each value is stored in the uppermost area in the first special figure holding area where no holding information is stored. In addition, in the acquisition process, when the winning of the game ball B1 to the second operation port 939 occurs, the number of the hold information stored in the second special figure hold area is read, and the number of the hold information Is less than the upper limit value (specifically, “4”), the holding random number counter C1, the big hit type counter C2 and the reach random number counter C3 are stored as holding information in the first special figure holding area. Store in the uppermost area that is not.

  In the acquisition process, when the holding information about the first special figure holding area or the holding information about the second special figure holding area is acquired, a holding command is transmitted to the sound emission control device 81 (FIG. 5). The voice light emission control device 81 transmits a command corresponding to the received hold command to the display control device 82 (FIG. 5). The display control device 82 receives the hold command, and changes the display of the number of hold information on the symbol display device 41 (FIG. 102) in accordance with the increase in the hold number. In this case, since the holding command includes information indicating which holding information of the first special figure holding area and the second special figure holding area has increased, the symbol display device 41 has increased. The display of the number of holds corresponding to the side is changed.

  When the number of hold information increases as described above, the first special figure hold display unit 932c (FIG. 102) and the second special figure are displayed in the display control process of step S215 in the timer interrupt process (FIG. 8). Display control is performed so that the display content corresponding to the increase in the reserved number is changed to the side corresponding to the increase in the reserved number in the figure hold display unit 932d (FIG. 102).

  In the special figure special power control process of the present embodiment, in addition to the above-described special figure side hold information acquisition process, a process for controlling the effects for game rotation, and a process for controlling the opening / closing execution mode ,It is included. As a process for controlling the effects for game times, a special figure variation start process that is a process for starting effects for game times, a process for advancing effects for game times, and a process for game times A process for ending the effect is set.

  Further, as a process for controlling the opening / closing execution mode, a process for controlling the opening of the opening / closing execution mode, a process for controlling the open state of the special electric prize device 32 (FIG. 102), and a special electric prize device A process for controlling the closed state of 32 and a process for controlling the ending of the opening / closing execution mode and the transition of the gaming state at the end of the opening / closing execution mode are set.

  The main RAM 65 (FIG. 5) includes a special-purpose special electric counter as a counter for the main CPU 63 (FIG. 5) to grasp which of the above-described plural types of processing should be executed. Further, the main ROM 64 (FIG. 5) includes a special figure special power address table in which start addresses of programs for executing the above-described plural types of processing are set.

  The special figure special power counter is the special figure special electric power control at the next processing time when the condition for updating the numerical information is satisfied when the processing corresponding to the numerical information stored at present is finished. Corresponding to the process executed in the process, 1 addition, 1 subtraction, or “0” is cleared. In the special figure special power control process in each processing time, a process according to the numerical information set in the special figure special electric power counter is executed.

  Next, the special figure fluctuation start process executed in the special figure special electric control process of this embodiment will be described. The special figure change start process includes a success / failure determination process, a distribution determination process, and a reach determination process. The success / failure determination process is executed on the condition that the hold information is stored, not during the game rotation or the opening / closing execution mode.

  First, it is determined whether or not the common holding number that is the total number of holding information in the first special figure holding area and the second special figure holding area is 1 or more. If the number of common holds is less than 1, it means that no hold information is stored in the first special figure hold area and the second special figure hold area, so the success / failure determination process and the distribution determination process are not executed. . On the other hand, if the common hold number is 1 or more, the data setting process is executed.

  In the data setting process, first, it is determined whether or not the number of holdings in the second special figure holding area is “0”. When the number of holds in the second special figure reservation area is “0”, data setting processing for the first special figure is executed, and when the number of reservations in the second special figure reservation area is not “0”, 2. Data setting processing for special maps is executed.

  Here, the case where the data setting process is executed is a case where the common pending number is 1 or more as described above. In this case, in the data setting process, it is determined whether or not the number of holds in the second special figure holding area is “0”. If it is not “0”, that is, the second special figure display unit 932b is used for variable display. When the hold information is stored, the data stored in the second special figure holding area is set for variable display regardless of whether the number of holdings in the first special figure holding area is 1 or more. I tried to do it. As a result, when the hold information is stored in both the first special figure holding area and the second special figure holding area, the holding is stored in the second special figure holding area corresponding to the second operation port 939. The information is prioritized as a game round start target.

  In the first special figure data setting process, first, the data stored in the first special figure first area of the first special figure reservation area is moved to the special figure execution area AE (FIG. 6). Then, the process which shifts the data stored in the storage area of the 1st special figure reservation area is executed. This data shift process is a process for sequentially shifting the data stored in the first special figure first area to the first special figure fourth area to the lower area side.

  Thereafter, the second special figure flag provided in the main RAM 65 (FIG. 5) is cleared to “0”. The second special figure flag is a flag for specifying whether the start of the current variation display is the first special figure display unit 932a or the second special figure display unit 932b. Then, a shift time command that is information for causing the voice light emission control device 81 (FIG. 5), which is the sub-side control device, to recognize that the data of the first special figure reservation area has been shifted is output, This data setting process ends. The voice light emission control device 81 transmits a command corresponding to the received shift command to the display control device 82 (FIG. 5), so that the number of the hold information corresponding to the first special figure hold area in the symbol display device 41 is increased. Change the display to correspond to the decrease in the number of holds.

  If the number of hold information in the first special figure reservation area decreases as described above, the display control process in step S215 in the timer interrupt process (FIG. 8) causes the first special figure hold display unit 932c to On the other hand, display control is performed so as to change the display contents to correspond to the decrease in the number of reserved items.

  In the data setting process for the second special figure, first, the data stored in the second special figure first area of the second special figure reservation area is moved to the special figure execution area AE (FIG. 6). Then, the process which shifts the data stored in the storage area of the 2nd special figure reservation area is executed. This data shift process is a process of sequentially shifting data stored in the second special figure first area to the second special figure fourth area to the lower area side.

  Thereafter, “1” is set in the second special figure flag provided in the main RAM 65. Then, a shift time command, which is information for causing the voice light emission control device 81 to recognize that the data of the second special figure reservation area has been shifted, is output, and this data setting process is terminated. The sound emission control device 81 transmits a command corresponding to the received shift command to the display control device 82, thereby displaying the number of the hold information corresponding to the second special figure hold area in the symbol display device 41. Change in response to the decrease in

  If the number of hold information in the second special figure reservation area decreases as described above, the display control process in step S215 in the timer interrupt process (FIG. 8) causes the second special figure hold display unit 932d to On the other hand, display control is performed so as to change the display contents to correspond to the decrease in the number of reserved items.

  After the data setting process is executed, the validity determination process is executed. In the success / failure determination process, it is determined whether or not “1” is set in the second special figure flag of the main RAM 65, so that the current game number of the first special figure holding area and the second special figure holding area is determined. It is determined which holding information corresponds to the information. Further, it is determined whether or not the lottery mode is a high probability mode. Then, the validity table corresponding to these determination results is divided into a low accuracy table for the first special figure, a high accuracy table for the first special figure, a low accuracy table for the second special figure, and the second special figure. Select from the high-accuracy table. After selection of the hit / fail table, information for determining whether or not the hold information stored in the special drawing execution area AE (FIG. 6), that is, the numerical information obtained from the hit random number counter C1 is the above selection. It is determined whether or not it matches any of the numerical information set as the jackpot result in the success / failure table. If the numerical information set as the jackpot result does not match, it is determined whether or not it matches any of the numerical information set as the small hit result in the selected success / failure table.

  If the result of the success / failure determination process is a jackpot result, the distribution determination process is executed. In the allocation determination process, it is determined whether or not “1” is set in the second special figure flag of the main side RAM 65, so that the current game times are the first special figure reservation area and the second special figure reservation area. It is determined which of the hold information corresponds to. Then, the distribution table corresponding to the determination result is selected from the distribution table for the first special figure and the distribution table for the second special figure. After the selection of the allocation table, information for allocation determination among the hold information stored in the special chart execution area AE (FIG. 6), that is, the numerical information acquired from the jackpot type counter C2, It is grasped which type of jackpot result corresponds to the selected sorting table. Specifically, when the allocation table for the first special figure is selected, any of the jackpot results among the low likelihood jackpot result, the non-explicit high probability jackpot result, the explicit high likelihood jackpot result, and the most advantageous jackpot result To know if it corresponds to Further, when the distribution table for the second special figure is selected, it is grasped which of the big hit results corresponds to the low probability big hit result or the most advantageous big hit result.

  Thereafter, a process of setting a flag corresponding to the type of jackpot result specified this time in the main RAM 65 (FIG. 5) is executed. Specifically, “1” is set to the low-accuracy flag when it is specified that the result is a low-accuracy large hit result, and “1” is set to the implicit flag when it is specified that the result is an implicit high-accuracy big hit result. ”Is set,“ 1 ”is set in the explicit flag when it is specified that the result is an explicit high probability jackpot result, and“ 1 ”is set in the most advantageous flag when it is specified that the result is the most advantageous jackpot result. set. In the following description, whether or not the various jackpot results are determined is determined by determining whether or not a flag corresponding to the main RAM 65 is set.

  Thereafter, the stop result setting process for the jackpot result is executed. Specifically, information on the pattern mode to be finally stopped and displayed on the first special figure display unit 932a or the second special figure display unit 932b in the current game round is stored in the main ROM 64 (FIG. 5) in advance. The stop result table for the jackpot result is specified, and the specified information is stored in the main RAM 65. In the jackpot result stop result table, the types of patterns that are stopped and displayed on the first special figure display unit 932a or the second special figure display unit 932b are set differently for each type of jackpot result. Thus, information on the pattern mode corresponding to the specified type of jackpot result is stored in the main RAM 65.

  The information on the type of the picture to be stopped and displayed is determined according to the value of the jackpot type counter C2. In this case, the pattern mode may be set corresponding to each jackpot result on a one-to-one basis, and a plurality of types of pattern modes may be set for each jackpot result.

  On the other hand, if it is determined that the result is not a big hit result, it is determined whether or not the result of the success / failure determination process is a small hit result. If the result is a small hit result, “1” is set in the small hit flag provided in the main RAM 65. Then, a stop result setting process for the small hit result is executed. Specifically, the small hits stored in advance in the main ROM 64 are information on the pattern mode that is finally stopped and displayed on the first special figure display unit 932a or the second special figure display unit 932b in the current game round. The information is specified from the result stop result table, and the specified information is stored in the main RAM 65. The information on the pattern mode selected in this case is different from the information on the pattern mode selected in the case of the jackpot result.

  If it is determined that the result is not a small hit result, a stop result setting process for a losing result is executed. Specifically, in the current game round, information on the pattern mode that is finally stopped and displayed on the first special figure display unit 932a or the second special figure display unit 932b is stored in the main ROM 64 in advance. And the specified information is stored in the main RAM 65. The picture mode information selected in this case is different from the picture mode information selected for the jackpot result and the picture mode information selected for the jackpot result.

  After executing any one of the stop result setting process for the big hit result, the stop result setting process for the small hit result, and the stop result setting process for the outlier result, the display duration grasping process is executed. In such processing, numerical value information of the variation type counter CS is acquired. In addition, it is determined whether or not reach display occurs in the symbol display device 41 in the current game round. Specifically, if the current game round is the most advantageous jackpot result or the low probability jackpot result, it is determined that the reach display occurs. If the numerical information of the reach random number counter C3 stored in the special drawing execution area AE (FIG. 6) is not the result of any jackpot, the reach indication is displayed. Determine that it occurs.

  When it is determined that the reach display occurs, the display duration information corresponding to the numerical information of the current variation type counter CS is acquired with reference to the reach generation display duration table stored in the main ROM 64. . On the other hand, if it is determined that the reach display does not occur, it is determined whether the current game round is one of the explicit high-accuracy big hit results, the non-explicit high-precision big hit results, or the small hit results. In some cases, a display duration table corresponding to the result is read from the main ROM 64, and display duration information corresponding to the numerical information of the current variation type counter CS is acquired. In this case, at least in the game times triggered by the hold information stored and stored in the first special figure reservation area, it is impossible to identify or difficult to identify whether the result is an unspecified high probability big hit result or a small hit result. The display duration is selected so that the design display device 41 (FIG. 102), the display light emitting unit 53 (FIG. 1), and the speaker unit 54 (FIG. 1) perform effects. However, the degree of expectation that the success / failure lottery mode after the open / close execution mode is the high probability mode due to the difference in the display duration table referenced in the case of the non-explicit high probability hit result and the case of the small hit result It is possible to make the selection rate of the performance with a high difference between the two cases. Specifically, the production with a high expectation level occurs in the case of an unspecified high-precision hit result than in the case of a small hit result. It is easy. On the other hand, when the reach display is not generated, and when neither the explicit high-precision hit result, the non-explicit high-precision big hit result, or the small hit result is obtained, the display duration table for detachment is read from the main ROM 64, Display duration information corresponding to the numerical information of the variation type counter CS is acquired.

  In addition, if the display continuation time information in the case where the display continuation time table for detachment is referred to is a game time triggered by the hold information stored in the first special figure reservation area, the display is performed in the first special figure reservation area. The display duration time is set to be shorter as the number of stored hold information increases, and if the game time is triggered by the hold information stored in the second special figure hold area, the second special feature is set. The display duration time is set to be shorter as the number of pieces of hold information stored in the figure hold area increases. Also, in the situation where the support mode is the high frequency support mode, compared to the case where the number of pending information is the same as in the situation where the support mode is the low frequency support mode, the display duration is selected so that a shorter display duration is selected. Display duration table is set. However, the present invention is not limited to this, and the display duration may not be changed according to the number of hold information and the support mode, and the above relationship may be reversed. Furthermore, the above-described configuration may be applied to the display continuation time when reach occurs.

  Thereafter, the information on the grasped display continuation time is set in the special figure special electricity timer counter. The update of the numerical information set in the timer counter is executed in the timer update process in step S210 in the timer interrupt process (FIG. 8) of the main CPU 63. By the way, as the effects for the game times, the variation display of the pattern in the first special symbol display unit 932a or the second special symbol display unit 932b and the variation display of the symbol in the symbol display device 41 are performed. When the game is ended, the final stop display is displayed for the final stop time in a state in which the result of the stoppage of the game is displayed (in the symbol display device 41, a predetermined symbol combination is on the active line). . In this case, the acquired display continuation time is a time obtained by subtracting the final stop time from the total time of one game. In this respect, the display continuation time can be rephrased as the time before the final stop.

  After the display duration information is set in the special figure special timer counter, the change command and the type command are output. The change command includes display duration information. Here, as described above, the display duration acquired with reference to the display duration display table for deviation is different from the display duration acquired with reference to the display duration table for reach occurrence. Even if the information on the presence or absence of reach has not been included, the sound emission control device 81 can specify the presence or absence of the reach from the information on the display duration. In this regard, it can be said that the change command includes information indicating whether or not reach has occurred. Note that the change command may include information that directly indicates whether or not reach has occurred. The type command includes game result information. The output variation command and type command are received by the sound emission control device 81 which is a sub-side control device.

  After that, in the first special figure display part 932a and the second special figure display part 932b, the display of the variation of the pattern is started on the display part on the execution side of the current game time. Then, by adding “1” to the special figure special electricity counter, in the next special figure special electricity control process, a process for advancing the effect for game play is executed.

  According to the embodiment described in detail above, the following excellent effects are obtained.

  The game board 931 has a configuration in which the player can separately aim for winning in the first operating port 938 and winning in the second operating port 939 by adjusting the amount of rotation of the operation handle. . Further, in each game round, the holding information acquired based on the winning to the first operating port 938 is the winning lottery performed using the holding information acquired based on the winning to the second operating port 939 It is set to be more advantageous to the player than the winning lottery performed using. In the winning lottery of each game time, the hold information acquired based on the winning to the second operating port 939 is prioritized over the holding information acquired based on the winning to the first operating port 938. is there. That is, the player expects a better result when aiming for a winning at the second operating port 939 than when aiming for a winning at the first operating port 938. In this configuration, the printed wiring board 957 of the main control board 61 includes a second working port connector 956 to which the two-pole connector 954 of the second harness 952a extending from the second working port detection sensor 952 is attached. In the wiring board 957, a short-circuit prevention hole 761 is formed around the two pins 784s and 784t of the second working port connector 956. For this reason, in the soldering process, the possibility that molten solder adhering around the two pins 784s and 784t of the second working port connector 956 merges to form a solder bridge is suppressed. This reduces the possibility that a connection failure will occur in the connection of the second working port detection sensor 952 with the main control board 61 and a winning to the second working port 939 will not be detected. By reducing the possibility of a situation in which a winning is not detected at the second operating port 939 that the player is aiming for with a good result, the possibility that the player will be greatly disappointed can be reduced.

  In this configuration, signal lines 958 extending from the first working port detection sensor 951 and the second working port detection sensor 952 are divided into bundles in units of the respective working port detection sensors 951 and 952, and connected to the main control board 61. For this reason, a gap is formed between the bundles of signal lines 958, and an illegal substrate can be found from the gap.

  The first harness 951 a extending from the first working port detection sensor 951 and the second harness 952 a extending from the second working port detection sensor 952 are connected to separate working port connectors 955 and 956 on the main control board 61. is there. Assuming that an unauthorized board is used, by setting a large number of connectors to which the unauthorized board is connected, it is possible to make it difficult to use the unauthorized board in the game hall.

  The fluorescent color of the first harness 951a and the first working port connector 955 to which the first harness 951a is connected is for the second working port to which the second harness 952a and the second harness 952a are connected. The fluorescent color of the connector 956 is different. For this reason, in the operation of connecting the first operating port detection sensor 951 and the second operating port detection sensor 952 to the main control board 61, the connection destination of each harness 951a, 952a can be identified by color, and the harness 951a , 952a can be prevented from being mistakenly connected.

  The printed wiring board 957 includes a first working port connector 955 to which the two-pole connector 953 of the first harness 951a extending from the first working port detection sensor 951 is attached. In the printed wiring board 957, the first working port is provided. A short-circuit prevention hole 761 is formed around the two pins 784q and 784r of the connector 955 for use. Thereby, in the connection with the main control board 61 of the 1st working port detection sensor 951, it can suppress that the solder bridge 751 is formed and short-circuited.

<Another embodiment of the twenty-second embodiment>
In the twenty-second embodiment described above, the first working port connector 955 may include four pins 784 (FIG. 91). For example, two signal lines 958 extending from the first working port detection sensor 951 and two signal lines extending from other electronic components connected to the main control board 61 are connected to the first working port connector 955. It is good also as a structure. Thereby, the effect that the connection mistake of the 1st harness 951a and the 2nd harness 952a is suppressed, the effect that an illegal board becomes difficult to use in a game hall, and the 2nd operation port detection sensor 952 and main control board 61 While maintaining the effect that the formation of the solder bridge 751 is suppressed in the connection, it is possible to facilitate the connection work of the electronic component including the first working port detection sensor 951 to the main control board 61. Further, for example, the first working port detection sensor 951 includes four signal lines 958, and the four signal lines are connected to a first working port connector 955 having four pins 784. Good. By adopting a configuration in which the number of signal lines 958 included in the first working port detection sensor 951 is not limited to two, the types of sensors that can be used as the first working port detection sensor 951 are increased, and the degree of freedom in design is increased. Can do.

  In the above-described twenty-second embodiment, only one of the two signal lines 958 constituting the first harness 951a has a yellow fluorescent color, and the other has no fluorescent color. Also good. In addition, only one of the two signal lines 958 constituting the second harness 952a may have a green fluorescent color, and the other may not have a fluorescent color. By visually observing the first harness 951a, the connection destination of the first harness 951a is known in relation to the color of the first working port connector 955, and by visually observing the second harness 952a, the second working port Since the connection destination of the second harness 952a is known in relation to the color of the connector 956, connection errors between the first harness 951a and the second harness 952a can be suppressed.

  In the second working port region 962 of the twenty-second embodiment described above, the configuration for preventing the formation of the solder bridge 751 is not limited to the short-circuit prevention hole 761. For example, instead of the short-circuit prevention hole 761, the separation-type short-circuit prevention hole 871 already described in FIG. 99A of the twentieth embodiment may be used. The configuration will be described below.

  Around the first via hole 793s in the second working port region 962 (FIG. 103 (b)), the joint hole 762 (FIG. 99 (a)) already described in the twentieth embodiment is formed. On the right side of the joint hole 762, the separation-type short-circuit prevention hole 874 (FIG. 99 (a)) already described in the twentieth embodiment is provided. The separation-type short-circuit prevention hole 874 is not continuous with the joint hole 762 around the first via hole 793s, and is formed in such a manner that the reduced width portion 874b (FIG. 99A) faces the direction of the first via hole 793s. ing. For this reason, in the soldering process of the printed wiring board 957, when the first via hole 793s is positioned at the rear end in the transport direction, the pin 784s inserted through the first via hole 793s (FIG. 103B). The possibility that the molten solder adhering to the periphery of the metal plate moves in the direction of the second via hole 793t to form the solder bridge 751 (FIG. 95C) is reduced.

  Around the second via hole 793t in the second working port region 962 (FIG. 103 (b)), the joint hole 762 (FIG. 99 (a)) already described in the twentieth embodiment is formed. On the left side of the joint hole 762, the separation-type short-circuit prevention hole 871 (FIG. 99 (a)) already described in the twentieth embodiment is provided. The separation-type short-circuit prevention hole 871 is not continuous with the joint hole 762 around the second via hole 793t, and is formed in such a manner that the reduced width portion 871b (FIG. 99 (a)) faces the second via hole 793t. ing. For this reason, in the soldering process of the printed wiring board 957, when the second via hole 793t is located at the rear end in the transport direction, the pin 784t inserted into the second via hole 793t (FIG. 103B) The possibility that the molten solder adhering to the periphery of the solder moves in the direction of the first via hole 793s and the solder bridge 751 (FIG. 95C) is formed is reduced.

  As described above, the separate short-circuit prevention holes 871 and 874 are provided around the two via holes 793s and 793t in the second working port region 962, and the solder bridge is connected in the connection between the second working port detection sensor 952 and the main control board 61. By reducing the possibility that 751 will be formed, even if a win to the second operating port 939 occurs, the winning is not detected, and the player who aimed at the second operating port 939 with great expectation is disappointed. The possibility can be reduced.

  Further, similarly to the two via holes 793s and 793t in the second working port region 962, around the two via holes 793q and 793r (FIG. 103 (b)) in the first working port region 961 (FIG. 103 (b)). Are provided with separate short-circuit prevention holes 871, 874 (FIG. 99 (a)) to connect the first operating port detection sensor 951 (FIG. 103 (b)) and the main control board 61 (FIG. 103 (b)). In this case, the possibility of forming the solder bridge 751 (FIG. 95C) can be reduced.

<Other embodiments>
In addition, it is not limited to the description content of embodiment mentioned above, A various deformation | transformation improvement is possible within the range which does not deviate from the meaning of this invention. For example, you may change as follows. Incidentally, the following configuration of another embodiment may be applied individually or in combination to the configuration of the above embodiment.

  (1) In each of the above-described embodiments, all of the out port 24a, the general winning port 31, the special winning device 32, the first operating port 33, and the second operating port 34 are stored as history information (or pitching history). However, the present invention is not limited to this, and only a part of the out port 24a, the general winning port 31, the special prize winning device 32, the first operating port 33, and the second operating port 34 is stored as history information. It is good also as composition which becomes. For example, only the general winning opening 31, the special prize winning device 32, and the second operation opening 34 may be configured to store history information, and only the general winning opening 31 is configured to store history information. It ’s good. Even in this case, it is possible to grasp the game ball entry mode in a predetermined period for the ball entry part for which history information is to be stored.

  (2) In each of the above embodiments, information corresponding to the result of entering the game ball is transmitted in correspondence with each of the first prize opening detection sensor 42a, the second prize opening detection sensor 43a, and the third prize opening detection sensor 44a. However, the present invention is not limited to this, and the information corresponding to the result of entering the same type of entrance part is the same type of entrance part. There may be a configuration in which a plurality of incoming ball detection sensors are present and a plurality of ball detection sensors are transmitted in accordance therewith. As a result, the number of types of information transmitted from the main CPU 63 to the management IC 66 can be suppressed.

  (3) In the first embodiment or the like, correspondence information indicating the type of information transmitted from the main CPU 63 to the management IC 66 and the correspondence between the buffers 122a to 122o is transmitted from the main CPU 63 to the management IC 66. However, the present invention is not limited to this, and the correspondence information may be stored in the management IC 66 in advance. In this case, it is not necessary to execute processing for causing the management IC 66 to recognize the correspondence information, and thus the processing load on the main CPU 63 can be reduced.

  (4) In the first embodiment, the correspondence information indicating the correspondence between the type of information transmitted from the main CPU 63 to the management IC 66 and the respective buffers 122a to 122o is transmitted from the main CPU 63 to the management IC 66. However, the present invention is not limited to this. For example, the main CPU 63 and the management IC 66 can communicate with each other and can be handled by the management IC 66. The configuration may be such that the correspondence information is transmitted from the main CPU 63 to the management IC 66 when a signal requesting transmission of the relationship information is received. In this case, the correspondence memory 116 is provided as a non-volatile memory and used for both reading and writing. Correspondence information provided from the main CPU 63 to the management IC 66 after shipment of the pachinko machine 10 is sent to the main CPU 63. Even when the supply of operating power is stopped, the correspondence memory 116 is configured to store and hold the operation power. Thereby, it becomes possible to reduce the frequency with which correspondence information is transmitted.

  (5) In the first embodiment, the correspondence information indicating the correspondence between the type of information transmitted from the main CPU 63 to the management IC 66 and the respective buffers 122a to 122o is transmitted from the main CPU 63 to the management IC 66. However, the signal paths 118a to 118g for transmitting the detection result information of the respective ball detection sensors 42a to 48a are used. However, the present invention is not limited to this, and the correspondence information is mainly used. A configuration may be employed in which a dedicated signal path for transmitting from the side CPU 63 to the management IC 66 is provided. As a result, the management IC 66 can determine which type of information is received from the main CPU 63 based on the types of the buffers 122a to 122o that receive the information.

  (6) In the first embodiment, etc., information is transmitted from the main CPU 63 to the management IC 66, but information is not transmitted from the management IC 66 to the main CPU 63. However, the present invention is not limited to this. Instead, the information may be transmitted from the management IC 66 to the main CPU 63. For example, various parameters calculated by the management CPU 112 based on the history information may be transmitted to the main CPU 63. In this case, the main CPU 63 may directly execute the notification control of the notification means in the same manner as in the eleventh embodiment so that notification corresponding to the contents of the received various parameters is performed. The main CPU 63 transmits a command corresponding to the contents of the received various parameters to the sound emission control device 81, so that the contents of the various parameters are obtained using the display light emitting unit 53, the speaker unit 54, and the symbol display device 41. It is good also as a structure which performs corresponding alerting | reporting.

  (7) When the supply of operating power to the main CPU 63 is started, various parameters are calculated by the main CPU 63 or the management CPU 112 based on the history information stored in the history memory 117. The contents of various parameters may be notified using the display light emitting unit 53, the speaker unit 54, the symbol display device 41, and the like. In this case, it is possible to confirm whether or not the game ball entering mode of the game area PA was normal on the previous business day at the start of the game hall.

  (8) When various parameters calculated based on the history information stored in the history memory 117 are abnormal results, the pachinko machine 10 cannot start a game until the prohibition release operation is performed. It is good. As a configuration for preventing the game from starting, for example, a configuration in which the launch of the game ball may be prohibited, a configuration in which each of the ball detection sensors 42a to 49a is invalidated, or the first operation port Even if a winning to 33 or the 2nd operation mouth 34 occurs, it is good also as composition which does not perform the success-and-failure determination processing. Further, the prohibition canceling operation may be an operation of turning on the power of the pachinko machine 10 again with the RAM erasure switch turned ON, and can be operated when the gaming machine main body 12 is released from the outer frame 11. It is good also as operation of the operation means used. As a result, it is possible to prevent the game from being played as it is in a situation where the game ball entering mode in the game area PA is in an abnormal mode.

  (9) Although history information corresponding to the detection results of the entrance detection sensors 42a to 48a is stored in the history memory 117, calculation of various parameters using the history information is performed in either the main CPU 63 or the management CPU 112. Also, the configuration may be such that neither is executed. In this case, the history information may be read by a reading device electrically connected to the reading terminal 102, and various parameters may be calculated using the read history information by an operator of the reading work. Alternatively, the reading device may be configured to execute various parameters using the read history information. In this case, the processing load on the main CPU 63 and the management CPU 112 can be reduced.

  (10) The management IC 66 is not provided, and the main CPU 63 may have a function of executing a history information storing process and a function of calculating various parameters in each of the above embodiments. A configuration provided in the CPU 92 or a configuration provided in the sound emission control device 81 may be employed. When the payout-side CPU 92 or the sound emission control device 81 is provided with these functions, information on the detection results of the respective entrance detection sensors 42a to 48a is transmitted from the main CPU 63 to the control subject having the functions. It will be.

  (11) The management IC 66 is provided with a power source separate from the main CPU 63, and even if the supply of operating power to the main CPU 63 is stopped, the management IC 66 calculates various parameters using history information. Alternatively, it may be configured to be able to output history information or information of various parameters. As a result, even when the supply of operating power to the main CPU 63 is stopped, the history information and various parameters can be read by the reading device.

  (12) The reading terminal 102 used for reading the program from the main ROM 64 is also used as a terminal used for reading history information or various parameters by the reading device. The terminal used for reading history information or various parameters by the reading device may be provided separately from the reading terminal 102 for reading the program from the main ROM 64. In this case, a terminal used for reading history information or various parameters may be provided in the MPU 62 or may be provided in a position different from the MPU 62 in the main control board 61.

  (13) The correspondence relationship memory 116, the history memory 117, and the calculation result memory 131 in each of the above embodiments are not limited to the configuration provided as nonvolatile storage means such as a flash memory. 116, 117, or 131 is provided as a volatile storage unit that requires power supply to store and store information, and backup power is supplied to the memory, thereby operating power to the main CPU 63. Even if the supply is stopped, the information may be stored and held. In this case, a configuration may be adopted in which a dedicated backup power device is provided for the memory, and backup power is supplied to the memory from the power supply / launch control device 78 that supplies the main RAM 65 with backup power. Also good.

  (14) The present invention is not limited to a configuration in which various parameters are calculated using history information, and history information is not stored and held. Various parameters may be calculated and updated each time a new detection is made. In this case, although the calculation frequency of various parameters increases, it is possible to extract various parameters at an arbitrary timing.

  (15) The management IC 66 includes the management-side CPU 112 as a general-purpose CPU, and is not limited to a configuration that executes history information storage processing and various parameter calculation processing based on programs and data stored in the management-side ROM 113. A hardware circuit designed to have these functions may be formed in the management IC 66. Specifically, for example, in the case of the first embodiment, the hardware circuit receives a signal indicating that a game ball has been detected by any of the detection sensors 42a to 48a from the main CPU 63. The correspondence information corresponding to the buffer that received the signal is stored in the history memory 117 from the correspondence memory 116, and the information of the RTC 115 at that time is stored in the history memory 117. To do. For example, in the ninth embodiment, when the hardware circuit receives a signal indicating that a game ball has been detected by any of the detection sensors 42a to 48a from the main CPU 63, the hardware circuit receives the signal. The counter value corresponding to the buffer is incremented by one. In addition, when an operation trigger occurs in the first embodiment or the like, the hardware circuit calculates various parameters using history information at that time. In addition, when an external output trigger to the reading terminal 102 occurs, the hardware circuit externally outputs various parameters as calculation results and externally outputs history information.

  (16) In addition to or instead of the configuration in which the information on the detection results of the entrance detection sensors 42a to 48a is stored as history information, the configuration in which the transition to the opening / closing execution mode has occurred is stored as history information. The transition timing to the opening / closing execution mode and the end timing may be stored as history information, or the transition to the high frequency support mode may be stored as history information, and a predetermined abnormality It is good also as a structure by which it is memorize | stored as historical information that generation | occurrence | production occurred. Moreover, it is good also as a structure by which the transition probability to opening / closing execution mode is calculated by using the above history information, and it is good also as a structure by which the transition probability to high frequency support mode is calculated, and predetermined | prescribed abnormality is The frequency of occurrence may be calculated. The history information and various parameters may be read by a reading device.

  (17) The main CPU 63 and the management IC 66 may be provided as separate chips, may be provided as separate substrates, or may be provided as separate control devices.

  (18) In the first embodiment and the like, the number of balls entered for the game balls entering the out port 24a is measured, while the general winning port 31, the special prize winning device 32, the first operating port 33, and History information including RTC information may be stored for awarding of a prize ball of a game ball such as the second operation port 34 and entering a privilege triggering ball portion that triggers the determination process. As a result, it is possible to calculate the frequency of game balls entering each privilege opportunity ball portion with respect to the total number of game balls discharged while allowing the game ball entry history to the privilege opportunity ball portion to be extracted. Become.

  (19) It is good also as a structure in which things other than the thing in said each embodiment are contained as object kept as log | history information. For example, at least one of the timing when the lower plate 56a becomes full, the timing when the full state is started, and the timing when the full state is released may be stored as history information. It may be configured that at least one of the timing when the ball has become unsatisfied, the timing at which the ball has no state is started, and the timing at which the state without the ball is released is stored as history information, and the dispensing device 76 becomes in an abnormal state. In addition, at least one of the timing at which the abnormal state of the payout device 76 is started and the timing at which the abnormal state of the payout device 76 is canceled may be stored as history information. In this case, it is possible to grasp the frequency of occurrence of these events.

  (20) In the first embodiment and the like, a configuration in which the 16th buffer 122p of the input port 121 in the management-side I / F 111 corresponds to the output instruction signal is preset in the design stage of the management IC 66. However, the present invention is not limited to this, and the fact that the sixteenth buffer 122p corresponds to the output instruction signal is also recognized by the management IC 66 by transmitting a type identification command from the main CPU 63. It is good also as a structure. In this case, it is not necessary to previously set the correspondence relationship between the buffers 122a to 122p and the types of signals input to the buffers 122a to 122p in the management IC 66.

  (21) The number of game balls that have entered a predetermined ball-entry part that is generated when the front door frame 14 is in the open state is stored as history information, and the number of balls that have been grasped using the history information. May be externally output to the reading device. As a result, it is possible to grasp the number of game balls that have entered a predetermined entry portion in a state where the front door frame 14 is in an open state, and it is possible to grasp the presence or absence of fraud. In addition, the number of balls entered into a predetermined ball-entry part generated in a situation where the front door frame 14 is in an open state is calculated when a predetermined calculation trigger occurs, and the calculated number of balls entered is an abnormal number. In some cases, abnormality notification may be executed. As a result, it is possible to deal with an illegal act of illegally opening the front door frame 14 and causing a game ball to enter a predetermined entrance part.

  (22) The management IC 66 may be configured to transmit a normal operation signal to the main CPU 63 when operating normally. In this case, the main CPU 63 can monitor whether or not the management IC 66 is operating normally.

  (23) In the first embodiment or the like, the order in which the management CPU 112 executes the confirmation processing of the first to fifteenth buffers 122a to 122o may be reverse to that of the first embodiment or the like. In this case, the order in which the main CPU 63 executes the process for changing the output state of each signal coincides with the order in which the management CPU 112 executes the confirmation process for the buffers 122a to 122o.

  (24) When information stored in the main ROM 64 is externally output using the reading terminal 102, one of a program and data may be selectively externally output, and a predetermined program It is good also as a structure which can output only to the outside. In this case, the information to be analyzed can be selectively read by the reading device. As a configuration for selectively outputting information to the outside, the main CPU 63 selects information to be externally output from selection information received from the reading device through the reading terminal 102, and outputs the selected information to the outside. Can be considered.

  (25) Other information to be externally output through the reading terminal 102 for externally outputting the program stored in the main ROM 64 is not limited to history information and various parameters. For example, when an abnormality occurs May be configured to store the history information of the occurrence of the abnormality and output the stored history information to the outside through the reading terminal 102.

  (26) The detection sensors 42a to 48a are individually provided for the out port 24a, the general winning port 31, the special electricity winning device 32, the first operating port 33, and the second operating port 34, and the detection sensors 42a to 48a are provided. The total number of game balls discharged from the game area PA by grasping the total number of game balls detected in this way is not limited to this. For example, all of the game balls discharged from the game area PA It is good also as a structure which provides the discharge | emission detection sensor which detects the game ball which passes the said channel | path area | region while providing the channel | path area | region where one game ball will pass one by one. In this case, it is possible to grasp the total number of game balls discharged from the game area PA by using the detection result of the discharge detection sensor. Further, in the configuration, as in each of the above-described embodiments, a detection sensor for detecting the number of game balls received in each of the general winning port 31, the special winning device 32, the first operating port 33, and the second operating port 34. By providing 42a to 47a, it is possible to calculate the ratio of the number of game balls that have entered each of the entrance parts to the total number of game balls that have been discharged from the game area PA.

  (27) Display control based on a command transmitted from the main control device 60 instead of a configuration in which the display control device 82 is controlled by the sound emission control device 81 based on a command transmitted from the main control device 60 The device 82 may be configured to control the sound emission control device 81. Further, instead of the configuration in which the sound emission control device 81 and the display control device 82 are separately provided, the both control devices may be provided as one control device, and one of the two control devices has a function. May be integrated into the main control device 60, and both functions of these two control devices may be integrated into the main control device 60. The configuration of the command transmitted from the main control device 60 to the sound emission control device 81 and the configuration of the command transmitted from the sound emission control device 81 to the display control device 82 are also arbitrary.

  (28) Other types of pachinko machines different from the above embodiments, for example, a pachinko machine in which an electric accessory is released a predetermined number of times when a game ball enters a specific area of a special device, or a game ball in a specific area of a special device The present invention can also be applied to a pachinko machine that generates a right if a player enters, a pachinko machine equipped with other objects, an arrangement ball machine, a sparrow ball, and other gaming machines.

  Also, a non-ball-type gaming machine, for example, a plurality of reels with a plurality of types of symbols attached in the circumferential direction, starts rotation of the reel by inserting a medal and operating a start lever, and a stop switch is operated. If a specific symbol or a combination of specific symbols is established on the active line visible from the display window after the reel has stopped after a predetermined time has passed, a privilege such as paying out medals is given to the player The present invention can also be applied to a slot machine.

  In addition, the gaming machine main body supported by the outer frame so as to be openable and closable is provided with a storage unit and a capture device, and the start lever is operated after a predetermined number of game balls stored in the storage unit are captured by the capture device. Thus, the present invention can also be applied to a gaming machine in which a pachinko machine and a slot machine are fused, which starts rotating the reel.

  When the present invention is applied to a slot machine or a gaming machine in which a pachinko machine and a slot machine are integrated, for example, a result of a lottery process of a combination executed when starting one game based on an operation of a start lever is history information. The actual winning probability of each role may be calculated using the history information, and when a transition to a special gaming state such as a bonus game occurs, it is stored as history information, and the history The configuration may be such that the actual transition probability to the special gaming state is calculated using information, or the ratio of the number of staying games in the special gaming state to the total number of digested games may be calculated. The history information and various parameters may be readable by a reading device, or notification corresponding to the calculation results of various parameters may be performed by the gaming machine itself.

  (29) The characteristic configurations of the first to twelfth embodiments may be applied to each other in any combination. For example, the characteristic configuration of the first embodiment, the characteristic configuration of the sixth embodiment, and the characteristic configuration of the twelfth embodiment may be combined. You may combine the characteristic structure of embodiment, the characteristic structure of the said 4th Embodiment, and the characteristic structure of the said 8th Embodiment.

  (30) In the thirteenth to sixteenth embodiments, the nail 213, 214, 262, 322 and the base 351 that distribute the path of the game ball B1 in two ways are the probability of one distribution result and the other distribution It is good also as a structure which distributes the course of game ball | bowl B1 in the aspect from which a significant difference comes out with the probability as a result. For example, in the first left and right allocating nail 213 of the thirteenth embodiment, the area of the first allocating surface 217a is larger than the area of the second allocating surface 218a. All of the game balls B1 that are positioned and a part of the game balls B1 that are positioned on the front side are allocated to the right side, and only the remaining game balls B1 that are positioned on the front side of the game area PA are allocated to the left side. In this way, by adopting a configuration that makes it easier to hit the first distribution surface 217a than the second distribution surface 218a, the probability that the game ball B1 colliding with the first left / right distribution nail 213 will win the operating ports 33, 34 is increased. The player's attention can be drawn to the behavior of the game ball B1 around the first left / right sorting nail 213.

  Also, for example, in the front / rear distribution nail 262 of the fourteenth embodiment, the area of the first distribution surface 264a is larger than the area of the second distribution surface 265a, so that the back side of the game area PA All of the game balls B1 positioned at the front and a part of the game balls B1 positioned at the front side are distributed to the back side, and only the remaining game balls B1 positioned at the front side of the game area PA are distributed to the front side. . In this way, by adopting a configuration that is easier to hit the first distribution surface 264a than the second distribution surface 265a, the probability that the game ball B1 colliding with the front / rear distribution nail 262 wins the operating ports 33, 34 is increased. The player's attention can be drawn to the behavior of the game ball B1 around the sorting nail 262.

  Further, for example, in the repelling nail 322 of the fifteenth embodiment, the length of the high repulsion portion 334d is longer than the length of the low repulsion member 333, so that the game ball B1 located on the far side of the game area PA And a part of the game ball B1 located on the near side collide with the repelling nail 322 and greatly bounce off, and only the remaining game ball B1 located on the near side of the game area PA collides with the repelling nail 322. Bounce small. In this way, by adopting a configuration that makes it easier to hit the high repulsion portion 334d than the low repulsion member 333, the probability that the game ball B1 colliding with the repulsion nail 322 wins the operating ports 33 and 34 is increased, and the game balls around the repulsion nail 322 The player's attention can be drawn to the behavior of B1.

  Further, for example, in the front / rear sorting table 351 of the sixteenth embodiment, the area of the first downstream surface 372 is larger than the area of the second downstream surface 373, so that it is located on the far side of the game area PA. All of the game balls B1 and a part of the game balls B1 located on the front side are assigned to the back side, and only the remaining game balls B1 located on the front side of the game area PA are assigned to the front side. In this way, the configuration is such that the rolling on the first downstream surface 372 is easier to roll on the first downstream surface 372 than on the second downstream surface 373, so that the game ball B 1 rolling on the front / rear sorting table 351 wins the operation ports 33 and 34. And the player's attention can be drawn to the behavior of the game ball B1 around the front / rear sorting table 351.

  (31) The game board of each of the above embodiments is not limited to plywood, and may be an acrylic board. Moreover, in each said embodiment, you may utilize the board made from a polycarbonate as a game board. In short, any plate-like member that can define the game area PA where the game ball B1 flows down may be used. Here, the game board includes a game board 24 (FIG. 3) in the first to twelfth embodiments, a game board 233 (FIG. 50) in the thirteenth embodiment, and a game in another form of the thirteenth embodiment. Board 235 (FIG. 59), game board 236 (FIG. 60), game board 237 (FIG. 61 (b)), game board 238 (FIG. 62 (b)), game board 261 in the fourteenth embodiment (FIG. 63) The game board 321 (FIG. 68) in the fifteenth embodiment, the game board 341 (FIG. 72) in the sixteenth embodiment, the game board 381 (FIG. 75) in another form of the sixteenth embodiment, and the seventeenth implementation A game board 421 (FIG. 78) in the form, a game board 451 (FIG. 82) in the eighteenth embodiment, a game board 452 (FIG. 87 (a)) in another form of the eighteenth embodiment, and the twenty-second embodiment. Game board 931 (FIG. 102 It is included.

  (32) The solder in the nineteenth to twenty-second embodiments is a connecting means made of a low melting point component such as lead or bismuth or a tin alloy containing silver. As a connection means, lead-free solder (a tin alloy containing copper and zinc and not containing lead) may be used. In addition to solder, a metal such as iron, nickel, copper, zinc, silver, indium, gold, bismuth, or an alloy of these metals may be used as the connection means. The connection means may be any means that can attach the electronic component or connector to the substrate by adhering to the terminals of the electronic component or connector and the connection region of the substrate in a molten state and solidifying. When using the connection means, by providing a hole for preventing a short circuit around the connection region on the substrate, there is a possibility that the connection means around the adjacent terminals communicate to form a short circuit. Can be reduced. Here, the terminals include a terminal 775 and pins 784, 784a to 784t. The connection region on the substrate includes via holes 793, 793a to 793t. The connection region includes a hole that is formed up to a middle position of the substrate and does not penetrate the substrate, in addition to a through hole that vertically penetrates the substrate. Further, the holes for preventing the short circuit are the short circuit preventing hole 761 (FIG. 92B) in the nineteenth embodiment, the inclined short circuit preventing hole 861 (FIG. 98A) in another form of the nineteenth embodiment, 20, separate short-circuit prevention holes 871, 874 (FIG. 99 (a)), separate form short-circuit prevention holes 875-878, 886, 887 in another form of the twentieth embodiment (FIG. 100 (a), 3 Direction separation type short-circuit prevention holes 881, 884 (FIG. 100B), short-circuit prevention hole groups 891 to 895, 921 to 925 (FIG. 101) in the twenty-first embodiment, short-circuit prevention holes 761 in the twenty-second embodiment ( FIG. 103 (b)) includes separate short-circuit prevention holes 871, 874 (FIG. 99 (a)) in another form of the twenty-second embodiment.

  Moreover, you may apply the structure of the said another form with arbitrary combinations with respect to the structure which applied the characteristic structure of the said 1st-22nd embodiment with the predetermined combination.

<Invention Group Extracted from Each Embodiment>
Hereinafter, the characteristics of the invention group extracted from each of the above-described embodiments will be described while showing effects and the like as necessary. In the following, for easy understanding, the corresponding configuration in each of the above embodiments is appropriately shown in parentheses, but is not limited to the specific configuration shown in parentheses.

<Feature A group>
Feature A1. Predetermined ball entry means (out port 24a, general winning port 31, special winning device 32, first operating port 33, second operating port 34) into which a game ball flowing down the game area can enter;
When a game ball enters the predetermined ball entry means, specific storage execution means (incoming detection processing in the main CPU 63 is executed so that information corresponding to the game ball is stored in the specific storage means (main RAM 65). Function)
A privilege for executing a process for giving a privilege to a player based on the fact that information corresponding to a game ball entering the predetermined ball entry means is stored in the specific storage means A granting unit (a function for executing the process of step S217 in the main CPU 63, a function for executing the process of step S408 in the payout CPU 92);
In a gaming machine equipped with
When a game ball enters the predetermined ball entry means, information corresponding to the game ball is stored in the predetermined storage means (history memory 117 in the first to ninth and eleventh to twelfth embodiments, the tenth embodiment). Is executed in the main RAM 65), and predetermined information (first information) that enables the number of game balls entering the predetermined ball entry means or the frequency of entry into the predetermined ball entry means to be specified by the game machine or a device outside the game machine. In the eighth and twelfth embodiments, the predetermined storage execution means (first information is stored in the predetermined storage means in the history information, and in the ninth to eleventh embodiments, the numerical information measured by the counter). In the ninth to eleventh and eleventh to twelfth embodiments, a function for executing history setting processing in the management CPU 112, and in the tenth embodiment, steps S2302, S2305, and S2308 in the main CPU 63 are executed. Step S2312, step S2316, the gaming machine characterized by comprising a function of executing the processing of step S2320 and step S2323).

  According to the feature A1, when a game ball enters a predetermined ball entry means, information corresponding to the game ball is stored in the specific storage means, and when the information is stored in the specific storage means, a privilege is given to the player Is done. As a result, the player plays the game while expecting the game ball to enter the predetermined ball entry means. In this configuration, when a game ball enters the predetermined ball entry means, information corresponding to the game ball is stored in the predetermined storage means, and the number of balls entered or the frequency of the ball entry into the predetermined ball entry means. Predetermined information that can be specified by the control means of the gaming machine or a device external to the gaming machine is stored in the predetermined storage means. As a result, it becomes possible to store and hold information for managing the number of game balls entering or the frequency of entering the predetermined ball entry means in the game machine. By using this managed information, it is possible to store and hold information. It becomes possible to appropriately manage the manner of entering the game ball into the ball entry means. In addition, since the predetermined information is stored and held by the gaming machine itself, it is possible to prevent unauthorized access and unauthorized modification to the predetermined information.

  Feature A2. The gaming machine according to Feature A1, wherein the predetermined information does not trigger execution of a process for giving a privilege to a player.

  According to the feature A2, the purpose is to appropriately manage the entrance mode of the game ball to the predetermined entrance means by the predetermined information not triggering the execution of the process for granting a privilege to the player It is possible to store and hold predetermined information in an information form.

Feature A3. Specific entry means (out port 24a, general winning port 31, special prize winning device 32, first operating port 33, second operating port 34) capable of entering a game ball flowing down the game area are provided,
The predetermined storage execution means is configured such that, when a game ball enters the specific ball entry means, storage of information corresponding thereto is executed in the predetermined storage means, and the game ball enters the specific ball entry means. Specific information that enables the number of balls to be specified by the control means of the gaming machine or a device external to the gaming machine (history information in the first to eighth and twelfth embodiments, and a counter in the ninth to eleventh embodiments) The gaming machine according to feature A1 or A2, wherein the measured numerical information) is stored in the predetermined storage means.

  According to the feature A3, not only predetermined information corresponding to the predetermined entry means but also specific information corresponding to the specific entry means is stored in the predetermined storage means. As a result, it is possible to manage not only the manner of entering the game ball into the predetermined entrance means but also the manner of entering the game ball into the specific entrance means. Further, by using both the predetermined information and the specific information, it becomes possible to manage the ratio of the pitching frequency between the predetermined pitching means and the specific pitching means.

  Feature A4. All the entry means for discharging the entered game balls from the game area, including the predetermined entry means, are stored in the predetermined storage means for information corresponding to the occurrence of the entry of the game balls. The gaming machine according to any one of features A1 to A3, which is a ball entry means.

  According to the feature A4, all the entrance means for discharging the game balls from the game area are managed by using the information stored in the predetermined storage means, so that the entrance frequency for any entrance means Can be managed using the information stored in the predetermined storage means. In addition, it is possible to manage the ratio of the number of game balls entering the predetermined ball entry means with respect to the number of game balls discharged from the game area using information stored in the predetermined storage means.

  Feature A5. The gaming machine according to any one of features A1 to A4, wherein the predetermined information includes information corresponding to a timing at which a game ball enters the predetermined ball entry means.

  According to the feature A5, since the information corresponding to the timing at which the game ball enters the predetermined entry means is included in the predetermined information, the use of the predetermined information allows the game ball to enter the predetermined entry means. It becomes possible to grasp the entry history in detail.

  Feature A6. The gaming machine according to any one of features A1 to A5, wherein the predetermined information is count information of the number of game balls that have entered the predetermined ball entry means.

  According to the feature A6, the predetermined information is the counting information of the number of game balls that have entered the predetermined ball entry means, so that the game ball can enter the predetermined ball entry means while suppressing the information capacity of the predetermined information. Can be managed.

  Feature A7. The predetermined storage execution means is means for allowing the predetermined storage means to store information that makes it possible to specify whether or not a game ball entering the predetermined ball entry means is in a predetermined situation (first operation). In the first to seventh embodiments, the function of executing steps S804 and S809 in the management CPU 112, in the eighth embodiment, the function of executing processing of step S2104 in the management CPU 112, and in the ninth embodiment, the management The gaming machine according to any one of features A1 to A6, further comprising a function of executing the processing of step S2203 in the side CPU 112).

  According to the feature A7, it is possible to manage the entrance mode of the game ball to the predetermined entrance means by distinguishing whether or not the situation is a predetermined situation.

  Feature A8. Any one of features A1 to A7, comprising external output means (a function for executing external output processing in the management CPU 112) for outputting the information stored in the predetermined storage means to a device outside the gaming machine. A gaming machine according to claim 1.

  According to the feature A8, it is possible to read the information stored in the predetermined storage means from the gaming machine and analyze the entrance mode of the game ball to the predetermined entry means using the read information.

Feature A9. Program output means (function to execute the process of step S903 in the main CPU 63) for outputting a control program to a device outside the gaming machine using the information output unit (reading terminal 102),
The game machine according to Feature A8, wherein the external output means outputs the information stored in the predetermined storage means to a device external to the game machine using the information output unit.

  According to the feature A9, it is possible to externally output the information stored in the predetermined storage unit by using the information output unit for externally outputting the control program. As a result, it is possible to externally output the information stored in the predetermined storage unit while preventing the configuration from becoming complicated.

  Feature A10. Means for identifying whether the information to be output from the information output unit is the information stored in the predetermined storage means or the control program, and outputting information corresponding to the identification result (mainly) A gaming machine according to Feature A9, further comprising a function of executing the process of step S902 in the side CPU 63).

  According to the feature A10, in the configuration in which the information output unit for outputting the control program to the outside is used to output the information stored in the predetermined storage unit to the outside, the information to be externally output is the control program and the predetermined information. Which of the information stored in the storage means is specified on the gaming machine side, and the specified information is output to the outside. As a result, only necessary information can be read out even when the information output unit is also used.

Feature A11. First control means (main-side CPU 63) having the specific storage execution means;
Second control means (management CPU 112) having the predetermined storage execution means;
The gaming machine according to any one of features A1 to A10, comprising:

  According to the feature A11, the processing load of the first control unit is extremely increased because the second control unit provided separately from the first control unit having the specific storage execution unit has the predetermined storage execution unit. It is possible to achieve the excellent effects as already described while avoiding this.

  Feature A12. The gaming machine according to Feature A11, wherein the first control means and the second control means are provided on the same chip.

  According to feature A12, since the first control means and the second control means are provided on the same chip, unauthorized access to the communication path between the first control means and the second control means is prevented. It becomes possible to stop.

Feature A13. Specific entry means (out port 24a, general winning port 31, special prize winning device 32, first operating port 33, second operating port 34) capable of entering a game ball flowing down the game area are provided,
The predetermined storage execution means is configured to cause the predetermined storage means to store information corresponding to a game ball entering the specific ball entry means, so that the game to the specific ball entry means is executed. Specific information (the history information in the first to eighth and twelfth embodiments, the ninth to the ninth information) that can be specified by the control means of the gaming machine or the device outside the gaming machine. In the eleventh embodiment, numerical information measured by the counter) is stored in the predetermined storage means,
The first control means includes
First transmission means for transmitting first information to the second control means using a first signal path when a game ball enters the predetermined entry means (first to seventh signals of the main CPU 63). Function to output either), and
Second transmitting means for transmitting second information to the second control means using the second signal path when a game ball enters the specific entry means (the first to seventh signals of the main CPU 63). Function to output either), and
A gaming machine according to Feature A11 or A12, wherein

  According to the feature A13, not only the predetermined information corresponding to the predetermined entry means but also the specific information corresponding to the specific entry means is stored in the predetermined storage means. As a result, it is possible to manage not only the manner of entering the game ball into the predetermined entrance means but also the manner of entering the game ball into the specific entrance means. Further, by using both the predetermined information and the specific information, it becomes possible to manage the ratio of the pitching frequency between the predetermined pitching means and the specific pitching means.

  Further, when a game ball enters the predetermined ball entry means, the first information is transmitted to the second control means using the first signal path, and when a game ball enters the specific ball entry means. The second information is transmitted to the second control means using the second signal path. As a result, the type of information to be transmitted corresponds to the signal path, and the configuration for distinguishing the type of each information by the second control means can be simplified.

  Feature A14. The first control means transmits, to the second control means using the third route, information for specifying that the second control means can specify whether or not a predetermined situation is present. (In the first, third to ninth and twelfth embodiments, the function of outputting any of the eighth to tenth signals in the main CPU 63, and in the second embodiment, the signal in the open / close execution mode in the main CPU 63, The gaming machine according to feature A13, further comprising a function of outputting either a high frequency support mode signal or a door opening signal.

  According to the feature A14, it is possible to manage whether the game ball enters the predetermined ball entry means and the game ball entry mode into the specific ball entry means by distinguishing whether or not the situation is a predetermined situation. In addition, since the information for identification that can identify whether or not the predetermined situation is present is transmitted to the second control means using the third route, the information for identification is transmitted to the second information by the second control means. It is possible to simplify the configuration for distinguishing from other information such as two information.

  Feature A15. The first control means provides the second control means with identification information indicating that the first information corresponds to the predetermined pitching means and the second information corresponds to the specific pitching means. The gaming machine according to Feature A13 or A14, comprising identification information transmitting means for transmitting (a function for executing recognition processing in the main CPU 63).

  According to the feature A15, identification information indicating that the first information corresponds to the predetermined entry means and the second information corresponds to the specific entry means is transmitted from the first control means to the second control means. Therefore, it is not necessary to previously store the correspondence relationship of these pieces of information in the second control unit. Thereby, the versatility of a 2nd control means can be improved.

  Feature A16. The gaming machine according to Feature A15, wherein the identification information transmitting means transmits the identification information to the second control means when supply of operating power to the first control means is started.

  According to feature A16, when supply of operating power to the first control means is started, the identification information is transmitted from the first control means to the second control means. In a situation where a game ball can enter the ball, it is possible to specify the correspondence between the information transmitted from the first control means and the ball entry means by the second control means. Become.

  Feature A17. The identification information transmitting unit transmits the identification information to the second control unit using at least one of the first signal path and the second signal path. The feature according to A15 or A16, Gaming machine.

  According to the feature A17, the identification information is transmitted to the second control means using at least one of the first signal path and the second signal path, and thus a configuration in which a dedicated signal path for transmitting the identification information is provided. Compared to the above, the communication configuration can be simplified.

  Feature A18. When the second control means receives the identification information, the second control means can specify that the first information corresponds to the predetermined entry means and that the second information corresponds to the specific entry means. Any one of features A15 to A17, comprising: means for storing correspondence relation information to be stored in correspondence relation storage means (correspondence relation memory 116) (function for executing correspondence relation setting processing in the management side CPU 112) The gaming machine according to 1.

  According to the feature A18, the correspondence between the information transmitted from the first control unit and the ball entry unit is stored in the second control unit. As a result, information that enables the second control means to specify the ball entry means corresponding to the information to be transmitted is provided to the second control means every time the first information or the second information is transmitted from the first control means. There is no need to do it. Therefore, it is possible to suppress the information amount of the first information and the second information.

Feature A19. The first control means transmits third information enabling the second control means to specify whether or not a predetermined situation is present to the second control means using a third route. (In the first, third to ninth and twelfth embodiments, the function of outputting any of the eighth to tenth signals in the main CPU 63, and in the second embodiment, the signal in the open / close execution mode in the main CPU 63, High frequency support mode signal or door open signal output function)
The second control means can recognize that the third information is information that can specify whether or not the predetermined situation is present without receiving the identification information. A gaming machine according to any one of A18.

  According to the feature A19, it is possible to manage whether the game ball enters the predetermined ball entry means and the game ball entry mode into the specific ball entry means by distinguishing whether or not the situation is a predetermined situation. Further, the fact that the third information is information that can specify whether or not the predetermined situation is present can be specified by the second control means without receiving identification information from the first control means. . As a result, the information form of the identification information can be prevented from becoming complicated.

  Feature A20. The second control means has a receiving unit capable of receiving information from the first control means, more than the number of types of information that need to be transmitted from the first control means to the second control means. The gaming machine according to any one of features A13 to A19, wherein a large number of receiving units (buffers 122a to 122p) are provided.

  According to feature A20, since the second control means is provided with more receiving units than the number of types of information that need to be transmitted from the first control means to the second control means, Accordingly, even if the number of types of the information increases or decreases, it is possible to cope without changing the configuration related to the receiving unit. Therefore, the versatility of the second control means can be improved.

Feature A21. First external output means (management) that outputs information of a combination of the predetermined information stored in the predetermined storage means and information that makes it possible to recognize that it corresponds to the predetermined pitching means to a device outside the gaming machine Function for executing external output processing in the side CPU 112),
Second external output means (management) that outputs information of a combination of the specific information stored in the predetermined storage means and information that makes it possible to recognize that the specific entry means corresponds to the device outside the gaming machine Function for executing external output processing in the side CPU 112),
The gaming machine according to any one of features A13 to A20, comprising:

  According to the feature A21, the information stored in the predetermined storage means is read from the gaming machine, and using the read information, the game ball entering the predetermined ball entry means and the game ball entering the specific ball entry means It is possible to specify the entrance mode. In addition, when the external output is performed, information on a combination of the predetermined information and information that makes it possible to recognize that it corresponds to the predetermined pitching means is output to the outside, and the specific information corresponds to the specific pitching means. The information of the combination with the information that makes it possible to recognize that is being performed is output to the outside. Thereby, it becomes possible to specify each entrance mode using the information read from the predetermined storage means.

  Feature A22. Using the predetermined information, information calculating means (first, second, sixth, eighth, ninth, and third) for calculating the mode information corresponding to the entering mode of the game balls in the game area in the predetermined period. 10. In the twelfth embodiment, the function of executing the processing of step S1008, step S1013, and step S1017 in the management side CPU 112. In the third embodiment, the processing of step S1408, step S1413, and step S1417 in the management side CPU 112 is executed. Function, a function for executing the process of step S1602 in the management CPU 112 in the fourth embodiment, a function for executing a process of step S1802 in the management CPU 112 in the fifth embodiment, and a function in the management CPU 112 in the seventh embodiment. A function for executing the process of step S2005, The gaming machine according to any one of the features A1 to A21, characterized in that the facilities embodiment has a function) for executing the processing of step S2603 in the main side CPU 63.

  According to the feature A22, the aspect information corresponding to the entry state of the game ball is calculated by the gaming machine using the predetermined information stored in the predetermined storage means. Thereby, for example, it becomes possible for the gaming machine itself to perform processing corresponding to the entry mode of the game ball, or it is possible to externally output the mode information that is the result of calculation using predetermined information. .

Feature A23. The predetermined storage execution means is means for causing the predetermined storage means to include information that makes it possible to specify whether or not the game ball entering the predetermined ball entry means is in a predetermined situation (the first storage means) In the seventh embodiment, the function of executing the processing of step S804 and step S809 in the management CPU 112, the function of executing the processing of step S2104 in the management CPU 112 in the eighth embodiment, and the management side in the ninth embodiment A function of executing the processing of step S2203 in the CPU 112),
The information calculation means is a means (first, second, second) for calculating the mode information by extracting or excluding the predetermined information corresponding to the game ball entering the predetermined ball entry means in the predetermined situation. In the sixth, eighth, ninth, tenth, and twelfth embodiments, the function of executing the processing of step S1008, step S1013, and step S1017 in the management side CPU 112, and in the third embodiment, step S1408 in the management side CPU 112, A function for executing the processes of step S1413 and step S1417, a function for executing the process of step S1602 in the management CPU 112 in the fourth embodiment, and a function of executing the process of step S1802 in the management CPU 112 in the fifth embodiment; In the seventh embodiment, step S2005 in the management side CPU 112 is performed. Ability to run the process, the gaming machine according to the features A22 in the eleventh embodiment which is characterized in that a function) for executing the processing of step S2603 in the main side CPU 63.

  According to the feature A23, it is possible to calculate the mode information corresponding to the entrance mode of the game ball by distinguishing whether or not the situation is a predetermined situation.

  Feature A24. Means (first, second, eighth, ninth, tenth and twelfth implementations) for erasing the predetermined information stored in the predetermined storage means when the mode information is calculated by the information calculation means The feature A22 or A23 includes the function of executing the process of step S1019 in the management CPU 112 in the embodiment, and the function of executing the process of step S1605 in the management CPU 112 in the fourth embodiment. Gaming machine.

  According to the feature A24, when the mode information is calculated, the predetermined information stored in the predetermined storage unit is deleted, and thus it is difficult to generate an event that the predetermined information exceeds the storage capacity of the predetermined storage unit. It becomes possible to make it.

  Feature A25. Even if the mode information is calculated by the information calculation unit, the state in which the predetermined information used when calculating the mode information is stored in the predetermined storage unit is maintained. Or the gaming machine according to A23.

  According to the feature A25, even if the aspect information is calculated, the predetermined information used when calculating the aspect information is stored and held in the predetermined storage unit, so that the aspect information is read and the game ball enters When analyzing an aspect, it is possible to refer not only to the aspect information but also to predetermined information that is the basis for the calculation of the aspect information.

  Feature A26. When the supply of operating power to the control means having the specific storage execution means is stopped, or when the supply of operating power to the control means having the specific storage execution means is started, The gaming machine according to any one of features A22 to A25, wherein the aspect information is calculated.

  According to the feature A26, since the mode information is calculated when the supply of the operating power to the control unit is stopped or when the supply of the operating power to the control unit is stopped, the mode information is calculated for each business day. It becomes possible to manage.

  Feature A27. The information calculation means calculates the aspect information when a calculation opportunity that can repeatedly occur in a situation where operating power is supplied to the control means having the specific storage execution means is generated. The gaming machine according to any one of A26.

  According to feature A27, since the mode information is calculated every time an operation trigger occurs repeatedly in a situation where operating power is supplied to the control means, the mode information is managed in detail within the range of one business day. Is possible.

Feature A28. The information calculation means calculates the mode information every time the period measured by the period measurement means (measurement counter provided in the main RAM 65) becomes a predetermined period,
The period measurement means stops the period measurement in a situation where the game is not executed, and resumes the measurement in the period from the state before the stop when the game is started in the situation where the period measurement is stopped. The gaming machine according to any one of features A22 to A27, characterized by:

  According to the feature A28, since the aspect information is calculated every time the predetermined period elapses, it is possible to easily adjust the calculation frequency of the aspect information only by adjusting the predetermined period. In this case, in a situation where the game is not being executed, the measurement for a predetermined period is stopped, and when the game is started, the measurement for the predetermined period is resumed from the state before the stop. As a result, it is possible to exclude a situation in which a game is not being executed from the calculation target of the aspect information, and it is possible to appropriately derive aspect information in a situation in which a game is being executed.

  Feature A29. Features A22 to A28, characterized by comprising external output means (function for executing external output processing in the management CPU 112) for outputting the mode information calculated by the information calculation means to a device outside the gaming machine. The gaming machine according to any one of the above.

  According to the feature A29, it is possible to easily grasp the entrance mode of the game ball by outputting the mode information to a device outside the game machine.

  Feature A30. The gaming machine according to Feature A29, wherein the external output means outputs the predetermined information to a device outside the gaming machine when the mode information is output to a device outside the gaming machine.

  According to the feature A30, not only the mode information but also the predetermined information is output to a device outside the gaming machine, so that when the mode information is read and the game ball entering mode is analyzed, It is possible to refer to the predetermined information that is the basis for the calculation of the mode information.

Feature A31. First control means (main-side CPU 63) having the specific storage execution means;
Second control means (management CPU 112) having the external output means;
With
The external output means outputs the mode information to a device outside the gaming machine when the second control means receives the output instruction information transmitted from the first control means. A gaming machine according to A30.

  According to the feature A31, in a configuration in which the processing load of the first control unit is reduced by providing the second control unit having the external output unit separately from the first control unit, the mode is based on an instruction from the first control unit. It is possible to output information to a device outside the gaming machine.

Feature A32. The information calculation means calculates the mode information every time a predetermined calculation opportunity occurs,
Result storage execution means (steps S1410, S1414, and S1418 in the management side CPU 112 in the third embodiment) for sequentially storing the mode information calculated by the information calculation means in the calculation result storage means (calculation result memory 131). The gaming machine according to any one of features A22 to A31, further comprising a function of executing the process of step S1604 in the management CPU 112 in the fourth embodiment.

  According to the feature A32, the mode information can be accumulated in the gaming machine. Thereby, when managing the entrance mode of a game ball, it becomes possible to read several mode information collectively.

Feature A33. The result storage execution means includes
Means for determining whether or not the mode information is storage target information (a function of executing the process of step S1603 in the management CPU 112);
Means for storing the aspect information in the calculation result storage means when the aspect information is the storage target information (function for executing the process of step S1604 in the management CPU 112);
The gaming machine according to Feature A32, further comprising:

  According to the feature A33, when the mode information of the calculated result corresponds to the storage target information, the mode information is stored in the calculation result storage unit. Thereby, it is possible to limit the mode information to be stored in the calculation result storage means, and it is possible to suppress the storage capacity necessary for the calculation result storage means.

  Feature A34. The game according to Feature A32 or A33, wherein the result storage execution unit causes the calculation result storage unit to store information that can identify a time when the mode information is calculated, in association with the mode information. Machine.

  According to the feature A34, information that can specify the time when the mode information is calculated is attached to the mode information. Thereby, it becomes possible to analyze each aspect information, grasping | ascertaining the time when each aspect information was calculated.

Feature A35. First control means (main-side CPU 63) having the specific storage execution means;
Second control means (management CPU 112) having the information calculation means;
With
The information calculation means calculates the mode information when the second control means receives the calculation trigger information transmitted from the first control means. Any one of the features A22 to A34, Game machines.

  According to the feature A35, in the configuration in which the processing load of the first control unit is reduced by providing the second control unit having the information calculation unit separately from the first control unit, the mode is based on an instruction from the first control unit. Information can be calculated by the second control means.

  Feature A36. Provided with notification control means (function for executing the processes of steps S2605, S2607 and S2608 in the main CPU 63) for controlling the notification means (notification light-emitting unit 151) so as to notify the content corresponding to the aspect information. The gaming machine according to any one of features A22 to A35, wherein:

  According to the feature A36, the content corresponding to the mode information is notified by the gaming machine itself. Thereby, the manager of the game hall or the like can grasp the management result of the entrance mode of the game ball without reading the mode information from the gaming machine.

Feature A37. The control board (main control board 61) provided with the notification control means is housed in a board box,
The game machine according to Feature A36, wherein the notification means is provided on the control board.

  According to the feature A37, it is possible to make it difficult to perform unauthorized access to the communication path between the notification control unit and the notification unit.

Feature A38. First control means (main-side CPU 63) having the specific storage execution means;
Second control means (management CPU 112) having the predetermined storage execution means;
With
The gaming machine according to Feature A36 or A37, wherein the first control means includes the information calculation means and the notification control means.

  According to the feature A38, in the configuration in which the processing load of the first control unit is reduced by providing the second control unit having the predetermined storage unit separately from the first control unit, the function for calculating the mode information and the calculation result thereof It is possible to consolidate functions for executing notification corresponding to the first control means.

  Feature A39. The notification control unit controls the notification unit so that the first notification is executed when the aspect information is information of the first range, and when the aspect information is information of the second range. The gaming machine according to any one of features A36 to A38, wherein the notification means is controlled so that the second notification is executed.

  According to the feature A39, the aspect information is not notified as it is, but the content corresponding to the range including the aspect information is notified. As a result, it is possible to prevent the number of notification patterns in the notification unit from becoming excessive, and to reduce the load for controlling the notification unit.

  Feature A40. Features A1 to A1, further comprising means for externally outputting corresponding information corresponding to a game ball entering the predetermined ball entry means (function of executing step S218 in the main CPU 63) The gaming machine according to any one of A39.

  According to the feature A40, when a game ball enters the predetermined ball entry means, corresponding information corresponding to the game ball is externally output, and the predetermined information is stored in the predetermined storage means. This makes it possible to use the predetermined information stored in the predetermined storage means while easily grasping the number and frequency of game balls entering the predetermined entry means by using the correspondence information. It becomes possible to accurately grasp the number and frequency of game balls entering the ball means.

  Feature A41. The gaming machine according to any one of features A1 to A40, wherein the predetermined storage execution unit or the second control unit is provided as a dedicated circuit.

  According to the feature A41, it is possible to achieve an excellent effect as described above in the configuration in which the predetermined storage execution unit or the second control unit is provided as a dedicated circuit.

  In addition, with respect to the configuration of the features A1 to A41, the features A1 to A41, the features B1 to B20, the features C1 to C19, the features D1 to D7, the features E1 to E4, the features F1 to F10, the features G1 to G7, and the features H1 to H1. Any one or a plurality of configurations of H34, features I1 to I11, features J1 to J15, features K1 to K16, features L1 to L12, and features M1 to M5 may be applied. Thereby, it becomes possible to produce a synergistic effect by the combined configuration.

<Feature B group>
Feature B1. When a predetermined event occurs as a result of the game, information corresponding to the predetermined event is stored in a predetermined storage means (history memory 117 in the first to ninth and eleventh to twelfth embodiments, and the main side in the tenth embodiment. The predetermined information (history information in the first to eighth and twelfth embodiments and numerical information measured by the counter in the ninth to eleventh embodiments) is executed by the RAM 65). Predetermined storage execution means to be stored in the storage means (in the first to ninth and eleventh to twelfth embodiments, a function of executing history setting processing in the management CPU 112, in the tenth embodiment, the main CPU 63 In step S2302, step S2305, step S2308, step S2312, step S2316, step S2320, and step S2323, To function),
Information calculation means (first, second, sixth, eighth, ninth, tenth, and twelfth embodiments) that uses the predetermined information to calculate aspect information corresponding to a game result in a predetermined period. In the third embodiment, the management CPU 112 executes the processing of steps S1008, S1013, and S1017. In the third embodiment, the management CPU 112 executes the processing of steps S1408, S1413, and S1417, and the fourth embodiment. In the fifth embodiment, the management CPU 112 executes the process of step S1602. In the fifth embodiment, the management CPU 112 executes the process of step S1802. In the seventh embodiment, the management CPU 112 executes the process of step S2005. Function, in the eleventh embodiment, the main side CP Processing in step S2603 and the ability to perform) in 63,
A gaming machine characterized by comprising:

  According to the feature B1, when a predetermined event occurs, information corresponding to the predetermined event is stored in the predetermined storage unit, and the predetermined information is stored in the predetermined storage unit. This makes it possible to store and hold information for managing the occurrence frequency or occurrence frequency of a predetermined event in the gaming machine, and appropriately manage the occurrence mode of the predetermined event by using this managed information. Can be performed. In addition, since the predetermined information is stored and held by the gaming machine itself, it is possible to prevent unauthorized access and unauthorized modification to the predetermined information.

  Further, using the predetermined information stored in the predetermined storage means, the aspect information corresponding to the game result in the predetermined period is calculated in the gaming machine. Thereby, for example, it becomes possible for the gaming machine itself to perform processing corresponding to the result of the game in a predetermined period, or it is possible to externally output the aspect information that is the result of calculation using the predetermined information Become.

Feature B2. The predetermined storage execution means is means for causing the predetermined storage means to include information that can specify whether or not the occurrence of the predetermined event is in a predetermined situation (in the first to seventh embodiments). The function of executing steps S804 and S809 in the management side CPU 112, the function of executing processing of step S2104 in the management side CPU 112 in the eighth embodiment, and the processing of step S2203 in the management side CPU 112 in the ninth embodiment. Function to be executed)
The information calculation means is means for calculating the mode information by extracting or excluding the predetermined information corresponding to the occurrence of the predetermined event in the predetermined situation (first, second, sixth, eighth, In the ninth, tenth, and twelfth embodiments, the management CPU 112 has a function of executing steps S1008, S1013, and S1017. In the third embodiment, the management CPU 112 performs steps S1408, S1413, and S1417. In the fourth embodiment, a function of executing the process of step S1602 in the management CPU 112, a function of executing the process of step S1802 in the management CPU 112 in the fifth embodiment, and a management in the seventh embodiment. The process of step S2005 in the side CPU 112 is executed Function, the gaming machine according to the features B1 in the eleventh embodiment which is characterized in that a function) for executing the processing of step S2603 in the main side CPU 63.

  According to the feature B2, it is possible to calculate the mode information corresponding to the game result in a predetermined period by distinguishing whether or not the situation is a predetermined situation.

  Feature B3. Means (first, second, eighth, ninth, tenth and twelfth implementations) for erasing the predetermined information stored in the predetermined storage means when the mode information is calculated by the information calculation means The feature B1 or B2 has a function of executing the process of step S1019 in the management CPU 112 in the embodiment, and a function of executing the process of step S1605 in the management CPU 112 in the fourth embodiment. Gaming machine.

  According to the feature B3, when the mode information is calculated, it is difficult to generate an event that the predetermined information stored in the predetermined storage unit is erased and the predetermined information exceeds the storage capacity of the predetermined storage unit. It becomes possible to make it.

  Feature B4. Even if the mode information is calculated by the information calculation unit, the state in which the predetermined information used when calculating the mode information is stored in the predetermined storage unit is maintained B1 Or the gaming machine described in B2.

  According to the feature B4, even if the aspect information is calculated, the predetermined information used when calculating the aspect information is stored and held in the predetermined storage unit, so that the aspect information is read and a game in a predetermined period When analyzing the result, it is possible to refer not only to the mode information but also to the predetermined information that is the basis for the calculation of the mode information.

  Feature B5. The information calculation means calculates the mode information when supply of operating power to the control means (MPU 62) is stopped or supply of operating power to the control means is started. Thru | or the game machine of any one of B4.

  According to the feature B5, since the mode information is calculated when the supply of the operating power to the control unit is stopped or the supply of the operating power to the control unit is started, the mode information is calculated for each business day. It becomes possible to manage.

  Feature B6. Any of the characteristics B1 to B5, wherein the information calculation means calculates the mode information when a calculation opportunity that can repeatedly occur in a situation where operating power is supplied to the control means (MPU 62) is generated. The gaming machine according to 1.

  According to the feature B6, since the mode information is calculated every time the calculation trigger that repeatedly occurs in the situation where the operating power is supplied to the control means, the mode information is managed in detail within the range of one business day. Is possible.

Feature B7. The information calculation means calculates the mode information every time the period measured by the period measurement means (measurement counter provided in the main RAM 65) becomes a predetermined period,
The period measuring means stops measuring the period in a situation where the game is not executed, and resumes the period measurement from the state before the stop when the game is started in the situation where the period measurement is stopped The gaming machine according to any one of features B1 to B6, characterized by:

  According to the feature B7, since the aspect information is calculated every time the predetermined period elapses, it is possible to easily adjust the calculation frequency of the aspect information simply by adjusting the predetermined period. In this case, in a situation where the game is not being executed, the measurement for a predetermined period is stopped, and when the game is started, the measurement for the predetermined period is resumed from the state before the stop. As a result, it is possible to exclude a situation in which a game is not being executed from the calculation target of the aspect information, and it is possible to appropriately derive aspect information in a situation in which a game is being executed.

  Feature B8. Features B1 to B7, comprising external output means (function for executing external output processing in the management CPU 112) for outputting the mode information calculated by the information calculation means to a device outside the gaming machine. The gaming machine according to any one of the above.

  According to the feature B8, it is possible to easily grasp the entrance mode of the game ball by outputting the mode information to a device outside the game machine.

  Feature B9. The gaming machine according to Feature B8, wherein the external output means outputs the predetermined information to a device outside the gaming machine when the mode information is output to a device outside the gaming machine.

  According to the feature B9, not only the mode information but also the predetermined information is output to a device outside the gaming machine, so that when the mode information is read and the game ball entering mode is analyzed, It is possible to refer to the predetermined information that is the basis for the calculation of the mode information.

Feature B10. First control means (main-side CPU 63) having the specific storage execution means;
Second control means (management CPU 112) having the external output means;
With
The external output means outputs the mode information to a device outside the gaming machine when the second control means receives the output instruction information transmitted from the first control means. A gaming machine according to B9.

  According to the feature B10, in the configuration in which the processing load of the first control unit is reduced by providing the second control unit having the external output unit separately from the first control unit, the mode is based on an instruction from the first control unit. It is possible to output information to a device outside the gaming machine.

Feature B11. The information calculation means calculates the mode information every time a predetermined calculation opportunity occurs,
Result storage execution means (steps S1410, S1414, and S1418 in the management side CPU 112 in the third embodiment) for sequentially storing the mode information calculated by the information calculation means in the calculation result storage means (calculation result memory 131). The gaming machine according to any one of the features B1 to B10, further including a function of executing the processing of step S1604 in the management-side CPU 112 in the fourth embodiment.

  According to the feature B11, the mode information can be accumulated in the gaming machine. This makes it possible to read out a plurality of pieces of mode information collectively when managing the mode of game results in a predetermined period.

  Feature B12. The result storage executing means includes means for storing the aspect information in the calculation result storage means when the aspect information is storage target information (function to execute the process of step S1604 in the management CPU 112). The gaming machine of feature B11, characterized by

  According to the feature B12, when the mode information of the calculated result corresponds to the storage target information, the mode information is stored in the calculation result storage unit. Thereby, it is possible to limit the mode information to be stored in the calculation result storage means, and it is possible to suppress the storage capacity necessary for the calculation result storage means.

  Feature B13. The game according to Feature B11 or B12, wherein the result storage execution unit causes the calculation result storage unit to store information that can identify a time when the mode information is calculated, in association with the mode information. Machine.

  According to the feature B13, information that can specify the time when the mode information is calculated is attached to the mode information. Thereby, it becomes possible to analyze each aspect information, grasping | ascertaining the time when each aspect information was calculated.

Feature B14. First control means (main-side CPU 63) having the specific storage execution means;
Second control means (management CPU 112) having the information calculation means;
With
The information calculation unit calculates the mode information when the second control unit receives the calculation trigger information transmitted from the first control unit, according to any one of the features B1 to B13, Game machines.

  According to the feature B14, in the configuration in which the processing load of the first control unit is reduced by providing the second control unit having the information calculation unit separately from the first control unit, the mode is based on an instruction from the first control unit. Information can be calculated by the second control means.

  Feature B15. Provided with notification control means (function for executing the processes of steps S2605, S2607 and S2608 in the main CPU 63) for controlling the notification means (notification light-emitting unit 151) so as to notify the content corresponding to the aspect information. The gaming machine according to any one of features B1 to B14, wherein:

  According to the feature B15, the content corresponding to the mode information is notified by the gaming machine itself. Thereby, the manager of the game hall or the like can grasp the management result of the game in a predetermined period without reading out the mode information from the gaming machine.

Feature B16. The control board (main control board 61) provided with the notification control means is housed in a board box,
The game machine according to Feature B15, wherein the notification means is provided on the control board.

  According to the feature B16, it is possible to make it difficult to perform unauthorized access to the communication path between the notification control unit and the notification unit.

Feature B17. First control means (main-side CPU 63) having the information calculation means and the notification control means;
Second control means (management CPU 112) having the predetermined storage execution means;
A gaming machine according to Feature B15 or B16, characterized by comprising:

  According to the feature B17, in the configuration in which the processing load of the first control unit is reduced by providing the second control unit having the predetermined storage unit separately from the first control unit, the function of calculating the aspect information and the calculation result thereof It is possible to consolidate functions for executing notification corresponding to the first control means.

  Feature B18. The notification control unit controls the notification unit so that the first notification is executed when the aspect information is information of the first range, and when the aspect information is information of the second range. The gaming machine according to any one of features B15 to B17, wherein the notification unit is controlled so that the second notification is executed.

  According to the feature B18, the aspect information is not notified as it is, but the content corresponding to the range including the aspect information is notified. As a result, it is possible to prevent the number of notification patterns in the notification unit from becoming excessive, and to reduce the load for controlling the notification unit.

Feature B19. Predetermined ball entry means (out port 24a, general winning port 31, special winning device 32, first operating port 33, second operating port 34) into which a game ball flowing down the game area can enter;
When a game ball enters the predetermined ball entry means, information corresponding thereto is stored in the predetermined memory means (history memory 117 in the first to ninth and eleventh to twelfth embodiments, the tenth embodiment). Then, predetermined information (history information in the first to eighth and twelfth embodiments, numerical information measured by the counter in the ninth to eleventh embodiments) is executed by the main RAM 65). Is stored in the predetermined storage means (in the first to ninth and eleventh to twelfth embodiments, the function of executing the history setting process in the management CPU 112, in the tenth embodiment The main CPU 63 executes the processing of step S2302, step S2305, step S2308, step S2312, step S2316, step S2320, and step S2323. To function),
Using the predetermined information, information calculating means (first, second, sixth, eighth, ninth, and third) for calculating the mode information corresponding to the entering mode of the game balls in the game area in the predetermined period. 10. In the twelfth embodiment, the function of executing the processing of step S1008, step S1013, and step S1017 in the management side CPU 112. In the third embodiment, the processing of step S1408, step S1413, and step S1417 in the management side CPU 112 is executed. Function, a function for executing the process of step S1602 in the management CPU 112 in the fourth embodiment, a function for executing a process of step S1802 in the management CPU 112 in the fifth embodiment, and a function in the management CPU 112 in the seventh embodiment. A function for executing the process of step S2005, And functions) for executing the processing of step S2603 in the main side CPU63 in facilities form,
A gaming machine characterized by comprising:

  According to the feature B19, when a game ball enters the predetermined ball entry means, the corresponding information is stored in the predetermined storage means, and the predetermined information is stored in the predetermined storage means. Become. As a result, it becomes possible to store and hold information for managing the number of game balls entering or the frequency of entering the predetermined ball entry means in the game machine. By using this managed information, it is possible to store and hold information. It becomes possible to appropriately manage the manner of entering the game ball into the ball entry means. In addition, since the predetermined information is stored and held by the gaming machine itself, it is possible to prevent unauthorized access and unauthorized modification to the predetermined information.

  In addition, using the predetermined information stored in the predetermined storage means, the mode information corresponding to the entrance mode of the game ball is calculated in the gaming machine. Thereby, for example, it becomes possible for the gaming machine itself to perform processing corresponding to the entry mode of the game ball, or it is possible to externally output the mode information that is the result of calculation using predetermined information. .

  Feature B20. The gaming machine according to any one of features B1 to B19, wherein the predetermined storage execution unit or the second control unit is provided as a dedicated circuit.

  According to the feature B20, it is possible to achieve an excellent effect as described above in the configuration in which the predetermined storage execution unit or the second control unit is provided as a dedicated circuit.

  In addition, with respect to the configuration of the features B1 to B20, the features A1 to A41, the features B1 to B20, the features C1 to C19, the features D1 to D7, the features E1 to E4, the features F1 to F10, the features G1 to G7, and the features H1 to H1. Any one or a plurality of configurations of H34, features I1 to I11, features J1 to J15, features K1 to K16, features L1 to L12, and features M1 to M5 may be applied. Thereby, it becomes possible to produce a synergistic effect by the combined configuration.

<Feature C group>
Feature C1. When a predetermined event occurs as a result of the game, information corresponding to the predetermined event is stored in a predetermined storage means (history memory 117 in the first to ninth and eleventh to twelfth embodiments, and the main side in the tenth embodiment. The predetermined information (history information in the first to eighth and twelfth embodiments and numerical information measured by the counter in the ninth to eleventh embodiments) is executed by the RAM 65). Predetermined storage execution means to be stored in the storage means (in the first to ninth and eleventh to twelfth embodiments, a function of executing history setting processing in the management CPU 112, in the tenth embodiment, the main CPU 63 In step S2302, step S2305, step S2308, step S2312, step S2316, step S2320, and step S2323, To function),
Information calculation means (first, second, sixth, eighth) for calculating mode information corresponding to the result of a game in a predetermined period using the predetermined information every time a predetermined calculation opportunity occurs. In the ninth, tenth, and twelfth embodiments, the management CPU 112 has a function of executing steps S1008, S1013, and S1017. In the third embodiment, the management CPU 112 has steps S1408, S1413, and S1417. In the fourth embodiment, a function of executing the process of step S1602 in the management CPU 112, a function of executing the process of step S1802 in the management CPU 112 in the fifth embodiment, and the seventh embodiment. Then, the process of step S2005 in the management side CPU 112 is executed. That function, and function) In the eleventh embodiment of executing the processing in step S2603 in the main side CPU 63,
Result storage execution means (steps S1410, S1414, and S1418 in the management side CPU 112 in the third embodiment) for sequentially storing the mode information calculated by the information calculation means in the calculation result storage means (calculation result memory 131). A function for executing the process of step S1604 in the management CPU 112 in the fourth embodiment),
A gaming machine characterized by comprising:

  According to the feature C1, when a game ball enters the predetermined ball entry means, information corresponding to the game ball is stored in the predetermined storage means, and the predetermined information is stored in the predetermined storage means. . As a result, it becomes possible to store and hold information for managing the number of game balls entering or the frequency of entering the predetermined ball entry means in the game machine. By using this managed information, it is possible to store and hold information. It becomes possible to appropriately manage the manner of entering the game ball into the ball entry means. In addition, since the predetermined information is stored and held by the gaming machine itself, it is possible to prevent unauthorized access and unauthorized modification to the predetermined information.

  Further, using the predetermined information stored in the predetermined storage means, the aspect information corresponding to the game result in the predetermined period is calculated in the gaming machine. Thereby, for example, it becomes possible for the gaming machine itself to perform processing corresponding to the result of the game in a predetermined period, or it is possible to externally output the aspect information that is the result of calculation using the predetermined information Become.

  In addition, it becomes possible to accumulate the mode information in the gaming machine. This makes it possible to read out a plurality of pieces of mode information collectively when managing the mode of game results in a predetermined period.

  Feature C2. The result storage executing means includes means for storing the aspect information in the calculation result storage means when the aspect information is storage target information (function to execute the process of step S1604 in the management CPU 112). The gaming machine according to Feature C1, characterized by:

  According to the feature C2, when the mode information of the calculated result corresponds to the storage target information, the mode information is stored in the calculation result storage unit. Thereby, it is possible to limit the mode information to be stored in the calculation result storage means, and it is possible to suppress the storage capacity necessary for the calculation result storage means.

  Feature C3. The game according to the characteristic C1 or C2, wherein the result storage execution unit causes the calculation result storage unit to store information that enables specification of the time when the mode information is calculated, in association with the mode information. Machine.

  According to the feature C3, information that can specify the time when the mode information is calculated is attached to the mode information. Thereby, it becomes possible to analyze each aspect information, grasping | ascertaining the time when each aspect information was calculated.

Feature C4. The predetermined storage execution means is means for causing the predetermined storage means to include information that can specify whether or not the occurrence of the predetermined event is in a predetermined situation (in the first to seventh embodiments). The function of executing steps S804 and S809 in the management side CPU 112, the function of executing processing of step S2104 in the management side CPU 112 in the eighth embodiment, and the processing of step S2203 in the management side CPU 112 in the ninth embodiment. Function to be executed)
The information calculation means is means for calculating the mode information by extracting or excluding the predetermined information corresponding to the occurrence of the predetermined event in the predetermined situation (first, second, sixth, eighth, In the ninth, tenth, and twelfth embodiments, the management CPU 112 has a function of executing steps S1008, S1013, and S1017. In the third embodiment, the management CPU 112 performs steps S1408, S1413, and S1417. In the fourth embodiment, a function of executing the process of step S1602 in the management CPU 112, a function of executing the process of step S1802 in the management CPU 112 in the fifth embodiment, and a management in the seventh embodiment. The process of step S2005 in the side CPU 112 is executed Function, the gaming machine according to any one of the features C1 to C3, wherein the in the eleventh embodiment which has a function) for executing the processing of step S2603 in the main side CPU 63.

  According to the feature C4, it is possible to calculate the mode information corresponding to the game result in a predetermined period by distinguishing whether or not the situation is a predetermined situation.

  Feature C5. Means (first, second, eighth, ninth, tenth and twelfth implementations) for erasing the predetermined information stored in the predetermined storage means when the mode information is calculated by the information calculation means Any one of the features C1 to C4 is provided with a function for executing the process of step S1019 in the management-side CPU 112 in the embodiment, and a function for executing the process of step S1605 in the management-side CPU 112 in the fourth embodiment. The gaming machine according to 1.

  According to the feature C5, when the mode information is calculated, the predetermined information stored in the predetermined storage unit is erased, so that it is difficult to generate an event that the predetermined information exceeds the storage capacity of the predetermined storage unit. It becomes possible to make it.

  Feature C6. Even if the mode information is calculated by the information calculation unit, the state in which the predetermined information used when calculating the mode information is stored in the predetermined storage unit is maintained C1 The gaming machine according to any one of C5 to C5.

  According to the feature C6, even if the mode information is calculated, the predetermined information used when calculating the mode information is stored and held in the predetermined storage unit, so that the mode information is read and a game in a predetermined period When analyzing the result, it is possible to refer not only to the mode information but also to the predetermined information that is the basis for the calculation of the mode information.

  Feature C7. The information calculating means calculates the mode information when the supply of operating power to the control means (MPU 62) is stopped or when the supply of operating power to the control means is started. A gaming machine according to any one of C6 to C6.

  According to the feature C7, since the mode information is calculated when the supply of the operating power to the control unit is stopped or the supply of the operating power to the control unit is started, the mode information is calculated for each business day. It becomes possible to manage.

  Feature C8. Any of the features C1 to C7, wherein the information calculation means calculates the aspect information when a calculation opportunity that can repeatedly occur in a situation where operating power is supplied to the control means (MPU 62) is generated. The gaming machine according to 1.

  According to the feature C8, since the mode information is calculated every time an operation trigger that repeatedly occurs in a situation where operating power is supplied to the control means, the mode information is managed in detail within the range of one business day. Is possible.

Feature C9. The information calculation means calculates the mode information every time the period measured by the period measurement means (measurement counter provided in the main RAM 65) becomes a predetermined period,
The period measuring means stops measuring the period in a situation where the game is not executed, and resumes the period measurement from the state before the stop when the game is started in the situation where the period measurement is stopped The gaming machine according to any one of features C1 to C8, characterized by:

  According to the feature C9, since the aspect information is calculated every time the predetermined period elapses, the calculation frequency of the aspect information can be easily adjusted only by adjusting the predetermined period. In this case, in a situation where the game is not being executed, the measurement for a predetermined period is stopped, and when the game is started, the measurement for the predetermined period is resumed from the state before the stop. As a result, it is possible to exclude a situation in which a game is not being executed from the calculation target of the aspect information, and it is possible to appropriately derive aspect information in a situation in which a game is being executed.

  Feature C10. Features C1 to C9, comprising external output means (function for executing external output processing in the management CPU 112) for outputting the mode information calculated by the information calculation means to a device outside the gaming machine. The gaming machine according to any one of the above.

  According to the feature C10, it is possible to easily grasp the entering mode of the game ball by outputting the mode information to a device outside the gaming machine.

  Feature C11. The game machine according to Feature C10, wherein the external output means outputs the predetermined information to a device outside the gaming machine when the mode information is output to a device outside the gaming machine.

  According to the feature C11, when not only the mode information but also the predetermined information is output to the device outside the gaming machine, when the mode information is read and the entering mode of the game ball is analyzed, not only the mode information but also the mode information It is possible to refer to the predetermined information that is the basis for the calculation of the mode information.

Feature C12. First control means (main-side CPU 63) having the specific storage execution means;
Second control means (management CPU 112) having the external output means;
With
The external output means outputs the mode information to a device outside the gaming machine when the second control means receives the output instruction information transmitted from the first control means. A gaming machine according to C11.

  According to the feature C12, in the configuration in which the processing load of the first control unit is reduced by providing the second control unit having the external output unit separately from the first control unit, the mode is based on an instruction from the first control unit. It is possible to output information to a device outside the gaming machine.

Feature C13. First control means (main-side CPU 63) having the specific storage execution means;
Second control means (management CPU 112) having the information calculation means;
With
The information calculation unit calculates the mode information when the second control unit receives the calculation trigger information transmitted from the first control unit, according to any one of the features C1 to C12 Game machines.

  According to the feature C13, in the configuration in which the processing load of the first control unit is reduced by providing the second control unit having the information calculation unit separately from the first control unit, the mode is based on an instruction from the first control unit. Information can be calculated by the second control means.

  Feature C14. Provided with notification control means (function for executing the processes of steps S2605, S2607 and S2608 in the main CPU 63) for controlling the notification means (notification light-emitting unit 151) so as to notify the content corresponding to the aspect information. The gaming machine according to any one of features C1 to C13, wherein:

  According to the feature C14, the content corresponding to the mode information is notified by the gaming machine itself. Thereby, the manager of the game hall or the like can grasp the management result of the game in a predetermined period without reading out the mode information from the gaming machine.

Feature C15. The control board (main control board 61) provided with the notification control means is housed in a board box,
The game machine according to Feature C14, wherein the notification unit is provided on the control board.

  According to the feature C15, it is possible to make it difficult to perform unauthorized access to the communication path between the notification control unit and the notification unit.

Feature C16. First control means (main-side CPU 63) having the specific storage execution means;
Second control means (management CPU 112) having the predetermined storage execution means;
With
The gaming machine according to C14 or C15, wherein the first control means includes the information calculation means and the notification control means.

  According to the feature C16, in the configuration in which the processing load of the first control unit is reduced by providing the second control unit having the predetermined storage unit separately from the first control unit, the function for calculating the mode information and the calculation result thereof It is possible to consolidate functions for executing notification corresponding to the first control means.

  Feature C17. The notification control unit controls the notification unit so that the first notification is executed when the aspect information is information of the first range, and when the aspect information is information of the second range. The gaming machine according to any one of features C14 to C16, wherein the notification means is controlled so that the second notification is executed.

  According to the feature C17, the aspect information is not notified as it is, but the content corresponding to the range including the aspect information is notified. As a result, it is possible to prevent the number of notification patterns in the notification unit from becoming excessive, and to reduce the load for controlling the notification unit.

Feature C18. Predetermined ball entry means (out port 24a, general winning port 31, special winning device 32, first operating port 33, second operating port 34) into which a game ball flowing down the game area can enter;
When a game ball enters the predetermined ball entry means, information corresponding thereto is stored in the predetermined memory means (history memory 117 in the first to ninth and eleventh to twelfth embodiments, the tenth embodiment). Then, predetermined information (history information in the first to eighth and twelfth embodiments, numerical information measured by the counter in the ninth to eleventh embodiments) is executed by the main RAM 65). Is stored in the predetermined storage means (in the first to ninth and eleventh to twelfth embodiments, the function of executing the history setting process in the management CPU 112, in the tenth embodiment The main CPU 63 executes the processing of step S2302, step S2305, step S2308, step S2312, step S2316, step S2320, and step S2323. To function),
Information calculation means (first, first, and second) calculating mode information corresponding to a game ball entering mode of the game area in a predetermined period by using the predetermined information every time a predetermined calculation opportunity occurs. In the second, sixth, eighth, ninth, tenth, and twelfth embodiments, the function of executing steps S1008, S1013, and S1017 in the management CPU 112, and in the third embodiment, the steps in the management CPU 112 A function for executing the processing of S1408, step S1413 and step S1417, a function for executing the processing of step S1602 in the management CPU 112 in the fourth embodiment, and a processing of step S1802 in the management CPU 112 in the fifth embodiment Function, step S in the management CPU 112 in the seventh embodiment Function executing the processing in 005, the eleventh feature in the embodiment of executing the processing in step S2603 in the main side CPU 63),
Result storage execution means (steps S1410, S1414, and S1418 in the management side CPU 112 in the third embodiment) for sequentially storing the mode information calculated by the information calculation means in the calculation result storage means (calculation result memory 131). A function for executing the process of step S1604 in the management CPU 112 in the fourth embodiment),
A gaming machine characterized by comprising:

  According to the feature C18, when a game ball enters the predetermined ball entry means, a storage process of information corresponding to the game ball is executed for the predetermined storage means, and the predetermined information is stored in the predetermined storage means. Become. As a result, it becomes possible to store and hold information for managing the number of game balls entering or the frequency of entering the predetermined ball entry means in the game machine. By using this managed information, it is possible to store and hold information. It becomes possible to appropriately manage the manner of entering the game ball into the ball entry means. In addition, since the predetermined information is stored and held by the gaming machine itself, it is possible to prevent unauthorized access and unauthorized modification to the predetermined information.

  In addition, using the predetermined information stored in the predetermined storage means, the mode information corresponding to the entrance mode of the game ball is calculated in the gaming machine. Thereby, for example, it becomes possible for the gaming machine itself to perform processing corresponding to the entry mode of the game ball, or it is possible to externally output the mode information that is the result of calculation using predetermined information. .

  In addition, it becomes possible to accumulate the mode information in the gaming machine. This makes it possible to read out a plurality of pieces of mode information collectively when managing the mode of game results in a predetermined period.

  Feature C19. The gaming machine according to any one of features C1 to C18, wherein the predetermined storage execution unit or the second control unit is provided as a dedicated circuit.

  According to the feature C19, it is possible to achieve an excellent effect as described above in the configuration in which the predetermined storage execution unit or the second control unit is provided as a dedicated circuit.

  In addition, with respect to the configuration of the features C1 to C19, the features A1 to A41, the features B1 to B20, the features C1 to C19, the features D1 to D7, the features E1 to E4, the features F1 to F10, the features G1 to G7, and the features H1 to H1. Any one or a plurality of configurations of H34, features I1 to I11, features J1 to J15, features K1 to K16, features L1 to L12, and features M1 to M5 may be applied. Thereby, it becomes possible to produce a synergistic effect by the combined configuration.

<Feature D group>
Feature D1. When a predetermined event occurs as a result of the game, information corresponding to the predetermined event is stored in a predetermined storage means (history memory 117 in the first to ninth and eleventh to twelfth embodiments, and the main side in the tenth embodiment. The predetermined information (history information in the first to eighth and twelfth embodiments and numerical information measured by the counter in the ninth to eleventh embodiments) is executed by the RAM 65). First storage execution means to be stored in the storage means (in the first to ninth and 11th to twelfth embodiments, the function of executing the history setting process in the management CPU 112, in the tenth embodiment the main side The CPU 63 executes steps S2302, S2305, S2308, S2312, S2316, S2320, and S2323. To function),
When a specific event occurs as a result of the game, the information corresponding to the specific event is stored in the predetermined storage means so that the specific information (history information in the first to eighth and twelfth embodiments, In the ninth to eleventh embodiments, the second storage execution means (in the first to ninth and eleventh to twelfth embodiments) stores the numerical information measured by the counter in the predetermined storage means. A function of executing history setting processing in the management CPU 112, a function of executing processing in steps S2302, S2305, S2308, S2312, S2316, S2320, and S2323 in the main CPU 63 in the tenth embodiment) ,
First external output means (management-side CPU 112) for outputting the predetermined information stored in the predetermined storage means to a device outside the gaming machine so as to make it possible to recognize that the predetermined information corresponds to the predetermined event. Function to execute external output processing in),
Second external output means (management-side CPU 112) that outputs the specific information stored in the predetermined storage means to a device outside the gaming machine so as to make it possible to recognize that the specific information corresponds to the specific event. Function to execute external output processing in),
A gaming machine characterized by comprising:

  According to the feature D1, it is possible to read information stored in the predetermined storage unit from the gaming machine and use the read information to specify the occurrence mode of the predetermined event and the occurrence mode of the specific event. In addition, when the external output is performed, the predetermined information is output externally so that it can be recognized that the predetermined information corresponds to the predetermined event, and the specific information corresponds to the specific event The specific information is output to the outside so that it can be recognized. Thereby, even if the information processing is not performed in the second control means, it is possible to specify the occurrence mode of each event using the information read from the predetermined storage means.

  Feature D2. The gaming machine according to feature D1, further comprising means for externally outputting corresponding information corresponding to the predetermined event when it occurs (a function of executing the process of step S218 in the main CPU 63).

  According to the feature D2, when a predetermined event occurs, corresponding information corresponding to the predetermined event is output to the outside, and the predetermined information is stored in the predetermined storage unit. This makes it possible to accurately determine the number of occurrences and the occurrence frequency of the predetermined event by using the predetermined information stored in the predetermined storage means while easily grasping the occurrence number and the occurrence frequency of the predetermined event by using the correspondence information. It becomes possible to grasp.

  Feature D3. The gaming machine according to claim D1 or D2, wherein the predetermined information is frequency information on the number of times the predetermined event has occurred, and the specific information is frequency information on the number of times the specific event has occurred.

  According to the feature D3, the predetermined information is count information of the number of times that the predetermined event has occurred, and the specific information is count information of the number of times that the specific event has occurred, thereby suppressing the information capacity of the predetermined information and the specific information, It is possible to manage the occurrence mode of the predetermined event and the occurrence mode of the specific event.

Feature D4. Program output means (function to execute the process of step S903 in the main CPU 63) for outputting a control program to a device outside the gaming machine using the information output unit (reading terminal 102),
The first external output unit and the second external output unit use the information output unit to output information stored in the predetermined storage unit to a device outside the gaming machine. The gaming machine according to any one of D3.

  According to the feature D4, it is possible to externally output the information stored in the predetermined storage unit by using the information output unit for externally outputting the control program. As a result, it is possible to externally output the information stored in the predetermined storage unit while preventing the configuration from becoming complicated.

  Feature D5. Selection means for specifying whether the information to be output from the information output unit is the information stored in the predetermined storage means or the control program, and outputting information corresponding to the specification result ( The gaming machine according to Feature D4, further comprising a function of executing the process of Step S902 in the main CPU 63.

  According to the feature D5, in the configuration in which the information output unit for outputting the control program to the outside is used and the information stored in the predetermined storage unit is output to the outside, the information to be externally output is the control program and the predetermined information. Which of the information stored in the storage means is specified on the gaming machine side, and the specified information is output to the outside. As a result, only necessary information can be read out even when the information output unit is also used.

  Feature D6. The selection means includes information stored in the predetermined storage means and information on the control program based on information received from an external device electrically connected to the information output section. The game machine according to Feature D5, wherein the game machine is specified as one of the two.

  According to the feature D6, which information is to be output from the information output unit is specified based on information received from an external device electrically connected to the information output unit. Thereby, it becomes possible to prevent the configuration related to selection of information to be output from becoming complicated.

  Feature D7. A chip (MPU 62) having program storage means (main ROM 64) for storing the control program in advance has the information output unit, the first external output means, and the second external output means. The gaming machine according to any one of features D4 to D6.

  According to the feature D7, signal paths for the information output unit can be collected in the chip. As a result, it is possible to achieve the excellent effects as described above while making it difficult to illegally access the signal path to the information output unit.

  In addition, with respect to the configuration of the features D1 to D7, the features A1 to A41, the features B1 to B20, the features C1 to C19, the features D1 to D7, the features E1 to E4, the features F1 to F10, the features G1 to G7, and the features H1 to H1. Any one or a plurality of configurations of H34, features I1 to I11, features J1 to J15, features K1 to K16, features L1 to L12, and features M1 to M5 may be applied. Thereby, it becomes possible to produce a synergistic effect by the combined configuration.

<Feature E group>
Feature E1. Program output means for outputting a control program to a device external to the gaming machine using the information output unit (reading terminal 102) (function for executing the process of step S903 in the main CPU 63);
Information output means for outputting special information using the information output unit (function for executing external output processing in the management CPU 112);
A gaming machine characterized by comprising:

  According to the feature E1, it is possible to output the special information to the outside by using the information output unit for outputting the control program to the outside. This makes it possible to output special information to the outside while preventing the configuration from becoming complicated.

  Feature E2. Selection means for identifying whether the information to be output from the information output unit is the special information or the control program, and outputting information corresponding to the identification result (step S902 in the main CPU 63) The game machine according to Feature E1, further comprising:

  According to the feature E2, in the configuration in which the special information is output to the outside using the information output unit for outputting the control program to the outside, the information to be externally output is either the control program or the special information. Is specified on the gaming machine side, and the specified information is output to the outside. As a result, only necessary information can be read out even when the information output unit is also used.

  Feature E3. The selection means determines whether the information to be output from the information output unit is the special information or the control program based on information received from an external device electrically connected to the information output unit. The gaming machine according to Feature E2, characterized in that it is identified.

  According to the feature E3, which information is to be output from the information output unit is specified based on information received from an external device electrically connected to the information output unit. Thereby, it becomes possible to prevent the configuration related to selection of information to be output from becoming complicated.

  Feature E4. Any one of features E1 to E3, wherein a chip (MPU 62) having program storage means (main ROM 64) for storing the control program in advance has the information output unit and the information output means. The gaming machine described in 1.

  According to the feature E4, it is possible to collect signal paths for the information output unit in the chip. As a result, it is possible to achieve the excellent effects as described above while making it difficult to illegally access the signal path to the information output unit.

  In addition, with respect to the configuration of the features E1 to E4, the features A1 to A41, the features B1 to B20, the features C1 to C19, the features D1 to D7, the features E1 to E4, the features F1 to F10, the features G1 to G7, and the features H1 to H1. Any one or a plurality of configurations of H34, features I1 to I11, features J1 to J15, features K1 to K16, features L1 to L12, and features M1 to M5 may be applied. Thereby, it becomes possible to produce a synergistic effect by the combined configuration.

<Feature F group>
Feature F1. A first control unit (main CPU 63) and a second control unit (management CPU 112);
The first control means includes
A privilege granting means (a function for executing the process of step S217 in the main CPU 63, a function for executing the process of step S408 in the payout CPU 92) so that a privilege is granted to the player when a predetermined event occurs,
Information transmitting means (a function for executing management output processing in the main CPU 63) for transmitting predetermined event information corresponding to the predetermined event when it occurs;
With
When the second control unit receives the predetermined event information, the second control unit stores information corresponding to the predetermined event information (in the first to ninth and eleventh to twelfth embodiments, the history memory 117, the tenth In the embodiment, the information is executed by the main RAM 65) so that the number of occurrences or the occurrence frequency of the predetermined event can be specified by the gaming machine or a device outside the gaming machine (first to eighth). Predetermined storage execution means (first to ninth) for storing history information in the twelfth embodiment and numerical information measured by the counter in the ninth to eleventh embodiments in the predetermined storage means. In the eleventh to twelfth embodiments, a function for executing history setting processing in the management CPU 112, and in the tenth embodiment, steps S2302, S2305, and S2 in the main CPU 63 are used. 08, step S2312, step S2316, the gaming machine characterized in that it comprises a function for executing the processing of step S2320 and step S2323).

  According to the feature F1, when a predetermined event occurs, a privilege is given to the player. As a result, the player plays a game while expecting a predetermined event to occur. In this configuration, when a predetermined event occurs, storage of information corresponding to the predetermined event is executed in the predetermined storage means, and the number of occurrences or the occurrence frequency of the predetermined event can be specified by the gaming machine or a device outside the gaming machine. The predetermined information to be stored is stored in the predetermined storage means. This makes it possible to store and hold information for managing the occurrence frequency or occurrence frequency of a predetermined event in the gaming machine, and appropriately manage the occurrence mode of the predetermined event by using this managed information. Can be performed. In addition, since the predetermined information is stored and held by the gaming machine itself, it is possible to prevent unauthorized access and unauthorized modification to the predetermined information.

  In addition, the second control means provided separately from the first control means having the privilege granting means has the predetermined storage execution means so that the processing load of the first control means does not increase excessively. However, it is possible to achieve excellent effects as described above.

  Feature F2. The gaming machine according to F1, wherein the first control means and the second control means are provided on the same chip.

  According to the feature F2, since the first control means and the second control means are provided on the same chip, unauthorized access to the communication path between the first control means and the second control means is prevented. It becomes possible to stop.

Feature F3. The predetermined storage execution unit executes the storage process of information corresponding to the occurrence of a specific event in the predetermined storage unit, so that the number of occurrences or the occurrence frequency of the specific event is determined outside the gaming machine or the gaming machine Specific information that can be specified by the device (history information in the first to eighth and twelfth embodiments, numerical information measured by the counter in the ninth to eleventh embodiments) is stored in the predetermined storage means. To be
The first control means includes
First transmission means for transmitting first information to the second control means using the first signal path when the predetermined event occurs (function to output any one of first to seventh signals in the main CPU 63) )When,
Second transmission means for transmitting second information to the second control means using the second signal path when the specific event occurs (function to output one of the first to seventh signals in the main CPU 63) )When,
The gaming machine according to F1 or F2, characterized by comprising:

  According to the feature F3, not only the predetermined information corresponding to the predetermined event but also the specific information corresponding to the specific event is stored in the predetermined storage unit. As a result, it is possible to manage not only the occurrence mode of the predetermined event but also the occurrence mode of the specific event. Further, by using both the predetermined information and the specific information, it is possible to manage the ratio of the occurrence frequency between the predetermined event and the specific event.

  Further, when a predetermined event occurs, the first information is transmitted to the second control means using the first signal path, and when the specific event occurs, the second information is transmitted using the second signal path. It is transmitted to the second control means. As a result, the type of information to be transmitted corresponds to the signal path, and the configuration for distinguishing the type of each information by the second control means can be simplified.

  Feature F4. The first control means transmits, to the second control means using the third route, information for specifying that the second control means can specify whether or not a predetermined situation is present. (In the first, third to ninth and twelfth embodiments, the function of outputting any of the eighth to tenth signals in the main CPU 63, and in the second embodiment, the signal in the open / close execution mode in the main CPU 63, The gaming machine according to F3, wherein the gaming machine includes a function of outputting either a high frequency support mode signal or a door opening signal.

  According to the feature F4, it is possible to manage the occurrence mode of the predetermined event and the occurrence mode of the specific event by distinguishing whether or not the situation is a predetermined situation. In addition, since the information for identification that can identify whether or not the predetermined situation is present is transmitted to the second control means using the third route, the information for identification is transmitted to the second information by the second control means. It is possible to simplify the configuration for distinguishing from other information such as two information.

  Feature F5. The first control means transmits identification information indicating that the first information corresponds to the predetermined event and the second information corresponds to the specific event to the second control means. The gaming machine according to feature F3 or F4, comprising a transmission means (a function of executing recognition processing in the main CPU 63).

  According to the feature F5, the identification information indicating that the first information corresponds to the predetermined event and the second information corresponds to the specific event is transmitted from the first control unit to the second control unit. It is not necessary to store the correspondence relationship of these information in advance in the second control means. Thereby, the versatility of a 2nd control means can be improved.

  Feature F6. The gaming machine according to claim F5, wherein the identification information transmitting means transmits the identification information to the second control means when supply of operating power to the first control means is started.

  According to feature F6, when supply of operating power to the first control unit is started, identification information is transmitted from the first control unit to the second control unit, so that a predetermined event and a specific event can occur. In the situation, it becomes possible to specify the correspondence between the information transmitted from the first control means and the ball entry means by the second control means.

  Feature F7. The identification information transmitting unit transmits the identification information to the second control unit by using at least one of the first signal path and the second signal path. Gaming machine.

  According to the feature F7, since the identification information is transmitted to the second control unit using at least one of the first signal path and the second signal path, a dedicated signal path for transmitting the identification information is provided. Compared to the above, the communication configuration can be simplified.

  Feature F8. The second control means, when receiving the identification information, correspondence information that makes it possible to specify that the first information corresponds to the predetermined event and the second information corresponds to the specific event According to any one of the features F5 to F7, characterized in that a means (a function for executing a correspondence setting process in the management CPU 112) is stored in the correspondence storage means (correspondence memory 116). Gaming machine.

  According to the feature F8, the correspondence relationship between the information transmitted from the first control unit and the type of event is stored in the second control unit. As a result, information that enables the second control means to specify the type of event corresponding to the information to be transmitted is provided to the second control means each time the first information or the second information is transmitted from the first control means. There is no need to do it. Therefore, it is possible to suppress the information amount of the first information and the second information.

Feature F9. The first control means transmits third information enabling the second control means to specify whether or not a predetermined situation is present to the second control means using a third route. (In the first, third to ninth and twelfth embodiments, the function of outputting any of the eighth to tenth signals in the main CPU 63, and in the second embodiment, the signal in the open / close execution mode in the main CPU 63, High frequency support mode signal or door open signal output function)
The second control means is capable of recognizing that the third information is information that can specify whether or not the predetermined situation is present without receiving the identification information. F5 A gaming machine according to any one of F8.

  According to the feature F9, it is possible to manage the occurrence mode of the predetermined event and the occurrence mode of the specific event by distinguishing whether or not the situation is a predetermined situation. Further, the fact that the third information is information that can specify whether or not the predetermined situation is present can be specified by the second control means without receiving identification information from the first control means. . As a result, the information form of the identification information can be prevented from becoming complicated.

  Feature F10. The gaming machine according to any one of features F1 to F9, wherein the second control means is provided as a dedicated circuit.

  According to the feature F10, it is possible to achieve an excellent effect as described above in the configuration in which the second control unit is provided as a dedicated circuit.

  In addition, with respect to the configuration of the features F1 to F10, the features A1 to A41, the features B1 to B20, the features C1 to C19, the features D1 to D7, the features E1 to E4, the features F1 to F10, the features G1 to G7, and the features H1 to H1. Any one or a plurality of configurations of H34, features I1 to I11, features J1 to J15, features K1 to K16, features L1 to L12, and features M1 to M5 may be applied. Thereby, it becomes possible to produce a synergistic effect by the combined configuration.

  According to the invention relating to the feature A group, the feature B group, the feature C group, the feature D group, the feature E group, and the feature F group, the following problems can be solved.

  Pachinko machines and slot machines are known as gaming machines. For example, in a pachinko gaming machine, the front of the gaming machine is provided with a dish storage unit that stores game balls given to the player, and the game balls stored in the dish storage unit are guided to the game ball launching device. It is fired toward the game area in accordance with the player's launch operation. For example, when a game ball enters a ball entering portion provided in the game area, the game ball is paid out from the payout device to the dish storage portion, for example. In addition, the pachinko gaming machine is also known to have an upper tray storage section and a lower tray storage section as the tray storage section. In this case, the game balls stored in the upper tray storage section are released as game balls. The game balls that are guided by the apparatus and become surplus in the upper dish storage section are discharged to the lower dish storage section.

  Here, in gaming machines such as the above-described examples, management of gaming machines needs to be performed suitably, and there is still room for improvement in this respect.

<Feature G group>
Feature G1. First control means (main CPU 63);
Second control means (management CPU 112) for receiving information transmitted from the first control means;
With
The first control means includes
First transmission means for transmitting the first information to the second control means using the first signal path when the first event occurs (function to output one of the first to seventh signals in the main CPU 63) )When,
Second transmission means for transmitting the second information to the second control means using the second signal path when the second event occurs (function to output one of the first to seventh signals in the main CPU 63) )When,
Identification information transmission means (main side) for transmitting identification information indicating that the first information corresponds to the first event and the second information corresponds to the second event to the second control means A function of executing recognition processing in the CPU 63);
A gaming machine characterized by comprising:

  According to the characteristic G1, when the first event occurs, the first information is transmitted to the second control means using the first signal path, and when the second event occurs, the second signal path is used. Then, the second information is transmitted to the second control means. As a result, the type of information to be transmitted corresponds to the signal path, and the configuration for distinguishing the type of each information by the second control means can be simplified.

  In addition, since the first information corresponds to the first event and the identification information indicating that the second information corresponds to the second event is transmitted from the first control means to the second control means, these information This need not be stored in advance in the second control means. Thereby, the versatility of a 2nd control means can be improved.

  Feature G2. The gaming machine according to Feature G1, wherein the identification information transmitting means transmits the identification information to the second control means when supply of operating power to the first control means is started.

  According to the characteristic G2, since the identification information is transmitted from the first control unit to the second control unit when the supply of the operating power to the first control unit is started, the predetermined entrance unit and the specific entrance unit In a situation where a game ball can enter the ball, it is possible to specify the correspondence between the information transmitted from the first control means and the ball entry means by the second control means. Become.

  Feature G3. The identification information transmitting unit transmits the identification information to the second control unit by using at least one of the first signal path and the second signal path. Gaming machine.

  According to the feature G3, since the identification information is transmitted to the second control means using at least one of the first signal path and the second signal path, a dedicated signal path for transmitting the identification information is provided. Compared to the above, the communication configuration can be simplified.

  Feature G4. When the second control means receives the identification information, the second control means can specify that the first information corresponds to the first event and the second information corresponds to the second event. Any one of the characteristics G1 to G3 is provided with means (function for executing correspondence setting processing in the management side CPU 112) for storing the relation information in correspondence relation storage means (correspondence relation memory 116). The gaming machine described.

  According to the feature G4, the correspondence between the information transmitted from the first control unit and the ball entry unit is stored in the second control unit. Thus, it is necessary to provide the second control means with information that enables the second control means to specify an event corresponding to the information to be transmitted every time the first information or the second information is transmitted from the first control means. Disappears. Therefore, it is possible to suppress the information amount of the first information and the second information.

Feature G5. The first control means transmits third information enabling the second control means to specify whether or not a predetermined situation is present to the second control means using a third route. (In the first, third to ninth and twelfth embodiments, the function of outputting any of the eighth to tenth signals in the main CPU 63, and in the second embodiment, the signal in the open / close execution mode in the main CPU 63, High frequency support mode signal or door open signal output function)
The second control means is capable of recognizing that the third information is information that can specify whether or not the predetermined situation is present without receiving the identification information. A gaming machine according to any one of G4 to G4.

  According to the characteristic G5, it is possible to manage the occurrence mode of the first event and the occurrence mode of the second event by distinguishing whether or not the situation is a predetermined situation. Further, the fact that the third information is information that can specify whether or not the predetermined situation is present can be specified by the second control means without receiving identification information from the first control means. . As a result, the information form of the identification information can be prevented from becoming complicated.

  Feature G6. As a signal path through which information can be transmitted from the first control means to the second control means, the number of types of information that needs to be transmitted from the first control means to the second control means is greater than The gaming machine according to any one of features G1 to G5, wherein a signal path is provided.

  According to the feature G6, since there are provided more signal paths than the number of types of information that need to be transmitted from the first control means to the second control means, Even when the number of types increases or decreases, it is possible to cope with the configuration without changing the configuration related to the signal path. Therefore, the versatility of the second control means can be improved.

  Feature G7. The gaming machine according to any one of features G1 to G6, wherein the second control means is provided as a dedicated circuit.

  According to the characteristic G7, it is possible to achieve the excellent effects as already described in the configuration in which the second control unit is provided as a dedicated circuit.

  In addition, with respect to the configuration of the features G1 to G7, the features A1 to A41, the features B1 to B20, the features C1 to C19, the features D1 to D7, the features E1 to E4, the features F1 to F10, the features G1 to G7, and the features H1 to H1. Any one or a plurality of configurations of H34, features I1 to I11, features J1 to J15, features K1 to K16, features L1 to L12, and features M1 to M5 may be applied. Thereby, it becomes possible to produce a synergistic effect by the combined configuration.

  According to the invention relating to the above-described feature G group, the following problems can be solved.

  Pachinko machines and slot machines are known as gaming machines. For example, in a pachinko gaming machine, the front of the gaming machine is provided with a dish storage unit that stores game balls given to the player, and the game balls stored in the dish storage unit are guided to the game ball launching device. It is fired toward the game area in accordance with the player's launch operation. For example, when a game ball enters a ball entering portion provided in the game area, the game ball is paid out from the payout device to the dish storage portion, for example. In addition, the pachinko gaming machine is also known to have an upper tray storage section and a lower tray storage section as the tray storage section. In this case, the game balls stored in the upper tray storage section are released as game balls. The game balls that are guided by the apparatus and become surplus in the upper dish storage section are discharged to the lower dish storage section.

  Here, in the gaming machine such as the above-described example, it is necessary to make the configuration related to communication suitable, and there is still room for improvement in this respect.

<Feature H group>
Feature H1. A transparent plate (window panel 52) is arranged on the front side of the game board (for example, game board 233), and a game ball (game ball B1) is a game area (game area PA) between the game board and the transparent board. ) In a gaming machine that flows down from upstream to downstream,
The game board has predetermined changing means (first left and right sorting nails 213, 242 and second) that change the movement mode of the game ball after contact according to the position of the game ball in contact in the depth direction in the game area. Left / right sorting nail 214, reversing nail 251, front / rear sorting nail 262, rebound nail 322, front / rear sorting base 351, 391, 392, position change passage 423, replacement position change passage 442, inclined nail) A gaming machine characterized by

  According to the feature H1, the game balls in the game area can be dispersed in such a manner that the course of the game balls varies according to the position in the depth direction of the game balls. Compared with a gaming machine that affects the course of a game ball, it is possible to increase the variation of the movement of the game ball in the game area and improve the interest of the game.

The game board in the feature H1 is a plate having a predetermined changing means, and defines a game area for playing a game.

  Feature H2. The predetermined changing means repels the game ball by applying a drag force to the game ball contacted from the upstream side of the game area, and the movement mode of the game ball by the rebound is contacted in the depth direction of the game ball. The gaming machine according to Feature H1, wherein the gaming machine is different depending on the position.

  According to the feature H2, it is possible to change the movement mode of the game ball after rebounding according to the contact position in the depth direction of the game ball, and the movement mode can be changed by rebounding the game ball flowing down the game area. While adopting the conventional configuration of changing, it is possible to add a novel movement mode of changing the rebound direction according to the position in the depth direction.

  Feature H3. The predetermined changing means rolls a game ball placed on the upper side from the upstream side of the game area, and a movement mode of the game ball due to the roll depends on a contact position of the game ball in the depth direction. The gaming machine according to Feature H1 or H2, wherein the gaming machine is different.

  According to the feature H3, the movement mode of the game ball is changed in the process of rolling the game ball. Therefore, the movement mode of the game ball according to the contact position in the depth direction is assumed in the game machine design stage. It becomes easy to control.

  Feature H4. The gaming machine according to any one of features H1 to H3, wherein a plurality of the predetermined changing means are arranged in parallel in the gaming area.

  According to the feature H4, a game ball that has reached a region where a plurality of predetermined changing means are arranged side by side easily comes into contact with any of the predetermined changing means. Thereby, it becomes easy to produce the change of the movement mode of the game ball according to the contact position of the depth direction.

Feature H5. Different changing means (first left / right sorting nails 213, 242 and second left / right sorting nails 214) in which the moving mode of the game ball after contact according to the position in the depth direction of the game balls to be contacted is different from the predetermined changing means. , Reverse nail 251, front / rear distribution nail 262, rear nail 271, front priority member 291, rebound nail 322, front / rear distribution bases 351, 391, 392, position change passage 423, replacement position change passage 442, inclined nail) Prepared,
The gaming machine according to any one of features H1 to H4, wherein in the game area, the different changing means is arranged in parallel with the predetermined changing means.

  According to the feature H5, the game ball that has reached the region in which the predetermined changing unit and the different changing unit are arranged side by side has a position in the depth direction depending on, for example, which of the predetermined changing unit and the different changing unit contacts. It becomes possible to make the movement mode of the corresponding game ball different. In this case, the player pays attention to which of the predetermined changing means and the different changing means the game ball comes into contact with while expecting the movement mode desired by the player. Further, for example, depending on the position in the depth direction when one of the predetermined changing means and another changing means is contacted, it is possible to adopt a configuration in which the movement mode of the game ball when contacting the other after that is different. . In this case, it is possible to correlate the movement modes of the game balls by both changing means.

  Feature H6. In the features H1 to H5, the predetermined changing unit is configured to change a lateral movement mode of the game ball in the game area after contact according to a position of the game ball in contact in the depth direction. The gaming machine according to any one of the above.

  According to the feature H6, it is possible to change the lateral movement mode of the game ball according to the position of the game ball in the depth direction. This makes it possible to correlate the position of the game ball in the depth direction and the movement direction of the game ball in the lateral direction, and a player who pays attention to the movement of the game ball grasps the position of the game ball from various angles. The movement of the game ball will be predicted. Therefore, it is possible to improve the interest of the game.

Feature H7. The predetermined changing means includes
A first predetermined changing means (first distribution surface 217a, for changing the lateral movement mode of the game ball in contact with the first predetermined range in the depth direction (for example, the back side of the game area PA) in the first predetermined mode. 232a, 244a, first inversion surface 254a, rear nail 271, low repulsion member 333, first inclined portion of the inclined nail),
A second predetermined change in which the movement direction of the game ball in contact with a second predetermined range (for example, the front side of the game area PA) that does not overlap with the first predetermined range in the depth direction is changed in a second predetermined mode. Means (second distribution surfaces 218a, 234a, 245a, second reversing surface 254b, front priority member 291, high repulsion portion 334d, second inclined portion of the inclined nail),
The gaming machine according to Feature H6, comprising:

  According to the feature H7, the lateral movement mode of the game ball after contact is uniquely changed according to the contact position in the depth direction. As a result, in a configuration in which the movement mode of the lateral game ball is changed according to the contact position in the depth direction, the subsequent movement mode of the lateral game ball with respect to the position in the depth direction of the game ball is predicted to some extent by the player. It becomes possible to make it.

Feature H8. The first predetermined changing means gives a force including a leftward component to the game ball in contact with the first predetermined range;
The gaming machine according to Feature H7, wherein the second predetermined changing means gives a force including a component directed to the right to the game ball in contact with the second predetermined range.

  According to the feature H8, the lateral component of the force applied to the game ball according to the contact position in the depth direction is the opposite. Thereby, it becomes possible to change the movement mode of the game ball in the horizontal direction remarkably according to the contact position in the depth direction.

Feature H9. The first predetermined changing means gives a force including a component in a predetermined direction which is one of leftward and rightward to the game ball in contact with the first predetermined range;
The second predetermined changing means gives a force including a component in the predetermined direction to the game ball that contacts the second predetermined range, and the force in the predetermined direction is larger than the first predetermined changing means. The gaming machine according to Feature H7, wherein the gaming machine is provided.

  According to the feature H9, even if the contact position in the depth direction is either the first predetermined range or the second predetermined range, the same lateral force is applied to the game ball while the magnitude of the force is It is possible to make it different. Accordingly, it is possible to vary the amount of movement according to the contact position in the depth direction while moving the game ball in the same lateral direction.

  Feature H10. Any one of the features H1 to H9, wherein the predetermined changing means changes a movement mode of the game ball in the depth direction after the contact according to a position of the game ball in contact with the depth direction. The gaming machine described in 1.

  According to the feature H10, it is possible to change the movement mode of the game ball in the depth direction according to the position of the game ball in the depth direction. Thereby, it becomes possible to diversify the movement mode of the game ball in the depth direction, and to improve the interest of the game.

Feature H11. The predetermined changing means includes
Third predetermined changing means (first inversion surface 254a, first) for changing the movement mode of the game ball in contact with the third predetermined range in the depth direction (for example, the back side of the game area PA) in the third predetermined mode. 1 distribution surface 264a, first downstream surface 372, back side wall surface 443a),
A fourth predetermined change in which the movement mode in the depth direction of a game ball that contacts a fourth predetermined range (for example, the front side of the game area PA) that does not overlap the third predetermined range in the depth direction is changed in a fourth predetermined mode. Means (second reversing surface 254b, second distributing surface 265a, second downstream surface 373, front side wall surfaces 422b, 443b),
A gaming machine according to Feature H10, comprising:

  According to the feature H11, the movement mode in the depth direction of the game ball after the contact is uniquely changed according to the contact position in the depth direction. As a result, in a configuration in which the movement mode of the game ball in the horizontal direction is changed in accordance with the contact position in the depth direction, the subsequent movement mode of the game ball in the depth direction relative to the position in the depth direction of the game ball is predicted to some extent by the player. It becomes possible to make it.

Feature H12. The third predetermined changing means gives a force including a forward component to the game ball in contact with the third predetermined range,
The gaming machine according to Feature H11, wherein the fourth predetermined changing means gives a force including a backward component to the game ball in contact with the fourth predetermined range.

  According to the feature H12, the component in the depth direction of the force applied to the game ball according to the contact position in the depth direction is the opposite. This makes it possible to significantly change the movement mode of the game ball in the depth direction according to the contact position in the depth direction.

  Feature H13. The gaming machine according to Feature H12, wherein the third predetermined range exists on the back side of the fourth predetermined range.

  According to the feature H13, the position of the game ball in the depth direction can be changed reversely between the back side and the near side due to the presence of the predetermined changing means.

  Feature H14. The gaming machine according to any one of features H1 to H13, wherein the predetermined changing means has a coefficient of restitution different depending on a position in the depth direction.

  According to the feature H14, drags having different sizes can be applied to game balls having different collision positions in the depth direction. Thereby, the rebounding speed of the game ball after colliding with the predetermined changing means can be made different. As described above, by increasing the variation of the movement of the game ball in the game area, it is possible to improve the interest of the game.

Feature H15. The predetermined changing means includes
Resin members (first left and right sorting members 215 and 243, second left and right sorting members 231 and reversing members 254) for changing the moving mode of the game balls in contact with the mode in the depth direction of the game balls. , Front / rear sorting member 263, plate member 292),
A metal member (fixing member 216, support members 293, 294) for fixing the predetermined changing means to the game board in a state where the resin member is exposed to the game area;
The gaming machine according to any one of features H1 to H14, comprising:

  According to the feature H15, the degree of freedom in designing the member that changes the path of the game ball can be increased by forming the member that changes the path of the game ball with a resin that can be easily molded. In addition, by adopting a structure in which the resin member is firmly fixed with a metal member, the durability of the predetermined changing means is improved, and maintenance of the gaming machine having the predetermined changing means is frequently required. It can be avoided.

  Feature H16. One of the features H1 to H15, wherein the predetermined changing means is fixed to a base body (left guide member 255) provided separately from the game board and fixed to the game board. The gaming machine described.

  According to the feature H16, it is possible to provide the game board with the predetermined change means by fixing the base body integrated with the predetermined change means to the game board. This makes it possible to provide the predetermined change means on the game board after carefully aligning the predetermined change means.

  Feature H17. The gaming machine according to Feature H16, wherein a plurality of the predetermined changing means are fixed to the base body.

  According to the feature H17, since it is possible to provide the predetermined change means on the game board after careful alignment of the plurality of predetermined change means, the relative alignment of the plurality of predetermined change means. The accuracy can be increased.

  Feature H18. Any one of the features H1 to H17, wherein the game board includes a failure nail (failure nail 228) that changes a movement mode of the game ball after contact in a manner corresponding to a contact position in the left-right direction. The gaming machine described in 1.

  According to the feature H18, it is possible to provide a sufficient number of means for dispersing the course of the game ball on the game board. When all the obstacle nails in the conventional game board are changed to the predetermined change means, the number of the predetermined change means that can be provided on the game board is limited if the predetermined change means is manufactured larger than the obstacle nails in order to ensure the strength. End up. On the other hand, as a means for dispersing the course of the game ball on the game board, a small obstacle nail and a large predetermined change means are mixed to disperse the game balls that can be provided on the game board. The decrease in means can be suppressed, and the game balls can be sufficiently dispersed. And it can be set as the structure of the game board in which both the change of the course according to the position of the left-right direction of a game ball and the change of the course according to the position of the depth direction of a game ball are possible.

Feature H19. The predetermined changing means changes a lateral movement mode in the game area of the game ball after contact according to the position in the depth direction of the game ball to be contacted,
The game board has a specific change means (inverted nail 251, which allows the movement mode in the depth direction of the contacted game ball at a position upstream of the predetermined change means in the game area. Any one of the features H1 to H18 is provided with a front / rear distribution nail 262, front / rear distribution bases 351, 391, 392, a position change passage 423, a replacement position change passage 442, and a guide passage 461). The gaming machine described.

  According to the feature H19, it is possible to change the position of the game ball in the depth direction by providing the specific changing means. The game board includes not only the specific changing means but also predetermined changing means for changing the lateral movement mode of the game ball according to the contact position in the depth direction. It becomes possible to make it.

  In addition, since the specific change means is provided on the upstream side of the predetermined change means, depending on whether or not the position of the game ball in the depth direction has been changed by the specific change means, the game ball by the predetermined change means thereafter It is possible to make the distribution modes in the horizontal direction different. Thereby, it becomes possible to associate the movement modes of the game balls by the specific changing means and the predetermined changing means.

Feature H20. The game board is provided with openings (first operation port 33, second operation port 34) that serve as an opportunity for providing advantageous benefits to the player by entering a game ball,
A game ball that is in contact with the predetermined change means after the movement mode in the depth direction is changed to the specific mode by the specific change unit, is more than a game ball that is in contact with the predetermined change unit without being in the specific mode. The gaming machine according to Feature H19, wherein the specific changing means and the predetermined changing means are provided so as to make it easier to enter the opening.

  According to the feature H20, when the movement mode in the depth direction of the game ball is set to the specific mode by the specific change unit, it becomes easier to enter the opening, so the player's attention to the specific change unit is increased. It becomes possible. In addition, even a game ball whose movement direction in the depth direction has been set to the specific mode by the specific change unit will contact the predetermined change unit after that, and the movement mode in the depth direction is the specific mode in the process up to the contact. Therefore, it is possible to make the player pay attention to the process until the game ball contacts the predetermined changing means.

  Feature H21. The game according to claim H19 or H20, wherein the specific change unit changes a movement mode of the game ball in the depth direction after contact according to a position of the game ball in contact with the depth direction. Machine.

  According to the feature H21, it is possible to change the movement mode of the game ball in the depth direction according to the position of the game ball in the depth direction. Thereby, it becomes possible to diversify the movement mode of the game ball in the depth direction, and to improve the interest of the game.

Feature H22. The specific changing means includes
First specification changing means (first reversing surface 254a, first) for changing the movement mode in the depth direction of the game ball that contacts the first specific range in the depth direction (for example, the back side of the game area PA). 1 distribution surface 264a, back side wall surface 443a),
A second specific change in which the movement mode in the depth direction of a game ball that contacts a second specific range (for example, the front side of the game area PA) that does not overlap the first specific range in the depth direction is changed in a second specific mode. Means (second reversal surface 254b, second distribution surface 265a, front side wall surfaces 422b, 443b),
A gaming machine according to Feature H21, comprising:

  According to the feature H22, the movement mode in the depth direction of the game ball after the contact is uniquely changed according to the contact position in the depth direction. As a result, in a configuration in which the movement mode of the game ball in the horizontal direction is changed in accordance with the contact position in the depth direction, the subsequent movement mode of the game ball in the depth direction relative to the position in the depth direction of the game ball is predicted to some extent by the player. It becomes possible to make it.

Feature H23. The first specific changing means gives a force including a forward-facing component to the game ball in contact with the first specific range,
The game machine according to Feature H22, wherein the second specific changing means gives a force including a backward component to the game ball that contacts the second specific range.

  According to the feature H23, the component in the depth direction of the drag applied to the game ball in accordance with the contact position in the depth direction is the opposite. This makes it possible to significantly change the movement mode of the game ball in the depth direction according to the contact position in the depth direction.

  Feature H24. The gaming machine according to Feature H23, wherein the first specific range is present behind the second specific range.

  According to the feature H24, it is possible to reversely change the position of the game ball in the depth direction between the back side and the near side due to the presence of the specific change means.

  Feature H25. The specific change means has a guide passage (position change passage 423, replacement position change passage 442, guide passage 461) through which the game ball passes, and the movement direction of the game ball discharged from the guide passage in the depth direction. The gaming machine according to any one of features H19 to H24, wherein the gaming machine is configured to be able to have the specific mode.

  According to the feature H25, a player who is paying attention to the position of the game ball in the depth direction pays attention to whether or not the game ball enters the guide passage, and can improve the interest of the game. .

  Feature H26. The gaming machine according to Feature H25, wherein a movement mode in the depth direction of the game ball discharged from the guide path is changed according to a passing mode of the game ball in the guide path.

  According to the feature H26, the game ball is inserted into the guide passage by setting the movement mode in the depth direction of the game ball discharged from the guide passage according to the passage mode of the game ball in the guide passage. It becomes possible to make the player pay attention to whether or not the player can also pay attention to the passing mode of the game ball in the guide passage.

  Feature H27. In the feature H25 or H26, the guide passage is configured to vary a movement mode in the depth direction of the game ball discharged from the guide passage according to the position of the game ball at the entrance of the guide passage. The gaming machine described.

  According to the feature H27, the game ball that enters the guide passage enters the guide passage by changing the movement mode in the depth direction of the game ball discharged from the guide passage according to the position of the game ball at the entrance of the guide passage. It is possible to make the player pay attention to whether or not the player is also paying attention to the position of the game ball when entering the entrance of the guide passage.

Feature H28. The guide passage is formed by being partitioned into a plurality of passage walls, and is provided to extend in the vertical direction.
The depth direction of the game balls discharged from the guide passage when the game balls passing through the guide passage come into contact with predetermined passage walls (the front side wall surfaces 422b and 443b and the rear side wall surface 443a) among the plurality of passage walls. The game machine according to any one of features H25 to H27, wherein the movement mode is the specific mode.

  According to the feature H28, by having the configuration in which the movement mode in the depth direction of the game ball is changed by contact with the passage wall of the guide passage, the excellent effect as described above can be obtained while simplifying the configuration. Is possible.

  Feature H29. The guide passage is configured such that a game ball existing in the first range in the depth direction (near the surface of the game boards 421 and 451) at the entrance of the guide passage is closer to the front side than the first range at the exit of the guide passage. And the game balls existing in the second range (near the back surface of the window panel 52) at the entrance of the guide passage are closer to the first range than the second range at the exit of the guide passage. The game machine according to any one of features H25 to H28, wherein the game machine is also configured to move to the back side.

  According to the feature H29, it is possible to guide the game ball to a position opposite to the position in the depth direction at the entrance of the guide passage. Thereby, the position of the game ball in the depth direction can be positively changed.

  Feature H30. For the game ball existing at the front side of the first range at the entrance of the guide passage and at the back side of the second range, the guide passage is in the depth direction at the exit of the guide passage. The gaming machine according to Feature H29, wherein the game machine has a configuration that does not apply a force for changing the position of the game machine.

  According to the feature H30, it is possible to cause a situation in which the position of the game ball in the depth direction does not change even when passing through the guide passage. This makes it possible to diversify the positions of the game balls in the depth direction after passing through the guide passage.

  Feature H31. The feature H25 is characterized in that the guide passage has a configuration in which the movement mode in the depth direction of the game ball discharged from the guide passage is the specific mode regardless of the mode of passage of the game ball in the guide channel. The gaming machine described.

  According to the feature H31, since the game ball that has entered the guide passage has a specific movement mode in the depth direction after passing through the guide passage, the influence of the guide passage on the game board can be increased. It becomes. Therefore, it becomes possible to attract the player's interest in the movement of the game ball around the guide passage, and to improve the interest of the game.

  Feature H32. The guide passage is provided in a passage forming body (passage forming member 422, replacement passage forming member 441, guide member 471, replacement guide member 561) provided separately from the game board. The gaming machine according to any one of features H25 to H31.

  According to the feature H32, since the guide passage is provided in the passage formation body provided separately from the game board, the depth of the game ball can be obtained while using the same game board by exchanging the passage formation body. It becomes possible to change the movement mode of the direction.

Feature H33. The game board is provided with openings (first operation port 33, second operation port 34) that serve as an opportunity for providing advantageous benefits to the player by entering a game ball,
The predetermined changing means distributes the movement mode after contact of the game balls to be contacted into a movement mode having a high probability of entering the opening and a movement mode having a low probability of entering the opening. The gaming machine according to any one of features H1 to H32.

  According to the feature H33, the probability that the game ball wins the opening varies depending on the position of the game ball in the depth direction. In this way, by making the configuration in which the depth direction position of the game ball upstream of the opening is reflected in the game result, it is possible to improve the interest of the game.

Feature H34. The game board includes guidance means (stage unit 354) for guiding a game ball to a place with a high probability of entering the opening.
The predetermined change means includes a case where the game ball is guided to the guide means according to a position in the depth direction of the game ball and a case where the game ball is not guided to the guide means. The gaming machine described in 1.

  According to the feature H34, by causing the player to pay attention to whether or not the game ball whose course has been changed by the predetermined changing means is guided to the guiding means, the player's interest in the movement of the game ball is increased, and the game Can be improved. Further, by reflecting the difference in the position in the depth direction of the game ball in the game area in the game result, it is possible to improve the interest of the game.

  In addition, with respect to the configuration of the features H1 to H34, the features A1 to A41, the features B1 to B20, the features C1 to C19, the features D1 to D7, the features E1 to E4, the features F1 to F10, the features G1 to G7, and the features H1 to H1. Any one or a plurality of configurations of H34, features I1 to I11, features J1 to J15, features K1 to K16, features L1 to L12, and features M1 to M5 may be applied. Thereby, it becomes possible to produce a synergistic effect by the combined configuration.

<Feature I group>
Feature I1. A transparent board (window panel 52) is arranged on the front side of the game board (for example, game board 261), and a game ball (game ball B1) is a game area (game area PA) between the game board and the transparent board. ) In a gaming machine that flows down from upstream to downstream,
The game board can contact a game ball whose position in the depth direction in the game area is in a contactable range (for example, either the back side or the near side of the game area PA), and the depth direction Special changing means (a rear nail 271, a front priority member 291, a passage forming member 422) that cannot change a game ball whose position does not exist in the contactable range and can change the movement mode of the contacted game ball. A gaming machine comprising an exchange passage forming member 441).

  According to the feature I1, only a game ball in which the position in the depth direction in the game area is within the contactable range can contact the special changing means. As a result, the player who expects the game ball to come into contact with the special change means expects the game ball to be in the contactable range, and the player's attention to the position of the game ball in the depth direction in the game area It becomes possible to increase the degree. Therefore, it is possible to improve the interest of the game.

The game board in the feature I1 is a plate having special changing means, and defines a game area for playing a game.

  Feature I2. The special changing means is present from the surface of the game board to a midway position in the depth direction of the game area such that the accessible range is on the back side of the game area. The gaming machine according to I1.

  According to the feature I2, only a game ball existing on the back side of the game area can come into contact with the special changing means. As a result, the player who expects the game ball to come into contact with the special change means expects the game ball to exist at the back of the game area. In addition, since the special change means has a configuration that extends from the surface of the game board to an intermediate position in the depth direction, the special change means can be provided with a simple configuration.

Feature I3. The game board is provided with openings (first operation port 33, second operation port 34) that serve as an opportunity for providing advantageous benefits to the player by entering a game ball,
A game ball that has reached the area where the special change means is provided may or may not enter the opening or whether or not it can enter the opening, depending on whether or not it touches the special change means. The gaming machine according to the feature I1 or I2, wherein the game machines are different from each other.

  According to the feature I3, whether or not a game ball enters the opening or whether the game ball enters the opening differs depending on whether or not the special change means is touched. Therefore, it is possible to increase the player's attention to the special change means.

  Feature I4. Any one of the features I1 to I3, wherein the game board includes a failure nail (failure nail 228) that changes a movement mode of the game ball after contact in a manner corresponding to a contact position in the left-right direction. The gaming machine described in 1.

  According to the characteristic I4, it is possible to provide a sufficient number of means for dispersing the course of the game ball on the game board. When all the obstacle nails in the conventional game board are changed to the predetermined change means, the number of the predetermined change means that can be provided on the game board is limited if the predetermined change means is manufactured larger than the obstacle nails in order to ensure the strength. End up. On the other hand, as a means for dispersing the course of the game ball on the game board, a small obstacle nail and a large predetermined change means are mixed to disperse the game balls that can be provided on the game board. The decrease in means can be suppressed, and the game balls can be sufficiently dispersed. And it can be set as the structure of the game board in which both the change of the course according to the position of the left-right direction of a game ball and the change of the course according to the position of the depth direction of a game ball are possible.

  Feature I5. On the upstream side of the special change means, specific change means (front / rear distribution nail 262, obstacle nail 228, concave front / rear distribution nail) capable of contacting the game ball regardless of the position in the depth direction is provided. The gaming machine according to any one of features I1 to I4, wherein:

  According to the feature I5, the game ball that has reached the position of the specific change means is surely in contact with the specific change means, whereas the game ball that has reached the position of the special change means is not in contact with the special change means. Can happen. The specific change means is provided on the upstream side of the special change means, so that the game ball does not come into contact with the special change means in spite of reaching the position of the special change means. It is possible to give unexpectedness.

Feature I6. The special change means and the specific change means are provided so as to be arranged in a predetermined direction,
A gaming machine according to the characteristic I5, wherein a plurality of the specific changing means are provided so as to sandwich the special changing means in the predetermined direction.

  According to the feature I6, the situation in which the game ball is guided in the predetermined direction by the special change unit and the specific change unit according to the position of the game ball in the depth direction, and the game ball in the predetermined direction at the position of the special change unit It is possible to cause a situation in which the guidance of is terminated. Thereby, the player who expects the game ball to be guided in a predetermined direction pays attention to the special change means and the arrangement area of the specific change means, and it is possible to improve the interest of the game. .

  Feature I7. The gaming machine according to the characteristic I5 or I6, wherein the specific changing means is capable of changing a position in a depth direction of a game ball that comes into contact.

  According to the feature I7, when the game ball comes into contact with the specific change unit, the position in the depth direction of the game ball before reaching the position of the special change unit is changed from the previous position. This makes it possible for the player to pay attention to the presence or absence of contact of the game ball with the specific change means and the position in the depth direction of the game ball after the contact.

  Feature I8. The gaming machine according to Feature I7, wherein the specific changing unit changes a movement mode of the game ball in the depth direction after contact according to a position of the game ball in contact with the depth direction.

  According to the feature I8, it is possible to change the movement direction of the game ball in the depth direction according to the position of the game ball in the depth direction. Thereby, it becomes possible to diversify the movement mode of the game ball in the depth direction, and to improve the interest of the game.

Feature I9. The specific changing means includes
First specification changing means (first distribution surface 264a) that changes the movement mode in the depth direction of the game ball that contacts the first specific range in the depth direction (for example, the back side of the game area PA). When,
A second specific change in which the movement mode in the depth direction of a game ball that contacts a second specific range (for example, the front side of the game area PA) that does not overlap the first specific range in the depth direction is changed in a second specific mode. Means (second distribution surface 265a);
The gaming machine according to Feature I8, comprising:

  According to the feature I9, the movement mode in the depth direction of the game ball after the contact is uniquely changed according to the contact position in the depth direction. As a result, in a configuration in which the movement mode of the game ball in the horizontal direction is changed in accordance with the contact position in the depth direction, the subsequent movement mode of the game ball in the depth direction relative to the position in the depth direction of the game ball is predicted to some extent by the player. It becomes possible to make it.

Feature I10. The first specific changing means gives a force including a forward-facing component to the game ball in contact with the first specific range,
The game machine according to Feature I9, wherein the second specific changing means gives a force including a backward component to the game ball in contact with the second specific range.

  According to the feature I10, the component in the depth direction of the drag applied to the game ball in accordance with the contact position in the depth direction is the opposite. This makes it possible to significantly change the movement mode of the game ball in the depth direction according to the contact position in the depth direction.

  Feature I11. The gaming machine according to Feature I10, wherein the first specific range is located behind the second specific range.

  According to the feature I11, the position of the game ball in the depth direction can be changed reversely between the back side and the near side due to the presence of the specific change means.

  In addition, with respect to the configuration of the features I1 to I11, the features A1 to A41, the features B1 to B20, the features C1 to C19, the features D1 to D7, the features E1 to E4, the features F1 to F10, the features G1 to G7, and the features H1 to H1. Any one or a plurality of configurations of H34, features I1 to I11, features J1 to J15, features K1 to K16, features L1 to L12, and features M1 to M5 may be applied. Thereby, it becomes possible to produce a synergistic effect by the combined configuration.

<Feature J group>
Feature J1. A transparent board (window panel 52) is arranged on the front side of the game board (for example, game board 261), and a game ball (game ball B1) is a game area (game area PA) between the game board and the transparent board. ) In a gaming machine that flows down from upstream to downstream,
The game board has specific change means (inverted nail 251, front / rear distribution nail 262, front / rear distribution table 351, 391) that makes it possible to set the movement mode in the depth direction of the game area in contact with the game area. 392, a position change passage 423, a replacement position change passage 442, and a guide passage 461).

  According to the feature J1, it is possible to change the position of the game ball in the depth direction by providing the specific changing means. This makes it possible to diversify the movement mode of the game ball in the game area not only in the horizontal direction but also in the depth direction, thereby improving the interest of the game.

  The game board in the feature J1 is a plate having a specific change means, and defines a game area for playing a game.

  Feature J2. The gaming machine according to Feature J1, wherein the specific changing means changes a movement mode of the game ball in the depth direction after contact according to a position of the game ball in contact with the depth direction.

  According to the feature J2, it is possible to change the movement direction of the game ball in the depth direction according to the position of the game ball in the depth direction. Thereby, it becomes possible to diversify the movement mode of the game ball in the depth direction, and to improve the interest of the game.

Feature J3. The specific changing means includes
First specification changing means (first reversing surface 254a, first) for changing the movement mode in the depth direction of the game ball that contacts the first specific range in the depth direction (for example, the back side of the game area PA). 1 distribution surface 264a, back side wall surface 443a),
A second specific change in which the movement mode in the depth direction of a game ball that contacts a second specific range (for example, the front side of the game area PA) that does not overlap the first specific range in the depth direction is changed in a second specific mode. Means (second reversal surface 254b, second distribution surface 265a, front side wall surfaces 422b, 443b),
The gaming machine according to feature J2, characterized by comprising:

  According to the feature J3, the movement mode in the depth direction of the game ball after the contact is uniquely changed according to the contact position in the depth direction. As a result, in a configuration in which the movement mode of the game ball in the horizontal direction is changed in accordance with the contact position in the depth direction, the subsequent movement mode of the game ball in the depth direction relative to the position in the depth direction of the game ball is predicted to some extent by the player. It becomes possible to make it.

Feature J4. The first specific changing means gives a force including a forward-facing component to the game ball in contact with the first specific range,
The game machine according to Feature J3, wherein the second specific changing means gives a force including a backward component to the game ball in contact with the second specific range.

  According to the feature J4, the component in the depth direction of the drag applied to the game ball in accordance with the contact position in the depth direction is the opposite. This makes it possible to significantly change the movement mode of the game ball in the depth direction according to the contact position in the depth direction.

  Feature J5. The gaming machine according to Feature J4, wherein the first specific range is located behind the second specific range.

  According to the feature J5, it is possible to change the position of the game ball in the depth direction on the back side and the near side by the presence of the specific change means.

  Feature J6. The specific change means has a guide passage (position change passage 423, replacement position change passage 442, guide passage 461) through which the game ball passes, and the movement direction of the game ball discharged from the guide passage in the depth direction. The gaming machine according to any one of features J1 to J5, wherein the gaming machine is configured to be able to have the specific mode.

  According to the feature J6, the player who is paying attention to the position of the game ball in the depth direction pays attention to whether or not the game ball enters the guide passage, and can improve the interest of the game. .

  Feature J7. The game machine according to Feature J6, wherein a movement mode in the depth direction of the game ball discharged from the guide passage is changed according to a passing mode of the game ball in the guide passage.

  According to the feature J7, the game sphere enters the guide passage by setting the movement manner in the depth direction of the game sphere discharged from the guide passage according to the passage manner of the game ball in the guide passage. It becomes possible to make the player pay attention to whether or not the player can also pay attention to the passing mode of the game ball in the guide passage.

  Feature J8. The feature J6 or J7 is characterized in that the guide passage changes a movement mode of the game ball discharged from the guide passage in the depth direction according to the position of the game ball at the entrance of the guide passage. The gaming machine described.

  According to the feature J8, the game ball is inserted into the guide passage by changing the movement mode in the depth direction of the game ball discharged from the guide passage according to the position of the game ball at the entrance of the guide passage. It is possible to make the player pay attention to whether or not the player is also paying attention to the position of the game ball when entering the entrance of the guide passage.

Feature J9. The guide passage is formed by being partitioned into a plurality of passage walls, and is provided to extend in the vertical direction.
The depth direction of the game balls discharged from the guide passage when the game balls passing through the guide passage come into contact with predetermined passage walls (the front side wall surfaces 422b and 443b and the rear side wall surface 443a) among the plurality of passage walls. The game machine according to any one of features J6 to J8, wherein the movement mode is the specific mode.

  According to the feature J9, by having the configuration in which the movement mode in the depth direction of the game ball is changed by contact with the passage wall of the guide passage, there is an excellent effect as described above while simplifying the configuration. Is possible.

  Feature J10. The guide passage is configured such that a game ball existing in the first range in the depth direction (near the surface of the game boards 421 and 451) at the entrance of the guide passage is closer to the front side than the first range at the exit of the guide passage. And the game balls existing in the second range (near the back surface of the window panel 52) at the entrance of the guide passage are closer to the first range than the second range at the exit of the guide passage. The game machine according to any one of features J6 to J9, wherein the game machine is also configured to move to the back side.

  According to the feature J10, it is possible to guide the game ball to a position opposite to the position in the depth direction at the entrance of the guide passage. Thereby, the position of the game ball in the depth direction can be positively changed.

  Feature J11. For the game ball existing at the front side of the first range at the entrance of the guide passage and at the back side of the second range, the guide passage is in the depth direction at the exit of the guide passage. The gaming machine according to Feature J10, wherein the game machine has a configuration that does not apply a force for changing the position of the game machine.

  According to the feature J11, it is possible to cause a situation in which the position of the game ball in the depth direction does not change even when passing through the guide passage. This makes it possible to diversify the positions of the game balls in the depth direction after passing through the guide passage.

  Feature J12. In the feature J6, the guide passage is configured such that the movement mode in the depth direction of the game ball discharged from the guide passage is the specific mode regardless of the mode of passage of the game ball in the guide channel. The gaming machine described.

  According to the feature J12, since the game ball that has entered the guide passage has a specific movement mode in the depth direction after passing through the guide passage, the influence of the guide passage on the game board can be increased. It becomes. Therefore, it becomes possible to attract the player's interest in the movement of the game ball around the guide passage, and to improve the interest of the game.

  Feature J13. The guide passage is provided in a passage forming body (passage forming member 422, replacement passage forming member 441, guide member 471, replacement guide member 561) provided separately from the game board. The gaming machine according to any one of features J6 to J12.

  According to the feature J13, the guide passage is provided in the passage forming body provided separately from the game board, so that the depth of the game ball can be obtained while using the same game board by exchanging the passage forming body. It becomes possible to change the movement mode of the direction.

Feature J14. The game board is provided with openings (first operation port 33, second operation port 34) that serve as an opportunity for providing advantageous benefits to the player by entering a game ball,
The specific changing means distributes the movement mode after contact of the game balls to be contacted into a movement mode having a high probability of entering the opening and a movement mode having a low probability of entering the opening. The gaming machine according to any one of features J1 to J13.

  According to the feature J14, the probability that the game ball wins the opening varies depending on the position of the game ball in the depth direction. In this way, by making the configuration in which the depth direction position of the game ball upstream of the opening is reflected in the game result, it is possible to improve the interest of the game.

Feature J15. The game board includes guidance means (stage unit 354) for guiding a game ball to a place with a high probability of entering the opening.
The specific changing means includes a case where the game ball is guided to the guide means according to a position in the depth direction of the game ball and a case where the game ball is not guided to the guide means. The gaming machine described in 1.

  According to the feature J15, by causing the player to pay attention to whether or not the game ball whose course has been changed by the predetermined changing means is guided to the guiding means, the player's interest in the movement of the game ball is increased, and the game Can be improved. Further, by reflecting the difference in the position in the depth direction of the game ball in the game area in the game result, it is possible to improve the interest of the game.

  In addition, with respect to the configuration of the features J1 to J15, the features A1 to A41, the features B1 to B20, the features C1 to C19, the features D1 to D7, the features E1 to E4, the features F1 to F10, the features G1 to G7, and the features H1 to H1. Any one or a plurality of configurations of H34, features I1 to I11, features J1 to J15, features K1 to K16, features L1 to L12, and features M1 to M5 may be applied. Thereby, it becomes possible to produce a synergistic effect by the combined configuration.

  According to the invention relating to the feature group H, the feature group I, and the feature group J, the following problems can be solved.

  Pachinko machines and slot machines are known as gaming machines. For example, a pachinko gaming machine is provided with a game board that defines a game area where game balls flow down, and the game board includes nails and a ball to distribute and adjust the falling direction of the game balls flowing down the game area as appropriate. Various members such as a windmill are arranged. In addition, the game board is provided with an opening for a game ball to be paid out, such as a general winning opening, a special electric winning device, and an operating opening. The game balls launched from the game ball launcher flow down the game area while colliding with a nail or the like, and when the game ball enters the general prize opening, the special electric prize winning device, the operation opening, etc., a predetermined number of A game ball is paid out to a player.

  Here, in gaming machines such as the above-described examples, it is necessary to distribute the game balls in the game area suitably, and there is still room for improvement in this regard.

<Feature K group>
Feature K1. Insertion holes (via holes 793) through which terminals (pins 784a to 784t, terminals 775) of mounting parts (connectors 781 to 783, first operation port connector 955, second operation port connector 956, insertion mounting component) are inserted. 793a to 793t) and a connection region (short-circuit prevention hole 761, joint hole 762) provided around the insertion hole, and the terminal of the mounting component is inserted into the insertion hole. In a state, in a gaming machine including a board (for example, main control board 61) in which the terminal of the mounting component and the connection region are electrically connected by solder,
The substrate has a first connection region (joining hole 762) as a connection region provided for each of the different insertion holes, and a first area having a larger area than the first connection region. A gaming machine comprising two connection regions (short-circuit prevention holes 761).

  According to the characteristic K1, since the second connection region having a larger area than the first connection region is provided, the melting that adheres to a predetermined terminal when performing soldering while transporting the substrate The possibility that the solder moves toward the adjacent terminal is reduced. Therefore, it is possible to reduce the possibility that a solder bridge is formed.

Feature K2. The mounting component includes a terminal row in which a plurality of terminals are arranged in a row (a row of pins 784a to 784d of the one-row connector 782, a row of pins 784e and 784f of the two-pole connector 781, and a pin 784g of the two-row connector 783. 784p, a row of pins 784q and 784r of the first working port connector 955, and a row of pins 784s and 784t of the second working port connector 956),
The second connection region is provided so as to correspond to the insertion hole into which a terminal (for example, the fourth pin 784d of the one-row connector 782) existing at least at one end of the terminal row is inserted. The gaming machine according to Feature K1, characterized by

  According to the feature K2, the second connection region is provided corresponding to the predetermined terminal located at the end of the terminal row that tends to increase the amount of the molten solder that adheres when soldering while carrying the substrate. Yes. As a result, the possibility that the molten solder moves from the periphery of the predetermined terminal located at the end of the terminal row toward the terminal adjacent to the predetermined terminal is reduced, and as a result, a solder bridge is formed. It is possible to reduce the possibility of being lost.

  Feature K3. The second connection region includes at least the insertion hole through which a terminal existing at one end of the terminal row is inserted and a terminal existing at the other end of the terminal row (for example, one row connector 782). The game machine according to the feature K2, wherein the first pin 784a) is provided in correspondence with each of the insertion holes.

  According to the feature K3, when performing soldering while transporting a board, the board can be designed before the board transport direction is determined. Further, even if a change is made to reverse the substrate transport direction before soldering, a substrate with a low probability of solder bridges can be obtained.

Feature K4. The terminal row is provided with three or more terminals including grounding terminals (pins 784c, 784e, 784i connected to the GND solid 851) for grounding,
The gaming machine according to the feature K2 or K3, wherein the grounding terminal is arranged to avoid an end of the terminal row.

  According to the characteristic K4, since there is no grounding terminal at the end of the terminal row that tends to lower the temperature of the molten solder around the terminal, the predetermined terminal from the periphery of the predetermined terminal existing at the end of the terminal row. The possibility that the molten solder moves toward the terminal adjacent to the terminal is reduced. In addition, by reducing the possibility that the molten solder moves as described above, it is possible to prevent the area necessary for the second connection region from becoming extremely wide.

  Feature K5. The first connection region is provided corresponding to the insertion hole through which a terminal existing in a position different from an end of the terminal row is inserted in the terminal row. The gaming machine according to any one of thru K4.

  According to the feature K5, the terminal (for example, the second pin 784b and the third pin 784c of the one-row connector 782) which is present at a position different from the end of the terminal row is not the second connection region but the first connection region. By providing the connection regions, it is possible to prevent the range occupied by these connection regions on the substrate from becoming extremely wide.

  Feature K6. In the second connection area, the dimension between two adjacent terminals is a predetermined dimension (a reference value of 1.5 mm for the pin interval in the row of the single row connector, and 2.5 mm for the pin interval of the 2-pole connector The reference value, the reference value of 1.5 mm for the pin interval in the row of the two-row connector and the reference value of 2.5 mm for the row interval) or less, at least one of the terminals is inserted. The gaming machine according to any one of features K1 to K5, wherein the gaming machine is provided so as to correspond to a common hole.

  According to the feature K6, by providing the second connection region only in a place where the probability of occurrence of a solder bridge in the substrate is high, the range occupied by the connection region in the substrate can be prevented from becoming extremely wide. It becomes possible.

Feature K7. As the mounting component, a first mounting component (for example, a two-pole connector 781) in which the terminal arrangement mode is the first arrangement mode, and a second mounting component (for example, one row) in which the terminal arrangement mode is the second arrangement mode. Connector 782), and
The gaming machine according to Feature K6, wherein the predetermined dimension is different between the first arrangement mode and the second arrangement mode.

  According to the feature K7, the predetermined dimension between the terminals serving as the reference for providing the second connection region is different according to the terminal arrangement mode, so that only in the place where the probability that a solder bridge is generated on the substrate is high. It is possible to provide two connection areas. Thereby, it is possible to prevent the range occupied by the connection region on the substrate from becoming extremely wide.

Feature K8. The first arrangement mode is an arrangement mode (arrangement of pins 784e and 784f of the two-pole connector 781) in which two terminals are arranged in a predetermined direction.
The second arrangement mode is an arrangement mode in which three or more terminals are arranged in a predetermined direction (for example, an arrangement of pins 784a to 784d of the one-row connector 782),
The gaming machine according to Feature K7, wherein the predetermined dimension in the first arrangement mode is larger than the predetermined dimension in the second arrangement mode.

  According to the feature K8, in the case of the first arrangement mode in which two terminals are arranged in a predetermined direction, the terminals existing at the end in the arrangement direction are ground terminals, so that three or more terminals are predetermined. Solder bridges are more likely to occur than in the second arrangement mode arranged in the direction. In this case, according to the feature K8, the predetermined dimension in the first arrangement mode is set to be larger than the predetermined dimension in the second arrangement mode. While providing the connection region, it is possible to reduce the number of terminals to be formed with the second connection region.

Feature K9. The first arrangement mode is an arrangement mode in which two or more terminal rows in which three or more terminals are arranged in a predetermined direction are present in a direction orthogonal to the predetermined direction (for example, an arrangement of pins 784g to 784p of the two-row connector 783). And
The second arrangement mode is an arrangement mode in which there is only one terminal row in which three or more terminals are arranged in a predetermined direction (for example, an arrangement of pins 784a to 784d of the one-row connector 782),
The gaming machine according to feature K7, wherein the predetermined dimension in the first arrangement mode is larger than the predetermined dimension in the second arrangement mode.

  According to the feature K9, in the first arrangement mode in which two terminal rows are arranged side by side, a solder bridge is more likely to occur than in the second arrangement mode in which only one terminal row is provided. In this case, according to the feature K9, the predetermined dimension in the first arrangement mode is set to be larger than the predetermined dimension in the second arrangement mode. While providing the connection region, it is possible to reduce the number of terminals to be formed with the second connection region.

Feature K10. The mounting component includes a predetermined terminal row (a row of pins 784e and 784f of the two-pole connector 781) in which two terminals are arranged in a predetermined direction.
The second connection area is provided corresponding to each of the insertion holes through which the two terminals existing in the predetermined terminal row are individually inserted. The gaming machine according to any one of the above.

  According to the feature K10, in the case of a predetermined terminal array in which two terminals are arranged in a predetermined direction, a terminal existing at the end in the arrangement direction is a grounding terminal, so that three or more terminals are in a predetermined direction. Solder bridges are more likely to occur than a terminal array arranged in a row. In this case, according to the feature K10, since the second connection region is provided corresponding to each of the two terminals of the predetermined terminal row, the possibility that the solder bridge is generated is reduced. Is possible.

  Feature K11. The second connection region is formed to have a larger area on the side different from the terminal side existing closest to the terminal inserted through the insertion hole corresponding to the second connection region. The gaming machine according to any one of features K1 to K10, wherein:

  According to the feature K11, when performing soldering while transporting the substrate, the molten solder attached around the predetermined terminal can be held in a different direction from the terminal adjacent to the predetermined terminal. Accordingly, it is possible to prevent a solder bridge from being formed by joining with the molten solder around the adjacent terminals before the molten solder held in the second connection region is solidified.

  Feature K12. The second connection area has the largest area on the side opposite to the terminal side that is closest to the terminal inserted through the insertion hole corresponding to the second connection area. The gaming machine according to any one of features K1 to K11, wherein the gaming machine is formed.

  According to the feature K12, the molten solder adhering around the predetermined terminal can be held on the side farthest from the terminal adjacent to the predetermined terminal, so that it is difficult to form a solder bridge.

Feature K13. The mounting component includes a terminal row in which a plurality of terminals are arranged in a row (a row of pins 784a to 784d of the one-row connector 782, a row of pins 784e and 784f of the two-pole connector 781, and a pin 784g of the two-row connector 783. 784p, a row of pins 784q and 784r of the first working port connector 955, and a row of pins 784s and 784t of the second working port connector 956),
The second connection region is formed such that a length dimension of the plurality of terminals in the terminal row is larger than a direction orthogonal to the arrangement direction. The gaming machine according to any one of features K1 to K12.

  According to the feature K13, it is possible to provide the second connection region while suppressing the influence on the board design in the direction orthogonal to the arrangement direction of the terminals in the terminal row on the board.

Feature K14. The second connection area is:
A peripheral region (small short-circuit prevention holes 891, 921) formed around the insertion hole corresponding to the second connection region;
An external region (large-sized short-circuit prevention holes 892, 922) provided outside the peripheral region in the substrate;
A connection region (first passage region 894, 924) connecting the peripheral region and the external region;
The gaming machine according to any one of features K1 to K13, comprising:

  According to the feature K14, it is possible to separate and hold the molten solder in an external region that is separated from the surrounding region with the coupling region interposed therebetween. Thereby, it is possible to reduce the possibility that the molten solder moves to the surrounding region side.

  Feature K15. The gaming machine according to Feature K14, wherein the outer area has a larger area than the surrounding area.

  According to the feature K15, since the outer region has a larger area than the surrounding region, the molten solder accumulated in the surrounding region is attracted toward the outer region. Thereby, it is possible to reduce the possibility that the molten solder moves to the surrounding region side.

  Feature K16. The gaming machine according to Feature K14 or K15, wherein the connection area is narrower than the external area.

  According to the feature K16, the possibility that the molten solder held in the external region moves to the surrounding region through the connection region is reduced.

  In addition, with respect to the configuration of the features K1 to K16, the features A1 to A41, the features B1 to B20, the features C1 to C19, the features D1 to D7, the features E1 to E4, the features F1 to F10, the features G1 to G7, and the features H1 to H1. Any one or a plurality of configurations of H34, features I1 to I11, features J1 to J15, features K1 to K16, features L1 to L12, and features M1 to M5 may be applied. Thereby, it becomes possible to produce a synergistic effect by the combined configuration.

<Feature L group>
Feature L1. Insertion holes (via holes 793, through which terminals (pins 784a to 784t, terminals 775) of mounting parts (connectors 781 to 783, first working port connector 955, second working port connector 956, insertion mounting component) are inserted. 793a to 793t) and a connection region (joining hole 762) provided around the insertion hole, and the mounting component terminal is inserted in the insertion hole. In a gaming machine including a board (main control board 61) in which a terminal of a component and the connection region are electrically connected by solder,
The substrate is provided in a position outside the connection region without being communicated with the connection region, and is a special region (separate type short-circuit prevention holes 871, 874, 875-878, 886, where solder can be fastened). 887, a three-way separation type short-circuit prevention hole 881,884).

  According to the feature L1, it is possible to separate and hold the molten solder adhering to the connection region in the special region when performing soldering while transporting the substrate. Thereby, it is possible to reduce the possibility that a solder bridge is formed. In particular, the possibility that the molten solder moves from the special region to the connection region can be reduced by holding the molten solder separately from the connection region in the special region.

Feature L2. As the connection area,
A predetermined connection region provided corresponding to the insertion hole through which the predetermined terminal is inserted (for example, the fourth joint hole 762d of the back surface region 873 for one row);
A specific connection region provided corresponding to the insertion hole through which the adjacent terminal adjacent to the predetermined terminal is inserted (for example, the third joint hole 762c of the back surface region 873 for one row);
With
The gaming machine according to Feature L1, wherein the special area is provided on a side different from the specific connection area side with respect to the predetermined connection area.

  According to the feature L2, it is possible to prevent the molten solder held in the special region from moving to the specific connection region side.

  Feature L3. The gaming machine according to Feature L2, wherein the special area is provided on a side opposite to the specific connection area side with respect to the predetermined connection area.

  According to the feature L3, the molten solder adhering to the predetermined connection region can be held in a direction away from the specific connection region. In addition, when the predetermined connection area exists on the rear side in the transport direction with respect to the specific connection area, the special area exists on the rear side in the transport direction with respect to the predetermined connection area. Thereby, the molten solder adhering to the predetermined connection region is easily held in the special region.

  Feature L4. The special region is provided at a position where a distance (distance LD1) between the predetermined connection region and the predetermined connection region is closer than a distance (distance LD2) between the predetermined connection region and the specific connection region. The gaming machine according to Feature L2 or L3, wherein

  According to the feature L4, the special area is located closer to the predetermined connection area than the specific connection area. As a result, when soldering is performed while transporting the substrate, excess molten solder generated on the surface of the predetermined connection region is more easily held in the special region than in the specific connection region.

  Feature L5. The gaming machine according to any one of features L1 to L4, wherein the special area has a larger area than the connection area.

  According to the feature L5, since the special region has a larger area than the connection region, the molten solder is easily attracted to the special region.

  Feature L6. The gaming machine according to any one of features L1 to L5, wherein the special area is formed so that the area farther from the connection area is wider than the nearer side.

  According to the feature L6, since most of the molten solder held in the special region is held on the side far from the connection region, the molten solder held in the special region is difficult to move to the connection region side.

  Feature L7. The gaming machine according to any one of features L1 to L6, wherein the special area is provided so as to exist in a plurality of directions with respect to the connection area.

  According to the feature L7, since the special region is provided so as to exist in a plurality of directions with respect to the connection region, it is possible to secure a large number of movement paths of the molten solder that moves from the connection region to the special region. It becomes possible. Therefore, excess molten solder generated on the surface of the connection region is easily held in the special region.

  Feature L8. The gaming machine according to Feature L7, wherein a plurality of the special areas are provided around one connection area.

  According to the feature L8, since there are a plurality of special regions around the connection region for retracting excess molten solder generated on the surface of the connection region, the molten solder is held in the special region. It becomes easy.

Feature L9. The mounting component includes a terminal row in which a plurality of terminals are arranged in a row (a row of pins 784a to 784d of the one-row connector 782, a row of pins 784e and 784f of the two-pole connector 781, and a pin 784g of the two-row connector 783. 784p, a row of pins 784q and 784r of the first working port connector 955, and a row of pins 784s and 784t of the second working port connector 956),
The special area is provided for the connection area corresponding to the insertion hole into which a terminal (for example, the fourth pin 784d of the single-row connector 782) existing at least at one end of the terminal row is inserted. The gaming machine according to any one of features L1 to L8, wherein:

  According to the feature L9, a special region is provided corresponding to a predetermined terminal located at the end of the terminal row that tends to increase the amount of molten solder that adheres when soldering while carrying the substrate. As a result, the possibility that the molten solder moves from the periphery of the predetermined terminal located at the end of the terminal row toward the terminal adjacent to the predetermined terminal is reduced, and as a result, a solder bridge is formed. It is possible to reduce the possibility of being lost.

  Feature L10. The special region includes at least the connection region corresponding to the insertion hole through which the terminal existing at one end of the terminal row is inserted and the terminal existing at the other end of the terminal row (for example, The gaming machine according to feature L9, wherein the gaming machine is provided for each of the connection regions corresponding to the insertion holes through which the first pins 784a) of the one-row connectors 782 are inserted.

  According to the feature L10, when performing soldering while transporting a board, the board can be designed before the board transport direction is determined. Further, even if a change is made to reverse the substrate transport direction before soldering, a substrate with a low probability of solder bridges can be obtained.

Feature L11. The terminal row is provided with three or more terminals including grounding terminals (pins 784c, 784e, 784i connected to the GND solid 851) for grounding,
The gaming machine according to Feature L9 or L10, wherein the grounding terminal is disposed so as to avoid an end of the terminal row.

  According to the feature L11, since there is no grounding terminal at the end of the terminal row that tends to lower the temperature of the molten solder around the terminal, the predetermined terminal is located from the periphery of the predetermined terminal existing at the end of the terminal row. The possibility that the molten solder moves toward the terminal adjacent to the terminal is reduced. Further, by reducing the possibility that the molten solder moves in this way, it becomes possible to prevent the area required as the special region from becoming extremely wide.

  Feature L12. The special region is formed in the insertion hole through which a terminal (for example, the second pin 784b and the third pin 784c of the one-row connector 782) is present in a position different from the end of the terminal row in the terminal row. The gaming machine according to any one of features L9 to L11, which is not provided for the corresponding connection area.

  According to the feature L12, since the special region is not provided for the terminal existing at a position different from the end of the terminal row, the range occupied by the special region on the board does not become extremely wide. It becomes possible to.

  In addition, with respect to the configuration of the features L1 to L12, the features A1 to A41, the features B1 to B20, the features C1 to C19, the features D1 to D7, the features E1 to E4, the features F1 to F10, the features G1 to G7, and the features H1 to H1. Any one or a plurality of configurations of H34, features I1 to I11, features J1 to J15, features K1 to K16, features L1 to L12, and features M1 to M5 may be applied. Thereby, it becomes possible to produce a synergistic effect by the combined configuration.

<Feature M group>
Feature M1. A launching means (game ball launching mechanism 27) for launching a game ball toward a game area (game area PA) based on a launch operation by a player;
A starting entrance portion (first operation port 938, second operation port 939) into which a game ball flowing down the game area can enter,
Entry detection means (first operation port detection sensor 951, second operation port detection sensor 952) for detecting a game ball that has entered the start entry part,
Connection means (first working port connector 955, second working port connector) to which the transmission means (first harness 951a, second harness 952a) for transmitting information of the detection result of the entrance detection means is electrically connected. 956) a specific control means (main control device 60) having a specific board (main control board 61) provided with;
With
As the starting ball entering portion, at least a first starting ball entering portion (first working port 938) and a second starting ball entering portion (second working port 939) are provided,
As said entrance detection means, the 1st entrance detection means (1st operation port detection sensor 951) which detects the game ball which entered the said 1st start entrance part, and an entrance to the said 2nd start entrance part A second entry detection means (second operation port detection sensor 952) for detecting the game ball that has been played,
As said transmission means, the 1st transmission means (1st harness 951a) which transmits the information of the detection result of the said 1st entrance detection means, and the 2nd transmission which transmits the information of the detection result of the said 2nd entrance detection means Means (second harness 952a),
As the connection means, first connection means (first working port connector 955) to which the first transmission means is connected and second connection means (second working port connector 956) to which the second transmission means are connected. ) And
The first connection means and the second connection means are individually provided for the specific substrate,
There are two connection terminals provided in the second connection means, a first connection terminal (first pin 784s) and a second connection terminal (second pin 784t),
The specific substrate is:
A first insertion hole (first via hole 793s) through which the first connection terminal is inserted;
A second insertion hole (second via hole 793t) through which the second connection terminal is inserted;
A first connection region (short-circuit prevention hole 761) provided around the first insertion hole;
A second connection region (short-circuit prevention hole 761) provided around the second insertion hole;
A predetermined insertion hole (via hole 793) through which a predetermined terminal of a predetermined mounting component is inserted;
A predetermined connection region (joining hole 762) provided around the predetermined insertion hole;
With
In a state where the first connection terminal is inserted into the first insertion hole, the first connection terminal and the first connection region are electrically connected by solder,
In a state where the second connection terminal is inserted into the second insertion hole, the second connection terminal and the second connection region are electrically connected by solder,
In a state where the predetermined terminal is inserted into the predetermined insertion hole, the predetermined terminal and the predetermined connection region are electrically connected by solder,
In the game area, the first start ball entering portion is provided at a position where a game ball launched at least when the launch operation according to the first operation mode is performed can be reached,
In the game area, the second start ball entering part is a position where the game ball launched when the launch operation according to the first operation mode is being performed is not reachable or difficult to reach, and the second operation mode Is provided at a position where the game ball launched when the launch operation is performed can be reached,
The specific control means includes
First acquisition means for acquiring special information (holding information) based on detection of a game ball by the first incoming detection means (function for executing the process of step S213 in the main CPU 63);
First acquisition information storage means for storing the special information acquired by the first acquisition means (first special figure reservation area, function of executing step S213 in the main CPU 63);
Second acquisition means (a function for executing the process of step S213 in the main CPU 63) for acquiring special information based on detection of a game ball by the second incoming detection means;
Second acquisition information storage means for storing the special information acquired by the second acquisition means (second special figure reservation area, function of executing step S213 in the main CPU 63);
Grant determination means (main CPU 63) that performs grant determination as to whether or not the special information stored in the first acquisition information storage means or the second acquisition information storage means corresponds to predetermined grant information. The function of executing the process of step S213 in FIG.
A privilege granting unit that grants a privilege to a player based on the result of the grant determination by the grant determination unit being a grant response result that the special information to be determined corresponds to the grant information ( A function of executing the process of step S213 in the main CPU 63);
Acceptance control capable of switching the second starting entrance part to either a first state in which a game ball is difficult to enter or cannot enter, and a second state in which a game ball is easier to enter. Means (function of executing the process of step S214 in the main CPU 63);
With
The acceptance control means includes a first mode (low frequency support mode) and a second mode (high frequency support mode) that is more likely to be in the second state than the first mode, as the control mode of the second start ball entering part. ) And
The special information stored in the second acquisition information storage unit becomes the target of the determination of the grant rather than the case where the special information stored in the first acquisition information storage unit is the target of the determination of grant. Is a configuration in which the privilege that is advantageous to the player is given or is easily given,
The first connection region and the second connection region are formed to have a larger area than the predetermined connection region,
The first connection region is formed such that an area on a side different from the second insertion hole side is increased with the first insertion hole as a reference,
The gaming machine is characterized in that the second connection area is formed so that an area on a side different from the first insertion hole side becomes larger with the second insertion hole as a reference.

  According to the feature M1, the giving determination performed when entering the second starting entrance part is more advantageous to the player than the giving determination performed when entering the first starting entrance part. Therefore, when a game ball enters the second starting ball entering part, the player has great expectations. A first connection region having a larger area than the predetermined connection region is provided around the first connection terminal of the second connection means, and an area larger than the predetermined connection region is provided around the second connection terminal. A wide second connection area is provided. For this reason, in the soldering process of a specific board | substrate, it can suppress that a solder bridge is formed between the 1st connection terminal and the 2nd connection terminal, and it short-circuits. Thereby, possibility that the situation where the entrance of the game ball to the 2nd start entrance part is not detected due to poor connection can be reduced. It is possible to avoid disappointing the expected player due to poor connection.

  Moreover, the 1st connection means for connecting a 1st detection means to a specific board | substrate, and the 2nd connection means for connecting a 2nd detection means to a specific board | substrate are provided with respect to the specific board | substrate separately. When a fraudulent board is used, it is possible to make it difficult to cheat in the game hall by setting many connection points necessary for connecting the fraudulent board to the specific board.

  Feature M2. The first connection region and the second connection region are longer in the arrangement direction in which the first connection terminals and the second connection terminals are arranged than in the direction orthogonal to the arrangement direction. The gaming machine according to the feature M1, wherein the gaming machine is formed so as to be large.

  According to the feature M2, the first connection region and the second connection region are provided on the specific substrate while suppressing the influence on the substrate design in the direction orthogonal to the arrangement direction of the first connection terminals and the second connection terminals. It becomes possible.

Feature M3. The first connection area is:
A first peripheral region (small short-circuit prevention holes 891, 921) formed around the first insertion hole;
A first external region (large-sized short-circuit prevention holes 892, 922) provided outside the first peripheral region in the specific substrate;
A first connection region (first passage region 894, 924) connecting the first peripheral region and the first external region;
With
The second connection area is:
A second peripheral region (small short-circuit prevention holes 891, 921) formed around the second insertion hole;
A second external region (large-sized short-circuit prevention holes 892, 922) provided outside the second peripheral region in the specific substrate;
A second connection region (first passage region 894, 924) connecting the second peripheral region and the second external region;
A gaming machine according to the feature M1 or M2, characterized by comprising:

  According to the feature M3, it is possible to separate and hold the molten solder in the first external region that is separated from the first peripheral region with the first connection region interposed therebetween, and to the second peripheral region. It is possible to separate and hold the molten solder in the second external region that is spaced apart from the second connection region. Thereby, it is possible to reduce the possibility that the molten solder moves to the first peripheral region side and the second peripheral region side.

Feature M4. The first outer region has a larger area than the first surrounding region,
The gaming machine according to Feature M3, wherein the second external region has a larger area than the second surrounding region.

  According to the feature M4, since the first external region has a larger area than the first peripheral region, the molten solder that accumulates in the first peripheral region is drawn toward the first external region. In addition, since the second external region has a larger area than the second peripheral region, the molten solder that accumulates in the second peripheral region is drawn toward the second external region. Thereby, it is possible to reduce the possibility that the molten solder moves to the first peripheral region side and the second peripheral region side.

Feature M5. The first connection region is narrower than the first outer region,
The gaming machine according to Feature M3 or M4, wherein the second connection area is narrower than the second external area.

  According to the feature M5, the possibility that the molten solder held in the first external region moves to the first peripheral region through the first connecting region is reduced, and the molten solder held in the second external region is reduced. The possibility that the solder moves to the second peripheral region through the second connection region is reduced.

  In addition, with respect to the configuration of the features M1 to M5, the features A1 to A41, the features B1 to B20, the features C1 to C19, the features D1 to D7, the features E1 to E4, the features F1 to F10, the features G1 to G7, and the features H1 to H1. Any one or a plurality of configurations of H34, features I1 to I11, features J1 to J15, features K1 to K16, features L1 to L12, and features M1 to M5 may be applied. Thereby, it becomes possible to produce a synergistic effect by the combined configuration.

  According to the invention relating to the feature K group, the feature L group, and the feature M group, the following problems can be solved.

  Pachinko machines and slot machines are known as gaming machines. For example, a pachinko gaming machine includes a main control device that controls the main control of a game, a sound emission control device that outputs sound and light for production based on commands received from the main control device, and the like. These main control devices, sound emission control devices, and the like have a board inside, and the board is configured by mounting electronic components such as ICs and resistors, connectors, and the like on a printed wiring board. Electronic components, connectors, and the like are fixed in a state of being electrically connected to wiring formed on the printed wiring board by soldering.

  Here, in a gaming machine such as the above-described example, it is necessary to suitably perform soldering when mounting electronic components and connectors on a printed wiring board, and there is still room for improvement in this respect.

  The basic configuration of the gaming machine to which the above features can be applied or applied to each feature is shown below.

  Pachinko gaming machine: operation means operated by a player, game ball launching means for launching a game ball based on the operation of the operation means, a ball path for guiding the launched game ball to a predetermined game area, and a game A gaming machine that includes each gaming component arranged in an area, and gives a bonus to a player when a gaming ball passes through a predetermined passing portion of each gaming component.

  Revolving type gaming machine such as a slot machine: equipped with a picture display device for variably displaying a plurality of pictures, variably starting display of the plurality of pictures due to the operation of the start operation means, and due to the operation of the stop operation means In addition, the game machine is configured such that the variable display of the plurality of patterns is stopped when a predetermined time elapses and a privilege is given to the player according to the pattern after the stop.

  DESCRIPTION OF SYMBOLS 10 ... Pachinko machine, 24a ... Out port, 27 ... Game ball launching mechanism, 31 ... General winning port, 32 ... Special prize winning device, 33 ... First operating port, 34 ... Second operating port, 52 ... Window panel, 60 ... Main controller 61 ... Main control board 62 ... MPU 63 ... Main side CPU 65 ... Main side RAM 92 ... Discharge side CPU 102 ... Reading terminal 112 ... Management CPU 116 ... Correspondence memory 131 ... Memory for calculation results, 151 ... Light emitting part for notification, 213 ... First left / right sorting nail, 214 ... Second left / right sorting nail, 215 ... First left / right sorting member, 216 ... Fixing member, 217a ... 1st distribution surface, 218a ... 2nd distribution surface, 228 ... Obstacle nail, 231 ... 2nd right and left distribution member, 232a ... 1st distribution surface, 233 ... Game board, 234a ... 2nd distribution surface, 242 ... 1st left / right sorting nail, 243 ... 1st left / right sorting member, 2 4a: first distributing surface, 245a: second distributing surface, 251 ... reversing nail, 254 ... reversing member, 254a ... first reversing surface, 254b ... second reversing surface, 255 ... left guiding member, 262 ... front / rear vibration Dividing nail, 263 ... Front / rear sorting member, 264a ... First sorting surface, 265a ... Second sorting surface, 271 ... Rear nail, 291 ... Front priority member, 292 ... Plate member, 293 ... First support member, 294 2nd support member, 322 ... Repulsion nail, 333 ... Low repulsion member, 334d ... High repulsion part, 351 ... Front / rear sorting table, 354 ... Stage unit, 372 ... First downstream surface, 373 ... Second downstream surface, 391 , 392 ... Front / rear sorting table, 422 ... Path forming member, 422b ... Front side wall surface, 423 ... Position changing passage, 441 ... Replacement passage forming member, 442 ... Replacement position changing passage, 443a ... Back side wall surface, 443b ... Front side, 61 ... guide passage, 462 ... guide surface, 471 ... guide member, 561 ... replacement guide member, 761 ... short-circuit prevention hole, 762 ... joining hole, 762c ... third joining hole, 762d ... fourth joining hole, 775 ... terminal , 781 ... 2-pole connector, 782 ... 1 row connector, 783 ... 2 row connector, 784a to 784t ... pins, 793, 793a to 793t ... via holes, 891 ... small short prevention holes, 892 ... large short prevention holes, 894 ... 1 passage area, 851... GND solid, 871 .. Separation type short-circuit prevention hole, 873... Single row back surface area, 874... Separation type short-circuit prevention hole, 875 ... Upper left separation type short-circuit prevention hole, 876. 877 ... Upper right separation type short circuit prevention hole, 878 ... Lower right separation type short circuit prevention hole, 881, 884 ... Three-way separation type short circuit prevention hole, 886 ... Left separation type short circuit prevention hole, 887 ... Right-side separation type short-circuit prevention hole, 921... Small short-circuit prevention hole, 922... Large-scale short-circuit prevention hole, 924... First passage region, 938 ... First operation port, 939. 951a ... first harness, 952 ... second working port detection sensor, 952a ... second harness, 955 ... first working port connector, 956 ... second working port connector, B1 ... game ball, PA ... game area.

In order to solve the above-mentioned problem, the invention according to claim 1 is a launching means for launching a game ball toward a game area based on a launch operation by a player,
A starting pitching portion into which a gaming ball flowing down the gaming area can enter;
Entry detection means for detecting a game sphere that has entered the starting entrance part,
A specific control means having a specific substrate provided with a connection means to which a transmission means for transmitting information of the detection result of the entrance detection means is electrically connected;
With
As the starting pitching portion, at least a first starting pitching portion and a second starting pitching portion are provided,
As said entrance detection means, the 1st entrance detection means which detects the game ball which entered the 1st start entrance part, and the 2nd entrance which detects the game ball which entered the 2nd start entrance part And at least a ball detecting means,
As the transmission means, the first transmission means for transmitting the detection result information of the first entrance detection means, and the second transmission means for transmitting the detection result information of the second entrance detection means,
The connection means includes a first connection means to which the first transmission means is connected, and a second connection means to which the second transmission means is connected,
The first connection means and the second connection means are individually provided for the specific substrate,
The connection terminals provided in the second connection means are two, a first connection terminal and a second connection terminal,
The specific substrate is:
A first insertion hole through which the first connection terminal is inserted;
A second insertion hole through which the second connection terminal is inserted;
A first connection region provided around the first insertion hole;
A second connection region provided around the second insertion hole;
A predetermined insertion hole through which a predetermined terminal of a predetermined mounting component is inserted;
A predetermined connection area provided around the predetermined insertion hole;
With
In a state where the first connection terminal is inserted into the first insertion hole, the first connection terminal and the first connection region are electrically connected by solder,
In a state where the second connection terminal is inserted into the second insertion hole, the second connection terminal and the second connection region are electrically connected by solder,
In a state where the predetermined terminal is inserted into the predetermined insertion hole, the predetermined terminal and the predetermined connection region are electrically connected by solder,
In the game area, the first start ball entering portion is provided at a position where a game ball launched at least when the launch operation according to the first operation mode is performed can be reached,
In the game area, the second start ball entering part is a position where the game ball launched when the launch operation according to the first operation mode is being performed is not reachable or difficult to reach, and the second operation mode Is provided at a position where the game ball launched when the launch operation is performed can be reached,
The specific control means includes
First acquisition means for acquiring special information based on the fact that a game ball is detected by the first entry detection means;
First acquisition information storage means for storing the special information acquired by the first acquisition means;
Second acquisition means for acquiring special information based on the fact that a game ball is detected by the second entry detection means;
Second acquisition information storage means for storing the special information acquired by the second acquisition means;
Grant determination means for performing grant determination as to whether or not the special information stored in the first acquisition information storage means or the second acquisition information storage means corresponds to predetermined grant information;
Privilege granting means for granting a privilege to a player based on the result of the grant determination by the grant determination means being the grant correspondence result that the special information to be judged corresponds to the grant information; ,
Acceptance control capable of switching the second starting entrance part to either a first state in which a game ball is difficult to enter or cannot enter, and a second state in which a game ball is easier to enter. Means,
With
The acceptance control means has a first mode and a second mode that is more likely to be in the second state than the first mode as a control mode of the second starting and entering part,
The special information stored in the second acquisition information storage unit becomes the target of the determination of the grant rather than the case where the special information stored in the first acquisition information storage unit is the target of the determination of grant. Is a configuration in which the privilege that is advantageous to the player is given or is easily given,
The first connection region and the second connection region are formed to have a larger area than the predetermined connection region,
As the predetermined terminal, a first predetermined terminal and a second predetermined terminal adjacent to the first predetermined terminal,
The predetermined insertion hole is
A first predetermined insertion hole through which the first predetermined terminal is inserted;
A second predetermined insertion hole through which the second predetermined terminal is inserted;
With
The predetermined connection area is:
A first predetermined connection region provided around the first predetermined insertion hole;
A second predetermined connection region provided around the second predetermined insertion hole;
With
In a state where the first predetermined terminal is inserted into the first predetermined insertion hole, the first predetermined terminal and the first predetermined connection region are electrically connected by solder,
In a state where the second predetermined terminal is inserted into the second predetermined insertion hole, the second predetermined terminal and the second predetermined connection region are electrically connected by solder,
The first connection region is formed such that an area on a side different from the second insertion hole side is increased with the first insertion hole as a reference,
The second connection region is formed such that the area on the side different from the first insertion hole side is larger with the second insertion hole as a reference ,
The distance between the first connection terminal and the second connection terminal is shorter than the distance between the first predetermined terminal and the second predetermined terminal .

Claims (2)

A launching means for launching a game ball toward a game area based on a launch operation by a player;
A starting pitching portion into which a gaming ball flowing down the gaming area can enter;
Entry detection means for detecting a game sphere that has entered the starting entrance part,
A specific control means having a specific substrate provided with a connection means to which a transmission means for transmitting information of the detection result of the entrance detection means is electrically connected;
With
As the starting pitching portion, at least a first starting pitching portion and a second starting pitching portion are provided,
As said entrance detection means, the 1st entrance detection means which detects the game ball which entered the 1st start entrance part, and the 2nd entrance which detects the game ball which entered the 2nd start entrance part And at least a ball detecting means,
As the transmission means, the first transmission means for transmitting the detection result information of the first entrance detection means, and the second transmission means for transmitting the detection result information of the second entrance detection means,
The connection means includes a first connection means to which the first transmission means is connected, and a second connection means to which the second transmission means is connected,
The first connection means and the second connection means are individually provided for the specific substrate,
The connection terminals provided in the second connection means are two, a first connection terminal and a second connection terminal,
The specific substrate is:
A first insertion hole through which the first connection terminal is inserted;
A second insertion hole through which the second connection terminal is inserted;
A first connection region provided around the first insertion hole;
A second connection region provided around the second insertion hole;
A predetermined insertion hole through which a predetermined terminal of a predetermined mounting component is inserted;
A predetermined connection area provided around the predetermined insertion hole;
With
In a state where the first connection terminal is inserted into the first insertion hole, the first connection terminal and the first connection region are electrically connected by solder,
In a state where the second connection terminal is inserted into the second insertion hole, the second connection terminal and the second connection region are electrically connected by solder,
In a state where the predetermined terminal is inserted into the predetermined insertion hole, the predetermined terminal and the predetermined connection region are electrically connected by solder,
In the game area, the first start ball entering portion is provided at a position where a game ball launched at least when the launch operation according to the first operation mode is performed can be reached,
In the game area, the second start ball entering part is a position where the game ball launched when the launch operation according to the first operation mode is being performed is not reachable or difficult to reach, and the second operation mode Is provided at a position where the game ball launched when the launch operation is performed can be reached,
The specific control means includes
First acquisition means for acquiring special information based on the fact that a game ball is detected by the first entry detection means;
First acquisition information storage means for storing the special information acquired by the first acquisition means;
Second acquisition means for acquiring special information based on the fact that a game ball is detected by the second entry detection means;
Second acquisition information storage means for storing the special information acquired by the second acquisition means;
Grant determination means for performing grant determination as to whether or not the special information stored in the first acquisition information storage means or the second acquisition information storage means corresponds to predetermined grant information;
Privilege granting means for granting a privilege to a player based on the result of the grant determination by the grant determination means being the grant correspondence result that the special information to be judged corresponds to the grant information; ,
Acceptance control capable of switching the second starting entrance part to either a first state in which a game ball is difficult to enter or cannot enter, and a second state in which a game ball is easier to enter. Means,
With
The acceptance control means has a first mode and a second mode that is more likely to be in the second state than the first mode as a control mode of the second starting and entering part,
The special information stored in the second acquisition information storage unit becomes the target of the determination of the grant rather than the case where the special information stored in the first acquisition information storage unit is the target of the determination of grant. Is a configuration in which the privilege that is advantageous to the player is given or is easily given,
The first connection region and the second connection region are formed to have a larger area than the predetermined connection region,
The first connection region is formed such that an area on a side different from the second insertion hole side is increased with the first insertion hole as a reference,
The gaming machine is characterized in that the second connection area is formed so that an area on a side different from the first insertion hole side becomes larger with the second insertion hole as a reference.   The first connection region and the second connection region are longer in the arrangement direction in which the first connection terminals and the second connection terminals are arranged than in the direction orthogonal to the arrangement direction. The gaming machine according to claim 1, wherein the gaming machine is formed to be large.

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