JP6711244B2 - Amusement machine - Google Patents

Description

The present invention relates to a gaming machine.

As gaming machines, pachinko gaming machines and slot machines are known. It is known that these gaming machines perform a lottery using numerical information when a predetermined lottery condition is satisfied, and give a bonus to the player according to the result of the lottery.

For example, in a pachinko gaming machine, when a game ball enters a ball entering portion provided in the game area, numerical information is acquired from updating means for updating numerical information for lottery, and the acquired numerical information is It is determined whether or not it corresponds to the winning information (see, for example, Patent Document 1). In addition, a configuration is known in which numerical information is acquired based on the satisfaction of a predetermined acquisition condition, and specific performance and notification are performed based on the result of a lottery performed using the numerical information.

JP, 2009-261415, A

Here, novel game contents are required in the game machines as illustrated above, and there is still room for improvement in this respect.

The present invention has been made in view of the above-exemplified circumstances, and an object thereof is to provide a gaming machine capable of providing novel game contents.

In order to solve the above problems, the invention according to claim 1 is a profit giving means for giving advantageous profit to a player on the condition that a game ball has entered the ball entering portion, at least one condition ,
And guide means for guiding the game ball toward the ball entrance portion,
The guidance timing of the game ball guided by the guiding means at a predetermined time interval in the ball entrance portion is the grant timing when the game ball guided to the ball entrance portion becomes the trigger for granting the profit. Predetermined situation generating means for producing a predetermined situation to be dealt with,
It is characterized by having.

According to the present invention, it is possible to provide a novel game content.

It is a perspective view showing a pachinko machine in the first embodiment. It is a perspective view which decomposes|disassembles and shows the main structures of a pachinko machine. It is a front view showing a configuration of a game board. It is a front view of the game board which expands and shows the periphery of an adjustment mechanism. (A) It is a front view and a right side view of a rotary body separated from an adjustment mechanism, and (b) is a front view and a plan view of the rotary body. It is a transverse cross-sectional view of the window panel and the game board in the case where the upper surface of the inlet is cut by a plane perpendicular to the front surface of the game board. (A), (b) It is a front view of the adjustment mechanism shown in order to demonstrate the movement of the game ball taken in by the adjustment mechanism. (A), (b) It is a front view of the adjustment mechanism shown in order to explain the movement of the game ball discharged from the adjustment mechanism and winning the first through gate. It is a front view of the adjustment mechanism which shows the movement of the game ball discharged from the adjustment mechanism and removed from the first through gate. (A) It is a cross-sectional view of the window panel and the game board in the case where the upper surface of the game board is cut right above the intake port, and (b) In the case where the game board is cut in the plane perpendicular to the surface of the game board. It is a longitudinal cross-sectional view of the first blade portion, (c) is a horizontal cross-sectional view of the window panel and the game board in the case where a portion directly above the intake port is cut by a plane perpendicular to the surface of the game board. It is explanatory drawing for demonstrating the structure regarding the discharge of the game ball which flowed down the game area. It is a block diagram which shows the electric constitution of a pachinko machine. It is an explanatory view for explaining the contents of various counters used for win/win lottery. (A) It is a low-frequency winning determination value table showing the winning determination value for the regular electric lottery in the low frequency support mode, and (b) High frequency showing the winning determination value for the regular electric lottery in the high frequency support mode. It is a winning determination value table. (A) ~ (c) is a time chart showing the timing at which the universal electric open win can occur in the comparative pachinko machine. It is a time chart which shows the timing when (a)-(d) universal electric open winning may occur. It is a flow chart which shows the main processing performed by the main side CPU. It is a flowchart which shows the timer interruption process performed by the main side CPU. It is a flowchart which shows the open counter update process performed by the main side CPU. It is a flowchart which shows the universal figure universal communication control processing performed by the main side CPU. It is a flow chart which shows reservation information acquisition processing by the side of a universal figure performed by main side CPU. It is a flowchart which shows the universal figure fluctuation|variation start process performed by the main side CPU. It is a flowchart which shows the normal electric open lottery process performed by the main side CPU. It is a flow chart which shows processing during finalization of a universal figure performed by a master side CPU. It is explanatory drawing for demonstrating the structure which makes the detection result of a ball detection sensor input into a main side CPU. It is a flow chart which shows a ball detection processing performed by a main side CPU. It is a block diagram for explaining an electric configuration of a payout control device and various devices that communicate with the payout control device. It is a flow chart which shows timer interruption processing performed by a payment side CPU. It is a block diagram for explaining an electrical configuration of a management IC. It is an explanatory view for explaining the composition of the input port of the management side I/F. It is an explanatory view for explaining the composition of the memory for correspondence. It is an explanatory view for explaining the composition of a history memory. It is a flowchart which shows the process for recognition performed by the main side CPU. It is a flow chart which shows the management processing performed by the management side CPU. (A) ~ (d) is a time chart showing a state in which information on the correspondence between the first to fifteenth buffers and the types of signals is stored in the correspondence memory. It is a flow chart which shows management output processing performed by the master side CPU. It is a flow chart which shows history setting processing performed by a management side CPU. 8A to 8E are time charts showing how history information is stored in the history memory. 7 is a flowchart showing a data output process executed by the main CPU. 7 is a flowchart showing an external output process executed by the management-side CPU. It is a front view of the game board which expands and shows the periphery of the adjustment mechanism in 2nd Embodiment. (A) It is a top view of the housing which cuts and shows right above an adjustment mechanism, (b) It is a front view of the housing which expands and shows the circumference of a rotating shaft. It is a front view of the rotating body separated from the adjusting mechanism. (A) It is a transverse cross-sectional view of the window panel and the game board in the case where the distribution nail is cut right above the plane of the game board, and (b) the first through gate is discharged from the adjusting mechanism. It is a front view of an adjusting mechanism shown for explaining the movement of the game ball, and (c) a cross section of the window panel and the game board when the cut is performed just above the sorting nail with a plane perpendicular to the surface of the game board. It is a figure and (d) is a front view of the adjustment mechanism shown in order to explain the movement of the game ball discharged from the adjustment mechanism and coming off the first through gate. (A)-(d) It is a front view of the adjustment mechanism shown in order to demonstrate the movement of the game ball taken in and conveyed by the adjustment mechanism. (A) ~ (c) is a front view of an adjustment mechanism shown for explaining the movement of the game ball near the intake. It is a front view of the game board which expands and shows the periphery of the adjustment mechanism in 3rd Embodiment. (A) It is a front view of the game board which expands and shows the periphery of the electric nail in the permission position, and (b) is a front view of the game board which expands and shows the periphery of the electric nail in the prohibition position. (A) ~ (c) is a front view of the adjusting mechanism shown for explaining the movement of the game ball around the adjusting mechanism. (A) ~ (c) is a front view of the adjustment mechanism shown for explaining how the game ball is eliminated from the upper part of the adjustment mechanism. It is a front view of the game board which expands and shows the periphery of the adjustment mechanism in 4th Embodiment. It is a longitudinal cross-sectional view when the rotating body is cut along a plane perpendicular to the surface of the game board. (A) ~ (d) is a front view of the adjusting mechanism shown for explaining the movement of the game ball discharged from the adjusting mechanism and winning the first through gate. (A), (b) It is a front view of the adjustment mechanism shown in order to explain the movement of the game ball discharged from the adjustment mechanism and removed from the first through gate. It is a front view of the game board which expands and shows the periphery of the adjustment mechanism in 5th Embodiment. (A) It is a front view of the adjusting device in a closed state, (b) It is a front view of the adjusting device in an open state. (A) ~ (d) is a front view of the adjusting mechanism shown for explaining the movement of the game ball around the adjusting mechanism. It is a front view of the game board in a sixth embodiment. (A), (b) It is the schematic which shows the structure of a 2nd working opening. (A) It is a vertical cross-sectional view of the distribution winning apparatus as viewed from the side, and (b) is a vertical cross-sectional view of the distribution winning apparatus as viewed from the back side. It is a front view of the game board which expands and shows the periphery of the adjustment mechanism in 7th Embodiment. It is explanatory drawing for demonstrating the structure of the input port of the management side I/F in 8th Embodiment. It is a flowchart which shows the process for recognition performed by the main side CPU. It is a flow chart which shows the management processing performed by the management side CPU. (A) ~ (h) is a time chart showing a state in which information on the correspondence between the first to twelfth buffers and the types of signals is stored in the correspondence memory. It is a block diagram for demonstrating the electric constitution of the management IC in 9th Embodiment. It is an explanatory view for explaining the composition of the input port of the management side I/F. It is a flow chart which shows blackout information storage processing performed by the main side CPU. It is a flowchart which shows the power failure response process performed by the management side CPU. 7 is a flowchart showing an external output process executed by the management-side CPU. It is a flowchart which shows the power failure response process performed by the management side CPU in 10th Embodiment. (A) It is a flowchart which shows the trigger specific process performed by the main side CPU in 11th Embodiment, and (b) is a flowchart which shows the arithmetic process performed by the management side CPU. It is a flowchart which shows the trigger specific process performed by the main side CPU in 12th Embodiment. It is a flowchart which shows the arithmetic processing performed by the management side CPU in 13th Embodiment. It is a flow chart which shows the history setting processing performed by the management side CPU in a 14th embodiment. It is explanatory drawing for demonstrating the structure of the memory for history records in 15th Embodiment. It is a flow chart which shows history setting processing performed by a management side CPU. It is a block diagram for demonstrating the electric constitution of MPU of the main controller in 16th Embodiment. It is a flow chart which shows a ball detection processing performed by a main side CPU. It is a block diagram for explaining the electric composition of the main control unit in a 17th embodiment. It is an explanatory view for explaining the composition of the input port of the management side I/F. It is an explanatory view for explaining the composition of a history memory. It is a flow chart which shows history setting processing performed by a management side CPU. 7 is a flowchart showing an external output process executed by the management-side CPU. It is a flowchart which shows the parameter management process performed by the main side CPU. It is a block diagram for demonstrating the structure of the signal path which transmits the detection result of each ball detection sensor in 18th Embodiment to the main side CPU and management IC.

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

As shown in FIG. 1, the pachinko machine 10 includes an outer frame 11 forming an outer shell of the pachinko machine 10 and a gaming machine body 12 rotatably attached to the outer frame 11 in a forward direction. Have. The outer frame 11 is formed by connecting wooden plate members to four sides and has a rectangular frame shape. The pachinko machine 10 is installed in the game hall by fixing the outer frame 11 to the island facility. The outer frame 11 is not an essential component of the pachinko machine 10, and the island facility of the game hall may be equipped with the outer frame 11.

As shown in FIG. 2, the gaming machine body 12 includes an inner frame 13, a front door frame 14 arranged in front of the inner frame 13, and a back pack unit 15 arranged behind the inner frame 13. ing. The inner frame 13 of the gaming machine body 12 is rotatably supported by the outer frame 11. Specifically, the inner frame 13 is rotatable forward when the left side is the rotation base end side and the right side is the rotation front end side when viewed from the front.

A front door frame 14 is rotatably supported by the inner frame 13, and can be turned 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. A back pack unit 15 is rotatably supported by the inner frame 13, and is rotatable rearward with the left side being the rotation base end side and the right side being the rotation tip side in front view.

In addition, the gaming machine main body 12 is provided with a locking device at its rotating front end portion, and has a function of locking the gaming machine main body 12 with respect to the outer frame 11 in a locked state, and It has a function of locking the door frame 14 against the inner frame 13 so that the door frame 14 cannot be opened. Each of these locked states is released by performing an unlocking operation on the cylinder lock 17 exposed on the front surface of the pachinko machine 10 using an unlocking key.

Next, the configuration on 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 in 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.

As shown in FIG. 2, the front door frame 14 is provided so as to cover the entire front surface 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 that allows almost the entire game area PA to be viewed from the front. The window 51 has a substantially elliptical shape, and the window panel 52 is fitted therein. The window panel 52 is made of glass and is colorless and transparent. However, the window panel 52 is not limited to this and may be made of synthetic resin and is colorless and transparent, and the game area PA is provided from the front of the pachinko machine 10 through the window panel 52. If it is visible, it may be formed to be colored and transparent.

Here, the configuration of the game board 24 will be described with reference to FIG. FIG. 3 is a front view of the game board 24. As shown in FIG. 3, the game board 24 is formed with a plurality of large and small openings penetrating in the front-rear direction. In each opening, a general winning opening 31, a special electricity winning device 32, a first operating opening 33, a second operating opening 34, a first through gate 35, a second through gate 39, a variable display unit 36, a special drawing unit 37, and a universal drawing. Each of the drawing units 38 and the like is provided. A total of four general winning openings 31 are provided, and one is provided for each other.

The variable display unit 36 is provided with a symbol display device 41 that variably displays (or variably or switches) the symbols. The symbol display device 41 is provided with a display surface 41a for displaying effects, and is arranged in an opening 24c provided in the game board 24 to make the display surface 41a visible from the front of the pachinko machine 10. There is. Further, the variable display unit 36 is provided with a center frame 57 so as to surround the symbol display device 41. The upper portion of the center frame 57 extends forward of the pachinko machine 10. As a result, the game sphere is prevented from falling in front of the display surface 41a of the symbol display device 41, and there is no inconvenience that the visibility of the display screen is lowered due to the fall of the game sphere B1. ing.

Further, as shown in FIG. 3, the center frame 57 includes a roof unit 58 provided so as to define the upper edge and the left and right side edges of the opening 24c. The game board 24 has game areas PA on both the left and right sides of the center frame 57.

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, and the game ball is formed by the inner rail portion 25 and the outer rail portion 26. A guide rail for guiding B1 is configured. The game ball B1 launched from the game ball launching mechanism 27 (see FIG. 2) mounted below the window 23 in the resin base 21 is guided by the guide rail to the upper part of the game area PA.

Here, as shown in FIG. 2, the game ball launching mechanism 27 supplies a launch rail 27a extending toward the guide rail and a game ball B1 stored in a later-described upper plate 55a onto the launch rail 27a. It is provided with a feeding device 27b and a solenoid 27c which is an electric actuator for firing the game ball B1 supplied on the firing rail 27a toward the guide rail. When the firing operation device (or operation handle) 28 provided on the front door frame 14 is rotationally operated, the solenoid 27c is drive-controlled, and the game ball B1 is fired. By adjusting the turning amount in the turning operation, the player can aim the game area B1 on the left side of the center frame 57 to shoot the game ball B1 and also aim the game area PA on the right side of the center frame 57. The game ball B1 can be fired.

As shown in FIG. 3, even if a ball enters the first through gate 35 and the second through gate 39, the payout of the game ball B1 is not executed. On the other hand, when a ball enters the general winning opening 31, the special electric winning device 32, the first operating opening 33 and the second operating opening 34, a predetermined number of game balls B1 are paid out. Regarding the number of prize balls, specifically, when one game ball B1 enters the first operation port 33 or one game ball B1 enters the second operation port 34. In this case, one prize ball is paid out, and when one game ball B1 is thrown into the general winning opening 31, ten prize balls are paid out and the special electric prize is won. When one game ball B1 enters the device 32, 15 prize balls are paid out.

The number of prize balls is arbitrary, and for example, the number of prize balls may be smaller in the second operating port 34 than in the first operating port 33, and the second operating port 34 may be the first operating 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 the game ball B1 that has not entered various winning ports or the like is discharged from the game area PA through the out port 24a. Further, on the game board 24, a large number of nails 24b are planted in order to appropriately disperse and adjust the falling direction of the game ball B1, and various members such as a wind turbine are provided.

Here, the entry ball means that the game ball B1 passes through a predetermined opening, and not only the aspect in which it is discharged from the game area PA after passing through the opening, but also the game area PA after passing through the opening. A mode in which the game area PA continues to flow down without being discharged from the game area is also included. However, in the following description, in order to be clearly distinguished from the game ball B1 entering the outlet 24a, the general winning opening 31, the special electricity winning device 32, the first operating opening 33, the second operating opening 34, the first The entry of the game ball B1 into the through gate 35 and the second through gate 39 is also expressed as a prize.

As shown in FIG. 3, the first operating port 33 and the second operating port 34 are unitized as an operating port device and installed on the game board 24. Both the first operating port 33 and the second operating port 34 are open upward. Further, both the operation ports 33, 34 are arranged in the vertical direction so that the first operation port 33 faces upward. The second actuating port 34 is provided with a general electric accessory 34a as a guide piece composed of a pair of left and right movable pieces. The gaming ball B1 cannot win the second operating port 34 in the closed state of the universal electric object 34a, and the winning in the second operating port 34 becomes possible when the universal electric object 34a is in the open state.

As shown in FIG. 3, in the game area PA on the left side of the center frame 57, a first through gate 35 is provided on the upstream side of the game ball B1 in the downstream direction of the second operation port 34. The first through gate 35 has a through hole (not shown) penetrating in the vertical direction, and the game ball B1 that has won the first through gate 35 flows down in the game area PA after winning. Therefore, the game ball B1 that has won the first through gate 35 reaches the area where the first operating port 33 and the second operating port 34 are provided, and the first operating port 33 and the second operating port 34 It is possible to win one.

Further, as shown in FIG. 3, in the game area PA on the right side of the center frame 57, a second through gate 39 is provided on the upstream side of the second operation port 34 in the downflow direction of the game ball B1. .. The second through gate 39 has a through hole (not shown) penetrating in the vertical direction, and the game ball B1 that has won the second through gate 39 flows down in the game area PA after winning. Therefore, the game ball B1 that has won the second through gate 39 reaches the area where the first operating port 33 and the second operating port 34 are provided, and the first operating port 33 and the second operating port 34 It is possible to win one.

Based on the winning of the through-gates 35, 39, the universal electric accessory 34a of the second operating port 34 is switched from the closed state to the open state. Specifically, the winning prize to the through gates 35 and 39 is used as a trigger to perform the ordinary electric open lottery, which is a lottery, and is provided in the lower left corner of the game area PA where the game ball B1 does not pass. The variable display of the picture is performed on the public figure display portion 38a of the drawing unit 38. Then, when the result of the ordinary electric open lottery is the ordinary electric open winning, the stop result corresponding to the result is displayed and the variable display of the universal figure display portion 38a is ended, the ordinary electric open state is entered. In the general electric open state, the general electric accessory 34a is opened in a predetermined manner.

In the pachinko machine 10 of the present embodiment, the low frequency support mode in which the winning of the second working port 34 is supported by intermittently opening the universal electric accessory 34a when the through gates 35 and 39 are won. Then, the high frequency support mode in which the ordinary electric utility product 34a is in the open state in a mode that makes it easier to win the game ball B1 into the second operation port 34 than in the low frequency support mode is set.

In the pachinko machine 10, in the low frequency support mode in which the transition to the high frequency support mode is not performed, the player can aim at the left side game area PA where the first through gate 35 is provided. Done. Then, when the mode is shifted to the high frequency support mode, an effect of causing the player to aim at the game area PA on the right side where the second through gate 39 is provided is performed. Details of the low frequency support mode and the high frequency support mode will be described later.

The general-purpose display section 38a is composed of a segment display in which a plurality of segment light emitting sections are arranged in a predetermined manner, but not limited to this, a liquid crystal display device, an organic EL display device. , A CRT, a dot matrix display, or other type of display device. Further, as the pattern variably displayed on the public figure 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 types of colors are switched and displayed can be considered.

In the universal figure unit 38, a universal figure hold display section 38b is provided at a position adjacent to the universal figure display section 38a. The number of game balls B1 won in the through gates 35, 39 is reserved up to 4, and the reserved number is displayed by turning on the universal figure reservation display portion 38b.

A winning lottery is carried out with the winning of the first working opening 33 or the second working opening 34 as a trigger. Then, the lottery result is clearly shown through the display effect on the symbol display device 41 of the special drawing unit 37 and the variable display unit 36.

More specifically, the special drawing unit 37 is provided with a special drawing display portion 37a. The display area of the special figure display portion 37a is narrower than the display surface 41a of the symbol display device 41. In the special figure display unit 37a, a winning or lottery is performed with the winning of the first operating opening 33 or the winning of the second operating opening 34 as a trigger, whereby a variable display or a predetermined display of the pattern is performed. Then, the result corresponding to the lottery result is displayed. The special figure display unit 37a is composed of a segment display in which a plurality of segment light emitting units are arranged in a predetermined manner, but the invention is not limited to this, and the liquid crystal display device and the organic EL display device are not limited thereto. , A CRT, a dot matrix display, or other type of display device. As the picture displayed on the special figure display unit 37a, a plurality of types of characters are displayed, a plurality of types of symbols are displayed, a plurality of types of characters are displayed, or a plurality of types of colors are displayed. A configuration in which is displayed is considered.

In the special figure unit 37, a special figure reservation display section 37b is provided at a position adjacent to the special figure display section 37a. The maximum number of game balls B1 won in the first operating opening 33 or the second operating opening 34 is reserved, and the reserved number is displayed by turning on the special figure pending display portion 37b.

In detail about the symbol display device 41, 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 the 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 device. May be.

In the symbol display device 41, when the variable display or the predetermined display of the symbol is performed on the special symbol display portion 37a based on the winning of the first operating port 33 or the winning of 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 columns of upper, middle and lower tiers are set as a plurality of display areas, and each of the symbol columns is numbered "1" to "9". The symbols are scroll-displayed with the symbols arranged in ascending or descending order. In this scroll display, the scroll display in all the symbol rows is started first, and the scroll display is switched from the scroll display to the standby display in the order of the upper symbol row → the lower symbol row → the middle symbol row, and finally in each symbol row It ends with the pattern still displayed. Then, for example, in a game game in which the game result is a big hit result, a predetermined combination of symbols is stopped and displayed on the preset effective line on the display surface 41a of the symbol display device 41.

In addition, in the symbol display device 41, not only the display effect triggered by the winning of the first operation opening 33 or the second operation opening 34, but also the display effect in the opening/closing execution mode which is shifted after the winning is achieved. Be seen. In addition, based on the winning of any one of the operation ports 33, 34, the display is started on the special figure display portion 37a and the symbol display device 41, and a predetermined result is displayed and ended until one of the game times. Equivalent to times. Further, the manner of variable display of the symbols in the symbol display device 41 is not limited to the above, but is arbitrary, and the number of symbol columns, the direction of variable display of symbols in the symbol column, the number of symbols in each symbol column, etc. Can be changed as appropriate. Further, the picture variably displayed on the picture display device 41 is not limited to the above-mentioned picture, and for example, only numbers may be variably displayed as the picture.

When a big hit is won in the winning lottery based on the winning of the first working opening 33 or the winning of the second working opening 34, the opening/closing execution mode in which the special electric winning device 32 can be won is performed. The special electric prize winning device 32 includes a big winning opening (not shown) leading to the back side of the game board 24, and an opening/closing door 32a for opening and closing the big winning opening. The open/close door 32a is arranged in either a closed state or an open state. Specifically, the opening/closing door 32a is normally in a closed state in which the game ball B1 cannot win, and when the game is transferred to the open/close execution mode in the lottery, the game ball B1 is switched to an open state in which it can win. It is like this. By the way, the opening/closing execution mode is a mode to be shifted when a winning result is obtained. It should be noted that in the closed state, the winning is not impossible, but the winning state may be less likely to occur than in the open state.

As shown in FIG. 3, an adjusting mechanism 180 that adjusts the timing at which the game ball B1 is supplied toward the first through gate 35 is provided above the first through gate 35. The adjusting mechanism 180 supplies the game ball B1 to the first through gate 35 by ejecting the game ball B1 toward the lower first through gate 35. The distance between the adjusting mechanism 180 and the first through gate 35 is the distance at which the game ball B1 discharged from the adjusting mechanism 180 reaches the first through gate 35 after flowing down a distance equal to or larger than the diameter of the game ball B1. .. The adjusting mechanism 180 will be described below.

FIG. 4 is a front view of the game board 24 showing the first through gate 35 and the configuration above the first through gate 35 in an enlarged manner. As shown in FIG. 4, the adjusting mechanism 180 takes in the game ball B1 at the upper part of the adjusting mechanism 180 and conveys it to the lower part of the adjusting mechanism 180, and an adjusting drive for rotating the rotating body 183 clockwise. A portion 184 and a storage portion 181 that stores the rotating body 183 and that prevents the game ball B1 taken into the rotating body 183 by the centrifugal force associated with the rotation from being thrown out before the discharge position.

As shown in FIG. 4, the rotating body 183 is provided at the center of the adjusting mechanism 180. The rotating body 183 is formed by providing four recessed portions 183b to 183e capable of taking in the game ball B1 to a substantially disk-shaped transparent resin member whose diameter is reduced toward the rear. ing. 5A is a front view and a right side view of the rotating body 183, and FIG. 5B is a front view and a plan view of the rotating body 183. As shown in FIG. 5A, the recesses 183b to 183e of the rotating body 183 are formed so as to be recessed from the outer edge portion of the rotating body 183 toward the axis. The recesses 183b to 183e are arranged such that the centers thereof are arranged at equal intervals in the circumferential direction, and the first recess 183b→the second recess 183c→the third recess 183d→the fourth recess 183e are arranged in the order of rotation. Is formed.

As shown in FIG. 5A, none of the recesses 183b to 183e reach the position of the axis of the rotating body 183, and they are discontinuous with each other. Each of the recessed portions 183b to 183e has a shape and a size that allow the whole one game ball B1 to enter. In each of the recesses 183b to 183e, the inner wall near the outer edge of the rotating body 183 has an inclination that the recesses 183b to 183e widen toward the outer edge, and the width of each of the recesses 183b to 183e near the outer edge is equal. It is set wider than the diameter of the game ball B1.

As shown in FIG. 5A, the rotating body 183 has a first blade portion 188 sandwiched between a fourth recess 183e and a first recess 183b, a first recess 183b and a second recess 183c. The second blade portion 189 sandwiched between and, the third blade portion 190 sandwiched between the second recessed portion 183c and the third recessed portion 183d, and the third blade portion 183d and the fourth recessed portion 183e. And a fourth blade portion 191.

As shown in FIG. 4, in the adjusting mechanism 180, the accommodating portion 181 accommodating the rotating body 183 is arranged such that the game ball B1 taken into each of the recessed portions 183b to 183e of the rotating body 183 is conveyed from the front surface of the game board 24. Also includes a base body 181a that prevents the rearward movement. The base body 181a includes a fixing flange 181b that is formed by protruding radially from the outer periphery of the base body 181a.

FIG. 6 is a cross-sectional view of the window panel 52 and the game board 24 in the case where a plane perpendicular to the front surface of the game board 24 is cut right above the inlet 185. In order to explain the configuration of the housing portion 181, FIG. 6 shows a state in which the rotating body 183 is removed. As shown in FIG. 6, on the front surface of the game board 24, a fixing recess portion 24d capable of accommodating the base body 181a and the fixing flange 181b is formed. As shown in FIG. 4, the accommodating portion 181 has the base body 181a and the fixing flange 181b accommodated in the fixing recessed portion 24d (FIG. 6), and the fixing flange 181b is screwed to the game board 24. It is fixed to. The base body 181a is located behind the rotary body 183, and the front surface of the base body 181a is flush with the front surface of the game board 24.

As shown in FIG. 4, a housing space for housing the rotating body 183 is formed in front of the base body 181a, and the rotating body 183 is housed in the housing space. An adjustment drive unit 184 is arranged behind the rotating body 183. The adjustment drive unit 184 includes an output shaft 184a extending from the front surface of the adjustment drive unit 184 toward the front in a manner orthogonal to the front surface of the game board 24. The rotating body 183 is connected to the output shaft 184a such that the axis of the rotating body 183 is located on the same straight line as the output shaft 184a of the adjustment drive unit 184.

The adjustment drive unit 184 is connected to the output port of the MPU 62 (see FIG. 12) described later. When the drive signal is supplied and the adjustment drive unit 184 enters the drive state, the rotating body 183 rotates clockwise at an angular velocity of 90° for 1 second. A stepping motor is used as the adjustment drive unit 184, and specifically, 1-2 phase excitation drive that alternately performs 1-phase excitation and 2-phase excitation is adopted. Note that the phase excitation method is not limited to this, and another phase excitation method may be adopted. The adjustment drive unit 184 has a configuration in which the output shaft makes one round by transmitting an excitation signal for 500 pulses from the main control device 60, and an angle change based on the excitation signal of one pulse, that is, an angle change per step It is 0.72°.

As shown in FIG. 4, the housing portion 181 includes standing walls 181c and 181d for partitioning the housing space. The accommodation space is partitioned by the upright walls 181c and 181d to be slightly larger than the rotating body 183. The distance from the center of the rotating body 183 to the standing walls 181c and 181d of the housing portion 181 is longer than the distance from the center of the rotating body 183 to the peripheral surfaces 188a to 191a of the blade portions 188 to 191. The difference is shorter than the radius of the game ball B1. Therefore, the possibility that the game ball B1 may enter between the peripheral surfaces 188a to 191a of the blades 188 to 191 and the standing walls 181c and 181d is eliminated.

The standing walls 181c and 181d are formed in a plurality so as to be spaced from each other in the circumferential direction of the base body 181a so as to project forward from the front surface of the base body 181a. Among the plurality of standing walls 181c, 181d, the left standing wall 181c existing on the left side and the right standing wall 181d existing on the right side are laterally separated from each other, so that the upper part of the accommodation portion 181 is provided. An intake port 185 exists.

As shown in FIG. 4, the shape and size of the intake port 185 is such that one game ball B1 can pass through the intake port 185 and a plurality of game balls B1 are simultaneously taken in. It is set so that it is impossible to pass through the mouth 185. Therefore, the adjusting mechanism 180 can take in the game balls B1 one by one from the take-in port 185.

The left standing wall 181c prevents the game ball B1 flowing down from the upper left of the intake port 185 from entering the inside of the adjusting mechanism 180. Therefore, the game ball B1 is taken into the recesses 183b to 183e that are open toward the left, and the game ball B1 is discharged after being conveyed for a long time in the order of the upper part of the adjustment mechanism 180→the right part→the lower part. There is no such thing. In addition, the right standing wall 181d is located outside the adjusting mechanism 180 by the centrifugal force of the rotating body 183 before the game ball B1 taken into the adjusting mechanism 180 is conveyed to the lower portion of the adjusting mechanism 180 and the discharge timing is reached. Prevent being thrown into.

As shown in FIG. 4, the left standing wall 181c and the right standing wall 181d are laterally separated from each other, so that the housing portion 181 is opened downward. Therefore, the game ball B1 taken into any of the recesses 183b to 183e of the rotating body 183 and conveyed to the lower part of the adjusting mechanism 180 is discharged toward the first through gate 35 located below.

As shown in FIG. 4, the accommodating portion 181 includes a discharging protrusion 181e for discharging the game ball B1 taken into the recesses 183b to 183e of the rotating body 183 at a predetermined discharging position. The ejection protrusion 181e is provided in the lower vicinity of the center of the base body 181a. As shown in FIG. 6, the ejection protrusion 181e protrudes from the front surface of the base body 181a toward the front to a middle position in the game area PA so that the protrusion dimension is 9 mm.

As described above, the length dimension in the front-back direction of the game area PA (FIG. 3) sandwiched between the front surface of the game board 24 and the back surface of the window panel 52 (FIG. 1) is 18 mm and the game ball B1. Has a diameter of 11 mm. Therefore, the ejection protrusion 181e is a game ball B1 located on the back side (game board 24 side) of the game area PA, and a game ball B1 located on the front side (window panel 52 side) of the game area PA, Has a length dimension in the front-rear direction capable of contacting both. Further, as shown in FIG. 4, the discharge protrusion 181e is formed to extend downward from the lower vicinity of the center of the base body 181a.

As shown in FIG. 4, the distance from the center of the rotating body 183 to the lower end of the ejection protrusion 181e is from the center of the rotating body 183 to the peripheral surfaces 188a to 191a of the blade portions 188 to 191 (FIG. 5A). Shorter than the distance. As shown in FIG. 5A, the first blade portion 188 and the third blade portion 190 of the rotating body 183 are provided with a collision avoidance groove 192 for avoiding a collision with the ejection protrusion 181e. In addition, as shown in FIG. 5B, the second blade portion 189 and the fourth blade portion 191 are also provided with a collision avoidance groove 192 for avoiding a collision with the ejection protrusion 181e.

The collision avoidance groove 192 is provided so as to be larger than the projecting size of the ejection projection 181e, and does not come into contact with the rotating body 183 regardless of the rotation state of the ejection projection 181e. Therefore, the ejection protrusion 181e does not hinder the rotation of the rotating body 183.

As shown in FIG. 4, the discharge protrusion 181e includes a discharge right side surface 181g that is inclined downward to the left as a right side surface. The right side surface 181g for discharge comes into contact with the game ball B1 existing in the recessed portions 183b to 183e of the rotating body 183 at the discharge position of the game ball B1 taken into the adjustment mechanism 180. The game ball B1 is conveyed to the lower part of the adjusting mechanism 180 by the rotation of the rotating body 183, and then discharged toward the lower first through gate 35 upon contact with the discharge right side surface 181g.

When the game ball B1 is discharged downward from the adjusting mechanism 180, the game ball B1 wins the first through gate 35 located below without colliding with an obstacle on the way. As described above, the game ball B1 discharged from the adjusting mechanism 180 reaches the first through gate 35 after flowing down a distance equal to or larger than the diameter of the game ball B1. Specifically, the game ball B1 discharged from the discharge position reaches the first through gate 35 after flowing down a distance approximately 1.5 times the diameter of the game ball B1. Since the distance from the discharge position to the first through gate 35 is equal to or larger than the diameter of the game ball B1, the discharged game ball B1 from the first through gate 35 depends on the discharge direction and the discharge speed of the game ball B1 at the discharge position. There is a possibility of coming off. The ejection position of the game ball B1 in the adjustment mechanism 180 is fixed by the ejection protrusion 181e, and the distance from the ejection position to the first through gate 35 is short. Therefore, when the discharged game ball B1 wins the first through gate 35, the game ball B1 is discharged from the adjusting mechanism 180 until the game ball B1 wins the first through gate 35. The time falls within a predetermined range.

In the adjusting mechanism 180, the discharge timing of the game ball B1 is generated in a cycle of 1 sec, so that the winning of the game ball B1 to the first through gate 35 is also generated in a cycle of approximately 1 sec. Details of the flow of discharging the game ball B1 from the adjusting mechanism 180 will be described later.

The rotating body 183 rotates clockwise while the game ball B1 taken in from the intake port 185 is present in the recesses 183b to 183e, so that the game ball B1 is directed toward the lower part of the adjusting mechanism 180. Transport.

The adjusting mechanism 180 can take in the game ball B1 flowing down from above when any of the recessed portions 183b to 183e of the rotating body 183 is open upward. The adjusting mechanism 180 can take in the game ball B1 at the take-in port 185 by configuring the inner walls of the recesses 183b to 183e near the outer edge of the rotating body 183 to have a shape that widens toward the outer edge. You can extend the period. This makes it possible to increase the number of game balls B1 taken into the adjustment mechanism 180 and increase the number of game balls B1 discharged from the adjustment mechanism 180.

Further, by providing the rotary body 183 with a plurality of recesses 183b to 183e, it is possible to reduce the rotational speed of the rotary body 183 necessary for discharging the game ball B1 from the adjusting mechanism 180 in a cycle of 1 sec. You can Thus, by slowly rotating the rotating body 183, it is possible to increase the probability that the game ball B1 flowing down to the upper part of the adjusting mechanism 180 is taken into the recessed portions 183b to 183e of the rotating body 183.

Here, the configuration around the adjusting mechanism 180 in the game board 24 will be described. As shown in FIG. 4, a plurality of nails 24b are provided above the intake port 185 in order to collect the game balls B1 flowing down the game area PA upstream of the intake port 185 toward the intake port 185. It is arranged. In the upper left area of the intake port 185, a plurality of nails 24b for changing the course of the game ball B1 flowing down the area to the right and directing the game ball B1 toward the intake port 185 are arranged. In the upper right area of the intake port 185, a plurality of nails 24b for changing the course of the game ball B1 flowing down the area to the left and directing the game ball B1 toward the intake port 185 are arranged.

As shown in FIG. 4, the plurality of nails 24b arranged near the upper portion of the intake port 185 have a distance from the nail 24b to the left standing wall 181c and a distance from the nail 24b to the right standing wall 181d. It is provided to be longer than the diameter of the game ball B1 by one turn or more. Further, on the left side and the right side of the adjusting mechanism 180, there are provided spaces for letting down the game ball B1 which has flown toward the intake port 185 and has not been captured by the intake port 185, to the downstream side. The nail 24b is not arranged in the space. Therefore, the game ball B1 that has flowed near the intake port 185 and has not been captured by the adjustment mechanism 180 is adjusted between the nail 24b and the left standing wall 181c or between the nail 24b and the right standing wall 181d. It can be discharged to the left and right spaces of the mechanism 180. This can prevent the game ball B1 from staying around the intake port 185.

Next, a detailed configuration of the adjusting mechanism 180 will be described. First, a configuration for taking in the game ball B1 will be described.

As described above, the diameter of the game ball B1 is 11 mm, and the length of the game area PA (FIG. 3) in the front-rear direction is 18 mm, which is larger than the diameter of the game ball B1. Thus, the game area PA has a gap that allows the game ball B1 flowing down the game area PA to move in the front-rear direction.

As shown in FIG. 5, each of the recessed portions 183b to 183e of the rotating body 183 is inclined toward the front toward the axial center. Therefore, when the recesses 183b to 183e of the rotating body 183 are in a rotating state in which the recesses 183b to 183e are open upward, the recesses 183b to 183e are inclined downward toward the front. Become. For example, as shown in FIG. 4, when the first recess 183b is opened upward, the first recess 183b is inclined downward toward the front.

The game ball B1 taken into the adjusting mechanism 180 from the taking-in port 185 is set in one of the recesses 183b to 183e which is open upward at the upper part of the adjusting mechanism 180. As described above, the recesses 183b to 183e that are open upward at the upper portion of the adjustment mechanism 180 are in a state of being inclined downward toward the front. Therefore, while the game ball B1 is conveyed toward the lower part of the adjusting mechanism 180 by the rotation of the rotating body 183, the game ball B1 is located on the front side (the window panel 52 side) in the game area PA having a thickness in the front-rear direction. To do.

Next, the timing when the adjusting mechanism 180 takes in the game ball B1 will be described. As shown in FIG. 4, the intake port 185 is open upward. When the state in which any of the recessed portions 183b to 183e of the rotating body 183 is located below the intake port 185 is set to the intake permission state, in the intake permission state, the inside of the adjustment mechanism 180 from the intake port 185. The game ball B1 that has entered can be accommodated in the recesses 183b to 183e.

On the other hand, when the rotating body 183 rotates from the state of FIG. 4 and one of the blade portions 188 to 191 of the rotating body 183 is located below the intake port 185, the intake is prohibited. In the prohibited state, the game ball B1 attempting to enter the inside of the adjusting mechanism 180 from the intake port 185 collides with the peripheral surfaces 188a to 191a of the blade portions 188 to 191. In this case, the game ball B1 is not taken inside the adjusting mechanism 180.

At the intake port 185 of the adjusting mechanism 180, there are both a take-in permission state in which the game ball B1 can be taken in and a take-in prohibition state in which the game ball B1 cannot be taken in with the rotation of the rotating body 183. Repeated alternately.

First, the case where the intake port 185 is in the intake permission state will be described. 7A and 7B are front views of the game board 24 showing the vicinity of the adjusting mechanism 180 in an enlarged manner. The rotating body 183 of FIG. 7A is in a rotating state in which the first recessed portion 183b is positioned above, and the rotating body 183 of FIG. 7B is the rotating body 183 of FIG. 7A. It is a rotated state rotated 90° clockwise.

The game ball B1 that has entered the intake port 185 in the intake permission state is taken into the recesses 183b to 183e located above. For example, as shown in FIG. 7A, the game ball B1 that has entered the intake port 185 with the first recess 183b positioned above is captured in the first recess 183b.

The game ball B1 taken into one of the recesses 183b to 183e of the rotating body 183 at the upper part of the adjusting mechanism 180 is conveyed toward the lower part of the adjusting mechanism 180 as the rotating body 183 rotates. At this time, the right standing wall 181d prevents the game ball B1 taken into the adjusting mechanism 180 from being discharged to the outside of the adjusting mechanism 180 before the discharge timing comes.

For example, as shown in FIG. 7A, the game ball B1 taken into the first recessed portion 183b is a force from the first blade portion 188 toward the front in the rotation direction (rightward in FIG. 7A). Is added. Next, the game ball B1 which is about to fall due to its own weight is in a state of being supported by the second blade portion 189.

Then, as shown in FIG. 7B, the reaction force is applied from the right-side upright wall 181d to the game ball B1 which is about to fall toward the lower right due to its own weight and the force applied from the second blade portion 189. , The state in which the game ball B1 is prevented from falling to the lower right becomes. In this state, by rotating the rotating body 183, the game ball B1 taken in by the upper part of the adjusting mechanism 180 is conveyed toward the lower part of the adjusting mechanism 180.

The game ball B1 taken into one of the recesses 183b to 183e of the rotating body 183 and conveyed to the lower part of the adjusting mechanism 180 has a discharge right side surface 181g (FIG. 4) of the discharge protrusion 181e (FIG. 4). When they come into contact with each other, they are discharged in a certain direction.

Here, as shown in FIG. 5B, the side surface of the first blade portion 188 located on the front side in the rotation direction is referred to as a first front surface 188b, and the second side surface located on the front side in the rotation direction. The side surface of the blade portion 189 is referred to as a second front surface 189b. In addition, the side surface of the third blade portion 190 located on the front side in the rotation direction is the third front surface 190b, and the side surface of the fourth blade portion 191 located on the front side in the rotation direction is the fourth front surface 191b. And The front surfaces 188b to 191b of the blade portions 188 to 191 are surfaces extending in the radial direction of the rotating body 183.

When the game ball B1 taken into any of the recesses 183b to 183e (FIG. 5B) in the rotating body 183 comes into contact with the discharge right side surface 181g and the discharge timing comes, the game ball B1 is the game ball. In the recesses 183b to 183e in which B1 is present, the front surfaces 188b to 191b on the rear side in the rotation direction and the right side surface 181g for discharge are in contact with each other.

As shown in FIG. 5A, the first recess 183b, the second recess 183c, and the third recess 183d have the same shape and size. For this reason, the discharge mode of the game ball B1 taken into the second recess 183c and conveyed to the lower part of the adjusting mechanism 180, and the game ball B1 taken into the third recess 183d and conveyed to the lower part of the adjusting mechanism 180. The discharge mode of is the same as the discharge mode of the game ball B1 that has been taken into the first recess 183b and conveyed to the lower portion of the adjustment mechanism 180.

On the other hand, the fourth recess 183e has the same shape as the first recess 183b, the second recess 183c, and the third recess 183d, and is slightly smaller than the three recesses 183b to 183d. Have a size. Therefore, the discharge mode of the game ball B1 taken into the fourth recess 183e and conveyed to the lower part of the adjustment mechanism 180 is taken up by the first recess 183b to the third recess 183d to the lower part of the adjustment mechanism 180. It may be different from the discharged form of the conveyed game ball B1. When the discharge mode of the game ball B1 discharged from all the recesses 183b to 183e is the same, the movement of the game ball B1 after discharge becomes monotonous. On the other hand, by changing the discharge mode of the game ball B1 discharged from the fourth recess 183e, it is possible to avoid a decrease in the player's interest in the movement of the game ball B1 after discharge.

First, the discharge mode of the game ball B1 taken into any of the first recessed portion 183b to the third recessed portion 183d and conveyed to the lower portion of the adjusting mechanism 180 will be described by exemplifying the case of the first recessed portion 183b.

8A and 8B are front views of the game board 24 showing the vicinity of the adjusting mechanism 180 in an enlarged manner. FIG. 8A illustrates a state immediately before the game ball B1 captured in the first recess 183b reaches the discharge timing, and FIG. 8B illustrates the game ball B1 reaches the discharge timing. The state is illustrated.

As shown in FIG. 8A, immediately before the discharge timing comes, the contact state between the game ball B1 captured in the first recess 183b and the right standing wall 181d is canceled. As a result, the gaming ball B1 that has lost its support becomes ready to drop downward to the right. However, since the rotating body 183 rotates at an angular velocity of 90° for 1 second, the game ball B1 is pushed in the rotation direction (left direction in FIG. 8) from the first blade portion 188 and rotates in the rotation direction (left direction in FIG. 8). Keep moving to.

As shown in FIG. 8B, at the discharge timing, the game ball B1 is in contact with the discharge right side surface 181g and the first front surface 188b. The distance between the two surfaces 181g and 188b sandwiching the game ball B1 is gradually widened from the upper side to the lower side.

As the rotation of the rotating body 183 progresses, a region having a width larger than the diameter of the game ball B1 in the region sandwiched between the two surfaces 181g and 188b gradually disappears from the upper side. At this time, the force applied to the game ball B1 from the discharge right side surface 181g and the force applied to the game ball B1 from the first front surface 188b both have a component that pushes the game ball B1 downward. .. Therefore, the game ball B1 taken into the first recess 183b is pushed downward with the rotation of the rotating body 183. Then, as shown in FIG. 8B, the game ball B1 is discharged downward from the first recess 183b, and wins the first through gate 35 with a high probability.

At the discharge timing shown in FIG. 8B, the right side surface 181g for discharge and the first front surface 188b are also directed downward with respect to the game ball B1 that is originally trying to drop due to its own weight. Add force to drop the. At this time, the leftward movement of the game ball B1 is limited by the discharge right side surface 181g. Therefore, the discharging direction of the game ball B1 is limited to one direction, and the probability of winning the first through gate 35 is increased.

As described above, in the outer edge portion of the rotating body 183, the width of the recessed portions 183b to 183e is wider than the diameter of the game ball B1. Therefore, the position of the game ball B1 in the recesses 183b to 183e is not the same each time immediately before the discharge timing. The discharge direction of the game ball B1 is different depending on the position immediately before the discharge timing of the game ball B1 in the recesses 183b to 183e.

At the design stage, most of the game ball B1 taken into the first recess 183b, the game ball B1 taken into the second recess 183c, and the game ball B1 taken into the third recess 183d are the first through. The position of the ejection protrusion 181e and the inclination of the ejection right side surface 181g are adjusted so as to win the gate 35. However, as described above, the distance between the discharge position of the adjustment mechanism 180 and the first through gate 35 is set to be approximately 1.5 times the diameter of the game ball B1. Therefore, when the game ball B1 discharged from the first recess 183b is caught on the first front surface 188b and pushed to the left, the game ball B1 discharged from the second recess 183c is transferred to the second front surface 189b. When caught and pushed to the left, and when the game ball B1 discharged from the third recess 183d is caught on the third front surface 190b and pushed to the left, the discharged game ball B1 is the first through. It may come off to the left of the gate 35.

Here, the discharge mode of the game ball B1 taken into the fourth recess 183e and conveyed to the lower portion of the adjusting mechanism 180 will be described. FIG. 9 is a front view of the game board 24 showing the adjustment mechanism 180 in an enlarged manner for explaining the case where the game ball B1 discharged from the fourth recess 183e comes off the first through gate 35.

As described above, the fourth recess 183e is formed slightly smaller than the first recess 183b, the second recess 183c, and the third recess 183d. Therefore, as shown in FIG. 9, the game ball B1 discharged from the fourth recess 183e is easily caught on the fourth front surface 191b and pushed to the left side, and easily disengaged to the left side of the first through gate 35. ..

At the design stage, the winning probability of the game ball B1 discharged from the fourth recess 183e to the first through gate 35 is to the first through gate 35 of the game ball B1 discharged from the other three recesses 183b to 183d. The position of the ejection protrusion 181e and the inclination of the ejection right side surface 181g are adjusted so as to be lower than the winning probability of.

By making a part of the game ball B1 discharged from the adjusting mechanism 180 out of the first through gate 35, it is possible to avoid the player's interest from concentrating only on the taking in of the game ball B1 in the adjusting mechanism 180, and thus the game. It is designed so that the person is also interested in discharging the game ball B1 in the adjusting mechanism 180.

As described above, the ejection protrusion 181e is located below the center of the rotating body 183. Therefore, as shown in FIG. 8B, in the lower part of the adjusting mechanism 180, the center of the game ball B1 which is in contact with the ejection protrusion 181e is located to the right of the center of the rotating body 183. positioned. The game ball B1 taken into the rotating body 183 at the upper part of the adjusting mechanism 180 comes into contact with the ejecting projection 181e and is ejected at a timing earlier than rotating 180° around the center of the rotating body 183.

The game ball B1 taken in at the upper part of the adjusting mechanism 180 is rotated around the center of the rotating body 183 by 180° or more and is discharged before starting to rise, so that the game ball at the lower part of the adjusting mechanism 180 is discharged. It is possible to prevent the rise of B1. Further, by setting a short time from when the game ball B1 is taken into the adjusting mechanism 180 to when it is discharged, the time required for a series of flow of taking in, transferring, and discharging the game ball B1 by the adjusting mechanism 180 is shortened. Then, it is possible to suppress the possibility that the player's interest may be transferred to the other in the middle of the flow of the series.

As shown in FIG. 8B, in the lower part of the adjusting mechanism 180, when the game ball B1 is in contact with both the ejection protrusion 181e and the rotating body 183, the left side of the game ball B1 is in contact. The region sandwiched between the discharging right side surface 181g and the front side surfaces 188b to 191b in contact with the right side of the game ball B1 has a shape gradually widening from the upper part to the lower part. Then, as the clockwise rotation of the rotating body 183 progresses, the width of the region sandwiched by the ejection right side surface 181g and the front surfaces 188b to 191b becomes narrower overall. Therefore, in the area sandwiched between the right side surface 181g for discharge and the front surfaces 188b to 191b, the portion having a width in which the game ball B1 can exist is limited to the lower part.

As shown in FIG. 8B, the right side surface 181g for discharge is inclined downward to the left. Therefore, when a leftward force is applied to the game ball B1 that is in contact with the right side surface 181g for discharge from the rotating rotating body 183, the game ball B1 follows the inclination of the right side surface 181g for discharge. Move to the left and move downward. At the lower part of the adjusting mechanism 180, the game ball B1 that is in contact with both the ejection protrusion 181e and the rotating body 183 is pushed downward and ejected as the rotating body 183 rotates. The right side surface 181g for discharge is inclined downward to the left, so that the game ball B1 is prevented from rising in the lower part of the adjusting mechanism 180 and staying without being discharged.

Next, a configuration will be described in which the game ball B1 that has not been taken into the inside of the adjusting mechanism 180 is released to the rear of the game board 24 while trying to enter the take-in port 185 of the adjusting mechanism 180. As shown in FIG. 4, at the rear of the game board 24, an escape passage 172 is provided as a passage for allowing the game ball B1 that has not been taken in at the intake 185 to escape. A passage entrance 171 which is an entrance of the escape passage 172 is provided on the front surface of the game board 24. The passage entrance 171 is located behind the intake 185. By letting the game ball B1 not taken in at the take-in port 185 escape to the passage entrance 171, it is possible to prevent the game ball B1 not taken in from staying around the take-in port 185.

First, the game ball B1 that has flowed down to the intake port 185 in the intake prohibited state and has not been taken into the intake port 185 will be described.

FIG. 10A is a horizontal cross-sectional view of the window panel 52 and the game board 24 in the case where a plane perpendicular to the front surface of the game board 24 is cut right above the intake port 185, and FIG. 10B is a game board. 24 is a vertical cross-sectional view of the first blade portion 188 when cut along a plane perpendicular to the front surface of 24. FIG. 10A and 10B, the rotating body 183 is in a rotating state in which the first blade portion 188 is located above.

As shown in FIG. 10A, when the game ball B1 flows down to the intake port 185 in the intake prohibited state, the game ball B1 is one of the rotating bodies 183 located below the intake port 185. It contacts the peripheral surfaces 188a to 191a (FIG. 5B) of the blade portions 188 to 191.

As shown in FIGS. 5A and 5B, the peripheral surfaces 188a to 191a of the blades 188 to 191 of the rotating body 183 are inclined rearward toward the axis. Therefore, as shown in FIG. 5A, when the first blade portion 188 is facing upward, the peripheral surface 188a of the first blade portion 188 is inclined downward toward the rear. As a result, as shown in FIG. 10A, the game ball B1 that is in contact with the peripheral surface 188a of the first blade portion 188 is guided rearward.

In the intake-prohibited state in which the second blade portion 189 is facing upward, the peripheral surface 189a of the second blade portion 189 is tilted downward toward the rear, and the third blade portion 190 is facing upward. In the state in which the intake is in the facing state, the peripheral surface 190a of the third blade portion 190 is inclined downward toward the rear. Further, in the intake-prohibited state in which the fourth blade portion 191 faces upward, the peripheral surface 191a of the fourth blade portion 191 is inclined downward toward the rear.

Although not shown, the peripheral surface 189a of the second blade portion 189, the peripheral surface 190a of the third blade portion 190, and the peripheral surface 191a of the fourth blade portion 191 that face upward in the intake prohibited state are in contact with each other. The game ball B1 is guided rearward similarly to the game ball B1 contacting the peripheral surface 188a of the first blade portion 188 shown in FIG.

As shown in FIG. 4, the passage entrance 171 is an opening provided on the front surface of the game board 24, and is located behind the intake opening 185. The passage inlet 171 is formed from the left end of the inlet 185 to the right end of the inlet 185 on the front surface of the game board 24.

The upper end of the passage inlet 171 is higher than the upper end of the game ball B1 that contacts the peripheral surfaces 188a to 191a of the blades 188 to 191 when any of the blades 188 to 191 of the rotating body 183 faces upward. About half of the game ball B1 is set high. For this reason, the game ball B1 that flows down from above the game area PA and collides with the peripheral surfaces 188a to 191a of the blade portions 188 to 191 that are inclined downward toward the rear, and bounces back obliquely rearward to the passage entrance 171. You can enter the ball.

On the other hand, the area on the upper side of the passage entrance 171 is taken in by the intake 185 so that the game ball B1 flowing down the game area PA does not enter the passage entrance 171 before reaching the intake 185. It is set to the minimum area that allows the game ball B1 that was not present to be prevented from staying and staying.

As shown in FIG. 4, the lower end on the left side of the passage inlet 171 is lower than the upper end of the back surface of the blade portion 188 to 191 in a state where any of the blade portions 188 to 191 of the rotating body 183 faces upward. Is located in. Further, the right lower end of the passage inlet 171 is located below the left lower end. The right lower end of the passage entrance 171 will be described later in detail.

As shown in FIG. 4, in the upper part of the base body 181a in the housing portion 181, the blades 188 to 191 of any of the rotating bodies 183 are guided to the passage inlet 171 by the peripheral surfaces 188a to 191a (FIG. 5A). The passage recessed portion 181f is formed so as not to interfere with the movement of the gaming ball B1.

The passage recess 181f is formed from the left end to the right end of the passage inlet 171. On the left side of the passage recessed portion 181f, the upper end of the base body 181a is below the upper end of the back surface of the blade portion 188 to 191 in a state where any of the blade portions 188 to 191 of the rotating body 183 faces upward. It is formed so as to be located.

On the left side of the passage recess 181f, the upper end of the base body 181a is located at the same position as the lower end of the passage inlet 171 or above the lower end of the passage inlet 171. Therefore, as shown in FIG. 10B, the game ball B1 that is in contact with the blade portions 188 to 191 and tries to enter the intake port 185 in the intake prohibited state has the peripheral surface 188a of the blade portions 188 to 191. To 191a, the ball enters the passage entrance 171 without being obstructed by the base body 181a of the accommodation portion 181.

As shown in FIG. 4, an escape passage 172 is formed on the front surface of the game board 24 as a recessed portion that is recessed rearward. The escape passage 172 is formed as a recess having a depth dimension larger than the diameter of the game ball B1 in the front-rear direction and a width dimension larger than the diameter of the game ball B1 in the lateral direction. There is. For this reason, the escape passage 172 has a passage cross section through which the game balls B1 can pass by forming one row.

The upstream side of the escape passage 172 is formed from the passage inlet 171 toward the lower left, and the downstream side of the escape passage 172 is formed vertically downward. The escape passage 172 guides the game ball B1 entered from the passage entrance 171 to the lower left of the first through gate 35.

On the front surface of the game board 24, a step is provided at the edge of the recess formed as the escape passage 172. The escape passage 172 is covered from the front by a transparent acrylic plate 172a formed in the same shape as a portion of the accommodation portion 181 that does not overlap with the base body 181a in the outer shape when the escape passage 172 is viewed from the front. The acrylic plate 172a is fixed to a step portion formed on the edge of the escape passage 172 with an adhesive.

The step formed at the edge of the escape passage 172 has the same depth as the thickness of the acrylic plate 172a in the front-rear direction, and the front surface of the acrylic plate 172a is located on the same plane as the front surface of the game board 24. ing. The escape passage 172 is closed by the acrylic plate 172a and the base body 181a of the accommodating portion 181, and the place where the game ball B1 can go in and out is limited to the passage entrance 171 and the passage exit 173.

Since the acrylic plate 172a fixed to the front of the escape passage 172 and the adjusting mechanism 180 are transparent, the movement of the game ball B1 passing through the escape passage 172 can be visually recognized from the outside. When the movement of the game ball B1 passing through the escape passage 172 cannot be grasped from the outside, the player cannot follow the movement process of the game ball B1 after the game ball B1 enters the passage entrance 171 and the game ball B1 cannot be followed. The flow of B1 is interrupted on the way. On the other hand, by making the game ball B1 passing through the escape passage 172 visible from the outside, the flow of the game ball B1 that can be grasped by the player can be kept continuous.

As shown in FIG. 4, in the game board 24, a passage outlet 173 which is an outlet of the escape passage 172 is provided at the lower left of the first through gate 35. The passage outlet 173 is formed on the front surface of the game board 24 as an opening directed forward. The passage outlet 173 has a shape and a size capable of discharging the game balls B1 guided by the escape passage 172 toward the front one by one.

As shown in FIG. 4, near the upper portion of the passage outlet 173, an outlet for preventing the game ball B1 discharged from the passage outlet 173 from colliding with the game ball B1 flowing down in front of the front surface of the game board 24. A roof 174 is provided. The exit roof 174 is provided as a projecting portion that projects from the front surface of the game board 24 toward the window panel 52 (FIG. 1) side, and extends from the front surface of the game board 24 to near the back surface of the window panel 52. ing. Since the upper surface of the exit roof 174 is inclined downward to the right, the game ball B1 flowing down from above and contacting the exit roof 174 does not collide with the game ball B1 discharged from the passage exit 173. You will be guided to the right in a manner.

The game ball B1 which has passed through the escape passage 172 and is discharged from the passage outlet 173 to the front side of the front surface of the game board 24 flows down in the game area PA. As shown in FIG. 3, the passage outlet 173 is located upstream of the first operating port 33 and the second operating port 34. For this reason, the game ball B1 discharged from the passage outlet 173 reaches the area where the first operating port 33 and the second operating port 34 are provided, and either the first operating port 33 or the second operating port 34 is reached. It is possible to win a crab.

As described above, the game ball B1 that has won the first through gate 35 can also flow down in the game area PA and win the prize in either the first operating port 33 or the second operating port 34. The game ball B1 guided to the first through gate 35 by the adjusting mechanism 180 and the game ball B1 guided to the escape passage 172 by the adjusting mechanism 180 and discharged from the passage outlet 173 are both the first operating port 33 and the second operating port. It can flow down to the area where 34 is provided. Therefore, since the adjusting mechanism 180 is provided, the game ball B1 that reaches the area where the first operating port 33 and the second operating port 34 are provided does not decrease.

Returning to the description of taking in the game ball B1 at the taking-in port 185, as shown in FIG. 4, in the transition process from the take-in permitted state to the take-in prohibited state, the gap between the blade portions 188 to 191 and the right standing wall 181d. When the game ball B1 flows down to the intake port 185 at the timing when the state changes from a state wider than the diameter of the game ball B1 to a narrow state, the game ball B1 becomes the blade portions 188 to 191 of the rotating body 183 and the right standing wall 181d. It may be caught. In the following, the state in which the acquisition permitted state is transited to the acquisition prohibited state is an intermediate state. In addition, the right end of the intake port 185 is a surface that defines the right end, and the end face located above the right standing wall 181d that sandwiches the game ball B1 together with the blades 188 to 191 in the intermediate state is the standing wall side end face 182. ..

Here, a configuration for allowing the game ball B1 sandwiched between the blade portions 188 to 191 and the standing wall side end surface 182 at the intake port 185 in the intermediate state to escape to the escape passage 172 will be described. First, the inclination of the front surfaces 188b to 191b that are the side surfaces of the blade portions 188 to 191 and are located on the front side in the rotation direction of the rotating body 183 will be described with reference to FIG.

As shown in FIG. 5B, the front surfaces 188b to 191b of the blades 188 to 191 of the rotating body 183 are inclined rearward in the rotational direction toward the rear. Therefore, in a state where the blade portions 188 to 191 face upward, the front surfaces 188b to 191b of the blade portions 188 to 191 are inclined leftward toward the rear.

Regardless of the rotating state of the rotating body 183, the front surfaces 188b to 191b of the upper blade portions 188 to 191 are inclined leftward toward the rear. For this reason, at the intake port 185 in the intermediate state, the game ball B1 sandwiched between the second front surface 189b of the second blade portion 189 and the standing wall side end surface 182, and the third front surface 190b of the third blade portion 190 are erected. The game ball B1 sandwiched between the wall-side end surface 182 and the game ball B1 sandwiched between the fourth front surface 191b of the fourth blade portion 191 and the standing wall-side end surface 182 is the first front surface 188b of the first blade portion 188. It moves in the same direction as the game ball B1 sandwiched between the standing wall side end surface 182. In the following, the movement of the game ball B1 sandwiched by the intake port 185 in the intermediate state will be described by taking the game ball B1 sandwiched between the first front surface 188b and the standing wall side end surface 182 as an example.

As shown in FIG. 5B, the first front surface 188b of the first blade portion 188 that is facing upward is inclined rearward to the left. FIG. 10C is a horizontal cross-sectional view of the window panel 52 and the game board 24 when a portion right above the inlet 185 is cut by a plane perpendicular to the front surface of the game board 24. As shown in FIG. 10C, the standing wall side end surface 182 is inclined rearward and rightward. Therefore, when the game ball B1 flows down into the intake port 185 in the intermediate state and is sandwiched between the first front surface 188b and the standing wall side end surface 182, the two surfaces 182, 188b sandwiching the game ball B1. The rear side (game board 24 side) is wider than the front side (window panel 52 side).

When the rotating body 183 rotates clockwise in a state where the game ball B1 is sandwiched between the two surfaces 182 and 188b, the distance between the two surfaces 182 and 188b becomes gradually smaller from the front side. At this time, the force applied to the game ball B1 from the first front surface 188b and the force applied to the game ball B1 from the standing wall side end surface 182 are components that move the game ball B1 backward. have. Therefore, as shown in FIG. 10C, the game ball B1 sandwiched between the two surfaces 182 and 188b is a passage provided behind the intake port 185 when the rotating body 183 rotates. It is pushed out toward the entrance 171. Then, the pushed game ball B1 enters the escape passage 172 from the passage entrance 171 and is guided to the passage exit 173.

As described above with reference to FIG. 5B, the front surfaces 188b to 191b of the blade portions 188 to 191 are surfaces extending in the radial direction of the rotating body 183. Therefore, when the game ball B1 is in contact with both of the front surfaces 188b to 191b and the right standing wall 181d (FIG. 10(c)) at the intake 185, the game ball B1 The front surfaces 188b to 191b that are in contact with B1 are inclined downward to the left. Therefore, the force applied to the game ball B1 from the front surfaces 188b to 191b by the clockwise rotation of the rotating body 183 includes a downward component. As a result, when the game ball B1 is pushed toward the passage entrance 171, the game ball B1 is prevented from moving upward.

As shown in FIG. 10C, a configuration in which the game ball B1 that is sandwiched by utilizing the inclination of the front surfaces 188b to 191b and the standing wall side end surface 182 and the rotation of the rotating body 183 is pushed out to the passage inlet 171. By doing so, it is possible to eliminate the state in which the game ball B1 is sandwiched while avoiding that the game ball B1 stops or rises.

As shown in FIG. 4, the right side of the passage inlet 171 and the right side of the passage recess 181f are provided with the game ball B1 sandwiched between the blade portions 188 to 191 of the rotating body 183 and the right standing wall 181d in the intermediate state. It is formed so that it can enter the ball 171.

The game ball B1 sandwiched between the wing portions 188 to 191 and the right standing wall 181d is lower than the game sphere B1 contacting any one of the peripheral surfaces 188a to 191a of the blade portions 188 to 191 in the take-in prohibited state. Located in. Therefore, as shown in FIG. 4, the lower end on the right side of the passage inlet 171 is located below the lower end on the left side of the passage inlet 171, and the upper end of the base body 181a on the right side of the passage recess 181f is It is located below the upper end of the base body 181a on the left side of the passage recess 181f.

The upper end of the base body 181a on the right side of the passage recessed portion 181f is located below the lower end of the game ball B1 sandwiched between the blade portions 188 to 191 and the right standing wall 181d in the intermediate state. The lower end on the right side of the passage inlet 171 is formed at the same position as the upper end of the base body 181a on the right side of the passage recess 181f, or below the upper end of the base body 181a.

However, in the take-in permission state, the game ball B1 taken into any of the recesses 183b to 183e of the rotating body 183 passes through the passage-use recess 181f formed in the rear and enters the passage entrance 171. In order to prevent this, the upper end of the base body 181a on the right side of the passage recessed portion 181f is positioned slightly lower than the lower end of the game ball B1 sandwiched between the blade portions 188 to 191 and the right standing wall 181d in the intermediate state. It is set.

In addition, as described above, since the recesses 183b to 183e of the rotating body 183 are inclined toward the axial center toward the front, the game ball B1 taken into the recesses 183b to 183e is the game area PA. Hold on the front side. Therefore, the game ball B1 taken into each of the recesses 183b to 183e may enter the passage inlet 171 through the passage recess 181f located rearward (particularly the right side of the passage recess 181f). Has been reduced.

At the take-in port 185, another game ball B1 is taken in in a state where one game ball B1 has already been taken into the recesses 183b to 183e located above (FIG. 7(a)). It is possible that 185 is reached. In this case, the recesses 183b to 183e are already held on the window panel 52 side. Therefore, it is highly possible that the center of the game ball B1 that has reached the intake port 185 later is located behind the center of the game ball B1 that has already been taken in by the recesses 183b to 183e. In this case, the game ball B1 that has reached the intake port 185 afterwards comes into contact with the game ball B1 captured in the recesses 183b to 183e, bounces backward, and enters the passage entrance 171.

In addition, when the center of the game ball B1 that has reached the intake port 185 later is deviated to the left or right of the center of the game ball B1 captured in the recessed portions 183b to 183e, the intake port 185 is later provided. The game ball B1 that has reached the contact with the game ball B1 captured in the recessed portions 183b to 183e and bounces back to the left or right, and is not captured by the adjustment mechanism 180, and the game area PA on the side of the adjustment mechanism 180 is captured. It will flow down to the downstream. In this way, when a plurality of game balls B1 reach the intake port 185 in the intake permission state of the intake port 185 once, one game ball B1 has one of the recesses 183b to 183e. While being taken in, the remaining game ball B1 can flow down the downstream of the game area PA without staying near the intake port 185.

FIG. 11 is an explanatory diagram for explaining the configuration related to the discharge of the game ball B1 flowing down the game area PA.

As described above, the game ball B1 that has entered the general winning opening 31, the special electric winning device 32, the first operating opening 33, the second operating opening 34, or the out opening 24a is discharged from the game area PA. In other words, the game ball B1 that has been launched from the game ball launching mechanism 27 and flowed into the game area PA is one of the general winning opening 31, the special electricity winning device 32, the first operating opening 33, the second operating opening 34, and the out opening 24a. By entering the crab, it will be discharged from the game area PA. The game ball B1 that has entered the general winning opening 31, the special electric winning device 32, the first operating opening 33, the second operating opening 34, or the out opening 24a is guided to the back side of the game board 24.

On the back surface of the game board 24, discharge passage portions 42 to 48 are formed corresponding to the general winning opening 31, the special electric winning device 32, the first operating opening 33, the second operating opening 34, and the out opening 24a. .. The game ball B1 that has flowed into the discharge passages 42 to 48 is guided to the lower end of the game board 24 on the back side of the game board 24 by flowing down the flowed discharge passages 42 to 48. Will be collected at. Then, the game ball B1 collected by the discharge ball collecting unit is discharged to the ball circulating device of the island facility in which the pachinko machine 10 is installed in the game hall.

Various detection sensors 42a to 48a for detecting the game ball B1 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 openings 31 are provided as described above, the discharge passage portions 42 to 44 are provided 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 adjacent thereto. 43a is provided. Specifically, the first winning opening detection sensor 42a is provided so that the detection range exists in the middle position of the first discharge passage portion 42, and the detection range is formed in the middle position of the second discharge passage portion 43. The second winning opening detection sensor 43a is provided so as to exist. The game ball B1 that has entered the leftmost general winning opening 31 is detected by the first winning opening detection sensor 42a while passing through the first discharge passage portion 42, and has entered the general winning opening 31 adjacent to the right. The game ball B1 is detected by the second winning opening detection sensor 43a while passing through the second discharge passage portion 43. In addition, a third discharge passage portion 44 formed so as to join at the middle position with respect to the two right winning openings 31 on the right side is provided. The third discharge passage portion 44 has an entrance side area corresponding to each of the two general winning openings 31, and also has one exit side area due to the entrance side areas joining in the middle. doing. The third winning opening detection sensor 44a is provided so that the detection range exists in the middle of the outlet side region of the third discharge passage portion 44. The game ball B1 that has entered one of the two right prize holes 31 is detected by the third prize hole detection sensor 44a while passing through the third discharge passage portion 44.

The fourth discharge passage portion 45 is provided so as to correspond to the special electric winning device 32. The special electricity detection sensor 45a is provided so that the detection range exists at an intermediate position of the fourth discharge passage portion 45, and the game ball B1 that has entered the special electricity prize winning device 32 is in the middle of passing through the fourth discharge passage portion 45. Is detected by the special electric power detection sensor 45a. The fifth discharge passage portion 46 is provided so as to correspond to the first operation port 33. The first working port detection sensor 46a is provided so that the detection range exists in the middle of the fifth discharging passage part 46, and the game ball B1 entering the first working port 33 is the fifth discharging passage part 46. It is detected by the first working port detection sensor 46a while passing through. The sixth discharge passage portion 47 is provided so as to correspond to the second operation port 34. The second working port detection sensor 47a is provided so that the detection range exists in the middle of the sixth discharging passage part 47, and the game ball B1 entering the second working port 34 is the sixth discharging passage part 47. It is detected by the second working port detection sensor 47a while passing through. The seventh discharge passage portion 48 is provided corresponding to the outlet 24a. The outlet detection sensor 48a is provided so that the detection range exists in the middle of the seventh discharge passage 48, and the game ball B1 entering the outlet 24a is passing through the seventh discharge passage 48. Is detected by the outlet detection sensor 48a.

The game ball B1 detected by any one of the various detection sensors 42a to 48a is not detected by the other detection sensors 42a to 48a. Further, the first through gate 35 is provided with a first gate detection sensor 49a, and the second through gate 39 is provided with a second gate detection sensor 50a. Therefore, while flowing down the game area PA, the game ball B1 passing through the first through gate 35 is detected by the first gate detection sensor 49a, and the game ball B1 passing through the second through gate 39 is second. It is detected by the gate detection sensor 50a.

An electromagnetic induction type proximity sensor is used as each of the various detection sensors 42a to 50a, but any sensor may be used as long as it can individually detect the game ball B1. The various detection sensors 42a to 50a are electrically connected to the main control device 60 described later, and the detection results of the various detection sensors 42a to 50a are output to the main control device 60. Specifically, the various detection sensors 42a to 50a output a LOW level signal when the game ball B1 is not detected, and output a HI level signal when the game ball B1 is detected. Note that the relationship between HI and LOW is not limited to this, and may be reversed.

As shown in FIG. 2, a display light emitting unit 53 is provided above the window 51. Further, a pair of left and right speaker units 54 for outputting sound effects and the like according to the game state are provided. Further, below the window portion 51, an upper bulge portion 55 and a lower bulge portion 56 which bulge toward the front side are arranged in parallel vertically. An upper plate 55a that opens upward is provided inside the upper bulging portion 55, and a lower plate 56a that also opens upward is provided inside the lower bulging portion 56. The upper plate 55a has a function of temporarily storing the game balls B1 paid out by the payout device described later and guiding them to the game ball launching mechanism 27 side while aligning them in a line. In addition, the lower plate 56a has a function of storing the game balls B1 that are excessive in the upper plate 55a.

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

As shown in FIG. 2, on the back surface of the inner frame 13 (specifically, the game board 24), a main controller 60 that controls the main game is mounted. The main controller 60 has a main control board 61 housed in a board box 60a. The substrate box 60a may be provided with a trace means for leaving a trace of the opening, or may be provided with a trace structure for leaving a trace of the opening. Examples of the trace means include a structure of a joint portion that inseparably joins a plurality of case bodies that constitute the substrate box 60a and requires destruction of a predetermined portion at the time of separation, or that an adhesive layer remains on an object to be adhered at the time of peeling. A configuration may be considered in which a sealing sticker that leaves a trace of being peeled off is attached so as to straddle the boundary between a plurality of case bodies. In addition, as the trace structure, a configuration in which an adhesive is applied to the boundaries between the plurality of case bodies that form the 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 transparent synthetic resin, and the payout mechanism unit 73 and the control device assembly unit 74 are attached to the back pack 72.

The payout mechanism unit 73 includes a tank 75 to which the game balls B1 supplied from the island facility of the game hall are sequentially replenished, and a payout device 76 for paying out the game balls B1 stored in the tank 75. There is. The game ball B1 paid out by the payout device 76 is 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 main power source of, for example, 24 V AC, and a back pack substrate having a power switch for performing ON and OFF operations of the power source.

The control device gathering unit 74 generates and outputs a payout control device 77 having a function of controlling the payout device 76, a predetermined electric power required by various control devices and the like, and accompanies the player's operation of the firing operation device 28. A power supply/launch control device 78 for controlling the launch of the game ball B1 is provided. The payout control device 77 and the power supply/launch control device 78 are arranged in front of and behind each other so that the payout control device 77 is behind the pachinko machine 10.

<Electrical structure of the pachinko machine 10>
FIG. 12 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 contains 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 contains an interrupt circuit, a timer circuit, a data input/output circuit, various counter circuits as a random number generator, and the like.

The main-side ROM 64 is a memory such as a NOR flash memory and a NAND flash memory that does not require external power supply for storage, 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. As shown in FIG. 12, the main ROM 64 has a low-frequency win determination value table T1 and a high-frequency win used in the universal electric open lottery for determining whether to open or close the universal electric accessory 34a. The judgment value table T2 is stored. In the low-frequency winning determination value table T1 and the high-frequency winning determination value table T2, determination values to be won in the ordinary electric open lottery are recorded. Details of the low frequency winning determination value table T1 and the high frequency winning determination value table T2 will be described later.

The main RAM 65 is a memory (that is, a volatile storage unit) such as an SRAM and a DRAM that needs power supply from the outside to retain the storage, and is used for both reading and writing. The main RAM 65 can be randomly accessed, and has a shorter read time than the main ROM 64 when compared with the same data capacity. The main RAM 65 temporarily stores various data and the like for execution of the control program stored in the main ROM 64.

The management IC 66 is a management device that manages the entry mode of the game ball B1 in the game area PA based on the information supplied from the main CPU 63. As will be described later in detail, while the management IC 66 grasps the entry history of the game ball B1 into the general winning opening 31, the special electric 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 opening 31, the special electric winning device 32, the first operating opening 33, and the second operating opening 34 is ascertained in accordance with the obtained entering history.

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

Various sensors such as various ball detection sensors 42a to 50a are connected to the input side of the MPU 62. The various winning ball detection sensors 42a to 50a are, as already described, the first winning hole detecting sensor 42a, the second winning hole detecting sensor 43a, the third winning hole detecting sensor 44a, the special electricity detecting sensor 45a, and the first working opening detecting sensor. 46a, a second working port detection sensor 47a, an out port detection sensor 48a, a first gate detection sensor 49a, and a second gate detection sensor 50a. On the basis of the detection results of these ball detection sensors 42a to 50a, the main CPU 63 determines whether or not each ball has entered the ball. Further, in the main CPU 63, various kinds of lottery are executed based on the winning of the first operating port 33, and various kinds of lottery are executed based on the winning of 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. In the payout control device 77, a prize ball command is issued, for example, based on the fact that the game ball B1 has entered the prize ball-corresponding ball input part corresponding to the payout of the game ball B1 in the ball input part. Is output. Various commands such as a variation 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 32b for opening/closing the opening/closing door 32a of the special electric prize winning device 32, a general electric drive unit 34b for opening/closing the general electric officer 34a of the second operating port 34, The drawing unit 37, the universal drawing unit 38, and the adjustment drive unit 184 are connected. By the way, the special drawing unit 37 is provided with a special drawing display portion 37a and a special drawing reservation display portion 37b, all of which are connected to the output side of the MPU 62. Similarly, the universal figure unit 38 is provided with a universal figure display section 38a and a universal figure hold display section 38b, all of which are connected to the output side of the MPU 62. Various driver circuits are provided on the main control board 61, and the MPU 62 executes drive control of various drive units and various display units through the driver circuits.

That is, in the opening/closing execution mode, the main CPU 63 executes drive control of the drive unit 32b for special electricity so that the special electricity winning device 32 is opened and closed. Further, when the general electric outlet 34a is in the open state, the main CPU 63 performs drive control of the general electric drive unit 34b so that the general electric outlet 34a is opened and closed. Further, at the time of each game, the main CPU 63 executes display control of the special figure display portion 37a. Further, in the case of clearly indicating the lottery result of whether or not to open the general electric accessory 34a, the main CPU 63 executes the display control of the general figure display unit 38a. Further, when a winning is generated in the first operation port 33 or the second operation port 34, or when the variable display is started in the special figure display unit 37a, the main CPU 63 controls the display of the special figure hold display unit 37b. Is executed and a prize is generated in the through gates 35 and 39, or when the variable display is started on the universal figure display section 38a, the main CPU 63 executes the display control of the universal figure hold display section 38b. ..

The power failure monitoring board 67 relays the main control board 61 and the power supply/launch control device 78 and monitors the voltage of DC stable 24V which is the maximum voltage output from the power supply/launch control device 78. The payout control device 77 controls payout of prize balls and loan balls by the payout device 76 based on the prize ball command received from the main control device 60.

The power supply/launch control device 78 is connected to, for example, a commercial power supply (external power supply) in a game hall or the like. Then, based on the external power supplied from the commercial power source, the operating power necessary for each of the main control board 61, the payout control device 77, the adjustment drive unit 184, and the like is generated, and the generated operating power is generated. To supply. By the way, the power supply/launch control device 78 is provided with a power supply unit for power interruption such as a backup capacitor, and even when the power of the pachinko machine 10 is in the OFF state, the power supply unit for power interruption is mainly used. Electric power for storage is supplied to the main RAM 65 of the control device 60 and the payout control device 77. Further, the power supply/launch control device 78 is responsible for the launch control of the game ball launch mechanism 27, and the game ball launch mechanism 27 is driven when a predetermined launch condition is satisfied.

The sound emission control device 81 drives and controls the display light emission part 53 and the speaker part 54 provided in the front door frame 14 based on various commands received from the main control device 60, and also controls the display control device 82. Is. The display control device 82 executes the display control of the symbol display device 41 based on the command received from the voice emission control device 81.

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

The main side CPU63 uses the various counter information at the time of the game, and performs the jackpot occurrence lottery, the setting of the display of the special symbol display portion 37a, the setting of the symbol display of the symbol display device 41, the setting of the display of the general symbol display portion 38a, etc. Specifically, as shown in FIG. 13, the winning random number counter C1 used for the lottery for winning, the jackpot type counter C2 used when determining the jackpot type, and the symbol display device 41 are displaced. Reach random number counter C3 used for reach generation lottery when performing, random number initial value counter CINI used for initial value setting of the hit random number counter C1, and display duration in the special figure display portion 37a and the symbol display device 41 are determined. The fluctuation type counter CS is used. Further, a general electric utility object release counter C4 used for a lottery to determine whether the general electric utility object 34a of the second operation port 34 is to be in the general electric open state, and an initial value setting of the general electric effect object release counter C4. The opening initial value counter C5 to be used is used. The counters C1 to C3, CINI, CS, C4 and C5 are provided in various counter areas 65b of the main RAM 65.

Each of the counters C1 to C3, CINI, CS, C4, and C5 is a loop counter in which 1 is added to the previous value each time it is updated, and after reaching the maximum value, it returns to "0". Each counter is updated at short time intervals. The information corresponding to the winning random number counter C1, the jackpot type counter C2, and the reach random number counter C3 is provided as acquisition information storage means in the main RAM 65 when a prize is awarded to the first operating opening 33 or the second operating opening 34. It is stored in the reserved storage area 65a.

The hold storage area 65a includes a hold 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, and the winning history of the first working opening 33 or the second working opening 34 is stored in the holding area RE. In addition, a combination of numerical value information of the hit random number counter C1, the big hit type counter C2, and the reach random number counter C3 is stored in any of the holding areas RE1 to RE4 as holding information.

In this case, in the first holding area RE1 to the fourth holding area RE4, when the winning of the first working opening 33 or the second working opening 34 occurs in succession a plurality of times, the first holding area RE1→the second holding area RE1 Numerical information is stored in chronological order in the order of the holding area RE2→the third holding area RE3→the fourth holding area RE4. Since the four holding areas RE1 to RE4 are provided in this way, the winning history of the game ball B1 to the first working opening 33 or the second working opening 34 can be held and stored up to a maximum of four. There is.

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

The execution area AE is an area for moving each numerical value information stored in the first holding area RE1 of the holding area RE when starting the variable display of the special figure display portion 37a, and starts one game time. At that time, a win/fail judgment is made on the basis of various numerical information stored in the execution area AE.

In addition, the information corresponding to the general electric outlet opening counter C4 is stored in the general electric storage storage area 65c provided in the main RAM 65 when a prize is awarded to the first through gate 35 or the second through gate 39. To be done.

The ordinary electricity reservation storage area 65c includes an ordinary electricity reservation area HA and an ordinary electricity execution area HB. The ordinary electric power holding area HA includes a first ordinary electric power holding area HA1, a second ordinary electric power holding area HA2, a third ordinary electric power holding area HA3 and a fourth ordinary electric power holding area HA4, and the first through gate 35 or In accordance with the winning history to the second through gate 39, the numerical information of the universal electric accessory release counter C4 is stored in any of the ordinary electric power holding areas HA1 to HA4 as ordinary electric power holding information.

In this case, when the winnings to the first through gate 35 or the second through gate 39 occur in a plurality of consecutive times in the first normal power holding area HA1 to the fourth normal power holding area HA4, Numerical information is stored in time series in the order of the holding area HA1, the second ordinary electric power holding area HA2, the third ordinary electric power holding area HA3, and the fourth ordinary electric power holding area HA4. As described above, since the four normal electric power holding areas HA1 to HA4 are provided, the winning history of the game ball B1 to the first through gate 35 or the second through gate 39 can be reserved and stored up to a maximum of four. Is becoming

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

The ordinary electric power execution area HB is an area in which the ordinary electric power holding information of the target of the ordinary electric power open lottery is stored when the variable display is started on the general electric figure display portion 38a (FIG. 3). Specifically, when starting the variable display of the universal map display portion 38a, the universal communication holding information stored in the first universal communication holding area HA1 is shifted to the universal communication execution area HB.

Each of the above counters will be described in detail.

First, the general electric accessory opening counter C4 and the opening initial value counter C5 will be described. The general electric utility article release counter C4 and the opening initial value counter C5 are loop counters that are sequentially incremented by 1 within the range of 0 to 65535 and return to "0" after reaching the maximum value. When the general electric utility object release counter C4 makes one revolution, the value of the initial value counter C5 for opening at that time is read as the initial value of the general electric object release counter C4.

As described above, in the pachinko machine 10, the ordinary electric open lottery is executed in response to the winning of the game ball B1 to the through gates 35 and 39. Numerical information updated in the general electric opener counter C4 is used for the general electric open lottery. Specifically, when the game ball B1 wins the through gates 35 and 39, the numerical information updated by the general electric outlet opening counter C4 is acquired as a random number for opening. In the following, the numerical information that is updated by the general electric outlet opening counter C4, is acquired upon the winning of the through gates 35 and 39, and is used in the general electric lottery is described as a random number for opening. In the usual electric open lottery, it is judged whether or not the random number for opening of the lottery is the winning judgment value that is the target of the ordinary electric open winning, and if the positive judgment is made, it becomes the ordinary electric open winning. , When the negative judgment is made, it becomes a disengagement result.

In this pachinko machine 10, a plurality of types of support modes are set so that the modes of support by the general electric accessory 34a are different from each other. In detail, in the support mode, when comparing in a situation where the game ball B1 is continuously fired in the same manner in the game area PA, the ordinary electric vehicle object 34a of the second working port 34 is per unit time. The high frequency support mode and the low frequency support mode are set so that the frequency of the open state is relatively high and low.

First, the ordinary electric open lottery executed in the low frequency support mode will be described. The main ROM 64 (FIG. 12) stores a low-frequency winning determination value table T1 in which the winning determination values that are the targets of the universal opening winning are recorded in the regular opening lottery executed in the low-frequency support mode. ing. FIG. 14A is a low frequency winning determination value table T1.

As shown in FIG. 14A, the winning determination value of the ordinary electric open lottery executed in the low frequency support mode is set to (250×n−5) to (250×n). Here, the variable n is a natural number of 1 to 262. The probability of winning the Hoden opening is approximately 1/42 in the Hoden opening lottery executed in the low frequency support mode.

As shown in FIG. 14( a ), the winning judgment values targeted for the universal electric open winning are serial numbers in units of six. Further, the updating cycle of the random number for opening in the general electric utility article opening counter C4 is 4 msec. For this reason, in the general electric outlet opening counter C4, the period during which the updated random number for opening is the winning determination value of the general electric opening winning target in the general electric open lottery in the low frequency support mode continues for 24 msec.

Assuming that a period of 24 msec in which the winning determination value that is the target of the ordinary electric open winning continues is the winning target period, as shown in FIG. 14A, in the low frequency support mode, the winning target period occurs in a cycle of 1 sec. Here, assuming that the timing at which the game ball B1 discharged from the adjusting mechanism 180 (FIG. 4) wins the first through gate 35 is the winning possible timing, as described above, the cycle in which the winning possible timing occurs is low. It is 1 sec, which is the same as the cycle in which the winning target period occurs in the frequency support mode.

Therefore, in the low-frequency support mode, the period in which the winning possible timing overlaps with the winning target period is the winning consecutive period in which the universal electric open winning occurs continuously. The winning continuous period continues until the initial value of the general electric utility open counter C4 is updated and the generation timing of the winning period shifts. When the generation timing of the winning target period is deviated, it is a non-winning continuous period in which the failure result continues in the normal electric open lottery executed in the low frequency support mode until the winning target period and the winning possible timing overlap again.

As described above, the winning possible timing at which the game ball B1 is discharged from the adjusting mechanism 180 and the winning of the first through gate 35 occurs can occur at a cycle of 1 sec. For this reason, in the non-winning continuous period and the winning continuous period in the low frequency support mode, the universal figure changing time in which the universal figure display portion 38a (FIG. 3) fluctuates is set to 0.5 sec, which is shorter than 1 sec. Therefore, even if the game balls B1 are continuously discharged from the adjusting mechanism 180 in a cycle of 1 sec, the variation of the universal figure display portion 38a corresponding to the previous winning is finished when the winning occurs. As a result, it is possible to prevent the state in which the general-use reservation information exceeds the upper limit number (4 pieces) from becoming normal.

Next, the ordinary electric open lottery executed in the high frequency support mode will be described. The main side ROM 64 (FIG. 12) stores a high-frequency winning determination value table T2 in which the winning determination values targeted for the general electric opening winning are recorded in the general electric opening lottery executed in the high frequency support mode. ing. FIG. 14B is a high-frequency winning determination value table T2.

As shown in FIG. 14B, the winning determination value of the ordinary electric open lottery executed in the high frequency support mode is set to (m to m+2). Here, the variable m is a natural number of 1 to 65501. The probability of winning the Hoden opening is approximately 3/5 in the Hoden opening lottery executed in the high-frequency support mode. Further, the universal figure fluctuation time in the high frequency support mode is set to 0.5 sec in order to expedite the digestion of the universal figure pending information.

The opening mode of the general electric utility object 34a when the general electric opening is won in the low frequency support mode is the same as the opening mode of the general electric object 34a when the general electric opening is won in the high frequency support mode. .. Specifically, a series of opening/closing operations in which the universal electric accessory 34a is in the open state for 1 sec and is in the closed state for 1 sec is repeated five times, triggered by one universal power release win. Further, in the low frequency support mode, the minimum securing time required for performing the next ordinary electric train opening lottery after one ordinary electric train opening lottery is performed (that is, one time in the universal map display unit 38a). The display duration) is set to the same length as the securing time in the high frequency support mode.

During the non-winning continuous period in the low-frequency support mode, the general electric open winning is basically not generated in the general electric open lottery that is triggered by the winning of the first through gate 35. On the other hand, even in the non-winning continuous period in the low frequency support mode, a prize may be won in the second through gate 39 without the adjusting mechanism 180 above. In this case, in the ordinary electric open lottery that is triggered by the winning of the second through gate 39, the ordinary electric open prize is won with a low probability (approximately 1/42). In the non-winning continuous period in the low frequency support mode, both the winning of the game ball B1 in the first operating opening 33 and the winning of the second operating opening 34 can occur. In the non-winning continuous period in the low-frequency support mode, it is unlikely that the opening/closing operation of the universal electric accessory 34a will be executed due to the universal electric open winning, so that the probability of winning the first operating opening 33 is high. This is higher than the probability that a prize will be awarded to the second operating port 34.

In the high-frequency support mode, in the ordinary electric open lottery which is carried out upon winning the prize in the through gates 35 and 39, the ordinary electric open prize is won with a high probability (approximately 3/5). Here, the interval at which the game ball B1 is fired from the game ball firing mechanism 27 (FIG. 2) is 0.6 sec at the shortest. On the other hand, the interval at which the game ball B1 is discharged from the adjusting mechanism 180 toward the first through gate 35 is 1 sec at the shortest. Therefore, in the high-frequency support mode, it is more advantageous for the player to aim at the second through gate 39 than to aim at the first through gate 35.

In the high frequency support mode, both the winning of the game ball B1 in the first operating port 33 and the winning of the second operating port 34 can occur. In the high-frequency support mode, since the normal electric power open win occurs and the general electric power accessory 34a is opened/closed frequently, the second operational opening is more likely to win than the first operational opening 33. There is a higher possibility that a prize for 34 will occur. Since a predetermined number of game balls B1 are paid out upon the winning of the second operation opening 34, the player can play the game in the high frequency support mode while not reducing the number of balls he/she holds.

In the case of continuous winning periods in the low-frequency support mode, the ordinary electric open winning is successively generated with a high probability in the ordinary electric open lottery that is carried out when the first through gate 35 is won. For this reason, the opening and closing operation of the universal electric accessory 34a is executed more frequently, and during the winning continuous period in the low frequency support mode, the winning of the game ball B1 to the first operating port 33 and the second operating port 34 are won. Both winning and winning can occur.

In the case of continuous winning in the low-frequency support mode, the interval at which the ordinary electric open winning continuously occurs is 1 sec at the shortest, and it is better to shoot the game ball B1 aiming at the first through gate 35. There is a high possibility that the normal electric open win will occur rather than launching the game ball B1 aiming at the through gate 39. Therefore, during the winning continuous period in the low frequency support mode, aiming at the first through gate 35 is more advantageous to the player than aiming at the second through gate 39.

The possibility of launching the game ball B1 aiming at the first through-gate 35 in the continuous winning period of the low frequency support mode and performing the ordinary electric open lottery to become the ordinary electric open winning is the highest in the high frequency support mode. There is a higher possibility that the game ball B1 is fired aiming at the 2 through gate 39, and the ordinary electric open lottery is carried out to become the ordinary electric open victory. Further, as described above, the opening mode of the general electric utility object 34a when the general electric open item is won in the low frequency support mode is the same as the general electric object object 34a when the general electric object is elected in the high frequency support mode. It is the same as the opening mode of. For this reason, in the low frequency support mode, when the winning continuous period is reached, it is temporarily more likely than in the high frequency support mode to win the second operating port 34.

The winning continuation period is set in the low-frequency support mode in which the player's expectation for winning in the second working opening 34 is low, and the timing of transition from the non-winning continuous period to the winning continuation period in the low-frequency support mode is the game. It is a configuration that is not notified to the person. Therefore, in the non-winning continuous period of the low frequency support mode, the player aims at the first through gate 35 to perform the shooting operation of the game ball B1 while expecting to shift to the continuous winning period.

In the case of a pachinko machine that does not generate a continuous winning period, the probability of being a universal open prize in the low frequency support mode is lower than the possibility of being a universal open prize in the high frequency support mode. For this reason, the player's expectation of winning the universal communication open prize is lower in the low frequency support mode than in the high frequency support mode.

On the other hand, like the pachinko machine 10, in the non-winning continuous period of the low-frequency support mode, the initial value of the universal electric accessory release counter C4 is changed to shift to the winning continuous period. As a result, it is possible to make the player expect that the low-frequency support mode may shift to a winning continuous period in which there is a higher possibility of being a normal electric open prize than the high-frequency support mode. Then, by not providing the player with the transition timing from the non-winning continuous period to the winning continuous period, the player can always have the expectation that the transition to the winning continuous period may occur. it can.

For this reason, while maintaining a state in which the probability of becoming a general electric open winning in the low frequency support mode combining the non-winning continuous period and the continuous winning period is lower than the possibility of becoming a general electric open winning in the high frequency support mode , It is possible to increase the player's expectation of winning the universal call opening in the low frequency support mode.

It should be noted that the configuration for increasing the frequency of being in the normal power open state per unit time in the high frequency support mode is higher than that in the low frequency support mode is not limited to the above. Here, the low frequency support mode is a low frequency support mode in which the non-winning continuous period and the winning continuous period are combined. For example, a securing time that is secured when the next ordinary electric train open lottery is performed after one ordinary electric train open lottery is performed (for example, executed on the universal map display portion 38a based on winning in the through gates 35, 39) In a configuration in which multiple types of variable display time) are prepared, the high-frequency support mode is set so that a shorter securing time is easier to select or an average securing time is shorter than in the low-frequency support mode. May be. In addition, the number of times of opening is increased, the time of opening is increased, and the securing time that is secured when the next ordinary electric train opening lottery is held is shortened. The advantage of the high-frequency support mode over the low-frequency support mode may be increased by applying any one condition or an arbitrary combination of conditions of shortening the average time and increasing the winning probability.

Here, the winning continuous period and the non-winning continuous period that occur during the low frequency support mode will be described based on FIGS. 15(a) to (c) and FIGS. 16(a) to (d). First, in the comparative pachinko machine in which the winning continuous period and the non-winning continuous period do not occur, the timing of the normal electric open winning will be described based on the time charts of FIGS. FIG. 15(a) shows the timing at which a prize may be paid to the through gates 35, 39 in the comparative pachinko machine, and FIG. 15(b) is a numerical value updated in the general electric accessory release counter C4 of the comparative pachinko machine. The information (random number for opening) indicates a winning target period during which the winning judgment value is a target of the general electric opening winning, and FIG. 15C shows a timing at which the general electric pachinko machine can generate the general electric opening winning.

Here, in the pachinko machine 10 of the present embodiment, the comparison pachinko machine is not provided with the adjusting mechanism 180 (FIG. 4) in the game board 24, and is opened by the general electric officer open counter C4. This is a pachinko machine with a configuration in which the initial value of the for-use random number is not updated. Further, at the timings t1 to t6 shown in FIGS. 15A to 15C, the comparative pachinko machine is in the low frequency support mode. In the comparative pachinko machine, the timing of winning the through gates 35 and 39 is random, so the timing shown in FIG. 15A is an example.

As shown in FIG. 15(a), a winning of the game ball B1 to the through gates 35 and 39 occurs at the timing of t1. However, as shown in FIG. 15B, the timing of t1 is outside the winning target period. The winning period starts at the timing of t2 after the timing of t1. For this reason, even if the random number for opening is acquired triggered by the winning that is generated at the timing of t1 and the ordinary electric open lottery is performed using the random number for opening, the result is out of scope.

As shown in FIG. 15B, when the next winning target period starts at the timing of t3, which is after the timing of t2, the winning target period continues for 24 msec. As shown in FIG. 15(a), when a prize is awarded to the through gates 35 and 39 of the game ball B1 at the timing of t4 which is within the winning target period, the winning is generated at the timing of the relevant t4. A random number is obtained. Then, as shown in FIG. 15C, the ordinary electric open lottery is performed in the ordinary electric open lottery performed by using the opening random number acquired at the timing of t4.

As shown in FIG. 15B, at the timing of t5, which is 1 sec after the timing of t3, the next winning target period that continues for 24 msec is started. Then, as shown in FIG. 15A, at the timing of t6 after the end of the winning target period, a prize is generated in the through gates 35 and 39 of the game ball B1, and a random number for opening is acquired. As shown in FIG. 15C, the ordinary electric open lottery performed using the random number for opening acquired at the timing of t6 has a failure result.

In this way, in the pachinko machine for comparison, in which the game board 24 is not provided with the adjusting mechanism 180 and the initial value of the opening random number is not updated, the winning of the game ball B1 to the through gates 35 and 39 is won. The timing of occurrence is random, and only when the timing of the prize winning coincides with the winning target period that starts at a cycle of 1 sec, the regular electric open prize is won. Therefore, in the comparative pachinko machine, the winning continuous period and the non-winning continuous period do not occur.

Next, in the pachinko machine 10 of the present embodiment, the timing at which the universal electric open win occurs will be described based on the time charts of FIGS. 16(a) to 16(d). FIG. 16(a) shows a timing at which a winning of the game ball B1 to the first through gate 35 may occur, and FIG. 16(b) shows numerical information (random number for opening) updated in the universal electric accessory release counter C4. Shows the winning target period which is the winning judgment value which is the target of the general electric open prize, and FIG. 16C shows the initial value update timing of the numerical information (random number for opening) updated by the general electric opener counter C4. FIG. 16D shows the timing at which the universal electric open win can occur. At timings t1 to t12 shown in FIGS. 16A to 16D, the pachinko machine 10 is in the low frequency support mode.

As shown in FIG. 16B, the winning target period starts at the timing of t1, and the winning target period continues for 24 msec. As shown in FIG. 16(a), the timing of t2 when the winning of the first through gate 35 occurs starts at the timing of t3 which is started at the timing of t1 and the timing of t3 which is 1 sec after the timing of t1. It is located between the next winning period and the timing outside the winning period. For this reason, even if a prize is awarded to the first through gate 35 at the timing of t2, the ordinary electric open prize is not obtained.

As described above, the interval at which the game ball B1 can be discharged from the adjusting mechanism 180 toward the first through gate 35 is 1 sec. As shown in FIG. 16A, the timing of t4 at which the winning of the first through gate 35 may occur after the timing of t2 is 1 sec after the timing of t2. As shown in FIG. 16B, the timing t4 is outside the winning target period. For this reason, as shown in FIG. 16D, even if a prize is awarded to the first through gate 35 at the timing of t4, the ordinary electric open prize is not obtained.

The period in which the first through gate 35 can be won and the period in which the winning target period occurs are the same period. Therefore, when the timing at which the winning of the first through gate 35 may occur is out of the winning target period, it is a non-winning continuous period in which the result of losing in the ordinary electric lottery is continuous.

As shown in FIG. 16C, at the timing of t5, the initial value of the universal electric accessory release counter C4 is updated. When the initial value of the general electric accessory release counter C4 is updated, the timing at which the first through gate 35 can be won may be deviated and the winning target period may overlap. In this case, as shown in FIG. 16B, the winning target period starts at the timing of t6, which is after the timing of t5. Then, as shown in FIG. 16A, at the timing of t7, which is within the winning target period, a winning is generated in the first through gate 35, and a random number for opening is acquired. As shown in FIG. 16D, when the universal electric open lottery is executed by using the opening random number acquired at the timing of t7, the ordinary electric open lottery becomes the ordinary electric open prize.

As shown in FIG. 16B, the winning target period is started again at the timing of t8, which is 1 sec after the timing of t6. Further, as shown in FIG. 16A, at the timing of t9, which is 1 sec after the timing of t7, a prize is generated in the first through gate 35, and a random number for opening is acquired. As shown in FIG. 16(d), in the general electric open lottery performed using the random number for opening acquired at the timing of t9, the general electric open winning is generated. In this way, once the timing at which the prize can be won in the first through gate 35 overlaps with the winning target period, the winning continuous period occurs in which the ordinary electric open winning occurs continuously in the ordinary electric lottery.

After that, as shown in FIG. 16C, at the timing of t10, the initial value of the universal electric accessory release counter C4 is updated again. As a result, the timing at which the first through gate 35 can be won is deviated from the winning target period. As shown in FIG. 16A, at the timing of t11, which is later than the timing of t10, a winning is generated in the first through gate 35, and the opening random number is acquired. As shown in FIG. 16B, the timing of t11 is outside the winning target period, and the next winning target period is started at the timing of t12, which is after the timing of t11. Therefore, as shown in FIG. 16(d), if the normal electric open lottery is executed using the open random number acquired at the timing of t11, the result is a loss. In this way, if the timing at which the winning of the first through gate 35 can be won is deviated from the winning target period by updating the initial value of the ordinary electric utility article opening counter C4, the non-winning result in which the result of deviating in the ordinary electric open lottery is continuous. Return to the continuous period.

As shown in FIG. 12, in the main RAM 65, a send-off flag that enables execution of the send-off of the initial value update in the general electric accessory release counter C4 by setting “1” at the start timing of the winning continuous period. 65d, a send-off completion flag 65e that is set to "1" when it is in the winning continuation period and during the winning continuation period that the initial value update in the ordinary electric material open counter C4 has already been sent off And are provided.

In the pachinko machine 10, when the winning consecutive period is reached, the initial value update of the general electric utility product release counter C4 is postponed once at the initial value update timing of the general electric utility object release counter C4 which first comes to the end. It is composed. By frequently updating the initial value of the general electric utility article release counter C4, it is possible to increase the possibility of becoming a continuous winning period in the non-winning consecutive period, and when the continuous winning period is reached, By delaying the initial value update, the winning continuous period is continued for a long time. As a result, the generation of the winning continuous period can be made attractive to the player. By making the occurrence of the winning continuous period an event that the player expects, the interest of the game can be improved.

Next, the winning random number counter C1 will be described. The hit random number counter C1 is configured to be incremented by 1 in order within a range of 0 to 599, for example, and returns to "0" after reaching the maximum value. In particular, when the hit random number counter C1 makes one round, the value of the random number initial value counter CINI at that time is read as the initial value of the hit random number counter C1. The random number initial value counter CINI is a loop counter similar to the random number counter C1 (value=0 to 599). The hit random number counter C1 is regularly updated and is stored in the reserved storage area 65a of the main RAM 65 at the timing when the game ball B1 wins the first operation opening 33 or the second operation opening 34.

The value of the random number that wins the jackpot is stored in the main ROM 64 as a win/loss table. As the win/loss table, a win/loss table for the low probability mode and a win/loss 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 win/loss lottery means.

In the gaming state in which the win/loss table for the low-probability mode is referred to in the lottery, the number of random numbers that is a big hit is two. On the other hand, in the gaming state in which the high probability mode win/loss table is referred to in the above-mentioned lottery, the number of random numbers to be a big win 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 configured to be sequentially incremented by 1 within the range of 0 to 29, and returned to "0" after reaching the maximum value. The jackpot type counter C2 is regularly updated, and is stored in the reserved storage area 65a at the timing when the game ball B1 wins the first operating opening 33 or the second operating opening 34.

In this pachinko machine 10, a plurality of jackpot results are set. These plural jackpot results are (1) a mode of the opening/closing control of the special electric prize winning device 32 in the opening/closing execution mode, (2) a lottery mode in the winning/losing lottery means after the opening/closing execution mode, and (3) A plurality of jackpot results are set by differentiating the three conditions of the support mode of the universal electric accessory 34a of the 2 working port 34.

As an aspect of the opening/closing control of the special electric prize winning device 32 in the opening/closing execution mode, the high frequency is set so that the frequency of winning the special electric 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 either the high frequency winning mode or the low frequency winning mode, the round game of a predetermined number of times is executed as an upper limit.

Here, the round game, until either one of the conditions that a predetermined upper limit duration elapses and that a predetermined upper limit number of game balls B1 wins the special electric prize winning device 32 is satisfied. It is a game that continues. Further, the number of round games in the opening/closing execution mode triggered by the jackpot result is the same as the fixed round number regardless of the type of jackpot result triggered by the transition. Specifically, no matter which jackpot result is obtained, the upper limit number of round games is set to 15 rounds.

In addition, in the pachinko machine 10, a plurality of types of opening mode of the special electric prize winning device 32 are set with different open durations from the opening of the special electric winning device 32 to the closing. Specifically, a long time mode in which the open duration is set to 29 sec, which is a long time, and a short time mode in which the open duration is set to 0.06 sec, which is a short time shorter than the above long time, are set. Has been done.

In the pachinko machine 10, when the firing operation device 28 is operated by the player, the game ball launching mechanism 27 is driven so that one game ball B1 is launched toward the game area PA in 0.6 sec. Controlled. Further, the upper limit number of end conditions for the round game is set to nine. Then, in the long-time mode among the above-mentioned open modes, the open duration time that is longer than the product of the firing cycle of the game ball B1 and one round game is set. On the other hand, in the short time mode, the opening duration is set to a time shorter than the product of the firing cycle of the game ball B1 and one round game, more specifically, a duration shorter than the firing cycle of the game ball B1. There is. Therefore, when the opening is performed once in the long time mode, it is expected that the special electric prize winning device 32 will be won by the upper limit number in one round game. It is expected that if the special opening award device 32 is opened once, no prize is won in the special electric prize winning device 32, or even if a prize is won, the number is one.

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

In addition, the number of times of opening and closing the special electric prize winning 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 the higher frequency winning mode. Is not limited to the above value as long as the frequency of winning the special electric prize winning device 32 from the start to the end of the opening/closing execution mode is higher than that in the low frequency winning mode. Is.

The distribution destination of the game result for the jackpot type counter C2 is stored in the main ROM 64 as a distribution table. Then, as the distribution destination, a low-probability jackpot result, a low winning high-probability jackpot result, and a most advantageous jackpot result are set.

The low-probability 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/winning 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-accuracy jackpot result is a big hit result in which the opening/closing execution mode becomes the low frequency winning mode, and after the opening/closing execution mode ends, the win/loss 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 winning/winning lottery is a big hit state winning and the big hit state is brought about.

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/winning 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 winning/winning lottery is a big hit state winning and the big hit state is brought about.

Note that the normal game state in relation to each of the above-mentioned game states means not the open/close execution mode but the winning/winning lottery mode is the low probability mode and the support mode is the low frequency support mode. In addition, as a game result, a low winning high probability jackpot result may not be set. Further, in the opening/closing execution mode in the low winning high-probability jackpot result, the number of round games may be smaller than that in the low-probability jackpot result and the most advantageous jackpot result.

In the distribution table, "0-9" of the values of the jackpot type counter C2 of "0-29" correspond to the low-probability jackpot result, and "10-14" correspond to the low winning high-probability jackpot result. "15-29" corresponds to the most advantageous jackpot result.

Next, the reach random number counter C3 will be described. The reach random number counter C3 is configured to be sequentially incremented by 1 within a range of 0 to 238, for example, and returned 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 is provided with a symbol display device 41 capable of performing variable display of symbols, and in a game machine in which a final stop result is a given response result in a game time that is a predetermined jackpot result, the symbol display device 41 The display state for making the player think that the variation display state is likely to be the above-mentioned assignment correspondence result in the stage before the stop result is derived and displayed after the variable display of the symbol is started. In addition, as for the assignment correspondence result, specifically, a combination of symbols having the same number is stopped and displayed on any of the activated lines.

Two types of expected display are set: a reach display and a notice display for expecting the occurrence of the reach display or the result of the assignment response in a stage before the reach display occurs.

In the reach display, the symbols are stopped and displayed for a part of the symbol columns displayed on the display surface 41a of the symbol display device 41, thereby displaying the combination of the reach symbols, and the remaining symbols are displayed in that state. A display state in which a variable display of symbols is performed in the symbol column is included. Moreover, while displaying the combination of reach symbols as described above, while performing variable display of the symbols in the remaining symbol columns, and by performing a reach effect by displaying a predetermined character or the like as a moving image on the background screen, , Which includes reducing or displaying a combination of reach patterns and displaying a predetermined character or the like as a moving image on substantially the entire display surface 41a to perform a reach effect.

In the notice display, after the variable display of the symbols is started on the display surface 41a of the symbol display device 41, the symbols are variably displayed in all the symbol columns, or some symbol columns are plural. In the situation where the symbols are variably displayed in the symbol column, a mode in which the character is displayed separately from the symbols on the symbol column is included. Further, it also includes a background screen having a predetermined mode different from the previous modes, and a pattern on the symbol row having a predetermined mode different from the previous modes. Such advance notice display can occur at both game times when the reach display is performed and when the reach display is not performed, but the reach display is higher than the case where the reach display is not performed. It is set to occur with a probability.

Reach display is executed irrespective of the value of the reach random number counter C3 at the game time when the same symbol combination is finally stopped and displayed. Further, in the game times corresponding to the jackpot result in which the same symbol combination is not stopped and displayed, it is not executed regardless of the value of the reach random number counter C3. Further, in the game times corresponding to the out-of-coupling result, it is executed when the reach random number counter C3 obtained at a predetermined timing by referring to the reach table stored in the main ROM 64 corresponds to the occurrence of the reach display. ..

On the other hand, the decision as to whether or not to display the advance notice is made in the sound emission control device 81, not in the main control device 60. In this case, the voice emission control device 81 is more likely to give a notice display in the game times corresponding to any of the jackpot results than in the game times corresponding to the miss result, and to give a notice display with a low appearance rate. The lottery process for displaying the advance notice is executed so as to satisfy at least one of the conditions that is likely to occur. By the way, this lottery result is reflected when the effect for game use is executed on the symbol display device 41.

Next, the fluctuation type counter CS will be described. The variation type counter CS is configured to be incremented by 1 in the range of 0 to 198, for example, and return to "0" after reaching the maximum value. The fluctuation type counter CS is used when the main CPU 63 determines the display duration of the special figure display portion 37a and the display duration of the symbol on the symbol display device 41. The variation type counter CS is updated once every time a normal process described below is executed once, and is repeatedly updated within the remaining time in the normal process. Then, the buffer value of the variation type counter CS is acquired when the variation display is determined on the special figure display unit 37a and when the variation display of the symbol is started by the symbol display device 41 when the variation pattern is determined.

<Regarding the processing configuration of the main CPU 63>
Next, each process executed by the main CPU 63 for advancing a game will be described. The processes of the main CPU 63 are roughly classified into a main process that is started when the power is turned on and a timer interrupt process that is started regularly (in this embodiment, at a cycle of 4 msec).

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

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

After that, it is determined whether or not the RAM erase switch provided in the power/launch control device 78 is manually operated (step S104), and whether or not the power failure flag of the main RAM 65 is set to "1" is determined. The determination is made (step S105). In addition, a checksum calculation process for calculating a checksum is executed (step S106), and it is determined whether or not the checksum matches the checksum saved at the time of power-off, that is, the validity of the stored and held data ( Step S107).

In the pachinko machine 10, when the RAM data is initialized when the power is turned on, for example, when the game hall is opened, the power is turned on while pressing the RAM erase switch. Therefore, if the RAM erase switch is pressed, the process proceeds to step S108. Also, when the power-off occurrence information is not set, or when an abnormality in the stored and held data is confirmed by the checksum, the process similarly proceeds to step S108. In step S108, the main RAM 65 is cleared. Then, it progresses to step S109.

On the other hand, if the RAM erase switch is not pressed, the power failure flag is set to "1" and the checksum is normal, and the process of step S108 is not executed, and step S109 is performed. Proceed to. In step S109, power-on setting processing 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 game state is transmitted to the voice emission control device 81. Further, after the processing of step S109 is executed, the recognition processing for causing the management IC 66 to recognize various information (step S110), and the data output for outputting various data to the reading device connected to the MPU 62. The process is executed (step S111). Details of the recognition process and the data output process will be described later.

Although the main CPU 63 is configured to periodically execute the timer interrupt process, the generation of the timer interrupt process is prohibited at the stage when the main process is started. The state in which the generation of the timer interrupt process is prohibited is released 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 the operating power to the main CPU 63 is started, the data output process of step S111 ends, and the timer interrupt process is not executed until the stage before the process of step S112 is started. Therefore, the processing for advancing the game in the main CPU 63 is not started until the situation is reached.

After that, the process proceeds to the residual process of steps S112 to S115. That is, the main CPU 63 is configured to periodically execute the timer interrupt process, but there is a remaining time between one timer interrupt process and the next timer interrupt process. This remaining time will vary depending on the processing completion time of each timer interrupt processing, but the remaining processing of steps S112 to S115 is repeatedly executed using this irregular time. In this respect, it can be said that the residual process of steps S112 to S115 is an irregular process that is irregularly executed.

In the residual processing, first, in step S112, interrupt prohibition is set in order to prohibit the occurrence of timer interrupt processing. In a succeeding step S113, a random number initial value updating process for updating the random number initial value counter CINI and the opening initial value counter C5 is executed, and a variation counter updating process for updating the fluctuation type counter CS is executed in step S114. To do. In these updating processes, the current numerical value information is read from the corresponding counter of the main RAM 65, the process of adding 1 to the read numerical value information is performed, and then the process of overwriting the counter of the reading source is executed. In this case, when the counter value reaches the maximum value, it is cleared to "0". After that, in step S115, the setting of interrupt permission for switching from the state in which the generation of the timer interrupt process is prohibited to the state in which the timer interrupt processing is permitted is performed. After executing the process of step S115, the process returns to step S112, and the processes of steps S112 to S115 are repeated.

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

First, a power failure information storage process is executed (step S201). In the power failure information storage processing, it is monitored whether or not a power failure signal corresponding to the occurrence of the power cutoff is received from the power failure monitoring board 67, and if the occurrence of the power failure is identified, the power failure processing is executed and an infinite loop is executed. Become. In the power failure process, the power failure flag of the main RAM 65 is set to "1", the checksum is calculated, and the calculated checksum is saved.

After that, the random number for lottery updating process is executed (step S202). In the random number updating process for lottery, the winning random number counter C1, the big hit type counter C2, and the reach random number counter C3 are updated. Specifically, after the current numerical value information is sequentially read from the hit random number counter C1, the big hit type counter C2, and the reach random number counter C3, and the read numerical value information is incremented by 1, the reading source counter Execute the overwrite process. In this case, when the counter value reaches the maximum value, it is cleared to "0".

After step S202, in step S203, the opening counter updating process is executed to update the universal electric accessory opening counter C4 (FIG. 13). Details of the release counter updating process will be described later. Thereafter, in step S204, a random number initial value updating process for updating the random number initial value counter CINI and the opening initial value counter C5 (FIG. 13) is executed as in step S113, and in step S205, as in step S114. The fluctuation counter updating process is executed.

The universal electric utility article release counter C4 is a loop counter, and the open counter updating process for updating the universal electric body accessory release counter C4 is periodically executed. For this reason, the initial value update timing of the universal electric utility article release counter C4, which occurs when the universal electric accessory release counter C4 makes one round, periodically occurs.

Here, when the opening initial value counter C5 for updating the initial value of the ordinary electric utility article opening counter C4 is a loop counter and the updating of the opening initial value counter C5 is regularly executed, The numerical value information acquired as the initial value from the opening initial value counter C5 at the initial value update timing of the electrical equipment opening counter C4 is limited to a part of the numerical value information updated by the opening initial value counter C5. ..

In this case, the generation timing of the winning continuous period in the low frequency support mode described above does not become random. There is no overlap between the winning period and the winning timing, and there is no continuous winning period, there is a frequent overlap between the winning period and the winning timing, and there are frequent winning periods, and there are regular winning periods. In this case, the player may easily guess the timing of occurrence of the winning continuous period.

On the other hand, the pachinko machine 10 performs the random number initial value updating process for updating the opening initial value counter C5 both in the regular timer interrupt process and in the aperiodic residual process of the main process. It is a configuration to be executed in. Therefore, the winning period and the possible winning timing overlap with each other at an appropriate frequency. As a result, in the low-frequency support mode that combines the non-winning continuous period and the continuous winning period, the probability that the general electric open win will occur is lower than the probability that the general electric open win will occur in the high-frequency support mode. It is possible to generate a continuous winning period.

Returning to the description of FIG. 18, after performing the fluctuation counter updating process in step S205, in step S206, a rotation control process for rotating the rotating body 183 once for 4 seconds is executed. In the rotation control process, it is determined whether it is the timing to rotate the output shaft 184a of the adjustment drive unit 184 that is in communication with the rotating body 183. If it is the timing to rotate the output shaft 184a, the adjustment is performed. A pulse signal is transmitted to the driving unit 184 to rotate the output shaft 184a. In this rotation control process, a pulse signal for rotating the output shaft 184a of the adjustment drive unit 184 by 0.72° is transmitted once every 8 msec. That is, in the timer interrupt process executed in the cycle of 4 msec, the adjustment drive unit 184 is driven by transmitting the pulse signal once every two times.

Then, the fraud detection process of monitoring whether or not a predetermined event set as a fraudulent monitoring target has occurred is executed (step S207). In the fraud detection process, the occurrence of a plurality of types of events is monitored, and by confirming that a predetermined event has occurred, the game stop flag provided in the main RAM 65 is set to "1". In a succeeding step S208, it is determined whether or not the game is stopped by determining whether or not "1" is set in the game stop flag. When a negative determination is made in step S208, the processing from step S209 is executed.

In step S209, port output processing is executed. In the port output process, when the output information is set in the previous timer interrupt process, a process for outputting the various drive units 32b and 34b corresponding to the output information 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 the information for switching to the closed state is set. Stops the output of the drive signal. Further, when the information for switching the universal electric accessory 34a of the second operation port 34 to the open state is set, the output of the drive signal to the drive unit 34b for the general electric power is started to switch to the closed state. When the information is set, the output of the drive signal is stopped.

Then, the reading process is executed (step S210). 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 processes.

After that, the ball detection processing is executed (step S211). In the entrance detecting process, the signals received from the entrance detecting sensors 42a to 50a are read, and based on the read results, the outlet 24a, the general winning opening 31, the special electricity winning device 32, and the first operating opening 33. The presence or absence of a ball entering the second operating port 34, the first through gate 35, and the second through gate 39 is specified. The details of the ball detection process will be described later.

After that, the timer updating process for collectively updating the numerical information of the plurality of types of timer counters provided in the main RAM 65 is executed (step S212). In this case, the configuration is such that the timer counters that are updated by subtracting the stored numerical information are handled collectively, but both the subtraction-type timer counter update and the addition-type timer counter update are performed collectively. It may be configured.

Then, the firing control process for controlling the firing of the game ball B1 is executed (step S213). In the situation where the firing operation to the firing operation device 28 is continued, one game ball B1 is fired at a predetermined firing cycle of 0.6 sec. In the following step S214, as input state monitoring processing, based on the information read in the reading processing of step S210, disconnection confirmation of each of the ball detection sensors 42a-50a and opening confirmation of the gaming machine main body 12 and the front door frame 14 are performed. I do.

After that, the special figure special electric power control processing for executing the execution control of the game times and the execution control of the opening/closing execution mode is executed (step S215). In the special figure special electric power control process, when a prize is generated in the first working opening 33 or the second working opening 34 in a situation where the number of holding information stored in the holding storage area 65a is less than the upper limit number, A process of sequentially storing the numerical information of the hit random number counter C1, the big hit type counter C2, and the reach random number counter C3 as pending information in the pending storage area 65a is performed.

Here, when the period during which the opening/closing operation of the general electric accessory 34a is being performed is the support execution period, if a winning is generated in the second working port 34 during the support execution period, the during-support prize counter is displayed. A process of adding "1" is performed. Then, when the value of the in-support winning counter reaches the upper limit number of winnings set in the support execution period, "1" is set to the support end flag. Here, the in-support prize counter is a counter that the main CPU 63 refers to in order to grasp the total number of times of winning to the second operation port 34 that occurred during the support execution period, and is provided in the main RAM 65. There is. The in-support prize counter is cleared to "0" at the start timing of the support execution period. Further, the support end flag is referred to in order for the main CPU 63 to refer to the fact that the number of winnings to the second operation port 34 that has occurred during the support execution period has reached the upper limit number, and the end timing of the support execution period has come. It is a flag and is provided in the main RAM 65.

In the special figure special electric control process, whether or not the hold information corresponds to the jackpot win, provided that the hold information is not stored during the game turn and the opening/closing execution mode and the hold information is stored, In addition, when the jackpot winning is supported, the distribution determination processing for determining which jackpot result the holding information corresponds to is executed.

Here, in the win determination process, when the jackpot is won, the high frequency flag is set to "1". The high-frequency flag is a flag that is set to "1" when the support mode for winning a prize for the second operating port 34 is the high-frequency support mode. The main CPU 63 refers to the high-frequency flag to specify whether the support mode for winning in the second operating port 34 is the high-frequency support mode or the low-frequency support mode. As already described, when the jackpot result is obtained, the support mode becomes the high-frequency support mode after the opening/closing execution mode ends, regardless of which jackpot.

In the special figure special electric control process, not only the winning/disabling judgment process and the sorting judgment process, but also when the holding information does not correspond to the jackpot winning, it is determined whether the holding information corresponds to the reach occurrence. The reach determination process is executed, and the process of selecting the duration of the game time is executed by using the numerical value information of the fluctuation type counter CS at that time. Then, the variation command including the information of the duration time corresponding to the result of each of the processes, and the type command including the information of the game result are transmitted to the sound emission control device 81, and the pattern in the special figure display unit 37a is displayed. Start variable display. Upon receiving the variation command and the type command, the voice emission control device 81 causes the display light emitting unit 53 and the speaker unit 54 to start the game use effect corresponding to the contents of these commands. Further, the voice emission control device 81 transmits a variation pattern command corresponding to the contents of the variation command and the type command to the display control device 82. By receiving the variation pattern command, the display control device 82 causes the symbol display device 41 to start 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, 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, whether or not it is the end timing of the game time. To judge. If it is the ending timing, the process for ending the game number is executed in a state where the display corresponding to the game result is displayed. In this case, when the game number of this 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 portion 37a, In the case where the game times correspond to the miss result, the picture corresponding to the miss result is stopped and displayed on the special figure display portion 37a. In addition, a final stop command indicating that the game time should be ended is transmitted to the voice emission control device 81. Upon receiving the final stop command, the voice emission control device 81 ends the effect for the current game play in the display light emitting unit 53 and the speaker unit 54. Further, the voice emission control device 81 transmits a final stop command to the display control device 82. By receiving the final stop command, the display control device 82 ends the effect for the current game in 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 open/close execution mode, a process for starting the open/close execution mode is executed. At the time of this start, an opening command indicating that the opening/closing execution mode is started is transmitted to the sound emission control device 81. Further, 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 electric prize winning device 32 is opened, and when the round game is finished, the special electric prize winning device 32 is closed. In each of these processes, an opening command indicating that the round game is started is transmitted to the sound emission control device 81, and a closing command indicating that the round game is ended is transmitted to the sound emission control device 81. In addition, in the special figure special power control process, when ending the opening/closing execution mode, 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 the effect for the open/close execution mode in a manner corresponding to various commands received during the open/close execution mode. Further, the sound emission control device 81 transmits a command corresponding to the command received during the open/close execution mode to the display control device 82. The display control device 82 causes the symbol display device 41 to execute the effect for the opening/closing execution mode in a manner corresponding to various commands received during the opening/closing execution mode. In addition, in the special figure special electric power control process, when the opening/closing execution mode is ended, the win/loss lottery mode and the support mode after the end of the opening/closing execution mode correspond to the types of the jackpot results that trigger the execution of the opening/closing execution mode. Perform the process to set the mode.

Specifically, when the type of jackpot result is a low-probability jackpot, "100" is set in the game number counter as the end criterion of the high frequency support mode. The game number counter is a counter for the main CPU 63 to specify whether or not the end reference number of game times has been exhausted in the high frequency support mode. The numerical information set in the game number counter is updated so that "1" is subtracted based on the end of the game number. In addition, when the kind of the big hit result is a low winning high probability big hit, and when it is the most advantageous big hit result, "1" is set to the indefinite flag. The indefinite flag is a flag for continuing the high frequency support mode until the lottery result in the win/loss lottery becomes a big hit state win after the opening/closing execution mode is finished, and the big hit state is shifted accordingly. In the high-frequency support mode in which the indefinite flag is set to "1", if the generated jackpot result is a low-probability jackpot, the indefinite flag is cleared to "0" and the game number counter is "100". Is set, and when the generated big jackpot result is a low winning high probability big jackpot, and when it is the most advantageous jackpot, the indefinite flag is set to "1" again.

After the special figure special power control processing of step S215 is executed in the timer interrupt processing, the universal figure normal power control processing is executed (step S216). In the general/universal/universal electric power control processing, processing for executing the general electric power open lottery to determine whether or not to open/close the general electric power accessory 34a when a prize has been paid to the through gates 35, 39. , And a process of executing the display of the universal figure display portion 38a and the opening/closing of the universal electric accessory 34a in a mode corresponding to the result of the ordinary electric train lottery. Details of the general/universal/universal control process will be described later.

In the following step S217, based on the processing results of the immediately preceding steps S215 and S216, the output information for reflecting the increased/decreased number of the hold information related to the special figure display unit 37a in the special figure hold display unit 37b is set and The output information for reflecting the increased/decreased number of the hold information related to the universal figure display section 38a on the universal figure hold display section 38b is set. In step S217, output information for updating the display content of the special figure display portion 37a is set based on the processing results of the immediately preceding steps S215 and S216, and the display content of the general figure display portion 38a is set. Set the output information for updating.

After that, the contents of the command and the signal received from the payout control device 77 are confirmed, and the payout state receiving process for performing the process corresponding to the confirmation result is executed (step S218). Further, a payout output process for setting the prize ball command as an output target is executed (step S219). Also, the 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 timer interrupt process this time is executed (step S220). After that, the management output process for outputting the information corresponding to the entry result of the game ball B1 in the game area PA to the management IC 66 is executed (step S221). Details of the management output process will be described later.

Next, the release counter updating process executed in step S203 of the timer interrupt process (FIG. 18) will be described with reference to the flowchart of FIG. FIG. 19 is a flowchart showing the release counter updating process executed by the main CPU 63.

First, in step S301, the current numerical value information is read out from the general electric utility article opening counter C4. In step S302, is the current numerical value information read out in step S301 a value obtained by subtracting "1" from the current initial value? Determine whether or not. Here, the current initial value is numerical value information that is newly stored each time the initial value of the universal electric accessory release counter C4 is updated.

When the current numerical information is a value obtained by subtracting "1" from the current initial value (step S302: YES), this means that this time is the initial value update timing of the utility battery role release counter C4. In this case, it is determined in step S303 whether or not "1" is set in the high frequency flag. If the high-frequency flag is not set to "1" in step S303, it means that the low-frequency support mode is set. In this case, it is determined in step S304 whether or not the send-off completion flag 65e (FIG. 12) is set to "1".

As described above, the main RAM 65 (FIG. 12) includes the send-off flag 65d (FIG. 12) and the send-off completion flag 65e (FIG. 12). The send-off flag 65d is a flag that is set to "1" when the regular electric open lottery is performed in the low frequency support mode and the winning consecutive period is reached and the regular electric open winning is generated three times in a row.

In the low-frequency support mode, when the general electric open win can occur, when the second through gate 39 wins during the non-winning consecutive period, the first through gate 35 wins during the winning consecutive period. In some cases, and during the winning period, a prize may be awarded to the second through gate 39. Of these, the probability of being a regular electric open prize when a prize is generated in the second through gate 39 is approximately 1/42 in both the non-winning continuous period and the winning continuous period.

Therefore, in the low-frequency support mode, the probability of being the regular electric open win three consecutive times is low in the regular electric lottery that is triggered by the winning of the second through gate 39 (approximately 1/74000), 3 There are almost no consecutive Open Dentsu wins. In addition, even if it happens by accident, the send-off flag 65d is cleared to "0" when the result of the miss in the next ordinary electric train open winning is a result.

On the other hand, during the continuous winning period, if the winning of the winning through the first through gate 35 is used as the opportunity for the opening of the general electric train, the general electric power is released. Therefore, when the player is operating the game ball launching device aiming at the first through gate 35, and the winning continuous period is reached, the first through gate 35 is won after the winning continuous period is reached. When it occurs three times, "1" is set to the see-off flag 65d. At the initial value update timing when the send-off flag 65d is set to "1" in the winning continuous period, the update of the initial value of the general electric auditor product release counter C4 is postponed.

Further, the send-off completion flag 65e is set to "1" when the initial value update timing is reached with the send-off flag 65d set to "1" and the update of the initial value of the universal electric accessory release counter C4 is delayed. It is a flag that is set. Here, the send-off flag 65d is a flag that is set to "1" on the condition that the low-frequency support mode is set. Therefore, in the high-frequency support mode, the send-off flag 65d is never set to "1". In the high frequency support mode, since the send-off flag 65d is not set to "1", the send-off completion flag 65e is not set to "1". The process of setting "1" in the see-off flag 65d will be described later.

When "1" is set to the send-off completion flag 65e in step S304 of the open counter updating process (FIG. 19), the initial value update of the ordinary electric utility article open counter C4 has already been sent off during the present winning continuous period. It means that it was done.

If "1" is not set in the send-off completion flag 65e in step S304, it is determined in step S305 whether or not "1" is set in the send-off flag 65d. When "1" is set to the send-off flag 65d (step S305: YES), it means that the initial value update timing of this time is the initial value update timing of the send-off target. In this case, the send-off flag 65d is cleared to "0" in step S306, and the send-off completion flag 65e is set to "1" in step S307.

After it is determined in step S302 that it is not the initial value update timing or after clearing the see-off completion flag 65e to "0" in step S307, the current numerical information is the maximum value of the utility electric utility open counter C4 in step S308. ("65505") is determined.

If the current numerical value information is not the maximum value in step S308, "1" is added to the current numerical value information in step S309 to update the numerical value information. If the current numerical information is the maximum value in step S308, the numerical information is updated by clearing the current numerical information to "0" in step S310.

When "1" is set to the send-off completion flag 65e in step S304, after the initial value update is postponed, the universal electric accessory release counter C4 makes one round and the initial value update timing comes again. Means that. In this case, the send-off completion flag 65e is cleared to "0" in step S311.

After it is determined in step S303 that the high-frequency support mode is set, in step S305 it is determined that the send-off flag 65d is not set to "1", or in step S311 the send-off completion flag 65e is cleared to "0". After that, the initial value of the general electric outlet opening counter C4 is updated. Specifically, in step S312, the current numerical information in the opening initial value counter C5 is acquired. Then, in step S313, the numerical information acquired in step S312 is overwritten on the current initial value as a new initial value to update the initial value. In this way, the winning target period is shifted by changing the initial value of the general electric accessory release counter C4. As a result, the transition from the non-winning continuous period to the winning continuous period can be generated at a timing when the player is not notified. The initial value updated in step S313 is used in step S302 to determine whether it is the initial value update timing.

In a succeeding step S314, the initial value updated in step S313 is overwritten on the universal electric accessory opening counter C4 to update the numerical information of the universal electric appliance opening counter C4, and the main opening counter updating process ends. To do.

In this way, by delaying the update of the initial value at the initial value update timing of the general electric utility product release counter C4 that first arrives after the winning continuous period, the duration of the continuous winning period is extended and the winning The continuous period can be made more attractive to the player. On the other hand, when the initial value update timing comes in the high-frequency support mode (step S303: YES), the initial value update of the universal electric accessory release counter C4 is always executed.

Next, the universal figure universal communication control process executed in step S216 of the timer interrupt process (FIG. 18) will be described with reference to the flowchart of FIG. FIG. 20 is a flowchart showing the universal figure/universal communication control process executed by the main CPU 63.

In the general/universal/universal control process, the process of acquiring the general/universal-university-side holding information is executed when a prize is paid to the through gates 35, 39, and the general-university/universal-side holding information is stored. If the holding information is used, the ordinary electric open lottery is performed, and further, the processing for performing the effect for the general figure is executed with the ordinary electric train open lottery as a trigger. Further, based on the result of the universal electric open lottery, a process of opening and closing the universal electric accessory 34a of the second operating port 34 is executed.

In the general/universal/universal control process, as shown in the flowchart of FIG. 20, first, in step S401, the general/universal-side retained information acquisition process is executed to acquire the suspended information corresponding to the winning in the through gates 35 and 39. get. Here, the reservation information acquisition process on the general map side will be described with reference to the flowchart in FIG. FIG. 21 is a flowchart showing the reservation information acquisition process on the universal figure side executed by the main CPU 63.

First, in step S501, it is determined whether or not a prize is given to the first through gate 35 of the game ball B1 by determining whether or not "1" is set in the first gate winning flag. Here, the first gate winning flag is a flag for the main CPU 63 to specify that one gaming ball B1 has entered the first through gate 35. When the first gate winning flag is set to "1", the first gate winning flag is cleared to "0" in step S502.

When "1" is not set in the first gate winning flag in step S501, the process proceeds to step S503. In step S503, it is determined whether or not a winning of the game ball B1 to the second through gate 39 has occurred by determining whether or not the second gate winning flag is set to "1". Here, the second gate winning flag is a flag for the main CPU 63 to specify that one gaming ball B1 has entered the second through gate 39.

If the second gate winning flag is not set to "1" in step S503, the present holding information acquisition processing is ended as it is, and if the second gate winning flag is set to "1", In step S504, the second gate winning flag is cleared to "0".

After the first gate winning flag is cleared to "0" in step S502, or the second gate winning flag is cleared to "0" in step S504, in step S505, the current ordinary electric power in the ordinary electric power holding area HA is set. It is determined whether or not the hold information is less than the upper limit number (4 pieces). Then, if the general-usage hold information is the upper limit number (step S505: NO), the main-hold information acquisition process is terminated as it is, and if the general-usage hold information is less than the upper limit number (step S505: YES), the step is executed. Move to S506. In step S506, the numerical information of the general electric outlet opening counter C4 is stored in the normal electric storage areas HA1 to HA4, which have the highest priority among the empty general electric storage areas HA1 to H4, and the main information is acquired. To finish.

In one process, acquisition of holding information corresponding to “1” set in the first gate winning flag and acquisition of holding information corresponding to “1” set in the second gate winning flag If both configurations are executed, the two pieces of suspension information acquired in the processing times become the same suspension information.

On the other hand, in the reserved information acquisition process on the universal figure side, if "1" is set to both the first gate winning flag and the second gate winning flag in the current process, the first gate Only the hold information corresponding to the fact that the winning flag is set to "1" is acquired. Then, the acquisition of the hold information corresponding to the setting of "1" in the second gate winning flag is executed in the next processing time.

Therefore, when the period in which the second gate winning flag is set to "1" overlaps with the period in which the first gate winning flag is set to "1", the second through gate 39 of the game ball B1. The opening random number acquired upon the winning of the prize can be different from the opening random number acquired upon the winning of the first through gate 35.

Returning to the explanation of the universal figure universal communication control process (FIG. 20), after executing the universal figure holding information acquisition process in step S401, in step S402, the information of the universal figure universal communication counter provided in the main RAM 65. Is read out, and in step S403, the processing for reading the universal figure/universal address table from the main ROM 64 is executed. Then, in step S404, a process of acquiring the start address corresponding to the information of the universal figure/universal telephone counter from the universal figure/universal telephone address table is executed.

Here, the processing contents of steps S402 to S404 will be described. As described above, the universal figure/general electric power control processing includes processing relating to the effect for universal figure and processing related to the opening/closing of the universal electric part 34a. In this case, a general figure fluctuation start process, a general figure fluctuation in-progress process, and a general figure confirmation in-progress process are set as processes related to the effect for the general figure. In addition, as the processing related to opening and closing of the general electric accessory 34a, a general electric opening processing and a general electric closing processing are set.

In such a processing configuration, the universal figure/universal phone counter is a counter for the main CPU 63 to know which of the plurality of types of processing should be executed. Is set with a start address in a program for executing the above-described plurality of types of processing in correspondence with the numerical information of the universal figure/genuine counter.

The numerical value of "0" to "4" can be set in the POUJU DENDEN counter, and the POUJU DENDEN address table is made to correspond to each numeric information of the POUJU DENDEN counter in a one-to-one correspondence. Address information (“NSA0” to “NSA4”) is set. In this case, the start address NSA0 is the start address of the program for executing the universal figure fluctuation start process, the start address NSA1 is the start address of the program for executing the universal figure fluctuation process, and the start address NSA2. Is the start address of the program for executing the universal figure confirming process, the start address NSA3 is the start address of the program for executing the universal line releasing process, and the start address NSA4 is the general address closing This is the start address of the program for executing the process.

The general/universal/general-purpose counter is used for the next general processing, triggered by the condition that the numerical information currently stored should be updated when the processing corresponding to the currently stored numerical information is completed. 1 addition, 1 subtraction, or “0” is cleared according to the processing executed in the power control processing. Therefore, in the universal/university/universal communication control process at each processing time, a process according to the numerical information set in the universal/universal/universal electric counter may be executed.

According to the above configuration, it becomes possible for the main CPU 63 to know which process is to be executed as the general/universal electric power control without checking the presence/absence of various flags. Therefore, the processing can be simplified.

Below, using the P/U/PED counter and the P/U address table, the PGD fluctuation start process, PDB changing process, PDB fixing process, PDO opening process, and PDO closing process are performed. The processing configuration for execution will be described.

Returning to the description of FIG. 20, after the process of step S404 is executed, the zero flag setting process of the universal figure side is executed in step S405. In the process of setting the zero flag on the universal figure side, the numerical information of the universal figure universal telephone timer counter is read, and when the numerical information of the universal figure universal telephone timer counter is “0”, the universal information provided in the register of the main CPU 63 is read. A process of setting "1" to the zero flag on the drawing side is executed. The universal figure/universal timer counter is a counter used by the main CPU 63 to specify the update timing of the universal figure/universal counter according to the passage of time. Numerical information corresponding to a predetermined time is obtained in step S407. The numerical information is updated by the timer updating process of step S212 in the timer interrupt process (FIG. 18) while being set in each process of step S411.

In the following step S406, a process of jumping (shifting) to the process indicated by the start address acquired in step S404 is executed. Specifically, when the acquired start address is NSA0, the process jumps to the universal figure fluctuation start process of step S407, and when the acquired start address is NSA1, the process jumps to step S408 during the universal map change process. If the acquired start address is NSA2, the process jumps to the universal figure confirming process of step S409, and if the acquired start address is NSA3, the process jumps to the universal communication open process of step S410 to acquire the acquired start address. If the address is NSA4, the process jumps to the process during step S411 for closing the universal communication. Then, after executing any one of steps S407 to S411, the general/universal figure universal communication control process is ended. The processing in steps S407 to S411 will be individually described below.

First, the universal figure variation start process (step S407) in the universal figure universal control process (FIG. 20) will be described with reference to the flowchart in FIG. FIG. 22 is a flowchart showing the universal figure fluctuation start process executed by the main CPU 63.

In the universal figure fluctuation start process, first in step S601, it is determined whether or not the high frequency support mode is set by referring to the high frequency flag provided in the main RAM 65. If the high frequency flag is set to "1" in step S601 and the high frequency support mode is set, it is determined in step S602 whether or not the indefinite flag is set to "1". As already explained, when the indefinite flag is set to "1", it is determined that the low winning high-probability jackpot or the most advantageous jackpot is won and the high-frequency support mode is entered after the opening/closing execution mode is finished. means.

When "1" is not set to the indefinite flag in step S602, it is determined in step S603 whether the value of the game number counter is "0". If the value of the game number counter is "0" in step S603, it means that the number of times of termination of the high frequency support mode has been reached. In this case, the high frequency flag is cleared to "0" in step S604. As a result, the support mode of the general electric accessory 34a shifts from the high frequency support mode to the low frequency support mode.

Here, the universal figure fluctuation start processing is the situation where the numerical information of the universal figure universal communication counter corresponds to the processing during the universal communication opening processing and the universal communication closing processing, that is, the universal communication role when the universal communication opening is elected. It is not executed during the opening/closing operation of the object 34a. Therefore, the support mode is maintained in the high-frequency support mode even if the ending reference number of game times is completed during the opening/closing operation based on the fact that the normal electric opening is won before the ending reference number of game times is completed. After the opening/closing execution operation of the general electric accessory 34a is completed, the low frequency support mode is switched to.

In a succeeding step S605, an external output setting process for canceling high frequency is executed. In the external output setting process, the data of the main RAM 65 is set so that the output of the high frequency signal from the external terminal board 97 (FIG. 2) to the game hall management computer is stopped. The high frequency signal is started to be output when the high frequency support mode is entered. Incidentally, the output stop of the high frequency signal is executed by the external information setting process of step S220 in the timer interrupt process (FIG. 18).

After a negative determination is made in step S601, an affirmative determination is made in step S602, a negative determination is made in step S603, or after the processing of step S605 is executed, in step S606, the normal image side is displayed. It is determined whether or not the total number NS of the hold information of 1 is 1 or more. Then, when the total number NS of the reservation information on the universal figure side is "0" (step S606: NO), the regular figure variation start process is ended as it is, and when it is 1 or more (step S606: YES). Advances to step S607.

In step S607, a universal electric open lottery process for determining whether or not the universal electric open prize for executing the opening/closing operation of the universal electric accessory 34a is executed, and the regular-universal-picture variation start process is ended. Here, the ordinary electric open lottery process will be described with reference to the flowchart of FIG. FIG. 23 is a flowchart showing the universal figure opening lottery process executed by the main CPU 63.

In the normal electric open lottery process, first, in step S701, the normal electric power holding area HA (FIG. 13) is shifted. In the shift process, the random number for opening stored in the first normal power saving area HA1 (FIG. 13) of the normal power holding area HA is shifted to the normal power execution area HB (FIG. 13), and after the shift, the 1. Clear the POD area HA1. Further, the second ordinary electric power holding area HA2 (FIG. 13)→the first ordinary electric power holding area HA1, the third ordinary electric power holding area HA3 (FIG. 13)→the second ordinary electric power holding area HA2, the fourth ordinary electric power holding area HA4( (Fig. 13) → The random number for opening in each area is shifted, such as the third normal communication holding area HA3.

In a succeeding step S702, it is determined whether or not the high-frequency flag is set to "1". If the high-frequency flag is set to "1" (step S702: YES), the opening/closing operation is performed in the step S703. It is determined whether or not it is in the execution mode. When a negative determination is made in step S702 or an affirmative determination is made in step S703, the process proceeds to step S704.

In step S704, the low-frequency winning determination value table T1 (FIG. 14A) is read from the main ROM 64, and in step S705, a universal figure winning/judging process (universal electric open lottery) is performed. In the normal electric open lottery, when the random number for opening stored in the normal electric power execution area HB matches one of the winning judgment values stored in the low frequency winning judgment value table T1, the ordinary electric opening win In addition, if the winning judgment value does not match any of the winning judgment values, a deviating result is obtained.

In a succeeding step S706, it is determined whether or not the result of the universal figure valid/invalid determination processing in step S705 is a universal electric open winning. When the result of the universal figure win/loss determination process is the win of the universal communication release (step S706: YES), it is determined in step S707 whether or not the high-frequency flag is set to "1". If the high-frequency flag is not set to "1" and the low-frequency support mode is set (step S707: NO), it is determined in step S708 whether or not the winning continuous flag is set to "1". To do. Here, the winning continuous flag is a flag for grasping that it is a winning continuous period in the low frequency support mode, and is provided in the main RAM 65 (FIG. 12).

The main RAM 65 is provided with a winning continuous counter for keeping track of the number of times the universal electric open winning occurs consecutively during the non-winning continuous period of the low frequency support mode. The main CPU 63 (FIG. 12) recognizes that the winning consecutive period has been reached when the value of the winning consecutive counter is “3”, and sets “1” in the winning consecutive flag.

If "1" has not been set in the winning success flag in step S708, "1" is added to the winning success counter in step S709, and the value of the winning success counter is "3" in step S710. Or not. Then, when the value of the winning continuous counter is “3” (step S710: YES), it is grasped that the winning continuous period has come.

In this case, the winning continuous counter is cleared to "0" in step S711, and the send-off flag 65d is set to "1" in step S712. As a result, at the initial value update timing of the general electric utility article release counter C4 that first comes after the present winning consecutive period occurs, the update of the initial value of the general electric utility article release counter C4 is postponed. Then, in step S713, the winning continuous flag is set to "1" to store the winning continuous period.

If the result of the universal figure win/no-judgment process (normal train open lottery) in step S705 is a miss (step S706: NO), the winning continuous counter is cleared to “0” in step S714, and the winning continuous is executed in step S715. Clear the flag to "0". For this reason, during the non-winning continuous period of the low frequency support mode, if the normal electric open winning is generated once or accidentally twice in succession due to the winning of the game ball B1 to the second through gate 39. However, it is not determined that the winning consecutive period has started.

When a negative determination is made in step S703, the high-frequency support mode is not set, and the open/close execution mode is not in progress. Therefore, in step S716, the high-frequency winning determination value table T2 (FIG. 14B) is read from the main ROM 64. ) Is read out, and in step S717, the universal figure validity determination process is performed as in step S705. In the universal figure win/no-judgment process, when the random number for release stored in the universal communication execution area HB matches any of the winning decision values stored in the high-frequency winning decision value table T2, the opening of the universal communication A winning result will result if none of the winning judgment values match.

After determining in step S707 that the high-frequency support mode is set, after determining in step S708 that the winning consecutive period has already been reached, and determining that the value of the winning consecutive counter is equal to or less than "2" in step S710 After setting the winning continuous flag to "1" in step S713, clearing the winning continuous flag to "0" in step S715, or executing the universal figure winning/judging process in step S717, and then in step S718. , The universal figure fluctuation time stored in the main ROM 64 is read. The main ROM 64 stores in advance information in which the normal figure fluctuation time is 0.5 sec.

In a succeeding step S719, the information for the universal figure variation time read in step S718 is set in the universal figure universal communication timer counter, and in step S720, processing for starting the variable display of the universal figure display unit 38a (FIG. 3) is started. To execute. Then, in step S721, "1" is added to the numeric value information of the POU/POD counter to update the numeric information of the POU/POD counter from "0" to "1". To finish.

As described above, even if the ordinary electric power open win is generated three times in a row in the high frequency support mode, "1" may be set to the send-off flag 65d at the opportunity of the three consecutive continuous electric power open wins. If it is determined that the high frequency support mode is set in step S707, the processes of steps S708 to S713 are not executed.

Next, the universal figure changing process (step S408) in the universal figure universal communication control process (FIG. 20) will be described. In the normal figure changing process, first, by referring to the zero flag, it is determined whether or not it is time to end the display on the normal figure display unit 38a. Then, if it is not the end timing of the variable display, the pattern displayed on the public figure display unit 38a is updated to the next order on the condition that the display content of the public figure display unit 38a is updated. To do. On the other hand, if it is the end timing of the variable display on the public figure display unit 38a, the pattern stop processing for displaying the final stop pattern of this time is executed on the public figure display unit 38a. In the pattern stop processing, information on the final stop time is set in the universal/universal timer counter. After the pattern stop processing is executed, the Uzu-Uden counter is updated from "1" to "2".

Next, the universal figure finalizing process (step S409) in the universal figure universal control process (FIG. 20) will be described with reference to the flowchart of FIG. In the universal figure fixing process, first, in step S801, it is determined whether or not the final stop time set in the universal figure universal call timer counter in the universal figure changing process has elapsed. Regarding the determination process, specifically, it is determined whether or not "1" is set in the zero flag.

If the final stop time has not elapsed (step S801: NO), the process for finalizing the normal figure is ended as it is, and if the final stop time has elapsed (step S801: YES), the process proceeds to step S802. Then, it is determined whether or not the result of the ordinary electric open lottery that triggered this change display is the ordinary electric open. Then, in the case of the universal communication open winning (step S802: YES), the process proceeds to step S803.

In step S803, the ordinary electric power open counter provided in the main RAM 65 is set to "5", and in step S804, the ordinary electric prize winning counter provided in the main RAM 65 is set to "10". The normal electric opening counter is a counter for the main CPU 63 to specify the remaining opening number of the general electric object 34a in the opening/closing operation of the general electric object 34a this time. This is a counter for the main CPU 63 to identify whether or not the winning number to the second operating port 34 has occurred for the upper limit number during the opening/closing operation of 34a. Then, in step S805, the currently-supported winning counter is cleared to "0", and in step S806, numerical information of the open duration time (specifically, 1 sec) is set in the universal figure/universal timer counter.

In the following step S807, "1" is added to the universal figure/universal counter to update the numerical information of the universal figure/universal counter from "2" to "3", and the general/universal figure variation start processing ends. ..

Further, in step S802, if the result of the universal electric open lottery that triggered the change display this time is not the ordinary electric power open winning, in step S808, the numerical information of the universal figure ordinary electric counter is set to "0". After clearing, the process for finalizing the general map ends.

Next, the processing for opening the universal communication (step S410) in the general/universal communication control processing (FIG. 20) will be described. In the normal electric power open processing, it is first determined whether or not it is the closing timing of the general electric member 34a, and if it is not the closing timing, the open state of the general electric member 34a is maintained. On the other hand, when it is the closing timing of the utility battery 34a, a process for bringing the utility product 34a into the closed state is executed. In this case, the value of the ordinary electric power open counter is updated to be subtracted by "1", and when the value of the ordinary electric power open counter is "0", the numerical information of the ordinary electric power generator counter is cleared to "0". Then, the opening/closing operation of the ordinary electric accessory 34a ends. If the support end flag is set to "1", it means that the number of winnings to the second operating port 34 has already reached the upper limit. In this case, the general electric open counter and the support end flag are cleared to "0", and the numerical information of the general electric figure counter is cleared to "0" to end the opening/closing operation of the general electric accessory 34a. Further, when the numerical information of the general electric utility article opening counter is “1” or more and the support end counter is not set to “1”, the information of the closing time of the general electric utility article 34a is displayed. It sets it to the electric timer counter and updates the normal/universal electric power counter from "3" to "4".

When the opening/closing operation of the ordinary electric accessory 34a reaches the reference number of times, or when the number of winnings to the second operating port 34 that has occurred during the support executing period of this time reaches the upper limit number, the support executing period of this time is finish.

Next, the processing for closing the universal communication (step S411) in the universal communication control processing (FIG. 20) will be described. In the normal electric power closing process, the normal electric power object 34a is maintained in the closed state, and when the closing time has elapsed, the normal electric power object 34a is opened again. Specifically, the information on the high-frequency open duration is set in the POU/UDEN timer counter, and the POU/UDEN counter is updated from "4" to "3".

Next, in the main CPU 63, based on the detection results of the respective ball detection sensors 42a-50a, the outlet 24a, the general winning opening 31, the special electricity winning device 32, the first working opening 33, the second working opening 34, A configuration for specifying whether or not the game ball B1 enters the first through gate 35 and the second through gate 39 will be described. FIG. 25 is an explanatory diagram for explaining a configuration in which the detection results of the ball detection sensors 42a to 50a are input to the main CPU 63.

The main CPU 63 has an input port 63a. The input port 63a is configured as a 9-bit parallel interface so that 9 types of signals can be handled simultaneously. Areas in which information of "0" or "1" is stored according to the voltage of each signal are provided in a one-to-one correspondence with each terminal. That is, the 0th bit D0 to the 8th bit D8 are provided as the area. Although more than 10 types of signals are input to the input port 63a, the signal group to be input to the input port 63a depends on the driver IC in order to limit the number of types of input signals to 9 types at the same time. It is switched through switching control.

In the incoming ball detection process (step S211) of the timer interrupt process (FIG. 18), the signal group to be input to the input port 63a is set to the signal group from each of the incoming ball detection sensors 42a to 50a. In such a situation where the setting is made, the 0th bit D0 stores the information corresponding to the detection signal from the first winning opening detection sensor 42a, and the first bit D1 corresponds to the detection signal from the second winning opening detection sensor 43a. The second bit D2 stores information corresponding to the detection signal from the third winning hole detection sensor 44a, and the third bit D3 stores information corresponding to the detection signal from the special electricity 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, the 7th bit D7 stores information corresponding to the detection signal from the first gate detection sensor 49a, and the 8th bit D8 stores the information. Information corresponding to the detection signal from the 2-gate detection sensor 50a is stored.

Each of the ball detection sensors 42a to 50a outputs a LOW level signal indicating non-detection as a detection signal when the passage of the game ball B1 is not detected, and detects the passage of the game ball B1. If it is, the 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 receiving the LOW level signal, and "1" for the corresponding bit when receiving the HI level signal. Stores the information of. That is, in the situation where passage of the game ball B1 is not detected by the ball detection sensors 42a to 50a, information of "0" corresponding to the information indicating non-detection is stored for the corresponding bit, and the game ball B1 of the game ball B1 is stored. In the situation where passage is detected, information of "1" corresponding to the information indicating detection is stored for the corresponding bit.

FIG. 26 is a flowchart showing the entry detection process executed in step S211 of the timer interrupt process (FIG. 18).

When it is confirmed that the state in which the information of “0” is stored in the 0th bit D0 is switched to the state in which the information of “1” is stored, one piece is detected by the first winning opening detection sensor 42a. It is determined that the game ball B1 has been detected (step S901: YES). In this case, "1" is set to the first output flag provided in the main RAM 65 (step S902), and the value of the 10 award ball counter provided in the main RAM 65 is incremented by 1 (step S903). .. The first output flag is for the main CPU 63 to specify that the information output indicating that one gaming ball B1 is detected by the first winning opening detection sensor 42a should be executed to the management IC 66. Flag. The ten prize ball counter is a counter for the main CPU 63 to specify the number of times that the payout of the ten game balls B1 should be executed. When the value of the counter for 10 award balls is 1 or more, the 10 award ball command is output to the award controller 77 in the payout output process of step S219 in the timer interrupt process (FIG. 18), and the 10 award balls are issued. When the command is output once, the value of the counter for 10 prize balls is decremented by 1. When the payout control device 77 receives the ten prize ball command, it drives and controls the payout device 76 so that ten game balls B1 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, one piece is detected by the second winning hole detection sensor 43a. It is determined that the game ball B1 has been detected (step S904: YES). In this case, "1" is set to the second output flag provided in the main RAM 65 (step S905), and the value of the 10 award ball counter provided in the main RAM 65 is incremented by 1 (step S906). .. The second output flag is for the main CPU 63 to specify that the information output indicating that one gaming ball B1 is detected by the second winning opening detection sensor 43a should be executed to the management IC 66. Flag.

When it is confirmed that the state in which the information of "0" is stored in the second bit D2 is switched to the state in which the information of "1" is stored, the third winning hole detection sensor 44a detects one It is determined that the game ball B1 has been detected (step S907: YES). In this case, "1" is set to the third output flag provided in the main RAM 65 (step S908), and the value of the 10 award ball counter provided in the main RAM 65 is incremented by 1 (step S909). . The third output flag is for the main CPU 63 to specify that the information output indicating that one gaming ball B1 is detected by the third winning opening detection sensor 44a should be executed to the management IC 66. Flag.

When it is confirmed that the state in which the information of "0" is stored in the third bit D3 is switched to the state in which the information of "1" is stored, one game ball B1 is detected by the special electric detection sensor 45a. Is detected (step S910: YES). In this case, the special electricity prize flag provided in the main RAM 65 is set to "1" (step S911), and the fourth output flag provided to the main RAM 65 is set to "1" (step S912). The value of the counter for 15 prize balls provided in the main RAM 65 is incremented by 1 (step S913). The special electric prize flag is a flag for the main CPU 63 to specify that one game ball B1 has entered the special electric prize device 32 in the round game in the opening/closing execution mode. In the special map special electric power control processing (step S215) of the timer interruption processing (FIG. 18), by confirming that the special electric prize winning flag is set to "1", one gaming ball B1 to the special electric winning device 32 is confirmed. It is specified that a ball has entered, and the remaining possible number of balls to enter the special electric prize winning device 32 in the round game is subtracted by one. When the process of subtracting 1 from the number of possible balls to enter is executed, the special electric 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 gaming ball B1 is detected by the special electric power detection sensor 45a should be executed to the management IC 66. is there. The counter for 15 prize balls is a counter for the main CPU 63 to specify the number of times the payout of 15 game balls B1 should be executed. When the value of the counter for 15 award balls is 1 or more, the 15 award ball command is output to the payout controller 77 in the payout output process of step S219 in the timer interrupt process (FIG. 18), and the 15 award balls When the command is output once, the value of the counter for 15 prize balls is decremented by 1. When the payout control device 77 receives the 15 prize ball command, it drives and controls the payout device 76 so that the 15 game balls B1 are paid out.

When it is confirmed that the state in which the information of “0” is stored in the fourth bit D4 is switched to the state in which the information of “1” is stored, the first operating port detection sensor 46a detects one It is determined that the game ball B1 has been detected (step S914: YES). In this case, the first operation winning flag provided in the main RAM 65 is set to "1" (step S915), and the fifth output flag provided to the main RAM 65 is set to "1" (step S916). Further, the value of the one prize ball counter provided in the main RAM 65 is incremented by 1 (step S917). The first operation winning flag is a flag for the main CPU 63 to specify that one gaming ball B1 has entered the first operating opening 33. In the special figure special electric power control process (step S215) of the timer interrupt process (FIG. 18), it is confirmed that the first operation winning flag is set to “1”, and the result is stored in the holding area RE of the holding storage area 65a. On condition that the number of held information items is less than 4, which is the upper limit number, a process of newly storing the held information items is executed. It is confirmed in the special electric power control process (step S215) that the first actuation winning flag is set to "1", and when the process corresponding to the confirmation is executed, the first actuation winning flag is cleared to "0". .. The fifth output flag is for the main CPU 63 to specify that the information output indicating that one gaming ball B1 has been detected by the first operation opening detection sensor 46a should be executed for the management IC 66. Flag. The one prize ball counter is a counter for the main CPU 63 to specify the number of times that one gaming ball B1 should be paid out. When the value of the one prize ball counter is 1 or more, the one prize ball command is output to the payout control device 77 in the payout output process of step S219 in the timer interrupt process (FIG. 18), and the one prize ball is obtained. When the command is output once, the value of the one prize ball counter is decremented by one. When the payout control device 77 receives the one prize ball command, it drives and controls the payout device 76 so that one game ball B1 is paid out.

When it is confirmed that the state in which the information of “0” is stored in the fifth bit D5 is switched to the state in which the information of “1” is stored, the second working port detection sensor 47a detects one It is determined that the game ball B1 is detected (step S918: YES). In this case, the second operation winning flag provided in the main RAM 65 is set to "1" (step S919), and the sixth output flag provided to the main RAM 65 is set to "1" (step S920). Further, the value of the one prize ball counter provided in the main RAM 65 is incremented by 1 (step S921). The second operation winning flag is a flag for the main CPU 63 to specify that one gaming ball B1 has entered the second operating port 34. In the special figure special electric power control process (step S215) of the timer interrupt process (FIG. 18), it is confirmed that the second operation winning flag is set to “1”, and the result is stored in the holding area RE of the holding storage area 65a. On condition that the number of held information items is less than 4, which is the upper limit number, a process of newly storing the held information items is executed. It is confirmed in the special electric power control process (step S215) that the second operation winning flag is set to "1", and if the process corresponding to the confirmation is executed, the second operation winning flag is cleared to "0". .. The sixth output flag is for the main CPU 63 to specify that the information output indicating that one gaming ball B1 has been detected by the second working opening detection sensor 47a should be executed for the management IC 66. Flag.

When it is confirmed that the state in which the information of "0" is stored in the sixth bit D6 is switched to the state in which the information of "1" is stored, one game ball is detected by the out-mouth detection sensor 48a. It is determined that B1 is detected (step S922: YES). In this case, "1" is set to the seventh output flag provided in the main RAM 65 (step S923). The seventh output flag is a flag for the main CPU 63 to specify that the information output indicating that one gaming ball B1 has been detected by the outlet detection sensor 48a should be executed for the management IC 66. Is.

If it is confirmed that the situation where the information of "0" is stored in the seventh bit D7 is switched to the situation where the information of "1" is stored, one game is performed by the first gate detection sensor 49a. It is determined that the ball B1 is detected (step S924: YES). In this case, the first gate winning flag provided in the main RAM 65 is set to "1" (step S925). The first gate winning flag is a flag for the main CPU 63 to specify that one gaming ball B1 has entered the first through gate 35. In the universal figure/general electric power control process (step S216) of the timer interrupt process (FIG. 18), it is possible to confirm that “1” is set in the first gate winning flag, as already described in FIG. , Numerical information of the current ordinary electric utility product release counter C4 is provided on condition that the number of ordinary information holding information stored in the ordinary electric current holding storage area 65c is less than 4 which is the upper limit number. A process of storing it as the holding information on the side in the normal telephone holding storage area 65c is executed. When it is confirmed that the first gate winning flag is set to "1" in the universal figure/universal control process (step S216), and the process corresponding to the confirmation is executed, the first gate winning flag is set to "0". "clear.

When it is confirmed that the situation where the information of "0" is stored in the eighth bit D8 is switched to the situation where the information of "1" is stored, one game is played by the second gate detection sensor 50a. It is determined that the ball B1 is detected (step S926: YES). In this case, "1" is set to the second gate winning flag provided in the main RAM 65 (step S927). The second gate winning flag is a flag for the main CPU 63 to specify that one game ball B1 has entered the second through gate 39. In the universal figure/general electric power control process (step S216) of the timer interrupt process (FIG. 18), as already described with reference to FIG. 21, it is possible to confirm that “1” is set in the second gate winning flag. , Numerical information of the current general electric utility accessory release counter C4 is provided on condition that the number of the general information holding information stored in the general electric storage area 65c is less than the upper limit number of 4. A process of storing it as the holding information on the side in the normal telephone holding storage area 65c is executed. When it is confirmed that the second gate winning flag is set to "1" in the universal figure control process (step S216), and the process corresponding to the confirmation is executed, the second gate winning flag is set to "0". "clear.

Since the timer interrupt process (FIG. 18) is activated at a cycle of 4 msec as already described, when the detection of one game ball B1 is started by one of the ball detection sensors 42a to 50a, the corresponding event is detected. The main side is to specify that one game ball B1 has been detected by the ball detection sensors 42a-50a while the ball detection sensors 42a-50a continue to detect that one game ball B1. It is performed by the CPU 63. Therefore, it suffices if each one of the first to seventh output flags is provided.

Next, the content of processing executed by the payout control device 77 will be described. First, the electrical configurations 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. 27.

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

The payout-side ROM 93 is a memory such as a NOR flash memory and a NAND flash memory that does not require external power supply for storage and storage (that is, a non-volatile storage means), and is used as a read-only memory. 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 means) such as an SRAM and a DRAM that needs to be supplied with electric power from the outside to retain the storage, and is used for both reading and writing. The payout side RAM 94 is randomly accessible and has a shorter read time than the payout side ROM 93 when compared with the same data capacity. The payout side RAM 94 temporarily stores various data and the like 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. Upon receipt of the prize ball command from the main CPU 63, the payout side CPU 92 drives and controls the payout device 76 so that the number of game balls B1 corresponding to the prize ball command is paid out. Further, the payout side CPU 92 monitors whether or not the payout of the game ball B1 can be normally performed, and when it is determined that the payout of the gaming ball B1 is not normally possible, the payout side RAM 94 is provided. Even when the unpaid prize ball number information is stored in the table, the payout device 76 is stopped. Further, the payout side CPU 92 transmits to the main side CPU 63 a payout restriction command indicating that the payout is not normally possible. 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 notify that the payout of the game ball B1 is not possible normally. A notification command is transmitted to the voice emission control device 81 so as to be executed. As a state in which it is not possible to normally pay out the game ball B1, a lower tank 56a is filled with the game ball B1 and a full tank state in which the game ball B1 is not replenished in the tank 75, There are a payout abnormal state in which the payout device 76 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. doing.

A not-shown full tank detection sensor is provided at an intermediate position of the game ball B1 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 gaming ball B1 is in the full tank state when the full tank detecting sensor continuously detects it, and releases the state in which the gaming ball B1 is continuously detected by the full tank detecting sensor. When it is done, it specifies that the full tank state has been released.

A ball non-detection sensor (not shown) is provided at an intermediate position of the game ball B1 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 there is no ball when the game ball B1 is not continuously detected by the ball no-detection sensor, and the state where the game ball B1 is not continuously detected by the no-ball detection sensor is released. In this case, it is specified that the ball-free state has been released.

The payout device 76 is provided with a payout detection sensor (not shown) for detecting the game ball B1 paid out from the payout device 76, and the detection result of the payout detection sensor is input to the payout side CPU 92. The payout side CPU 92 specifies that one gaming ball B1 has been paid out from the payout device 76 when the gaming ball B1 is detected by the payout detection sensor. Further, the payout side CPU 92 is in the payout abnormal state when the payout detection sensor does not continuously detect the game ball B1 despite the drive control of the payout device 76 so that the game ball B1 is paid out. It is specified that the abnormal payout state has been canceled when the state in which the gaming ball B1 is not continuously detected by the payout detection sensor is canceled.

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 closed with respect to the inner frame 13, the front door open sensor 95 transmits a close detection signal to the payout side CPU 92, and the front door frame 14 is opened with respect to the inner frame 13. In the case of, 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 the closing detection signal is received from the front door opening sensor 95, and when the opening detection signal is received from the front door opening sensor 95. The front door frame 14 is specified to be in an open state. Further, the payout side CPU 92 transmits a front door opening command to the main CPU 63 at the timing specified that the front door frame 14 has changed from the closed state to the open state, and specifies that the front door frame 14 has changed from the open state to the closed state. The front door closing command is transmitted to the main CPU 63 at the timing. The main CPU 63 specifies that the front door frame 14 is in the open state when receiving the front door opening command, and specifies that the front door frame 14 is in the closing state when receiving the front door closing command.

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 in the closed state 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 in the open state with respect to the outer frame 11. In some cases, the main body opening sensor 96 sends 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 the closed state when the closing detection signal is received from the opening sensor 96, and the gaming machine when the opening detection signal is received from the opening sensor 96. It specifies that the main body 12 is in the open state. Further, the payout side CPU 92 sends a main body opening command to the main CPU 63 at the timing specified that the gaming machine main body 12 has changed from the closed state to the open state, and specifies that the gaming machine main body 12 has changed from the open state to the closed state. A main body closing command is transmitted to the main CPU 63 at a timing. The main CPU 63 identifies that the gaming machine body 12 is in the open state when receiving the body opening command, and identifies that the gaming machine body 12 is in the closing state when receiving the body closing command.

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

First, a full tank process is executed (step S1001). In the processing for full tank, as described above, it is specified based on the detection result of the full tank detection sensor whether or not it is in the full tank state, and in the case of the full tank state, the payout of the game ball B1 is stopped. Along with executing the processing, a command indicating that the tank is full is sent to the main CPU 63. Further, when the full tank state is released, processing for enabling payout of the game ball B1 is executed, and a command indicating that the full tank state has been released is transmitted to the main CPU 63.

After that, the ball non-use process is executed (step S1002). In the ball non-use process, as described above, a process for identifying whether or not there is no ball based on the detection result of the ball non-detection sensor and for stopping the payout of the game ball B1 in the case of no ball Is executed and a command indicating that there is no ball is transmitted to the main CPU 63. In addition, when the non-sphere state is released, a process for enabling payout of the game ball B1 is executed, and a command indicating that the non-sphere state is released is transmitted to the main CPU 63.

After that, the payout abnormality monitoring processing is executed (step S1003). In the payout abnormality monitoring process, as described above, it is determined whether or not the payout state is abnormal based on the detection result of the payout detection sensor, and when the payout state is abnormal, the process of stopping the payout of the game ball B1 is executed. At the same time, it sends a command indicating that the dispensing is abnormal, to the main CPU 63. Also, when the payout abnormal state is canceled, processing for enabling the payout of the game ball B1 is executed, and a command indicating that the payout abnormal state has been canceled is transmitted to the main CPU 63.

Then, the front door opening monitoring process is executed (step S1004). In the front door opening monitoring process, as described above, it is specified 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, and when the front door frame 14 is in the open state, While executing the process of stopping the payout of the game ball B1, the front door opening command is transmitted to the main CPU 63. In addition, when the front door frame 14 is closed, processing for enabling payout of the game ball B1 is executed, and a front door closing command is transmitted to the main CPU 63.

Then, the main body opening monitoring process is executed (step S1005). In the main body opening monitoring process, as described above, it is specified whether or not the game machine main body 12 is in the open state based on the detection result of the main body open sensor 96. A process of stopping the payout of B1 is executed, and a main body release command is transmitted to the main CPU 63. Further, when the gaming machine body 12 is closed, a process for enabling payout of the game ball B1 is executed, and a main body closing command is transmitted to the main CPU 63.

After that, the command reading process is executed (step S1006). In the command reading process, a process of reading the prize ball command transmitted from the main CPU 63 is executed. Then, the prize ball command is stored in the payout side RAM 94. Then, after executing the prize ball setting processing 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 S1007), the game ball B1 by the payout device 76 A payout control process for controlling payout execution is executed (step S1008). In the payout control process, when the unpaid prize ball number information stored in the payout side RAM 94 has a value of 1 or more, the payout device 76 is driven and controlled, and the payout detection sensor detects one game ball B1. When it is detected, the value of the prize ball number information is subtracted by 1. Then, when the value of the prize ball number information becomes “0”, the drive control of the payout device 76 is stopped. After that, the 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 timer interrupt process this time is executed (step S1009).

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 board 97. The external terminal board 97 is provided with a large number of external terminals. Some of the external terminals are electrically connected to the main CPU 63 and some of the external terminals are provided. A plurality of external terminals are electrically connected to the payout side CPU 92. Since each of the main CPU 63 and the payout CPU 92 is electrically connected to the external terminal board 97 in this manner, the main CPU 63 and the payout CPU 92 send information to the hall computer HC as shown in FIG. 27. It is possible to output.

One external terminal of the external terminal board 97 is electrically connected to the front door opening sensor 95, and one external terminal of the external terminal board 97 is electrically connected to the main body opening sensor 96. In detail regarding the configuration of this electrical connection, a signal relay board 98 is provided at an intermediate position of a signal path from the front door opening sensor 95 to the payout side CPU 92. The signal relay board 98 is provided with a branch path SL2 branching from the signal path SL1 directed from the front door opening sensor 95 to the payout side CPU 92. The branch path SL2 is connected to the external terminal for opening the front door of the external terminal board 97. Therefore, the electric 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 the external terminal for opening the front door of the external terminal board 97. As a result, a signal indicating whether or not the front door frame 14 is in the open state can be externally output to the hall computer HC without the control of the payout side CPU 92.

For details of the main body opening sensor 96, the signal relay board 98 is provided with a branching path SL4 branched from the signal path SL3 from the main body opening sensor 96 to the payout side CPU 92. The branch path SL4 is connected to the external terminal for opening the main body of the external terminal board 97. Therefore, the electric signal corresponding to the detection result of the main body opening sensor 96 is input not only to the payout side CPU 92 but also to the external terminal for opening the main body of the external terminal board 97. As a result, a signal indicating whether or not the gaming machine main body 12 is in the open state can be externally output to the hall computer HC without the control of the payout side CPU 92.

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

The main CPU 63 performs the external information setting process (step S220) in the timer interrupt process (FIG. 18) to set the output of information to each external terminal assigned to the main CPU 63 in the external terminal board 97. As information output from the main CPU 63 to the external terminal board 97, information indicating that the open/close execution mode is in effect, information indicating that the support mode is in the high-frequency support mode, and one game time have ended. And information indicating that a predetermined number (for example, 100) of game balls B1 are provided through any one of the outlet 24a, the general winning opening 31, the special electricity winning device 32, the first operating opening 33, and the second operating opening 34. Information indicating that the game ball B1 has entered the first operating port 33, and information indicating that the game ball B1 has entered the second operating port 34 are included. Has been.

In the external information setting process (step S1009) in the timer interrupt process (FIG. 28), the payout side CPU 92 sets the output of information to each external terminal assigned to the payout side CPU 92 in 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 gaming balls B1 have been paid out.

In the hall computer HC, according to various information received from the pachinko machine 10 through the external terminal board 97, it is possible to grasp the execution mode of payout of the game balls B1 in the pachinko machine 10 and the like. For example,
A payout rate, which is the ratio of the number of payouts of the game balls B1 generated until 100 game balls B1 are discharged from the game area PA of the pachinko machine 10. A normal game state that is not the open/close execution mode or the high frequency support mode Ball yield rate (hereinafter, this ball yield rate is referred to as "B")
-Ball output rate in open/close execution mode-ball output rate in high-frequency support mode-number of game times executed until 100 game balls B1 are discharged from the game area PA of the pachinko machine 10 (hereinafter, this ratio Is referred to as "S")
B-S x "the number of prize balls for winning in the first working opening 33 and the second working opening 34"
The number of game balls B1 entering the first operating port 33 that have occurred until 100 game balls B1 have been discharged from the game area PA of the pachinko machine 10 (hereinafter, this ratio is referred to as "S1")
-The number of balls of the game ball B1 entering the second operation port 34 that has occurred until 100 game balls B1 are discharged from the game area PA of the pachinko machine 10 (hereinafter, this ratio is referred to as "S2")
B-(S1 x "the number of prize balls for winning in the first operating port 33" + S2 x "number of prize balls for winning in the second operating port 34")
Is calculated. As a result, the hall computer HC can manage the entry mode of the game ball B1 in the game area PA of the pachinko machine 10. The number of prize balls is the number of game balls B1 to be paid out when one game ball B1 enters the corresponding ball input section.

<Structure for managing the winning mode of the game ball B1>
Next, a configuration for managing the winning mode of the game ball B1 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. Further, 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 a device external to the MPU 62. The I/F 101 is electrically connected to the main CPU 63 via the internal bus 103. The detection result from the sensors such as the ball detection sensors 42a to 50a and the command 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 result and the content of the command. As described above, the main CPU 63 executes various processes. Further, when a signal is output to a device such as the drive unit 32b for special electric power as a result of the various processes executed by the main CPU 63, the signal is output through the output port of the I/F 101, and When a command is output to the payout side CPU 92 and the sound emission control device 81 as a result of the CPU 63 performing various processes, the command output is performed through the output port of the I/F 101.

The reading terminal 102 is a terminal for electrically connecting the reading device, which is an external device of the pachinko machine 10, to the MPU 62, and is provided such that the connection terminal portion is exposed on the surface of the MPU 62. .. However, as already described, the main control board 61 on which the MPU 62 is mounted is housed in the board box 60a, and the reading terminal 102 faces the wall portion of the board box 60a so as not to be exposed to the outside of the main control device 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 and expose the MPU 62. As a result, it is possible to prevent unauthorized electrical connection of the reading device to the reading terminal 102. Note that the present invention is not limited to this, and an opening for exposing the reading terminal 102 to the outside of the main control device 60 is formed in the substrate box 60a, so that the reading can be performed without destroying the substrate box 60a. The reading device may be electrically connected to the terminal 102.

The management IC 66 includes a management I/F 111, a management CPU 112, a management ROM 113, a management RAM 114, an RTC 115, a correspondence memory 116, and a history memory 117. These devices are connected to each other through an internal bus 66a provided in the management IC 66 so as to be capable of bidirectional communication.

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 the signal path group 119 for unidirectional communication built in the MPU 62. It is 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 communication 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-side ROM 113 is a memory such as a NOR flash memory and a NAND flash memory that does not require external power supply for storage and storage (that is, nonvolatile storage means), and is used as a read-only memory. The management-side ROM 113 stores various control programs executed by the management-side CPU 112 and fixed value data. The management side RAM 114 is a memory (that is, a volatile storage means) such as an SRAM and a DRAM that needs to be supplied with electric power from the outside to retain the storage, and is used for both reading and writing. The management-side RAM 114 is capable of random access and has a shorter read time than the management-side ROM 113 when compared with the same data capacity. The management side RAM 114 temporarily stores various data and the like for execution of the control program stored in the management side ROM 113.

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

The correspondence relationship memory 116 is a memory such as SRAM and DRAM that requires external power supply for storage and storage (that is, volatile storage means), 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 such as a NOR flash memory and a NAND flash memory that does not require external power supply for storage and storage (that is, a non-volatile storage unit), and is used for both reading and writing. The history memory 117 is used to store information regarding entry of the game ball B1 received from the main CPU 63 through the management 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. 30 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. Is low level, the information of "0" is stored as the first data, and when the signal to be input is the HI level, the information of "1" is stored as the second data. The relationship between the LOW and HI and the first data and the second data may be reversed.

The first signal corresponding to the detection result of the first winning opening detection sensor 42a is input to the first buffer 122a. In this case, the main CPU 63 outputs the first signal of the LOW level when the new gaming ball B1 is not detected by the first winning hole detection sensor 42a, and the first winning hole detection sensor 42a outputs one signal. When the game ball B1 is detected, the HI level first signal 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 first signal is input to the first buffer 122a.

The second signal corresponding to the detection result of the second winning opening detection sensor 43a is input to the second buffer 122b. In this case, the main CPU 63 outputs the second signal of the LOW level when the new game ball B1 is not detected by the second winning hole detection sensor 43a, and the second winning hole detection sensor 43a outputs one signal. When the game ball B1 is detected, the HI level second signal 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 second signal is input to the second buffer 122b.

The third signal corresponding to the detection result of the third winning opening detection sensor 44a is input to the third buffer 122c. In this case, the main CPU 63 outputs a LOW level third signal in a situation where the new game ball B1 is not detected by the third winning hole detection sensor 44a, and the third winning hole detection sensor 44a outputs one signal. When the game ball B1 is detected, the HI level third signal is output for a specific period. This specific period is a period sufficient for the management-side CPU 112 to specify that the third signal of the HI level is input to the third buffer 122c.

The fourth signal corresponding to the detection result of the special electric power detection sensor 45a is input to the fourth buffer 122d. In this case, the main CPU 63 outputs the fourth signal of the LOW level in a situation where the new game ball B1 is not detected by the special electric detection sensor 45a, and one game ball B1 is detected by the special electric detection sensor 45a. In that case, the fourth 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 fourth signal is input to the fourth buffer 122d.

The 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 LOW level fifth signal in a situation in which a new game ball B1 is not detected by the first working opening detection sensor 46a, and the first working opening detection sensor 46a outputs one signal. When the game ball B1 is detected, the HI level fifth signal 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.

The 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 side CPU 63 outputs a LOW level sixth signal in a situation in which a new game ball B1 is not detected by the second working opening detection sensor 47a, and the second working opening detection sensor 47a outputs one signal. When the game ball B1 is detected, the sixth 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 sixth signal is input to the sixth buffer 122f.

The seventh signal corresponding to the detection result of the outlet detection sensor 48a is input to the seventh buffer 122g. In this case, the main CPU 63 outputs a LOW level seventh signal in a situation where a new game ball B1 is not detected by the out-mouth detection sensor 48a, and one game ball B1 is output by the out-mouth detection sensor 48a. When detected, the seventh 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 seventh signal is input to the seventh buffer 122g.

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

The ninth signal corresponding to whether or not the high frequency support mode is in operation is input to the ninth buffer 122i. In this case, the main CPU 63 continuously outputs the LOW-level ninth signal in the situation not in the high-frequency support mode, and continuously outputs the HI-level ninth signal in the situation in the high-frequency support mode.

A tenth signal corresponding to whether or not the front door frame 14 is open 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.

An output instruction signal is input to the 16th buffer 122p for causing the management-side CPU 112 to recognize the trigger for outputting the history information stored in the history memory 117 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 16th buffer 122p.

The eleventh buffer 122k, the twelfth buffer 122l, the thirteenth buffer 122m, the fourteenth buffer 122n, and the fifteenth buffer 122o can input signals from the main CPU 63, but normal signals are not input in the pachinko machine 10. It is blank. As described above, as the input port 121 of the management-side I/F 111, the number of buffers 122a to 122p, which are larger than the types of signals output from the main CPU 63 to the management IC 66 in the pachinko machine 10, are provided. The management IC 66 can be used for a model different from the pachinko machine 10. This makes it possible to improve the versatility of the management IC 66. 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 in a one-to-one correspondence. However, the configuration 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 decided at the design stage of the management IC 66 that the output instruction signal is input to the 16th buffer 122p in the input port 121 of the management-side I/F 111, and the management-side CPU 112 receives no instruction from the main-side CPU 63. Can specify that the output instruction signal is input to the 16th buffer 122p. On the other hand, what kind 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 kind of these signals is instructed by the main CPU 63. As a result, the CPU 112 on the management side specifies. The details of the identification of the types of these signals in the management CPU 112 will be described later, but when the control is started in the main CPU 63 and the management CPU 112 with the supply of operating power to the MPU 62, the main CPU 63 transfers to the management CPU 112. This is performed by transmitting the 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 types of various signals are specified by the management side CPU 112 in the situation where the operating power is supplied, The information stored in the correspondence memory 116 is referred to.

FIG. 31 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. It is provided.

In the first correspondence area 123a, information indicating the general winning opening 31 is stored as information for the management-side CPU 112 to specify the type of signal input to the first buffer 122a. Further, in the first correspondence area 123a, together with information indicating that it is the general winning opening 31, information about the number of gaming balls B1 to be paid out when one gaming ball B1 enters the general winning opening 31 (10 pieces) ) Is also stored. In the second correspondence area 123b, information indicating the general winning opening 31 is stored as information for the management-side CPU 112 to specify the type of signal input to the second buffer 122b. In addition, in the second correspondence area 123b, information indicating that it is the general winning opening 31 and information on the number of gaming balls B1 to be paid out when one gaming ball B1 enters the general winning opening 31 (10 pieces) ) Is also stored. In the third correspondence area 123c, information indicating the general winning opening 31 is stored as information for the management-side CPU 112 to specify the type of signal input to the third buffer 122c. In addition, in the third correspondence area 123c, information indicating that it is the general winning opening 31 and information on the number of gaming balls B1 to be paid out when one gaming ball B1 enters the general winning opening 31 (10 pieces) ) Is also stored.

In the fourth correspondence area 123d, information indicating the special electric prize winning device 32 is stored as information for the management-side CPU 112 to specify the type of signal input to the fourth buffer 122d. Further, in the fourth correspondence area 123d, information indicating that it is the special electric prize winning device 32 and information on the number of game balls B1 to be paid out when one game ball B1 enters the special electric prize winning device 32 (15 pieces) ) Is also stored. In the fifth correspondence area 123e, information indicating the first operation port 33 is stored as information for the management-side CPU 112 to specify the type of signal input to the fifth buffer 122e. Further, in the fifth correspondence area 123e, information indicating that the game ball B1 is the first operation port 33 and information on the number of game balls B1 to be paid out when one game ball B1 enters the first operation port 33 ( 1) is also stored. In the sixth correspondence area 123f, information indicating the second operation port 34 is stored as information for the management-side CPU 112 to specify the type of signal input to the sixth buffer 122f. Further, in the sixth correspondence area 123f, together with information indicating that it is the second operation port 34, information on the number of game balls B1 to be paid out when one game ball B1 enters the second operation port 34 ( 1) is also stored. Information indicating the outlet 24a is stored in the seventh correspondence area 123g as information for the management-side CPU 112 to specify the type of signal input to the seventh buffer 122g.

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

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

As described above, what kind of signal is input to the first to fifteenth buffers 122a to 122o is specified by the management side CPU 112 by receiving an instruction from the main side CPU 63. The management IC 66 can be used for a model different from the pachinko machine 10. This makes it possible to improve the versatility of the management IC 66.

Also, each time the signal output corresponding to the storage of history information is performed to the first to fifteenth buffers 122a to 122o, the information for recognizing the type of the signal is not output, but the type of the signal is recognized in advance. And the information for specifying the type of the signal input to the first to fifteenth buffers 122a to 122o on the management side CPU 112 based on the output information is stored in the correspondence relationship memory 116. It is a configuration. As a result, when the signal output corresponding to the storage of the history information is output to the first to fifteenth buffers 122a to 122o, the information for recognizing the type of the signal 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-side CPU 112 is performed at the start of supply of operating power. As a result, when the game is started on the pachinko machine 10, it becomes possible for the management-side CPU 112 to specify the types of signals input to the first to fifteenth buffers 122a to 122o.

Further, information setting that the output instruction signal is input to the 16th 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 with respect to the output instruction signal that is surely used not only by the pachinko machine 10 but also by other types of pachinko machines that use the management IC 66. It is possible to omit the processing for. Therefore, it is possible to reduce the processing load of the processing for specifying the type of the signal.

Next, the history memory 117 of the management IC 66 will be described. FIG. 32 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 pieces of pointer information are set in serial numbers, and a history information storage area 125 is set in a one-to-one correspondence with each pointer information. The history information storage area 125 can store a combination of RTC information and correspondence information. In this case, each history information storage area 125 has a data capacity of 2 bytes, a data capacity of 1 byte is allocated as an area for storing RTC information, and an area for storing correspondence information. A data capacity of 1 byte is assigned. When it is necessary to store the correspondence information in accordance with 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/time information and the time information measured by 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 which is the current writing target. After that, the correspondence relationship information corresponding to the buffers 122a to 122o that triggered the information storage this time is read from the correspondence relationship areas 123a to 123o corresponding to the buffers 122a to 122o in the correspondence relationship memory 116, and the read correspondence relationship information. Is stored in the area for storing the correspondence information of the history information storage area 125 corresponding to the pointer information which is the current writing target.

Regarding the correspondence information stored in the history information storage area 125, specifically, the signals corresponding to the detection results of the ball entrance detection sensors 42a to 48a are input to the first to seventh buffers 122a to 122g as described above. Therefore, information corresponding to the types of the incoming ball detection sensors 42a to 48a is stored in the first to seventh correspondence areas 123a to 123g in the correspondence memory 116. More specifically, the information corresponding to the type of the ball entering portion corresponding to each of the ball detecting sensors 42a to 48a is stored in the first to seventh correspondence areas 123a to 123g. As described above, in the pachinko machine 10, since the first to third winning hole detection sensors 42a to 44a all detect the game ball B1 that has entered the general winning hole 31, these first to third winnings In the first to third correspondence relationship areas 123a to 123c corresponding to the mouth detection sensors 42a to 44a, information indicating that the general winning opening 31 is stored is stored. Further, information indicating that it is the special electricity winning device 32 is stored in the fourth correspondence area 123d, and information indicating that it is the first operation port 33 is stored in the fifth correspondence area 123e. Information indicating the second operating port 34 is stored in the sixth correspondence area 123f, and information indicating the out port 24a is stored in the seventh correspondence area 123g. When the buffers 122a to 122o that have triggered the information storage this time are any of the first to seventh buffers 122a to 122g, the information on the type of the ball entering portion corresponding to the buffers 122a to 122g is the first to the first. It is read from any of the seventh correspondence areas 123a to 123g, and the read information on the type of the ball entering portion is stored as it is in the area for storing the correspondence information of the history information storage area 125.

On the other hand, a signal indicating whether the eighth buffer 122h is in the open/close execution mode is input, a signal indicating whether 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 open is input. Therefore, the eighth correspondence area 123h stores information indicating the open/close execution mode, the ninth correspondence area 123i stores information indicating the high-frequency support mode, and the tenth correspondence area Information indicating the front door frame 14 is stored in 123j.

As described above, the main-side CPU 63 continuously outputs the LOW-level eighth signal when the open/close execution mode is not set, and continuously outputs the HI-level eighth signal when the open/close execution mode is set. The side CPU 112 identifies that the opening/closing execution mode has started when the eighth signal changes from the LOW level to the HI level, and identifies 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, regardless of whether the eighth signal changes from the LOW level to the HI level or when the HI level changes to the LOW level, the management-side CPU 112 causes the history information storage area 125 to store the correspondence information. Identify as done. That is, when the eighth signal changes from the LOW level to the HI level, not only the information indicating the open/close execution mode read from the eighth correspondence area 123h, but also the start information is stored together with the history information storage area 125. It is stored in the area for storing the correspondence information of. Further, when the eighth signal changes from the HI level to the LOW level, not only the information indicating the open/close execution mode read from the eighth correspondence area 123h but also the end information is recorded together with the history information storage area 125. It is stored in the area for storing the correspondence information of.

As described above, the main CPU 63 continuously outputs the LOW-level ninth signal in the situation where the high-frequency support mode is not set, and continuously outputs the HI-level ninth signal in the situation where the high-frequency support mode is set. The managing CPU 112 identifies that the high frequency support mode is started when the ninth signal changes from the LOW level to the HI level, and ends the high frequency support mode when the ninth signal changes from the HI level to the LOW level. It becomes possible to specify that it did. Then, regardless of whether the ninth signal changes from the LOW level to the HI level or when the HI level changes to the LOW level, the management-side CPU 112 causes the history information storage area 125 to store the correspondence information. Identify as done. 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 is stored together with the history information storage area. It is stored in the area for storing 125 correspondence information. Further, when the ninth signal changes from the HI level to the LOW level, not only the information indicating the high frequency support mode read from the ninth correspondence area 123i but also the end information together with the history information storage area It is stored 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. Since the continuous output is performed, 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. It is possible to specify that the front door frame 14 is closed. Then, regardless of whether the tenth signal changes from the LOW level to the HI level or when the HI level changes to the LOW level, the management-side CPU 112 causes the history information storage area 125 to store the correspondence information. Identify as done. That is, when the tenth signal changes from the LOW level to the HI level, not only the information indicating the front door frame 14 read from the tenth correspondence area 123j but also the opening start information is stored together with the history information. It is stored in the area for storing the correspondence information of the area 125. Further, when the tenth signal changes from the HI level to the LOW level, not only the information indicating the front door frame 14 read from the tenth correspondence area 123j but also the opening end information is stored together with the history information. It is stored in the area for storing the correspondence information of the area 125.

The history information storage area 125 stores all history information generated during the 10 consecutive business days in which the game ball B1 is continuously emitted from the pachinko machine 10 from opening to closing. It is provided as many times as possible. For example, if history information is generated 60,000 times a day, 600,000 or more history information storage areas 125 are provided. As a result, all history information can be stored and held in the history memory 117 for at least 10 days.

The history memory 117 is provided with a pointer area 126 in addition to the history area 124. The pointer area 126 stores information for identifying the pointer information, which is the current write target in the history memory 117, by the management CPU 112. Specifically, at the shipping stage of the pachinko machine 10, the pointer area 126 is set with information designating the pointer information of “0” as a writing target. Then, 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 pointer information in the last order is the write target and the history information is stored in the history information storage area 125 corresponding to the pointer information in the last order, the pointer information is set so that the pointer information of “0” is the write target. The information in the usage area 126 is updated. As a result, when the history information storage trigger exceeds the number of history information items that can be stored, new history information is overwritten in order from the history information storage area 125 in which old history information is stored. Become.

Also, when history information is read from the history memory 117 by the reading device, all the history information storage area 125 is cleared to “0” and the pointer information of “0” is set as a write target. The information in the pointer area 126 is updated. As a result, it is possible to prevent the history information that has once been read from being read again.

Next, a specific processing configuration for managing the winning mode of the game ball B1 using the management IC 66 will be described. First, the processing configuration for storing the 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 types of signals in the correspondence memory 116 will be described. FIG. 33 is a flowchart showing the recognition processing executed by the main CPU 63. The recognition process is executed in step S110 in the main process (FIG. 17).

First, "15" is set to the recognition output counter provided in the main RAM 65 (step S1101). The recognition output counter indicates the remaining necessary number of information outputs for causing the management CPU 112 to recognize which kind of signal each buffer 122a to 122p of the input port 121 in the management I/F 111 corresponds to. This is a counter for the main CPU 63 to specify. As already described, 15 of the first to fifteenth buffers 122a to 122o are targets for recognition of signal types, so "15" is set in the recognition output counter.

After that, the output process of the identification start command is executed (step S1102). The main CPU 63 outputs various commands to the management CPU 112 so that the management CPU 112 can recognize which type of signal the first to fifteenth buffers 122a to 122o correspond to. When outputting this command, the first to eighth signals input to the first to eighth buffers 122a to 122h are used. That is, using the first to eighth signals (that is, the first to eighth signal paths 118a to 118h) used to instruct the management side CPU 112 to store history information, the first to fifteenth buffers 122a are used. Command output is performed to cause the management CPU 112 to recognize which type of signal corresponds to 122o. This reduces the number of signal paths as compared with a configuration in which the signal path for performing the command output is provided separately from the signal paths 118a to 118p for outputting signals to the first to sixteenth buffers 122a to 122p. It becomes possible to simplify the configuration. The identification start command has an 8-bit data capacity, and the 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 when the output of the identification start command is started in order to make the management CPU 112 recognize that the new command has been transmitted. Further, 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 side CPU 112 to recognize the output state of the identification start command and the ninth signal. Has been done. By receiving the identification start command, the management-side CPU 112 should start the process for storing the information on the correspondence between the first to fifteenth buffers 122a to 122o and the types of signals in the correspondence memory 116. Identify.

Then, 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 S1103). In this case, the first to the fifteenth buffers 122a to 122o are dealt with so that the first buffer 122a becomes the signal type setting target first and then the n+1th buffer becomes the signal type setting target next to the nth buffer. The signal type recognition setting is set. Therefore, if the recognition output counter is “15” to “13”, the type identification command indicating the general winning opening 31 and the number of prize balls is read out, and if the recognition output counter is “12”, the special prize is won. The type identification command indicating that it is the device 32 and the number of prize balls thereof is read out, and if the recognition output counter is “11”, the type identification command indicating that it is the first operation port 33 and the number of prize balls thereof is read out. 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 out. If the recognition output counter is "9", it is the out port 24a. The type identification command shown is read out, and if the recognition output counter is "8", the type identification command indicating the open/close execution mode is read out, and if the recognition output counter is "7", it is the high frequency support mode. Is read, and if the output counter for recognition is "6", the type identification command indicating the front door frame 14 is read, and if the output counter for recognition is "5" to "1", it is blank. The type identification command indicating that is is read.

After that, the output processing of the read type identification command is executed (step S1104). The type identification command has an 8-bit data capacity similarly to the identification start command, and the 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 processing 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 so that the management side CPU 112 recognizes that a 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 side CPU 112 to recognize the output state of the identification type command and the ninth signal. Has been done. By receiving the identification type command, the management-side CPU 112 responds to the identification type command in the correspondence relation areas 123a to 123o corresponding to the buffers to be set this time among the first to fifteenth buffers 122a to 122o. Information to be stored.

Thereafter, the value of the recognition output counter of the main RAM 65 is decremented by 1 (step S1105), and it is determined whether the value of the recognition output counter after the decrement is 1 is "0" (step S1106). When the value of the recognition output counter is 1 or more (step S1106: NO), the process for outputting the type identification command corresponding to the value of the recognition output counter after subtraction of 1 is executed (step S1103 and Step S1104).

On the other hand, when the value of the recognition output counter is “0” (step S1106: YES), the identification end command output process is executed (step S1107). The identification end command has an 8-bit data capacity, 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 of maintaining the output state of the ninth signal at the HI level are set to a period sufficient for the management-side CPU 112 to recognize the output state of the identification end command and the ninth signal. Has been done. Upon receiving the identification end command, the management-side CPU 112 identifies that the process 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, the 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-side CPU 112 is started. The processing speed of the management CPU 112 is faster than that of the main CPU 63, and the next timer interrupt processing (FIG. 18) is started after one timer interrupt processing (FIG. 18) is started in the main CPU 63. By the time the process starts, the combination of the processes after step S1206 in the management process is executed 16 times or more.

When the identification start command is received from the main CPU 63 (step S1201: YES), the value of the setting target counter provided in the management side RAM 114 is cleared to "0" (step S1202). The setting target counter is a counter for the management-side CPU 112 to specify the type of the buffer 122a to 122o for which the signal type is set. The first buffer 122a is the target for setting the signal type first, and then the n+1th buffer is the target for setting the signal type after the nth buffer.

After that, on condition that the type identification command is received from the main CPU 63 (step S1203: YES), the correspondence relationship setting process is executed (step S1204). In the correspondence relation setting process, of the first to fifteenth correspondence relation areas 123a to 123o of the correspondence relation memory 116, in the correspondence relation area corresponding to the current value of the setting target counter of the management side RAM 114, the type identification received this time is identified. Stores the signal type information set in the command. Then, the value of the setting target counter of the management side RAM 114 is incremented by 1 (step S1205).

If a negative determination is made in step S1203, or if the process of step S1205 is executed, it is determined whether or not an identification end command has been received from the main CPU 63 (step S1206). If the identification end command has not been received (step S1206: NO), the process returns to step S1203, and under the condition that the type identification command is newly received from the main CPU 63 (step S1203: YES), steps S1204 and S1205 are performed. Execute the process again.

When the identification end command is received from the main CPU 63 (step S1206: YES), the processes of steps S1207 and S1208 are repeatedly executed. In step S1207, details will be described later, but history setting processing 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 S1208, an external output process for outputting the history information stored in the history memory 117 to the reading terminal 102, which will be described in detail later, is executed.

FIG. 35 is a time chart showing a state in which information on the correspondence between the first to fifteenth buffers 122a to 122o and the types of signals input to these buffers 122a to 122o is stored in the correspondence memory 116. FIG. 35A shows a period during 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). FIG. 35B shows a period during which the output state of the ninth signal is at the HI level, and FIG. 35C shows the first to fifteenth buffers 122a to 122o and the types of signals input to these buffers 122a to 122o. 35D shows the execution period of the identification state in which the process for identifying the correspondence is executed, and FIG. 35D shows the timing at which the management CPU 112 executes the correspondence setting process (step S1204).

The supply of the operating power to the main CPU 63 and the management CPU 112 is started, so that the output of the identification start command using the first to eighth signals is started at the timing of t1 as shown in FIG. It Also, at the timing of t1, the output state of the ninth signal is changed from the LOW level to the HI level as shown in FIG. After that, at the timing of t2 in which 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. 35(b). The management-side CPU 112 confirms that the output state of the ninth signal is changed from the HI level to the LOW level, thereby specifying that the command is transmitted from the main-side CPU 63, 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 information of. In this case, since the identification start command has been received, the management-side CPU 112 enters the identification state by making a positive determination in step S1201 of the management process (FIG. 34). Thereafter, at the timing of t3, the output of the identification start command is stopped as shown in FIG.

Thereafter, at timing t4, as shown in FIG. 35A, the output of the first type identification command using the first to eighth signals is started. Further, at the timing of t4, the output state of the ninth signal is changed from the LOW level to the HI level as shown in FIG. After that, at the timing of t5, which is the situation where 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. 35(b). The management-side CPU 112 confirms that the output state of the ninth signal has been changed from the HI level to the LOW level, thereby specifying that the command has been transmitted from the main-side CPU 63, and the first to eighth buffers 122a to 122h are identified. By confirming the information, the content of the command received from the main CPU 63 is grasped. In this case, since the first type identification command has been received, the management-side CPU 112 executes the correspondence setting process at the timing of t5 as shown in FIG. In the correspondence relationship setting process, information indicating the general winning opening 31 and information on the number of prize balls are stored in the first correspondence area 123a of the correspondence memory 116. Thereafter, at the timing of t6, the output of the type identification command is stopped as shown in FIG.

After that, at each of the timing t7 to the timing t9, the timing t10 to the timing t12, the timing t13 to the timing t15, and the timing t16 to the timing t18, the same as the timing t4 to the timing t6, Correspondence relationship 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 from the timing t16 to the timing t18.

After that, at the timing of t19, as shown in FIG. 35A, the output of the identification end command using the first to eighth signals is started. Also, at the timing of t19, the output state of the ninth signal is changed from the LOW level to the HI level as shown in FIG. After that, at the timing of t20 in which 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. The management-side CPU 112 confirms that the output state of the ninth signal has been changed from the HI level to the LOW level, thereby specifying that the command has been transmitted from the main-side CPU 63, and the first to eighth buffers 122a to 122h are identified. By confirming the information, the content of the command received from the main CPU 63 is 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, at the timing of t21, the output of the identification end command is stopped as shown in FIG.

In order to instruct the management-side CPU 112 to store history information, the management-side CPU 112 recognizes whether or not 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 clear to the management CPU 112 that the command is being output. It becomes possible to recognize.

Next, a processing configuration for storing history information in the history memory 117 will be described. FIG. 36 is a flowchart showing the management output process executed by the main CPU 63. The management output process is executed in step S221 in the timer interrupt process (FIG. 18).

First, "10" is set in the managed counter provided in the main RAM 65 (step S1301). The management target counter specifies, by the main CPU 63, whether or not there is a management target that is not a target for specifying whether or not the signal output state to the management side CPU 112 should be changed in this management output process. At the same time, it is a counter for the main CPU 63 to specify which management target should change the signal output state to the management CPU 112. In the one-time management output process, the main CPU 63 specifies whether or not the signal output state to the management CPU 112 should be changed. The management targets are seven ball entrance detection sensors 42a to 48a, There are a total of 10 whether the open/close execution mode is executed, the high-frequency support mode is executed, and the front door frame 14 is opened/closed. Therefore, first, "10" is set in the managed counter.

Then, it is determined whether or not the output state of the signal to the management-side CPU 112 regarding the management target corresponding to the current value of the management target counter is the HI level (step S1302). If it is not at the HI level (step S1302: NO), it is determined whether or not the value of the managed counter is 4 or more, so that the entry detection sensors 42a having the seven managed objects corresponding to the value of the managed counter are detected. To 48a are specified (step S1303).

When an affirmative determination is made in step S1303, it is determined whether the output flag of the main RAM 65 corresponding to the value of the managed counter is set to "1" (step S1304). Specifically, when the value of the managed counter is “10” and corresponds to the first winning opening detection sensor 42a, it is determined whether or not the first output flag is set to “1”, When the value of the managed counter is “9” and corresponds to the second winning hole detection sensor 43a, it is determined whether or not “1” is set in the second output flag, and the value of the managed counter is determined. Is “8” and corresponds to the third winning opening detection sensor 44a, it is determined whether or not the third output flag is set to “1”, and the value of the managed counter is “7”. If it corresponds to the special electric power detection sensor 45a, it is determined whether or not "1" is set in the fourth output flag, the value of the managed counter is "6", and the first working opening detection sensor 46a. If it corresponds to the second output port detection sensor 47a, it is determined whether or not the fifth output flag is set to "1". In this case, it is determined whether or not the sixth output flag is set to "1". If the value of the managed counter is "4" and it corresponds to the outlet 24a, the seventh output flag is set to " It is determined whether "1" is set. As described above, the first to seventh output flags are set to "1" in the incoming ball detection process (FIG. 26).

When "1" is set in the output flag corresponding to the value of the managed counter (step S1304: YES), the output state of the signal corresponding to the value of the managed counter among the first to seventh signals is set to the HI level. Is set (step S1305). After that, the output flag corresponding to the value of the managed counter is cleared to "0" (step S1306).

When a negative determination is made in step S1303, it is determined whether or not a trigger for switching the output state of the signal corresponding to the value of the managed counter to the HI level has occurred (step S1307). Specifically, when the value of the managed counter is “3”, it is determined whether or not the transition to the open/close execution mode has occurred, and when the value of the managed counter is “2”, it is high. It is determined whether or not the transition to the frequency support mode has occurred, and when the value of the managed counter is "1", it is determined whether or not the front door frame 14 is in the open state. If an affirmative decision is made in step S1307, the output state of the signal corresponding to the value of the managed counter is set to the HI level (step S1308).

When an affirmative determination is made in step S1302, it is determined whether a trigger for switching the output state of the signal corresponding to the value of the managed counter to the LOW level has occurred (step S1309). Specifically, when the value of the management target counter is 4 or more and the current management target is any of the ball 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 output state of the corresponding signal 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 S1007) of the management process (FIG. 34) 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. When the value of the managed counter is “3” and the current managed object is the open/close execution mode, it is determined whether or not the open/close execution mode has ended, and the value of the managed counter is “2”. If the current management target is the high-frequency support mode, it is determined whether 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 the front door frame 14 is closed. When the trigger for switching the output state of the signal corresponding to the value of the managed counter to the LOW level has occurred (step S1309: YES), the output state of the signal corresponding to the value of the managed counter is set to the LOW level ( Step S1310).

If a negative determination is made in step S1304, the process of step S1306 is executed, a negative determination is made in step S1307, the process of step S1308 is executed, a negative determination is made in step S1309, or When the process of S1310 is executed, the value of the managed counter of the main RAM 65 is decremented by 1 (step S1311). Then, it is determined whether or not the value of the managed counter after subtracting 1 is "0" (step S1312). When the value of the management target counter is 1 or more (step S1312: NO), the processing from step S1302 is executed on the management target corresponding to the new management target counter value.

Next, the history setting process executed by the management-side CPU 112 will be described with reference to the flowchart of FIG. The history setting process is executed in step S1207 of the management process (FIG. 34).

First, the number of buffers to be confirmed in the management CPU 112 among the first to fifteenth buffers 122a to 122o is set to the confirmation counter provided in the management RAM 114 (step S1401). Specifically, of the first to fifteenth correspondence areas 123a to 123o in the correspondence memory 116, the number of correspondence areas in which information other than the information indicating blank is stored is specified, and the identification is performed. The information of the number that was set is set in the check target counter. As described above, in the pachinko machine 10, since information other than the information indicating that it is blank is stored in the first to tenth correspondence areas 123a to 123j, "10" is set in the check target counter in step S1401. To do.

Then, it is confirmed whether 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". Then, 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 S1402). When the value of the check target counter is "n", the nth buffers 122a to 122o are the check targets of the numerical information. For example, if the value of the check target counter is “10”, the tenth buffer 122j is the check target of the numerical information, and if the value of the check target counter is “5”, the fifth buffer 122e is the check target of the numerical information. ..

When an affirmative determination is made in step S1402, the RTC information that is the date information and the time information is read from the RTC 115 (step S1403). Then, the writing process to the history memory 117 is executed (step S1404). In the writing process, the pointer area 126 of the history memory 117 is referred to identify the pointer information of the history area 124 that is the current writing target, and the pointer information corresponds to the writing target pointer information. The RTC information read in step S1403 is written in the history information storage area 125 of the history area 124. Also, the correspondence information is read from the correspondence areas 123a to 123o corresponding to the current value of the check target counter, and the correspondence information is written in the history information storage area 125 corresponding to the pointer information to be written. If the correspondence information is any one of the information indicating the open/close execution mode, the information indicating the high frequency support mode, and the information indicating the front door frame 14, Not only the correspondence information but also the start information is written in the history information storage area 125 corresponding to the pointer information to be written. When the value of the confirmation target counter is “n”, the n-th correspondence relationship areas 123a to 123o are targets for reading correspondence information. For example, if the value of the check target counter is "10", the tenth correspondence area 123j is the read target of the correspondence information, and if the value of the check target counter is "5", the fifth correspondence area 123e is the correspondence relationship. It is a target for reading information.

When the value of the check target counter is any of the outlet 24a, the general winning opening 31, the special electricity winning device 32, the first operating opening 33, and the second operating opening 34 by executing the writing process as described above. In the history information storage area 125 corresponding to the pointer information to be written, the RTC information, the outlet 24a, the general winning opening 31, the special electricity winning device 32, the first operating opening 33, and the second operating opening 34 are displayed. And the combination of the correspondence information indicating that any of the above is stored as history information. Further, when the value of the check target counter is one of the open/close 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. The combination of the opening/closing execution mode, the high-frequency support mode, and the correspondence information indicating any one of the front door frames 14 and the start information is stored as history information.

After that, the target pointer is updated (step S1405). In the update processing, the numerical information stored in the pointer area 126 of the history memory 117 is read and 1 is added. 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. If the maximum value is not exceeded, the pointer information after adding 1 is overwritten in the pointer area 126 as new pointer information to be written. If it exceeds the maximum value, 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 S1402, or if the processing of step S1405 is executed, it is determined whether or not the signal output is switched to the LOW level in the correspondence areas 123a to 123o corresponding to the current value of the check target counter. It is determined whether or not the correspondence information to be confirmed is stored (step S1406). Specifically, when the current value of the check target counter is "8" to "10", the corresponding correspondence areas 123h to 123j have the information indicating the open/close execution mode and the high frequency support mode. Since either the information indicating that there is the information or the information indicating that it is the front door frame 14 is stored, a positive determination is made in step S1406.

If an affirmative decision is made in step S1406, 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". By checking 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 S1407). If an affirmative decision is made in step S1407, RTC information is read out (step S1408) as in step S1403, and writing processing to the history memory 117 is executed (step S1409). In the writing process, the RTC information read in step S1408 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 from the correspondence areas 123a to 123o corresponding to the current value of the check target counter, and the correspondence information is written in the history information storage area 125 corresponding to the pointer information to be written. 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 open/close execution mode, the high frequency support mode, and the front door frame 14, the pointer information corresponding to the writing target is dealt with. In the history information storage area 125, a combination of RTC information, 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 of being. Then, similar to step S1405, the target pointer update process is executed (step S1410).

If a negative determination is made in step S1406, a negative determination is made in step S1407, or if the processing of step S1410 is executed, the value of the check target counter of the management side RAM 114 is decremented by 1 (step S1411). Then, it is determined whether or not the value of the confirmation target counter after the subtraction of 1 is "0" (step S1412). When the value of the check target counter is 1 or more (step S1412: NO), the process of step S1402 and subsequent steps is executed for the check target corresponding to the new check target counter value.

Next, how the history information is stored in the history memory 117 will be described with reference to the time chart of FIG. 38A shows a period in which the HI level signal is input to any of the first to seventh buffers 122a to 122g, and FIG. 38B shows the eighth buffer 122h in which the HI level signal is input. 38(c) shows a period in which the HI level signal is input to the ninth buffer 122i, and FIG. 38(d) shows a HI level signal in the tenth buffer 122j. FIG. 38(e) shows the timing of writing history information to the history memory 117.

At the timing of t1, as shown in FIG. 38A, 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, the history information is written in the history memory 117 at the timing of t1 as shown in FIG. Thereafter, at the timing of t2, the signal switched to the HI level at the timing of t1 is switched to the LOW level as shown in FIG. 38(a). However, since the signal is a signal input to any of the first to seventh buffers 122a to 122g, and the switching of the LOW level is not the target of storing history information, the timing t2 in FIG. As shown in e), writing of history information is not executed.

After that, at each of the timing of t3, the timing of t5, the timing of t6, the timing of t9, the timing of t10, the timing of t13, and the timing of t14, as shown in FIG. The output state of the signal input to any of .about.122g is switched from the LOW level to the HI level. Therefore, at each of these timings, the history information is written as shown in FIG.

As shown in FIG. 38B, the output state of the signal input to the eighth buffer 122h becomes the HI level from the timing of t4 to the timing of t7. The eighth buffer 122h corresponds to the presence/absence of the open/close execution mode. Therefore, as shown in FIG. 38(e), the timing of t4, which is the timing 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 the timing of t4 includes start information, and the history information written at the timing of t7 includes end information. As a result, by checking the history information in the history memory 117, the execution period of the open/close execution mode can be grasped.

Further, history information is written in the history memory 117 in the order of passage of time. Therefore, whether the history information indicating that a ball has entered the outlet 24a, the general winning opening 31, the special electric winning device 32, the first operating opening 33, or the second operating opening 34 is in the opening/closing execution mode. It becomes possible to distinguish whether or not. Further, since the history information includes RTC information, by comparing the RTC information, any of the outlet 24a, the general winning opening 31, the special electricity winning device 32, the first working opening 33, and the second working opening 34 can be obtained. It is possible to distinguish whether or not the history information indicating that a ball has entered is in the opening/closing execution mode.

As shown in FIG. 38C, 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 the presence/absence of the high frequency support mode. Therefore, as shown in FIG. 38(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 the timing of t8 includes start information, and the history information written at the timing of t11 includes end information. As a result, by checking the history information in the history memory 117, the execution period of the high frequency support mode can be grasped.

Further, history information is written in the history memory 117 in the order of passage of time. Therefore, history information indicating that a ball has entered into any of the outlet 24a, the general winning opening 31, the special electric winning device 32, the first operating opening 33, and the second operating opening 34 is displayed even in the high-frequency support mode. It becomes possible to distinguish whether or not. Further, since the history information includes RTC information, by comparing the RTC information, any of the outlet 24a, the general winning opening 31, the special electricity winning device 32, the first working opening 33, and the second working opening 34 can be obtained. It is possible to distinguish whether or not the history information indicating that a ball has entered the car is in the high frequency support mode.

As shown in FIG. 38D, the output state of the signal input to the tenth buffer 122j becomes the HI level from the timing of t12 to the timing of t15. The tenth buffer 122j corresponds to whether or not the front door frame 14 is opened. Therefore, as shown in FIG. 38(e), the timing 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 of t15. In this case, the history information written at the timing of t12 includes start information, and the history information written at the timing of t15 includes end information. As a result, by confirming the history information in the history memory 117, it is possible to grasp the period during which the front door frame 14 is in the open state.

Further, history information is written in the history memory 117 in the order of passage of time. Therefore, history information indicating that a ball has entered into any one of the outlet 24a, the general winning opening 31, the special electric winning device 32, the first operating opening 33, and the second operating opening 34 is opening the front door frame 14. It is possible to distinguish whether or not it is. Further, since the history information includes RTC information, by comparing the RTC information, any of the outlet 24a, the general winning opening 31, the special electricity winning device 32, the first working opening 33, and the second working opening 34 can be obtained. It is possible to distinguish whether or not the history information indicating that a ball has entered the car is opening the front door frame 14.

Next, a processing configuration for outputting the history information stored in the history memory 117 to the reading device electrically connected to the reading terminal 102 of the MPU 62 will be described. FIG. 39 is a flowchart showing the data output process executed by the main CPU 63. The data output process is executed in step S111 in the main process (FIG. 17).

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 S1501). The reading device is configured to output a connection signal when it is electrically connected to the reading terminal 102, and when the reading signal is received through the reading terminal 102, an affirmative determination is made in step S1501. do.

When a negative determination is made in step S1501, this data output process is ended 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 output the history information to the outside, it is necessary to start supplying the operating power to the MPU 62 with the reading device electrically connected to the reading terminal 102. .. Since the power supply operation unit for performing the stop operation and the start operation of the supply of the operating power to the MPU 62 is provided on the back surface of the back pack unit 15, the outer frame 11 is required to perform the stop operation and the start operation. It is necessary to open the gaming machine main body 12 to expose the back surface of the back pack unit 15. Under such circumstances, in order to output the history information to the outside, 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 such a configuration, it becomes possible to make it difficult to perform the operation of reading the history information, even if the person other than the game hall manager performs the operation.

If an affirmative decision is made in step S1501, it is decided whether or not a control information confirmation signal is received from the reading terminal 102, so that the current connection of the reading device to the reading terminal 102 is the main ROM 64. It is determined whether or not the control information (program and data) is checked (step S1502). The reading device has a configuration capable of confirming both control information and history information. When the confirmation of the control information is selected by manual operation on the reading device, the reading device confirms the control information. A signal is transmitted, and when 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. Note that the present invention is not limited to this, and the control information confirmation reading device and the history confirmation reading device may be separate. 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 the reading terminal 102 reads for history confirmation. When the device is electrically connected, a signal for history confirmation is transmitted from the reading device.

If an affirmative decision is made in step S1502, an output process for confirming control information is executed (step S1503). 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, it becomes possible to read the control information by the reading device electrically connected to the reading terminal 102, and confirm whether the control information is regular or normal. It becomes possible to do.

When a negative determination is made in step S1502, an output instruction signal is transmitted to the management CPU 112 (step S1504). Specifically, the output state of the output instruction signal is switched from LOW level to 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 16th buffer 122p. When the output state of the output instruction signal is switched to the HI level, the management side CPU 112 executes the process for outputting the history information. The process will be described in detail later.

When the process of step S1503 is performed or the process of step S1504 is performed, it is determined whether the electrical connection of the reading device to the reading terminal 102 is continued (step S1505). If it continues (step S1505: YES), the process stands by in step S1505. This makes it 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 S1505: NO), this data output process ends.

Next, the external output process executed by the management-side CPU 112 will be described with reference to the flowchart of FIG. The external output process is executed in step S1208 of the management process (FIG. 34).

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 S1601: YES), processing for outputting history information after step S1602 is executed. Specifically, first, by counting the number of history information storage areas 125 in the history area 124 of the history memory 117 in which the correspondence information indicating the outlets 24a is stored, The number of entered balls is calculated (step S1602). In addition, by counting the number of history information storage areas 125 in which the correspondence information indicating the general winning opening 31 is stored in the history area 124 of the history memory 117, the entry into the general winning opening 31 is achieved. The number is calculated (step S1603). In addition, by counting the number of history information storage areas 125 in which the corresponding relationship information indicating the special electric prize winning apparatus 32 is stored in the history area 124 of the history memory 117, the special electric prize winning apparatus 32 is allowed to enter the ball. The number is calculated (step S1604). In addition, by counting the number of history information storage areas 125 in which the corresponding relationship information indicating the first operation port 33 is stored in the history area 124 of the history memory 117, the first operation port 33 is stored. The number of entered balls is calculated (step S1605). Further, by counting the number of history information storage areas 125 in the history area 124 of the history memory 117 in which the corresponding relationship information indicating the second operation ports 34 is stored, The number of entered balls is calculated (step S1606).

Thereafter, in the history area 124 of the history memory 117, the history information storage area 125 in which the correspondence information indicating the front door frame 14 and the start information are stored and the correspondence relationship indicating the front door frame 14 are stored. By referring to the history information storage area 125 existing in a period between the history information storage area 125 in which the information and the end information are stored, the out door generated in the situation where the front door frame 14 is in the open state The number of balls entered into each of the 24a, the general winning opening 31, the special electric winning device 32, the first operating opening 33, and the second operating opening 34 is calculated (step S1607). A history information storage area 125 in which the correspondence information indicating the front door frame 14 and the start information are stored in the history area 124 of the history memory 117, and the correspondence information indicating the front door frame 14 and The period between the end information and the history information storage area 125 is calculated from the RTC information stored in the history information storage area 125. Further, in the entire pointer information that is the serial number, the history information storage area 125 in which the correspondence information indicating the front door frame 14 and the start information are stored, and the correspondence relation indicating the front door frame 14 are stored. When there are a plurality of sections with the history information storage area 125 in which the information and the end information are stored, the total number of incoming balls for the section is calculated. Further, although there is the history information storage area 125 in which the correspondence information indicating the front door frame 14 and the start information are stored, the RTC information corresponding to the time after the history information storage area 125 is present. If the correspondence information and the start information indicating the front door frame 14 are not stored in the history information storage area 125 in which is stored, the correspondence information and the start information indicating the front door frame 14 are stored. The 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 treated as when the front door frame 14 is in the open state.

After that, various parameters are calculated using the calculation results of steps S1602 to S1607 (step S1608). Specifically, first, the number of incoming balls generated during the opening of the front door frame 14 calculated in step S1607 is subtracted from the number of incoming balls calculated in each of steps S1602 to S1606. Then, the following parameters are calculated by using the respective numbers of incoming balls after the subtraction. The difference between the number of balls entered in the outlet 24a calculated in step S1607 and the number of balls entered in step S1602 is defined as the number of entered balls K1, and the number of entered balls calculated in step S1603 is calculated in step S1607. The difference in the number of entered balls of the general winning opening 31 is set as the number of entered balls K2, and the difference in the number of entered balls of the special electric prize winning device 32 calculated in step S1607 with respect to the number of entered balls is set as the entered ball number K3, The difference between the number of balls entered in the first operation port 33 calculated in step S1607 and the number of balls entered in step S1607 is defined as the number of entered balls K4, and the number of entered balls calculated in step S1606 is calculated in step S1607. The difference in the number of entered balls at the second working port 34 is defined as the number of entered balls K5.
-First parameter: total payout number of game balls B1 (K2 x "number of prize balls for winning in the general prize hole 31" + K3 x "number of prize balls for winning in the special electric prize device 32" + K4 x "first working hole The ratio of the total number (K1+K2+K3+K4+K5) of the game balls B1 discharged from the game area PA (hereinafter, this ratio) As "D1")
-Second parameter: ratio of the total number K2 of game balls B1 to the general winning opening 31 / the total number (K1+K2+K3+K4+K5) of game balls B1 discharged from the game area PA-Third parameter: to the special electric prize winning device 32 Proportion of the total number K3 of game balls B1 entered into the game ball B1/the total number (K1+K2+K3+K4+K5) of the game balls B1 discharged from the game area PA. Ratio of the total number (K1+K2+K3+K4+K5) of the game balls B1 discharged from the game area PA (hereinafter, this ratio is referred to as “D2”)
Fifth parameter: ratio of the total number K5 of game balls B1 entering the second operation port 34/the total number of game balls B1 discharged from the game area PA (K1+K2+K3+K4+K5) (hereinafter, this ratio is referred to as “D3”) Do)
-Sixth parameter: D1-(D2 x "number of prize balls for winning in the first operating port 33" + D3 x "number of prize balls for winning in the second operating port 34")
・Seventh parameter: (K3דnumber of prize balls for winning in special electric prize winning device 32”+K5דnumber of prize balls for winning in second working opening 34”)/total payout number of gaming balls B1 (K2ד "Number of prize balls for winning in the general prize hole 31" + K3 x "Number of prize balls for winning in the special electric prize winning device 32" + K4 x "Number of prize balls for winning in the first working port 33" + K5 x "Second working port Ratio of the number of prize balls for winning in 34")/Eighth parameter: K3 x "Number of prize balls for winning in special electric prize winning device 32"/Total payout number of gaming balls B1 (K2 x "For general winning hole 31") “Number of prize balls for winning”+K3דNumber of prize balls for winning in the special electric prize winning device 32”+K4דNumber of prize balls for winning in the first operating port 33”+K5דAward for winning in the second operating port 34” After that, it is necessary to use the oldest RTC information and the newest RTC information in the history area 124 of the history memory 117 until all the history information to be calculated this time is extracted. The calculated total time is calculated (step S1609). Then, the first output process is executed (step S1610). In the first 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. In addition, the various parameters calculated in step S1608 are sequentially output to the reading terminal 102, and the total time calculated in step S1609 is output to the reading terminal 102. As a result, the reading device electrically connected to the reading terminal 102 reads each piece of information that is the output target in the first output process.

Thereafter, in the history area 124 of the history memory 117, the history information storage area 125 in which the correspondence information indicating the open/close execution mode and the start information are stored, and the correspondence information indicating the open/close 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 outlet 24a and the general winning opening 31 generated in the opening/closing execution mode are referred to. , The special electric prize winning device 32, the first actuating port 33 and the second actuating port 34, respectively, the number of incoming balls is calculated (step S1611). A history information storage area 125 in which correspondence information indicating the open/close execution mode and start information are stored in the history area 124 of the history memory 117, and correspondence information and end information indicating the open/close execution mode. The period between the history information storage area 125 and the history information storage area 125 is calculated from the RTC information stored in the history information storage area 125. Further, in the entire pointer information that is a serial number, the history information storage area 125 in which the correspondence information indicating the open/close execution mode and the start information are stored, and the correspondence information indicating the open/close execution mode and When there are a plurality of sections with the history information storage area 125 in which the end information is stored, the total number of entered balls for the section is calculated. Further, although there is the history information storage area 125 in which the correspondence information indicating the open/close execution mode and the start information are stored, the RTC information corresponding to the time after the history information storage area 125 is stored. When the stored history information storage area 125 does not store the correspondence information and the start information indicating the open/close execution mode, the correspondence information and the start information indicating the open/close execution mode are stored. All 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 treated as in the open/close execution mode.

After that, during the period of the opening/closing execution mode specified in step S1611, the outlet 24a, the general winning opening 31, the special electricity winning device 32, the first working opening 33, and the opening 24a generated in the situation where the front door frame 14 is in the open state. The number of balls entering each of the second working ports 34 is calculated (step S1612). The method of calculating the number of entered balls is the same as in the case of step S1607, except that the period of the opening/closing execution mode specified in step S1611 is assumed.

After that, various parameters are calculated using the calculation results of step S1611 and step S1612 (step S1613). Specifically, first, the number of incoming balls generated during the opening of the front door frame 14 calculated in step S1612 is subtracted from the number of incoming balls calculated in step S1611. Then, the following parameters are calculated by using the respective numbers of incoming balls after the subtraction. The difference between the number of balls entered into the outlet 24a calculated in step S1611 and the number of balls entered into the outlet 24a calculated in step S1612 is defined as the number of entered balls K11, and the number of the general winning openings 31 calculated in step S1611 is calculated. The difference in the number of balls of the general winning opening 31 calculated in step S1612 with respect to the number of balls is defined as the number of balls K12, and the special prize winning device calculated in step S1612 with respect to the number of balls of the special prize winning device 32 calculated in step S1611. The difference in the number of entered balls of 32 is K13, and the difference in the number of entered balls of the first operating port 33 calculated in step S1612 with respect to the number of entered balls of the first operating port 33 calculated in step S1611 The number K14 is defined as the number K14, and the difference between the number of balls entered in the second operation port 34 calculated in step S1611 and the number of balls entered in the second operation port 34 is set as number K15.
Eleventh parameter: total payout number of game balls B1 (K12 x "number of prize balls for winning in general prize hole 31" + K13 x "number of prize balls for winning in special electric prize winning device 32" + K14 x "first working hole" The ratio of the total number (K11+K12+K13+K14+K15) of the game balls B1 discharged from the game area PA (hereinafter, this ratio: the number of prize balls for winning 33)+K15דthe number of prize balls for winning in the second operating port 34”) As "D11")
・Twelfth parameter: ratio of the total number of game balls B1 entered into the general winning opening 31 K12/the total number of game balls B1 discharged from the game area PA (K11+K12+K13+K14+K15)・Thirteenth parameter: To the special prize winning device 32 Proportion of the total number K13 of game balls B1 entered into the game ball B1/the total number (K11+K12+K13+K14+K15) of the game balls B1 discharged from the game area PA. Fourteenth parameter: The total number K14 of entered balls into the first operating port 33 Ratio of the total number (K11+K12+K13+K14+K15) of the game balls B1 discharged from the game area PA (hereinafter, this ratio is referred to as “D12”)
Fifteenth parameter: ratio of the total number K15 of game balls B1 entering the second operation port 34/the total number of game balls B1 discharged from the game area PA (K11+K12+K13+K14+K15) (hereinafter, this ratio is referred to as “D13”). Do)
16th parameter: D11-(D12 x "the number of prize balls for winning in the first operating port 33" + D13 x "number of prize balls for winning in the second operating port 34")
Seventeenth parameter: (K13דnumber of prize balls for winning in special electric prize winning device 32”+K15דnumber of prize balls for winning in second working port 34”)/total payout number of gaming balls B1 (K12ד "Number of prize balls for winning in the general prize hole 31" + K13 x "Number of prize balls for winning in the special electric prize winning device 32" + K14 x "Number of prize balls for winning in the first working port 33" + K15 x "Second working port Ratio of the number of prize balls to the prize 34”)/Eighteenth parameter: K13דNumber of prize balls for prize to special electric prize winning device 32”/Total number of payouts of game balls B1 (K12דTo general prize hole 31”) "Number of prize balls for winning" + K13 x "Number of prize balls for winning in the special electric prize winning device 32" + K14 x "Number of prize balls for winning in the first operating port 33" + K15 x "Award for winning in the second operating port 34" After that, the second output process is executed (step S1614). In the second output process, the various parameters calculated in step S1613 are sequentially output to the reading terminal 102. As a result, the reading device electrically connected to the reading terminal 102 reads each piece of information that is the output target in the second output process.

After that, in the history area 124 of the history memory 117, the history information storage area 125 in which the correspondence information indicating the high frequency support mode and the start information are stored, and the correspondence relationship indicating the high frequency support mode. By referring to the history information storage area 125 existing in the period between the history information storage area 125 in which the information and the end information are stored, the outlet 24a generated in the high frequency support mode, The number of balls entered into each of the winning opening 31, the special electric winning device 32, the first operating opening 33, and the second operating opening 34 is calculated (step S1615). In the history area 124 of the history memory 117, the history information storage area 125 in which the correspondence information indicating the high frequency support mode and the start information are stored, and the correspondence information indicating the high frequency support mode and The period between the end information and the history information storage area 125 is calculated from the RTC information stored in the history information storage area 125. Further, in the entire pointer information that is a serial number, the history information storage area 125 in which the correspondence information indicating the high frequency support mode and the start information are stored, and the correspondence relation indicating the high frequency support mode. When there are a plurality of sections with the history information storage area 125 in which the information and the end information are stored, the total number of incoming balls for the section is calculated. Further, although there is the history information storage area 125 in which the correspondence information indicating the high frequency support mode and the start information are stored, the RTC information corresponding to the time later than the history information storage area 125 is present. If the correspondence information and the start information indicating the high frequency support mode are not stored in the history information storage area 125 in which is stored, the correspondence information and the start information indicating the high frequency support mode are stored. All 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 treated as in the high frequency support mode.

After that, during the period of the high-frequency support mode specified in step S1615, the outlet 24a, the general winning opening 31, the special electricity winning device 32, and the first operating opening 33 that are generated when the front door frame 14 is in the open state. Then, the number of balls entering each of the second operation ports 34 is calculated (step S1616). The method of calculating the number of entered balls is the same as that in step S1607, except that the period of the high-frequency support mode specified in step S1615 is assumed.

Then, various parameters are calculated using the calculation results of steps S1615 and S1616 (step S1617). Specifically, first, the number of incoming balls generated during the opening of the front door frame 14 calculated in step S1616 is subtracted from the number of incoming balls calculated in step S1615. Then, the following parameters are calculated by using the respective numbers of incoming balls after the subtraction. The difference in the number of balls entered into the outlet 24a calculated in step S1616 with respect to the number of balls entered into the outlet 24a calculated in step S1615 is defined as the number of entered balls K21. The difference in the number of balls of the general winning opening 31 calculated in step S1616 with respect to the number of balls is defined as the number of balls K22, and the special prize winning device calculated in step S1616 with respect to the number of balls of the special prize winning device 32 calculated in step S1615. The difference in the number of entered balls of 32 is K23, and the difference in the number of entered balls of the first operating port 33 calculated in step S1616 with respect to the number of entered balls of the first operating port 33 calculated in step S1615 The number K24 is defined as the number K24, and the difference between the number of balls entered in the second operation port 34 calculated in step S1615 and the number of balls entered in the second operation port 34 is set as number K25.
21st parameter: total payout number of game balls B1 (K22 x "number of prize balls for winning in general prize hole 31" + K23 x "number of prize balls for winning in special electric prize winning device 32" + K24 x "first working hole Ratio of the total number (K21+K22+K23+K24+K25) of game balls B1 discharged from the game area PA (hereinafter, this ratio) As "D11")
-Twenty-second parameter: ratio of the total number K22 of game balls B1 to the general winning opening 31 / the total number (K21+K22+K23+K24+K25) of game balls B1 discharged from the game area PA-Twenty-third parameter: to the special electric prize winning device 32 Proportion of the total number K23 of game balls B1 entered into the game ball B1/the total number (K21+K22+K23+K24+K25) of the game balls B1 discharged from the game area PA. The 24th parameter: the total number K24 of entered balls into the first working port 33 K24/ Ratio of the total number (K21+K22+K23+K24+K25) of the game balls B1 discharged from the game area PA (hereinafter, this ratio is referred to as “D22”)
Twenty-fifth parameter: ratio of the total number K25 of game balls B1 entering the second operation port 34/the total number of game balls B1 discharged from the game area PA (K21+K22+K23+K24+K25) (hereinafter, this ratio is referred to as “D23”). Do)
-Twenty-sixth parameter: D21-(D22 x "number of prize balls for winning in first operating port 33" + D23 x "number of prize balls for winning in second operating port 34")
After that, the third output process is executed (step S1618). In the third output process, various parameters calculated in step S1617 are sequentially output to the reading terminal 102. As a result, the reading device electrically connected to the reading terminal 102 reads each piece of information to be output in the third output process. After that, a clear process is executed (step S1619). In the clearing process, the history information storage area 125 of the history memory 117 is all cleared to "0" and the pointer area 126 is cleared to "0". As a result, the history area 124 is in the initialized state.

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

In the ordinary train open lottery, the period for winning the regular train open prize is set to occur at intervals of 1 sec. In addition, the random number for opening used in the ordinary electric open lottery is numerical information that is cleared to "0" when "1" is added and becomes the maximum value each time the update timing is reached, and the initial value is also set every time it makes one turn. Is the numerical information to be updated. Further, the game board 24 is provided with an adjusting mechanism 180 for discharging the game ball B1 toward the first through gate 35 at intervals of 1 sec. For this reason, when the timing at which the prize can be entered into the first through gate 35 is deviated from the winning target period, it is a non-winning continuous period in which the result of losing is continuous in the ordinary electric lottery. In addition, when the timing when the prize can be entered into the first through gate 35 and the winning target period overlap with each other, it is a winning continuous period in which the ordinary electric open winning is continuous in the ordinary electric open lottery. The transition from the non-winning continuous period to the continuous winning period is performed without notifying the player in advance. In this way, by always expecting the player to have a winning continuous period in which it does not know when it will occur, it is possible to improve the interest of the game and to provide a novel effect.

In the opening initial value counter C5 for updating the initial value of the general electric utility article opening counter C4, the numerical value information is updated by adding "1" at each update timing, and the numerical value information is the maximum value. It is a loop counter that is cleared to "0" when it becomes. The random number initial value updating process for updating the numerical information in the opening initial value counter C5 is executed not only in the residual process of the main process that is executed irregularly but also in the timer interrupt process that is executed regularly. It is a configuration that is done. For this reason, it is possible to prevent the numerical value information obtained from the opening initial value counter C5 from being biased in the initial value update of the ordinary electric utility article opening counter C4 which is regularly performed. As a result, in the low frequency support mode, it is possible to generate a transition from the non-winning continuous period to the winning continuous period at a timing that is difficult for the player to guess and at an appropriate frequency.

When the transition from the non-winning continuous period to the continuous winning period is performed, the initial value update of the universal electric accessory release counter C4 is postponed once during the continuous winning period. Therefore, the initial value update interval in the winning continuous period is longer than the initial value update interval in the non-winning continuous period. By increasing the duration of the winning continuous period without reducing the frequency of occurrence of the winning consecutive period, it is possible to make the winning continuous period advantageous and attractive to the player. As a result, it is possible to increase the player's expectation for the winning consecutive period and to improve the interest of the game.

The probability that a general electric open win will occur in the low-frequency support mode, which combines the non-winning continuous period and the continuous winning period, is lower than the probability that a general electric open win will occur in the high-frequency support mode. However, if the transition from the non-winning continuous period to the winning continuous period occurs in the low frequency support mode, the possibility of the general electric open win is higher than the possibility of the general electric open win in the high frequency support mode. Get higher In the low-frequency support mode, the player will not be notified of the timing of shifting from the non-winning continuous period to the winning continuous period, so that the normal frequency is released in the low-frequency support mode combining the non-winning continuous period and the winning continuous period. While the probability of winning is lower than the probability of a general electric open winning in the high frequency support mode, the player's expectation for the general electric open win in the low frequency support mode is increased, The interest in can be improved.

The rotating body 183 of the adjusting mechanism 180 is configured to generate a plurality of timings at which the loaded game ball B1 can be discharged toward the first through gate 35 while the rotating body 183 makes one rotation. By reducing the angle at which the rotating body 183 has to rotate before ejecting the game ball B1, the state in which the rotating body 183 can take in the game ball B1 can be continued for a long time. Thereby, it is possible to increase the probability that the game ball B1 flowing down near the upstream of the intake port 185 of the adjusting mechanism 180 is taken into the recessed portions 183b to 183e of the rotating body 183. It is possible to prevent the gaming ball B1 that is periodically supplied to the first through gate 35 from being chipped, and to avoid a situation in which the timing of the universal electric open winning is missed during the winning continuous period.

The recesses 183b to 183e of the rotating body 183 have a shape that widens toward the outer edge. In addition, only the fourth recess 183e has a size slightly smaller than the sizes of the other recesses 183b to 183d. The distance from the discharge position in the adjusting mechanism 180 to the first through gate 35 is equal to or larger than the diameter of the game ball B1. Therefore, the discharge start position and the discharge direction of the game ball B1 discharged from the recessed portions 183b to 183e may be shifted to the left, and may be disengaged from the first through gate 35. When all of the game balls B1 taken into the adjusting mechanism 180 enter the first through gate 35, the player may pay attention only to taking in the game balls B1 into the adjusting mechanism 180 and not paying attention to the discharge. On the other hand, a part of the game ball B1 discharged from the adjusting mechanism 180 is removed from the first through gate 35, thereby attracting the player's attention until winning the first through gate 35, and playing the game. The interest in can be improved.

By setting the discharge start position of the game ball B1 discharged from the adjusting mechanism 180 to a position displaced to the right from the position right below the center of the adjusting mechanism 180, the game ball B1 is discharged after being taken into the adjusting mechanism 180. This is a configuration that shortens the time until By shortening the time required for the series of flows of the game ball B1 to be taken in, conveyed, and discharged by the adjusting mechanism 180, it is possible to suppress the possibility that the player's interest may be transferred to the middle of the series of flows. ..

The game ball B1 that has been taken into one of the recesses 183b to 183e of the rotating body 183 and conveyed from the upper part to the lower part of the adjustment mechanism 180 comes into contact with the discharge right side surface 181g of the discharge protrusion 181e. Since the ejecting protrusion 181e is fixed to the accommodating portion 181, the game ball B1 that is taken into one of the recesses 183b to 183e and conveyed in the lower portion of the adjusting mechanism 180 is on the left side of the ejecting right side surface 181g. Can't move to. The game ball B1 is discharged downward from a certain discharge position. In this way, the game ball B1 fails to be discharged in the lower part of the adjusting mechanism 180, and the game ball B1 that has not been discharged is not conveyed again to the upper part of the adjusting mechanism 180. For this reason, the failure to eject the game ball B1 in the lower part of the adjusting mechanism 180 continues, the same game ball B1 continues to rotate in the adjusting mechanism 180, and the taking in and discharging of the game ball B1 in the adjusting mechanism 180 are not delayed.

The game ball B1 discharged from the adjustment mechanism 180 and won in the first through gate 35, the game ball B1 discharged from the adjustment mechanism 180 and removed from the first through gate 35, and the game ball B1 not taken in from the intake port 185 The game ball B1 that has entered the escape passage 172 is then configured to be able to enter either the first operating port 33 or the second operating port 34. Therefore, even if the adjusting mechanism 180 is provided above the first through gate 35, the number of gaming balls B1 heading toward the second operating port 34 becomes insufficient when the winning continuous period is set in the low frequency support mode. There is no such thing.

The peripheral surfaces 188a to 191a of the blade portions 188 to 191 located above the rotary body 183 are configured to be inclined downward toward the rear. Therefore, the game ball B1 that is not taken in around the intake port 185 of the adjusting mechanism 180 is provided behind the intake port 185 while being guided by the inclination of the peripheral surfaces 188a to 191a of the blade portions 188 to 191. It moves to the passage entrance 171 of the escape passage 172 that is present. As a result, the number of game balls B1 taken into the adjusting mechanism 180 by stopping the unloaded game balls B1 near the intake port 185 or disturbing the flow of the game balls B1 upstream of the intake port 185. It can be prevented from decreasing. It is possible to prevent the player from being less interested in the adjusting mechanism 180 due to a decrease in the frequency with which the game ball B1 is taken into the adjusting mechanism 180.

The acrylic plate 172a fixed in front of the escape passage 172 and the adjustment mechanism 180 existing in front of the escape passage 172 are transparent. Therefore, the player can visually recognize the whereabouts of the game ball B1 after entering the passage entrance 171. This can prevent the flow of the game ball B1 that the player can grasp from being interrupted midway.

At the passage outlet 173 of the escape passage 172, a game ball B1 discharged from the passage outlet 173 toward the front side of the surface of the game board 24 and a game ball B1 flowing down at the front side of the surface of the game board 24. An exit roof 174 is provided to prevent the clashes at the exit of the escape passage 172. Thus, at the passage outlet 173, it is possible to avoid the situation in which the game ball B1 that is being discharged forward from the escape passage 172 returns to the inside of the escape passage 172 due to a collision.

Each of the front surfaces 188b to 191b of the blade portions 188 to 191 of the rotating body 183 and the standing wall side end surface 182 of the intake port 185 has the rotating body 183 when the game ball B1 is sandwiched in the intermediate state. It is a configuration in which an inclination is provided for allowing the game ball B1 to enter the rear passage entrance 171 by utilizing the rotating force. Therefore, in the state where the game ball B1 is sandwiched, it is possible to prevent the rotating body 183 from being unable to rotate. It is possible to reduce the possibility that a problem occurs during the game and a countermeasure is required to interrupt the game and solve the problem.

Further, at the intake port 185, the force applied from the front surfaces 188b to 191b to the game ball B1 in a state of being in contact with both the front surfaces 188b to 191b and the standing wall side end surface 182 is downward. Have ingredients. Therefore, the game ball B1 in contact with both the front surfaces 188b to 191b and the standing wall side end surface 182 is prevented from being pushed out upward, and the game ball B1 in the intake port 185 of the adjusting mechanism 180 is prevented. It is possible to prevent the flow from being disturbed. As a result, it is possible to avoid a situation in which the game ball B1 cannot be taken in and the periodic supply of the game ball B1 to the first through gate 35 is hindered.

The accommodating portion 181 of the adjusting mechanism 180 is formed with a discharge protrusion 181e for discharging the game ball B1 captured in the recesses 183b to 183e. As a result, it is possible to avoid a situation in which the game ball B1 conveyed to the lower side due to the rotation of the rotating body 183 is not discharged well, and the same game ball B1 continues to rotate. By preventing the frequency with which the game ball B1 is taken into the adjusting mechanism 180 and the frequency with which the game ball B1 is discharged from the adjusting mechanism 180 from decreasing, it is possible to keep the player's interest in the adjusting mechanism 180.

Further, by reliably ejecting the game ball B1 taken into the adjusting mechanism 180 within a fixed period, it is possible to prevent the pace at which a new game ball B1 is taken into the adjusting mechanism 180 from falling. By preventing the frequency at which the game ball B1 is taken into the adjustment mechanism 180 from decreasing, it is possible to avoid a situation in which the player is less interested in the adjustment mechanism 180.

Since the game ball B1 is paid out when the game ball B1 enters any of the general winning opening 31, the special electric winning device 32, the first operating opening 33, and the second operating opening 34, the player can play the ball A game is played while expecting the game ball B1 to enter one of them. In this configuration, the game ball B1 is inserted into any one of the outlet 24a, the general winning opening 31, the special electric winning device 32, the first operating opening 33, and the second operating opening 34 (hereinafter, also referred to as a history-targeted ball entering portion). When a sphere occurs, history information corresponding to the sphere is stored in the history memory 117 of the management IC 66. As a result, the pachinko machine 10 can store and hold information for managing the number of entered balls or the frequency of entering the game ball B1 into each history target entering portion, and use this managed information. By doing so, it becomes possible to appropriately manage the entry mode of the game ball B1 into each history target entry part. Further, by storing and holding the history information in the pachinko machine 10 itself, it becomes possible to prevent unauthorized access to the history information and unauthorized modification.

All the ball-in units that discharge the game ball B1 from the game area PA are targets for execution of storage processing of history information and targets for management using history information. As a result, it becomes possible to manage the ball entry frequency for any history-target ball entry section by using the history information. Further, it is possible to manage the ratio of the number of game balls B1 entering the history target ball-in portion to the number of game balls B1 discharged from the game area PA, using history information.

The history information includes RTC information, which is information corresponding to the timing at which the game ball B1 enters the history-targeted ball entering section that has triggered the storage of the history information. With this, by using the history information, it is possible to grasp the entry history of the game ball B1 into the history entry ball portion in detail.

In the memory 117 for history, not only history information corresponding to the game ball B1 entering the history target ball portion, but also history information indicating whether or not the opening/closing execution mode is in effect, and the high frequency support mode in History information indicating whether or not there is stored history information indicating whether or not the front door frame 14 is open. As a result, it is possible to manage whether or not the game ball B1 enters the history target ball-in section by distinguishing whether or not each of these situations is present.

The history information stored in the history memory 117 can be output to a reading device which is a device outside the pachinko machine 10. As a result, it becomes possible to read the history information with the reading device and analyze the entry mode of the game ball B1 into the history target entry part by using the read history information.

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

The information to be output from the reading terminal 102 is specified as a program or history information, and the information on the side corresponding to the specified result is externally output through the reading terminal 102. Accordingly, in the configuration in which the history information is externally output using the reading terminal 102 for externally outputting the program, the pachinko machine 10 determines whether the information to be externally output is the program or the history information. It is specified on the side, and the specified information is output to the outside. Therefore, it is possible to read out only the necessary information even if 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 whether the 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 regarding selection of information to be output to the outside from becoming complicated.

An MPU 62 having a main ROM 64 that stores a program in advance has a management IC 66 and a reading terminal 102. As a result, the signal paths for the reading terminal 102 can be integrated in the MPU 62. Therefore, it is possible to obtain the excellent effect as already described while making it difficult to illegally access the signal path to the reading terminal 102.

Mainly executes a process for allowing the game ball B1 to be paid out based on the game ball B1 entering the general winning opening 31, the special electric winning device 32, the first operating opening 33, or the second operating opening 34. A management CPU 112 is provided separately from the side CPU 63, and the management CPU 112 executes a process for storing history information in the history memory 117. As a result, it is possible to manage the entry mode of the game ball B1 into each history target entry part while preventing the processing load of the main CPU 63 from increasing extremely.

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

The main CPU 63 uses the signal paths corresponding to the detection results of the ball detection sensors 42a to 48a and the signal paths corresponding to the ball detection sensors 42a to 48a, respectively, to the buffers of the input port 121 of the management IC 66. 122a to 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 each type of information in the management CPU 112 is simplified. It becomes possible to do.

The main CPU 63 has information corresponding to whether the open/close execution mode is in effect, information corresponding to whether the high frequency support mode is in effect, 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 by using the signal paths corresponding to each of these situations. As a result, the type of information corresponding to each of these situations corresponds to each of the buffers 122h to 122j (that is, each signal path), and the configuration for distinguishing each type of information in the management side CPU 112 is simplified. It becomes possible.

The main CPU 63 transmits to the management CPU 112 correspondence information indicating which type of information each buffer 122a to 122j (that is, each signal path 118a to 118j) corresponds to. This eliminates the need to store the correspondence information in the management IC 66 in advance. Therefore, the versatility of the management IC 66 can be improved.

When the supply of operating power to the main CPU 63 is started, the correspondence information is transmitted from the main CPU 63 to the management IC 66. As a result, in a situation in which the game ball B1 can enter the history-targeted ball entrance portion, the management IC 66 can specify the correspondence between the information transmitted from the main CPU 63 and the history-targeted ball entrance portion. It becomes possible to become.

Correspondence relationship information is transmitted from the main CPU 63 to the management IC 66 by using the signal paths 118a to 118g for transmitting information indicating whether or not the game ball B1 has entered the history target ball portion. This makes it possible to simplify the configuration related to communication as compared with the configuration in which a dedicated signal path for transmitting the correspondence information is provided.

The management IC 66 is provided with a correspondence memory 116, and the correspondence information transmitted from the main CPU 63 to the management IC 66 is stored in the correspondence memory 116. With this, every time the main CPU 63 transmits the information of the detection result of each of the entrance detection sensors 42a to 48a, the information that enables the management target IC 66 to specify the history target entrance part corresponding to the information of the transmission target. Eliminates the need to provide. Therefore, it is possible to suppress the amount of information of the detection result of each of the ball detection sensors 42a to 48a transmitted from the main CPU 63.

Information is output from the management IC 66 to the reading terminal 102 by switching the output state of the output instruction signal output from the main CPU 63 to the management IC 66 from the LOW level to the HI level. In this case, the fact that the signal path corresponding to the 16th buffer 122p corresponds to the output instruction signal can be specified by the management-side CPU 112 without receiving the correspondence information from the main-side CPU 63. .. This makes it possible to prevent the configuration related to the transmission of the correspondence information from becoming extremely complicated.

The management IC 66 is provided with buffers 122a to 122p capable of receiving information from the main CPU 63, the number of which is larger than the number of types of information required to be transmitted from the main CPU 63 to the management IC 66. Has been. As a result, even when the number of types of the information increases or decreases depending on the model of the pachinko machine 10, it is possible to deal with it without changing the configuration related to the buffers 122a to 122p. Therefore, the versatility of the management IC 66 can be improved.

When the history information is transmitted from the management IC 66 to the reading terminal 102, each history information includes correspondence information indicating the type of history-target ball entrance portion corresponding to the history information. Thereby, it is possible to specify the entering mode of the game ball B1 into each history target entering part by using the read history information.

By using the history information stored in the history memory 117 in the management IC 66, various parameters (first to eighth, 11 to 18) corresponding to the entry mode of the game ball B1 in the game area PA in a predetermined period are used. , 21-26 parameters) are calculated. As a result, it becomes possible to externally output various parameters, which are the results of calculation using the history information.

Various parameters are calculated with the history information corresponding to the situation where the front door frame 14 is open is excluded. This makes it possible to derive various parameters in a normal situation where the front door frame 14 is in the closed state. In addition, various parameters corresponding to the open/close execution mode and the high-frequency support mode are calculated. As a result, it becomes possible for the manager of the game hall or the like to grasp the entry mode of the game ball B1 according to each situation.

When various parameters are calculated, the history memory 117 is initialized by executing the clearing process of the history memory 117. As a result, the history information that exceeds the storage capacity of the history memory 117 becomes a storage target in the history memory 117, and the history information that should normally be stored and retained is erased by overwriting. It becomes possible to make it difficult to generate.

When outputting various parameters to the reading terminal 102, the history information stored in the history memory 117 is also output to the reading terminal 102. As a result, when various parameters are read and the entry mode of the game ball B1 in the game area PA is analyzed, it is possible to refer not only to the various parameters but also to the history information that is the basis of the calculation of the various parameters. ..

The management-side CPU 112 calculates various parameters when the reading device is electrically connected to the reading terminal 102. This makes it possible to reduce the frequency of calculating various parameters.

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

Whether or not the reading device is electrically connected to the reading terminal 102 is specified by a process executed by the main CPU 63 at the time of starting the supply of operating power, and the reading device is electrically connected. If is specified, the output instruction information is transmitted from the main CPU 63 to the management IC 66. Thereby, in the situation where the processing at the time of starting the supply of the operating power is being executed by the main CPU 63 or the like, that is, before the normal processing for advancing the game in the main CPU 63 is started, various The parameter calculation and the external output of various parameters as the calculation result are completed. Therefore, it becomes possible to prevent the calculation of various parameters and the external output of the calculation results from being performed in a situation where the game ball B1 may enter the history target ball input unit, and the processing load of the management IC 66. Can be reduced.

When the game ball B1 enters the first operation port 33 or the second operation port 34, the history information is stored in the history memory 117 in a configuration in which an external output corresponding to the ball is generated through the external terminal board 97. It Thereby, by using the information output to the outside through the external terminal board 97, while easily grasping the number and the frequency of entering the game ball B1 into the first operating port 33 and the second operating port 34, By using the history information stored in the history memory 117, it is possible to accurately grasp the number and the frequency of the game balls B1 entering the history target entrance portion.

<Another form in the first embodiment>
-In the above-mentioned 1st Embodiment, it may change to the structure which updates the initial value of the universal electric accessory opening counter C4, and may change the drive mode of the adjustment drive part 184 at a predetermined timing. If the initial value of the general electric accessory release counter C4 is not updated, the winning target period always occurs in a cycle of 1 sec. On the other hand, for example, the adjustment drive unit 184 rotates the rotating body 183 at the first rotation speed, the first rotation mode, the rotating body 183 rotates at the second rotation speed, and the rotating body 183. May be configured to include a third rotation mode in which is rotated at a third rotation speed. Here, the first rotation speed is a rotation speed for supplying the game ball B1 to the first through gate 35 in a cycle of 0.8 sec, and the second rotation speed is the game ball B1 for the first through gate 35. It is the rotation speed supplied in a cycle of 1 sec. The third rotation speed is the rotation speed at which the game ball B1 is supplied to the first through gate 35 in a cycle of 1.2 sec.

In this case, the main CPU 63 is provided with a switching random number counter having the same configuration as the opening initial value counter C5 instead of the opening initial value counter C5 (FIG. 13). When the winning of the first through gate 35 occurs in the low-frequency support mode, the main CPU 63 uses the numerical information updated by the switching random number counter as the general electric power reservation information to store one of the general electric power reservation areas HA1 to HA1. Store in HA4. The main CPU 63 executes a switching determination process for determining whether or not the numerical information acquired from the switching random number counter is the numerical information of the switching target stored in the main ROM 64, whereby the adjustment drive unit 184. Determines the switching timing of the rotation mode of.

The switching determination process is executed when a prize is paid to the first through gate 35 in the low frequency support mode. By using the switching determination process, the timing at which the rotation mode of the adjustment drive unit 184 is switched can be randomized. In the switching determination process, the main CPU 63 sequentially switches the rotation modes of the adjustment drive unit 184 in the following order: first rotation mode→second rotation mode→third rotation mode→first rotation mode at each switching timing. .

Each time the rotation mode of the adjustment drive unit 184 is switched, the relationship between the winning possible timing for the first through gate 35 and the winning target period is changed. For example, in the first rotation mode in which the game ball B1 wins in the first through gate 35 in the 0.8 sec cycle, if the winning possible timing of the 0.8 sec cycle does not overlap with the winning target period of the 1 sec cycle, the ordinary electric power is released. In the lottery, the result of losing is continuous. In addition, in the first rotation mode, when the winning possible timing of the 0.8 sec cycle overlaps with the winning target period of the 1 sec cycle, the regular electric open winning is performed once every five times. Since the cycle length of the winning timing is different from the cycle length of the winning target period, the universal electric open winning occurs in the 4 sec cycle which is the least common multiple of the two cycles.

In the second rotation mode in which the game ball B1 wins the first through gate 35 in the 1 sec cycle, if the winning possible timing of the 1 sec cycle does not overlap the winning target period of the 1 sec cycle, it has already been described in the first embodiment. In addition to the non-winning continuous period, when the winning possible timing of the 1 sec cycle overlaps the winning target period of the 1 sec cycle, the winning continuous period has already been described in the first embodiment.

In the third rotation mode in which the game ball B1 wins the first through gate 35 in the 1.2 sec cycle, if the winning possible timing of the 1.2 sec cycle does not overlap with the winning target period of the 1 sec cycle, in the normal electric open lottery Continuation of out-of-range results. In addition, in the third rotation mode, when the winning possible timing of the 1.2 sec cycle overlaps with the winning target period of the 1 sec cycle, the regular electric open winning is performed once every five times. Since the cycle length of the winning timing is different from the cycle length of the winning target period, the universal electric open winning occurs in the 6 sec cycle which is the least common multiple of the two cycles.

Since the rotation speed of the rotating body 183 can be visually recognized from the outside, the player can check the rotation speed of the rotating body 183 during the game to know the timing when the rotation mode is switched. In a configuration that does not notify the player of the timing when the winning continuous period occurs, by making it possible to grasp the switching timing of the rotation mode, the expectation for the winning continuous period of the player is increased each time the rotating mode switches, The interest in can be improved.

In addition, in each regular electric train opening lottery, in addition to the continuous winning period in which the regular electric train opening win occurs in a 1 second cycle, there are five intervals and a period in which a regular electric train open win occurs in a 4 second cycle, and a fifth interval. At the same time, it is possible to generate a period in which a universal electric open win is generated in a cycle of 6 seconds. By increasing the variation of the mode of occurrence of the regular train open winning, it is possible to improve the interest of the game.

-In the above-mentioned 1st Embodiment, it may change to the structure which updates the initial value of the universal electric accessory opening counter C4, and may be a structure with which multiple types of winning judgment value tables in the ordinary electric lottery are prepared. For example, in the main ROM 64, in addition to the low-frequency winning determination value table T1 in which the winning target period of 24 msec is started in a 1 sec cycle, the first winning determination in which the winning target period of 24 msec is started in a 0.8 sec cycle is started. The value table and the second win determination value table in which the win target period of 24 msec starts at a 1.2 sec cycle may be stored in advance. The winning determination value is set to (200×n−5) to (200×n) in the first exchange table, and the winning determination value is set to (300×n−5) to (300) in the second exchange table. Xn) is set. Here, the variable n in the first exchange table is a natural number of 1 to 327, and the variable n in the second exchange table is a natural number of 1 to 218.

In this case, the main CPU 63 is provided with a switching random number counter having the same configuration as the opening initial value counter C5 instead of the opening initial value counter C5 (FIG. 13). The main CPU 63 acquires the numerical value information updated by the switching random number counter when a prize is paid to the first through gate 35 in the low frequency support mode, and uses the numerical value information to perform the switching determination process described above. To execute. By the switching determination process, the switching timing of the winning determination value table used for the ordinary electric open lottery is determined.

By using the switching determination process, the switching timing of the winning determination value table used for the universal electric open lottery can be set to a random timing. In the switching determination process, the main CPU 63 performs in the order of the low-frequency winning determination value table T1→the first winning determination value table→the second winning determination value table→the low-frequency winning determination value table T1 in the switching determination process. , Switch the winning judgment value table used for the ordinary electric open lottery.

Each time the winning determination value table used for the ordinary electric open lottery is switched, the relationship between the winning possible timing to the first through gate 35 and the winning target period is changed. For example, when the first winning judgment value table is used in the regular electric open lottery and the winning target period occurs in the 0.8 sec cycle, the winning timing of the 1 sec cycle does not overlap with the winning target period of the 0.8 sec cycle. Will continue to be missed in the regular open lottery. Further, in the case where the first winning determination value table is used, if the winning possible timing of the 1 sec cycle overlaps the winning target period of the 0.8 sec cycle, the regular electric open winning is performed once every five times. Since the cycle length of the winning timing is different from the cycle length of the winning target period, the universal electric open winning occurs in the 4 sec cycle which is the least common multiple of the two cycles.

In the case where the low frequency winning determination value table T1 is used for the regular electric lottery and the winning target period occurs in the 1 sec cycle, if the winning possible timing of the 1 sec cycle does not overlap with the winning target period of the 1 sec cycle, In the case where the non-winning continuous period has already been described in the first embodiment and the winning possible timing of the 1 sec cycle overlaps the winning target period of the 1 sec cycle, the winning continuous period already described in the first embodiment is set. Become.

In the case where the second winning judgment value table is used for the regular electric open lottery and the winning target period occurs in the 1.2 sec cycle, when the winning possible timing of the 1 sec cycle does not overlap with the winning target period of the 1.2 sec cycle , The result of continuous failure in the Open Dentsu lottery. Also, when the second winning determination value table is used, if the winning possible timing of the 1 sec cycle overlaps with the winning target period of the 1.2 sec cycle, the regular electric open winning is performed once every 5 times. Since the cycle length of the winning timing is different from the cycle length of the winning target period, the universal electric open winning occurs in the 6 sec cycle which is the least common multiple of the two cycles.

In addition to the winning continuous period in which the regular electric open lottery occurs every 1 sec in each regular electric open lottery, there are 5 intervals and the period in which the regular electric open win occurs in 4 sec periods It is possible to generate a period in which a regular electric train open win occurs. By increasing the variation of the mode of occurrence of the regular train open winning, it is possible to improve the interest of the game.

Further, for example, the main ROM 64 has a third exchange table in which the winning determination values are set to (250×n−105) to (250×n-100), and the winning determination value is (250×n−). 205) to (250×n−200) and the fourth replacement table may be stored in advance. Each time the numerical information in the ordinary electric utility open counter C4 is updated once, it is used in the ordinary electric open lottery in the order of the low frequency winning determination value table T1→the third exchange table→the fourth exchange table. The table of the winning determination value to be switched is switched. As a result, it is possible to create a winning continuous period and a non-winning continuous period by shifting the winning target period without changing the initial value of the general electric accessory opening counter C4.

In the above-described first embodiment, the frequency of the normal power open state per unit time in the winning continuous period of the low frequency support mode is higher than the frequency of the normal power open state per unit time in the high frequency support mode. It may have a low configuration. Then, in the low frequency support mode, the frequency of occurrence of the winning continuous period may be increased. For example, in a series of opening/closing operations of the universal electric accessory 34a executed by the universal electric open winning in the winning continuous period, the total time of the open state may be reduced. Specifically, in a series of opening/closing operations, a method of reducing the number of times of opening, a method of shortening one opening time, and a method of lengthening a closed state during a series of opening/closing operations are used alone or in combination. As a result, it is possible to reduce the frequency of being in the normal power open state per unit time during the winning continuous period of the low frequency support mode.

In addition, in the case where the universal electric open wins occur in succession during the winning period, a series of opening/closing operations based on one universal electric open win is performed, and then a series of opening/closing operations based on the next general electric open win. By using the method of lengthening the time until it is performed, it is possible to reduce the frequency of being in the universal communication open state per unit time during the winning continuous period of the low frequency support mode.

Further, for example, by increasing the frequency with which the initial value of the general electric auditors item release counter C4 is updated, it is possible to increase the frequency with which the winning continuous period occurs in the low frequency support mode. Specifically, the frequency of occurrence of the winning target period can be increased by adopting a configuration in which the initial value is updated at the timing when the general electric utility article release counter C4 makes a half turn. When the winning target period is reached, the initial value update of the general electric utility article release counter C4 is forgotten three times, so that only the frequency of the winning target period occurs without changing the length of the winning target period. Can be increased.

It is possible to reduce the frequency of the normal electric power open state per unit time in one winning continuous period, and increase the frequency of winning continuous period in the low frequency support mode. Therefore, in the low-frequency support mode in which the non-winning continuous period and the winning continuous period are combined, the continuous winning period can easily occur without changing the frequency of the normal electric power open state per unit time. It is possible to give the player the impression. As a result, in the low frequency support mode, it is possible to increase the expectation of the player for the winning continuous period that the winning continuous period may occur.

In the above-described first embodiment, the relationship between the winning continuous period in the low frequency support mode and the high frequency supporting mode is that the winning continuous period in the low frequency support mode is higher than the high operating frequency in the second operating port 34. It is not limited to the relation that winning a prize is likely to occur. In the low-frequency support mode, the regular electric open lottery occurs continuously in the regular electric open lottery during the winning period, whereas in the high frequent support mode, the regular electric open lottery has a probability of approximately 3/5 in the regular electric open lottery. Occurs. In the high-frequency support mode, a series of opening and closing operations in which the universal electric accessory 34a is in the open state for 1 sec and is in the closed state for 1 sec is repeated five times, triggered by one universal power release win. On the other hand, for example, during the winning continuous period of the low-frequency support mode, a series of opening/closing operations in which the universal electric device 34a is opened for 0.8 seconds and closed for 1 second is repeated three times. The possibility of winning a prize in the second operating port 34 in the high frequency support mode can be made higher than the probability of winning a prize in the second operating port 34 in the winning continuous period in the low frequency support mode. it can. As a result, while maintaining the superiority of the high-frequency support mode over the low-frequency support mode, the expectation for the winning of the second operating port 34 in the low-frequency support mode becomes extremely low. It can be avoided.

In addition, for example, in the winning continuous period of the low frequency support mode, a series of opening and closing operations in which the utility servant 34a is opened for 1 sec and closed for 1 sec is repeated three times, whereby the high frequency support mode is set. As a result, the possibility that a prize will be awarded to the second working port 34 can be made similar to the possibility that a prize will be awarded to the second operating port 34 in the low frequency support mode. As a result, even in the non-winning continuous period of the low frequency support mode, the player shoots the game ball B1 while expecting that the winning of the second operating port 34 will occur to the same extent as in the high frequency support mode. The operation can be performed.

It should be noted that the relationship between the possibility of winning the second working port 34 in the low-frequency support mode and the possibility of winning the second working port 34 in the high-frequency support mode is shown. The parameters for adjusting are not limited to the opening time and the number of times of opening the general electric accessory 34a. For example, as the parameter, the probability of being a general electric open prize in the general electric open lottery in the low frequency support mode, the probability of being a general electric power open prize in the high frequency support mode, or the like may be adjusted.

-In 1st Embodiment mentioned above, it is good also as a structure which the universal electric accessory 34a has only one type of support mode which supports the winning to the 2nd actuation mouth 34 of the game ball B1. Specifically, the main side ROM 64 stores only one winning determination value table in which a winning determination value to be a target of the universal opening lottery is set in the universal opening lottery. In the winning determination value table, (250×n−9) to (250×n) are set as the winning determination values that are targets of the universal electric open winning. Here, the variable n is a natural number of 1 to 262. In this configuration, the probability of winning the ordinary electric open prize in the ordinary electric open lottery is about 1/25. The winning target period in which the winning judgment value that is the target of the universal electric open winning continues for a period of 1 sec and continues for 40 msec. In this configuration, there are a non-winning continuous period that does not result in a general electric open lottery in the general electric open lottery, and a state in which it is a continuous winning period and a continuous continuous electric power open win occurs in the general electric open lottery. There are two possible states. Regarding the support by the ordinary electric equipment 34a, by limiting the advantageous period for the player only to the winning consecutive period that does not occur in advance, the player's expectation for the winning consecutive period is increased and the winning consecutive period is always maintained. Can be made aware of. As a result, the interest in the game can be improved.

In the above-described first embodiment, the adjusting mechanism 180 may have a configuration in which a discharging guard portion that surrounds the outer edge of the rotating body 183 is also formed in the lower portion. Further, the adjusting mechanism 180 may be provided with a discharge escape passage that allows the game ball B1 that is sandwiched when discharged to the rear of the game board 24. Specifically, in the lower portion of the adjusting mechanism 180, a discharge port formed along the outer edge of the rotating body 183 has a discharge port through which the game ball B1 can pass. The game ball B1 taken into the recesses 183b to 183e in the upper part of the adjusting mechanism 180 is discharged from the discharge port of the discharging guard part in the lower part of the adjusting mechanism 180.

The game board 24 is located behind the front surface of the game board 24 when the game ball B1 is sandwiched between the side surface of the discharge port and one of the blade portions 188 to 191 of the rotating body 183 when discharged from the adjusting mechanism 180. Equipped with an escape escape passage for escape. Further, on the surface of the game board 24 in the vicinity of the discharge port, a discharge passage inlet is formed as an opening that allows the game ball B1 sandwiched at the time of discharge to enter the discharge escape passage.

The discharge escape passage communicates with the escape passage 172. An end surface on the left side of the discharge port of the discharge guard portion is inclined rearward to the left. Therefore, when the game ball B1 is sandwiched between the rotating body 183 and the discharge guard portion when the game ball B1 is discharged from the discharge port, the sandwiched game ball B1 is rotated by the rotating body 183. Pushed backwards. The pushed game ball B1 passes through the discharge passage inlet and enters the discharge escape passage. The game ball B1 passes through the escape passage 172 and is discharged from the passage outlet 173.

By using the escape passage for discharge, even if the discharge guard portion is provided in the lower portion of the adjusting mechanism 180, it is possible to avoid the situation where the game ball B1 is stuck between the rotating body 183 and the discharge guard portion and does not move. can do. By arranging the game ball B1 to be discharged from the discharge port of the discharge guard section, the game ball B1 can be directed toward the first through gate 35 and discharged.

In the above-described first embodiment, a gap is provided between the rotating body 183 and the standing walls 181c, 181d so that the game ball B1 cannot enter, and the movement of the game ball B1 passing through the escape passage 172 is visually recognized from the gap. It may be possible. In this case, an opaque material can be used for the rotating body 183 and the standing walls 181c and 181d. By increasing the degree of freedom in selecting materials, it is possible to select materials that match costs and designs.

In the above-described first embodiment, the initial value of the universal electric accessory release counter C4 may be updated as in the non-winning continuous period even during the continuous winning period. Specifically, in the non-winning continuous period of the low frequency support mode, even if the universal electric open win occurs three times in a row, the send-off flag 65d is not set to "1". Therefore, at the initial value update timing that first comes after the winning continuous period, the updating of the initial value of the universal electric accessory release counter C4 is executed, and the winning continuous period ends. Expectation of winning in the second working port 34 in the low-frequency support mode by setting the winning continuous period shorter than the configuration in which the update of the initial value of the utility electric utility open counter C4 is forgotten during the continuous winning period. It is possible to maintain the superiority of the high frequency support mode over the low frequency support mode, while increasing the

In the above-described first embodiment, the initial value update of the ordinary electric utility article release counter C4 that is sent off when the send-off flag 65d is set to "1" is not limited to once. When the send-off flag 65d is set to "1", the update of the initial value of the universal electric accessory release counter C4 may be sent off a plurality of times. When the winning consecutive period is reached, the player can be more interested in the winning consecutive period by increasing the possibility of winning the jackpot in the win/loss lottery and shifting to the jackpot state.

When the send-off flag 65d is set to "1", the jackpot result may be obtained in the win/loss lottery, and the initial value update of the general electric accessory opening counter C4 may be postponed until the jackpot state is entered. In the low-frequency support mode, the send-off flag 65d is set to "1" when the universal electric open win is generated three times in a row, and the send-off flag 65d is cleared to "0" when the jackpot state is entered. . As a result, the player can be confident of shifting to the jackpot state when the winning consecutive period is reached. By making the winning consecutive period attractive to the player, it is possible to expect a transition to the big hit state even in the low frequency support mode, and it is possible to improve the interest of the game.

When the total number of winnings to the first operating port 33 and the number of winnings to the second operating port 34 in the period in which the send-off flag 65d is set to "1" is counted, and the total number exceeds the reference value The send-off flag 65d may be cleared to "0". As a result, in the continuous winning period, the winnings of the reference number of times or more to the operation ports 33 and 34 are secured. To make the winning continuous period attractive to the player by avoiding that the winning continuous period ends with a small number of winnings in the operating openings 33 and 34 despite the continuous winning period. You can

The number of times the initial value update of the universal electric accessory release counter C4 is postponed based on the fact that the send-off flag 65d is set to "1" may be random. For example, when the initial value update timing is reached with the send-off flag 65d set to "1", a lottery may be performed to determine whether or not to continue the winning continuous period. It is possible to raise the player's interest in the winning continuous period by making the possibility of the winning continuous period continuing for a long time.

In the above-described first embodiment, the fact that the main CPU 63 enters the winning continuous period is triggered by the occurrence of one prize in the first through gate 35 in the non-winning continuous period of the low frequency support mode. It may be configured to grasp. As already described in the first embodiment, during the non-winning continuous period of the low-frequency support mode, the universal electric open win does not occur based on the winning of the first through gate 35. On the other hand, the probability of winning the general electric open prize in the general electric open lottery based on the winning of the second through gate 39 is about 1/42. In the non-winning continuous period of the low-frequency support mode, when the first gate detection sensor 49a detects the winning of the first through gate 35, the main CPU 63 determines the seeoff flag 65d based on the one winning. Is set to "1", and when the second gate detection sensor 50a detects the winning of the second through gate 39, the "off" flag 65d is not set to "1". For this reason, even when the winnings to the second through gate 39 happen to be consecutive, it is possible to avoid setting the send-off flag 65d to "1" based on the winnings.

In the above-described first embodiment, it may be instructed to operate the game ball launching device aiming at the first through gate 35, and operating the game ball launching device aiming at the second through gate 39. May be instructed. For example, in the low frequency support mode, when the second gate detection sensor 50a detects the winning of the second through gate 39, the left hitting instruction command is transmitted to the sound emission control device 81. The sound emission control device 81 that has received the left-handed support command sends a command to the display control device 82 to prompt the player to operate the game ball launching device aiming at the first through gate 35. It is displayed on the display surface 41a of the display device 41. In addition, the sound emission control device 81 controls the speaker unit 54 to output a sound that prompts the player to operate the game ball launching device aiming at the first through gate 35.

In the high-frequency support mode, when the first gate detection sensor 49a detects the winning of the first through gate 35, the right-handing instruction command is transmitted to the sound emission control device 81. The sound emission control device 81 that has received the right-handed support command sends a command to the display control device 82 to prompt the player to operate the game ball launching device aiming at the second through gate 39. It is displayed on the display surface 41a of the display device 41. In addition, the sound emission control device 81 controls the speaker unit 54 to output a sound that prompts the player to operate the game ball launching device aiming at the second through gate 39.

When the main CPU 63 shifts from the low-frequency support mode to the high-frequency support mode, the main-side CPU 63 sends the above-described right-handing instruction command to the sound emission control device 81 to aim at the second through gate 39 and shoot a game ball When the player is urged to operate the device and when the high frequency support mode is changed to the low frequency support mode, the first through gate is transmitted by transmitting the above-mentioned left hitting support command to the sound emission control device 81. The player is urged to operate the game ball launching device aiming at 35. In this way, by notifying the operation mode of the game ball launching device that is advantageous to the player, even when an unskilled player operates the game ball launching device, the winning continuous period, the high frequency support mode, etc. The game contents can be enjoyed.

In the above-described first embodiment, when the main CPU 63 grasps the winning continuous period, it may be configured to notify the player of the winning continuous period. As already described in the first embodiment, the main CPU 63 determines that the winning continuous period has been reached when the universal electric open win occurs three times in succession in the low frequency support mode non-winning continuous period. Figure out In this case, the main CPU 63 transmits a continuous notification command to the voice emission control device 81. The sound emission control device 81 that has received the continuous notification command controls the display light emitting unit 53 and the speaker unit 54, and also transmits a command to the display control device 82, so that the player has won the winning continuous period. Notify that. For example, the configuration may be such that a direct notification is given by clearly indicating that the winning consecutive period has been reached, and by prompting the first through gate 35 to operate the game ball launching device. Further, it may be configured to indirectly notify by changing the background on the display surface 41a of the symbol display device 41.

In addition, the main CPU 63 transmits a continuous production command to the sound emission control device 81 in response to the winning continuous period, so that the sound emission control device 81 grasps that it is the continuous winning period. Good as The main CPU 63 transmits a continuous end command to the sound emission control device 81, triggered by the end of the winning continuous period. When the voice emission control device 81 receives the continuous end command, it recognizes that the winning continuous period has ended. When the voice emission control device 81 receives the variation command and the type command from the main CPU 63 during the period from the reception of the continuous effect command to the reception of the continuous end command, the effect for game play is won. Change to the one for continuous period.

In this way, not only the movement of the ordinary electric accessory 34a, but also the notification or effect using the display light emitting unit 53, the speaker unit 54, and the symbol display device 41, the winning continuous period is appealed, and the winning continuous period is played. Can impress the person. By making the winning continuous period conscious in the low frequency support mode, it is possible to avoid the boredom of the player in the low frequency support mode and to improve the enjoyment of the game.

In the above-described first embodiment, the winning lottery that is triggered by the winning of the second working opening 34 is more advantageous to the player than the winning lottery that is triggered by the winning of the first working opening 33. May be Then, the holding information acquired by winning the second operating port 34 may be preferentially consumed over the holding information acquired by winning the first operating port 33. The configuration will be specifically described below.

When a prize is generated in the first working opening 33, a combination of numerical information of the winning random number counter C1, the jackpot type counter C2, and the reach random number counter C3 is used as the first lottery pending information in order to use the first winning lottery. To be acquired. In addition, when a winning is generated in the second working opening 34, a combination of numerical value information of the winning random number counter C1, the big hit type counter C2, and the reach random number counter C3 is held for the second lottery in order to be used for the second winning lottery. It is acquired as information. In the hold storage area 65a, the second lottery hold information is stored in an area different from the first lottery hold information. Then, if at least one piece of the first lottery hold information and the second lottery hold information are stored at the execution timing of the winning lottery, the second winning lottery based on the second lottery hold information is the first. It is executed with priority over the lottery per one. When the winning is achieved in the winning lottery based on the winning of the first working opening 33, the mode is changed to the opening/closing execution mode in which the special electric winning device 32 can be won. Similarly, even if the winning is achieved in the winning lottery based on the winning of the second working opening 34, the mode is changed to the opening/closing execution mode in which the special electric winning device 32 can be won. The types of jackpot results set in the sorting table used for the second winning lottery are more advantageous to the player than the types of jackpot results set in the sorting table used for the first winning lottery. Has become.

In the configuration, as already described in the first embodiment, the adjusting mechanism 180 is provided above the first through gate 35, and the non-winning continuous period or the continuous winning period is set in the low frequency support mode. Become. The possibility of winning the operating ports 33, 34 in the low-frequency support mode, which is a combination of the non-winning continuous period and the winning continuous period, is the possibility of winning the operating ports 33, 34 in the high-frequency support mode. Since it is lower than the above, the player's expectation that a winning for the operating ports 33, 34 will occur is low. However, during the continuous winning period, the support by the universal electric accessory 34a is likely to be executed, so that the possibility of winning a prize in the second working port 34 increases. In addition, this configuration is a configuration in which the player is more likely to obtain a favorable result when a prize is generated at the second operating port 34 than when a prize is generated at the first operating port 33. For this reason, even in the low-frequency support mode, the player may enjoy great profits due to the occurrence of continuous winning periods. By increasing the player's expectation for the winning period, in the low frequency support mode, the player's expectation that a prize will be generated in the second operating port 34 will be increased and the interest of the game will be improved. it can.

<Second Embodiment>
In this embodiment, the configuration for periodically supplying the game ball B1 to the first through gate 35 is different from that of the first embodiment. The configuration different from that of the first embodiment will be described below. The description of the same configuration as the first embodiment is basically omitted.

First, the configuration of the game board 210 in this embodiment will be described with reference to FIG. FIG. 41 is a front view of the game board 210 showing the first through gate 35 and the configuration above the first through gate 35 in an enlarged manner. As shown in FIG. 41, in the game board 210 of the present embodiment, an adjusting mechanism 220 is provided above the first through gate 35 instead of the adjusting mechanism 180 in the first embodiment. The adjustment mechanism 220 adjusts the timing at which the game ball B1 wins the first through gate 35.

As shown in FIG. 41, the adjusting mechanism 220 rotates the rotating body 230 that conveys the game ball B1 (FIG. 3) taken into the adjusting mechanism 220 from the upper part to the lower part of the adjusting mechanism 220, and the rotating body 230. The drive unit 184 for adjusting which has already been described in the first embodiment, and the game ball B1 which houses the rotating body 230 and is conveyed to the discharge position by the rotating body 230 is provided for supplying the driving force for And a housing 250 for preventing the centrifugal force from discharging outward before reaching the discharge position.

The adjusting mechanism 220 discharges the game ball B1 taken in at the upper part of the adjusting mechanism 220 toward the first through gate 35 located below the adjusting mechanism 220. As shown in FIG. 41, the distance from the lower end of the adjusting mechanism 220 to the first through gate 35 is set to be equal to or larger than the diameter of the game ball B1. Specifically, the adjustment mechanism 220 is provided at a distance of about 2.5 times the diameter of the first through gate 35 and the game ball B1. And, in the course of the game ball B1 discharged from the adjusting mechanism 220 toward the first through gate 35, it is prevented that a part of the game ball B1 discharged from the adjusting mechanism 220 enters the first through gate 35. A sorting nail 271 is provided for this purpose.

The distribution nail 271 is provided so as to project forward by 6 mm from the front surface of the game board 210. Therefore, among the game balls B1 having a diameter of 11 mm flowing down the game area PA (FIG. 3) having a length dimension of 18 mm in the front-rear direction, the game ball B1 flowing down near the game board 24 collides with the sorting nail 271. As a result, the game ball B1 flowing down near the window panel 52 will be removed from the first through gate 35 and will win the first through gate 35 without colliding with the sorting nail 271.

The configuration of the adjusting mechanism 220 will be described. As shown in FIG. 41, the housing 250 includes a plate-shaped base body 251 used for fixing the housing 250 to the game board 210. FIG. 42( a) is a plan view of the housing 250 showing the adjustment mechanism 220 right above. As shown in FIG. 42(a), the game board 210 is provided with a fixing recess 211 that can accommodate the base body 251 without a gap. The adjustment mechanism 220 is fixed to the game board 210 by nailing the four corners of the base body 251 as shown in FIG. 41 in a state where the base body 251 is housed in the fixing recess 211. When the adjusting mechanism 220 is fixed to the game board 210, the front surface of the base body 251 is flush with the front surface of the game board 210.

As shown in FIG. 41, an accommodation space for accommodating the rotating body 230 is formed in the housing 250, and the rotating body 230 is arranged at the center of the accommodating space. Behind the base body 251, the adjustment drive unit 184 described in the first embodiment is arranged. The output shaft 184a of the adjustment drive unit 184 extends from the front surface of the adjustment drive unit 184 toward the front in a direction orthogonal to the front surface of the game board 210.

A through hole (not shown) for inserting the output shaft 184a is formed in the base body 251. The rotating body 230 is connected to the output shaft 184a such that the axis of the rotating body 230 is located on the same straight line as the output shaft 184a of the adjustment drive unit 184. When the adjustment drive unit 184 is driven, the rotating body 230 rotates clockwise at an angular velocity of 90° for 1 second.

In the adjusting mechanism 220, by rotating the rotating body 230, the game ball B1 taken into the adjusting mechanism 220 in the upper part of the accommodation space is conveyed to the lower part of the accommodation space. The adjusting mechanism 220 becomes a state in which one gaming ball B1 can be discharged each time the rotating body 230 makes a quarter rotation. That is, the adjusting mechanism 220 can supply the game ball B1 to the first through gate 35 in a cycle of 1 sec, similarly to the adjusting mechanism 180 in the first embodiment.

By generating the winning possible timing already described in the first embodiment in a cycle of 1 sec, it is possible to generate the non-winning continuous period when the winning possible timing does not overlap with the winning target period of the ordinary electric lottery. If the winning timing overlaps with the winning target period, a continuous winning period can be generated.

As shown in FIG. 41, the housing 250 includes standing walls 252, 253, 261 for partitioning a storage space in which the rotating body 230 is stored. A plurality of standing walls 252, 253, 261 are formed on the base body 251 so as to project forward from the front surface of the base body 251. As shown in FIG. 42( a ), the standing walls 252, 253, 261 extend from the front surface of the base body 251 to the vicinity of the back surface of the window panel 52. The standing walls 252, 253, 261 are formed in such a manner as to surround the rotary body 230 with a space from the outside of the peripheral surface of the rotary body 230. The distance from the center of the rotating body 230 to the standing walls 252, 253, 261 is constant, and the accommodation space is divided into a circle by the standing walls 252, 253, 261.

FIG. 43 is a front view of the single rotating body 230 shown separately from the adjusting mechanism 220. As shown in FIG. 43, the rotating body 230 is a substantially disk-shaped resin member, and four step portions that are equally spaced in the circumferential direction are present on the peripheral surface of the rotating body 230. Here, the step surfaces 241a to 244a of the four step portions are in the order of the first step surface 241a→the second step surface 242a→the third step surface 243a→the fourth step surface 244a in the rotation direction of the rotating body 230. Are lined up like this. The four step surfaces 241a to 244a project in the radial direction of the rotating body 230, and the projecting dimensions of the four step surfaces 241a to 244a are substantially the same as the radius of the game ball B1.

As shown in FIG. 43, the rotating body 230 has a side inside the first step surface 241a (a side closer to the center of the rotating body 230) and an outer side of the second step surface 242a (a side farther from the center of the rotating body 230). And a second support surface 242 that connects the inner side of the second step surface 242a and the outer side of the third step surface 243a. Is equipped with. In addition, the rotating body 230 includes a third support surface 243 that connects an inner side of the third step surface 243a and an outer side of the fourth step surface 244a, and also includes an inner side of the fourth step surface 244a. A fourth supporting surface 244 is provided that connects the side and the outer side of the first supporting surface 241.

As shown in FIG. 43, each of the support surfaces 241 to 244 is a curved surface formed by bulging outward. In each of the support surfaces 241-244, the distance from the center of the rotating body 230 to the support surfaces 241-244 gradually becomes shorter as the rotation direction (clockwise) advances from the front side to the rear side. For example, when the first support surface 241 is specifically described, as shown in FIG. 43, the distance from the center of the rotating body 230 to the first support surface 241 is the second step surface 242a which is the front side in the rotation direction. Side is long and becomes gradually shorter toward the first step surface 241a side which is the rear side in the rotation direction.

As shown in FIG. 41, any one of the support surfaces 241-244 of the rotating body 230, the step surfaces 241a-244a located at the rear ends of the supporting surfaces 241-244 in the rotation direction, and the rotating body 230 are housed. The space defined by the upstanding walls 252, 253, 261 that partition the housing space has a shape and size that can accommodate the game ball B1.

As shown in FIG. 41, the left side of the circular accommodation space is partitioned by the left standing wall 261 and the lower right side of the accommodation space is partitioned by the lower right standing wall 253. The left standing wall 261 and the lower right standing wall 253 are formed integrally with the base body 251. The lower right standing wall 253 includes a rotating shaft 254 at the upper end of the lower right standing wall. The rotation shaft 254 extends forward in a manner orthogonal to the front surface of the base body 251. The upper right side of the accommodation space is partitioned by an upper right standing wall 252 which is an independent member not fixed to the base body 251. The upper right standing wall 252 is connected to the lower right standing wall 253 in such a manner that the upper right standing wall 252 can be rotated around the rotating shaft 254 to a certain angle.

FIG. 42B is an enlarged front view of the housing 250 around the rotation shaft 254. As shown in FIG. 42( b ), in the portion where the lower right upright wall 253 and the upper right upright wall 252 are connected, the upper right upright wall 252 is centered on the rotary shaft 254 on the right side of the rotary shaft 254. There is a gap that allows it to rotate clockwise. Therefore, when a rightward force is applied to the upper right standing wall 252 from the outside, the upper right standing wall 252 can rotate clockwise about the rotating shaft 254. On the other hand, on the left side of the rotating shaft 254, there is no gap that allows the upper right standing wall 252 to rotate counterclockwise about the rotating shaft 254.

As shown in FIG. 42(b), the state in which the upper right standing wall 252 cannot be further rotated counterclockwise (to the left in FIG. 42(b)) is the initial state. The upper right standing wall 252 rotates clockwise up to a displacement position indicated by a chain double-dashed line in FIG. 41 with an upper limit of approximately 15°. By rotating the upper right standing wall 252 from the initial position to the displaced position, the distance from the center of the rotating body 230 to the upper right standing wall 252 is extended.

The upper right standing wall 252 is located at the initial position when a force is not applied from the outside, and when the force is applied from the outside in the right direction, the upper right standing wall 252 rotates about the rotation shaft 254 to a displacement position. When the force from the outside is removed, the upper right standing wall 252 that has been rotated to the deformed position by the force from the outside rotates counterclockwise about the rotation shaft 254 by its own weight and returns to the initial position.

As shown in FIG. 41, the upper side of the accommodation space is partitioned by a left standing wall 261 and an upper right standing wall 252. Directly above the rotating body 230, the left standing wall 261 and the upper right standing wall 252 are separated from each other, and the space between the two standing walls 252 and 261 is an inlet 262 for taking the game ball B1 into the accommodation space. Has become. The width of the intake port 262 is set to be slightly larger than the diameter of the game ball B1 so that the game balls B1 flowing down from above can be taken one by one.

Since the upper right standing wall 252 that defines the right end of the intake port 262 is rotatable around the rotation shaft 254 from the initial position to the displaced position, the intake port 262 is deformed as necessary, The adjustment mechanism 220 makes it easy to take in the game ball B1. The manner in which the adjusting mechanism 220 takes in the game ball B1 from the taking-in port 262 will be described later.

The game ball B1 taken into the adjusting mechanism 220 is conveyed from the upper part to the lower part of the adjusting mechanism 220 while being in contact with any of the supporting surfaces 241 to 244 of the rotating body 230. The support surfaces 241 to 244 of the rotating body 230 will be described below.

As shown in FIG. 43, the first support surface 241, the second support surface 242, and the third support surface 243 are inclined toward the front toward the axial center. Therefore, the game ball B1 conveyed while contacting any one of these three support surfaces 241-243 is located on the front side (window panel 52 side) of the game area PA (FIG. 3). On the other hand, the fourth support surface 244 is inclined rearward toward the axial center. Therefore, the game ball B1 that is transported while being in contact with the fourth support surface 244 is located on the rear side (base body 251 side) of the game area PA.

In this way, by changing the position in the front-rear direction of the conveyed game ball B1 according to the supporting surfaces 241 to 244 contacting in the adjustment mechanism 220, the game ball discharged from the adjustment mechanism 220. The position of B1 in the front-back direction can be different. As described above, the distance from the lower end of the adjustment mechanism 220 to the first through gate 35 is approximately 2.5 times the diameter of the game ball B1, and the path of the path discharged from the adjustment mechanism 220 toward the first through gate 35. Along the way, a distribution nail 271 is provided that protrudes to an intermediate position in the front-rear direction of the game area PA.

A game ball B1 that is taken into the adjustment mechanism 220 from the take-in port 262 and is moved in the rotational direction and discharged while being in contact with the first support surface 241, the second support surface 242, or the third support surface 243 (FIG. 41). Flows down toward the first through gate 35 from the front side of the game area PA.

44(a) and 44(c) are transverse cross-sectional views of the window panel 52 and the game board 210 in the case where the partition nail 271 is cut right above the plane perpendicular to the front surface of the game board 210, and FIG. ), (d) are front views of the game board 210 showing the periphery of the adjusting mechanism 220 in an enlarged manner. As shown in FIG. 44(a), the game ball B1 flowing down on the front side of the game area PA does not collide with the distribution nail 271 but flows down in front of the distribution nail 271. Then, the game ball B1 wins the first through gate 35 as shown in FIG. 44(b).

On the other hand, as already described in FIG. 41, when the fourth support surface 244 is located above, the fourth support surface 244 is inclined downward toward the rear of the fourth support surface 244. It has an inclined surface. Therefore, the game ball B1 that is taken into the adjustment mechanism 220 from the take-in port 262, moves in the rotation direction while being in contact with the fourth support surface 244, and is discharged is the back side of the game area PA to the first through gate 35. Run down. As shown in FIG. 44(c), the game ball B1 flowing down the back side of the game area PA collides with the right side of the distribution nail 271. As shown in FIG. 44(d), since the game ball B1 is bounced back to the right by the distribution nail 271, it does not enter the first through gate 35.

The probability that the game ball B1 taken in from the take-in port 262 is conveyed to the discharge passage 264 while being in contact with the first supporting surface 241, the second supporting surface 242, or the third supporting surface 243 is 3/4, The probability that the taken game ball B1 is conveyed to the discharge passage 264 while being in contact with the fourth support surface 244 is 1/4. Therefore, the game ball B1 discharged from the adjusting mechanism 220 wins the first through gate 35 with a probability of approximately 3/4, and collides with the sorting nail 271 with a probability of approximately ¼ to make the first through. Remove from gate 35.

Next, the configuration around the intake port 262 in the adjustment mechanism 220 will be described based on FIGS. 45(a) to 45(d). 45(a) to 45(d) are front views of the game board 210 showing the periphery of the adjusting mechanism 220 in an enlarged manner. As shown in FIG. 45A, the left standing wall 261 extends to the upper left of the rotating body 230 and has an end surface 261a at the upper end. The end face 261a has a gentle slope downward toward the left, and the right end of the end face 261a enters the intake port 262 and comes into contact with any of the support faces 241 to 244 of the rotating body 230. It is located below the upper end of the playing ball B1.

As shown in FIG. 45(a), in the game board 210, a plurality of left side guide nails 291 and right side guide nails 292 are provided above the adjusting mechanism 220 for guiding the game ball B1 to the intake port 262. There is. Here, the left guide nail 291 and the right guide nail 292 are the same members as the nails 24b (FIG. 3) provided in large numbers on the game board 210.

As shown in FIG. 45(a), in the game board 210, the left guide nails 291 are arranged in a row above the left standing wall 261 and the row is directed downward to the right. It is inclined. The row of the left guide nails 291 guides the game ball B1 flowing down from above the left standing wall 261 toward the intake port 262. Further, the right guide nails 292 are arranged in a row above the upper right standing wall 252, and the row is inclined downward to the left. By the row of the right guide nails 292, the game ball B1 flowing down from above the upper right standing wall 252 is guided toward the intake port 262.

As described above, the upper right standing wall 252 is configured to rotate rightward from the initial position to the displaced position when a rightward force is applied from the outside. In this configuration, the row of right guide nails 292 arranged above the upper right standing wall 252 prevents the game ball B1 flowing down from above from colliding with the upper right standing wall 252. Therefore, the rotating state of the upper right standing wall 252 does not change due to the collision of the game ball B1 flowing down from above with the upper right standing wall 252 in the displaced position.

As shown in FIG. 45(a), the distance from the right guide nail 292 located at the lower end of the row of the right guide nails 292 to the upper right standing wall 252 is shorter than the diameter of the game ball B1. Therefore, the game ball B1 does not enter the gap between the row of the right guide nails 292 and the upper right standing wall 252. On the other hand, the distance from the left guide nail 291 located at the lower end of the row of the left guide nails 291 to the left standing wall 261 is wider than the diameter of the game ball B1. Therefore, the game ball B1 guided to the left by the row of the right guide nails 292 and not taken into the intake port 262 is a space existing between the row of the left guide nails 291 and the left standing wall 261. And escapes to the left of the adjustment mechanism 220.

In addition, the game ball B1 which is guided to the right by the row of the left guide nails 291 and has not been taken into the intake opening 262 collides with the right guide nail 292 and the upper right standing wall 252 and is bounced back to the left. After that, it passes through the space existing between the row of left guide nails 291 and the left standing wall 261 and escapes to the left of the adjusting mechanism 220. In this way, the game ball B1 that has been guided to the vicinity of the intake port 262 but not taken into the inside of the adjustment mechanism 220 from the intake port 262 is allowed to escape to the left of the adjustment mechanism 220. It is possible to prevent the game ball B1 from staying near the intake port 262.

The game ball B1 flows into the intake port 262 of the adjusting mechanism 220 regardless of the rotation state of the rotating body 230. Therefore, there is a possibility that the game ball B1 flowing down to the intake port 262 may come into contact with the front side position of the supporting surfaces 241-244 located above, and a possibility that it may come into contact with the rear side position of the supporting surfaces 241-244. There are both. Here, the front side position of the support surfaces 241-244 is the front side portion of the support surfaces 241-244 in the rotation direction, and the rear side position of the support surfaces 241-244 rotates on the support surfaces 241-244. It is the rear part of the direction.

The behavior of the game ball B1 in the intake port 262 is common regardless of the support surfaces 241 to 244 with which the game ball B1 contacts. Therefore, in the following, the behavior of the game ball B1 that flows down to the intake port 262 and comes into contact with the first support surface 241 will be described as an example.

First, a case where the game ball B1 flowing down to the intake port 262 comes into contact with the rear side position of the upper first supporting surface 241 will be described with reference to FIG. 45(b). As shown in FIG. 45B, when the game ball B1 is in contact with the rear side position of the first support surface 241, the distance from the center of the rotating body 230 to the upper end of the game ball B1 is the rotating body 230. Is shorter than the distance from the center of the upright wall 252, 253, 261. Therefore, the game ball B1 is conveyed toward the lower part of the accommodation space while being pushed by the first step surface 241a existing at the rear end of the first supporting surface 241 in contact therewith.

Next, referring to FIGS. 45(b) and 45(c), regarding the case where the game ball B1 flowing down to the intake port 262 comes into contact with the front side position of the first supporting surface 241 located above. explain. As shown in FIG. 45(c), when the game ball B1 is in contact with the front side position of the first support surface 241, the distance from the center of the rotating body 230 to the upper end of the game ball B1 is equal to that of the rotating body 230. It is longer than the distance from the center to the standing walls 252, 253, 261. Therefore, at the intake port 262, the game ball B1 that is about to move to the right according to the rotation of the rotating body 230 comes into contact with the upper right standing wall 252.

When the rotating body 230 rotates in a state in which the rightward standing wall 252 prevents the game ball B1 from moving to the right, the game ball B1 cannot move to the right from the intake port 262, so the first and second game balls B1. The contact point with the support surface 241 moves from the front side of the first support surface 241 to the rear side.

As described above, the distance from the center of the rotating body 230 to the first supporting surface 241 gradually decreases from the front position to the rear position of the first supporting surface 241. Therefore, the distance from the center of the rotating body 230 to the upper end of the game ball B1 gradually becomes shorter. In this case, the game ball B1 that is continuously in contact with the first support surface 241 gradually sinks downward as the rotating body 230 rotates.

Then, as shown in FIG. 45(b), the game ball B1 is in a state of being present at the rear side position of the first support surface 241. As described above, the distance from the center of the rotating body 230 to the upper end of the game ball B1 in the state of being present at the rear side position of the first supporting surface 241 is from the center of the rotating body 230 to the standing walls 252, 253. It is shorter than the distance to 261. Therefore, the game ball B1 is pushed by the first step surface 241a existing at the rear end of the first support surface 241, and is conveyed toward the lower part of the accommodation space.

Here, when the rotating body 230 rotates from the state in which the game ball B1 exists in the front side position of the first support surface 241, to the state in which the game ball B1 exists in the rear side position, the game ball B1 and the first ball The distance to the contact point with the support surface 241 decreases continuously. Therefore, even if the game ball B1 is in a standby state at the intake port 262, it is not in a state of being stopped at one place but in a state of always moving downward.

As shown in FIG. 41, in the game area PA (FIG. 3), a space where the game ball B1 can flow downward is provided on the left side of the left standing wall 261. The nail 24b is not arranged in the space. Therefore, the game ball B1 that has not been taken into the adjustment mechanism 220 at the take-in port 262 can pass through the space and proceed to the downstream of the game area PA.

The game ball B1 that has flowed down to a position displaced to the left of the intake port 262 comes into contact with the end surface 261a of the left standing wall 261. As described above, the end surface 261a is inclined downward to the left. Therefore, the game ball B1 is guided to the end surface 261a of the left standing wall 261 and flows down in the space provided on the left side of the left standing wall 261.

The game ball B1 that has flowed down to a position displaced to the right of the intake port 262 is guided by the right guide nail 292 and moves toward the intake port 262. Since the game ball B1 does not collide with the upper right standing wall 252 from above, the upper right standing wall 252 rotates from the initial position to the displacement position or rotates from the displacement position to the initial position by the game ball B1 flowing down from above. It does not move.

As shown in FIG. 45(c), when the first game ball B1 enters the intake port 262 and is in contact with any of the support surfaces 241 to 244 of the rotating body 230, the second When the game ball B1 tries to enter the intake port 262, the game ball B1 comes into contact with the first game ball B1. Since the right guide nail 292 and the upper right standing wall 252 are present on the right side of the second game ball B1, the game ball B1 does not move to the right but moves to the left.

As described above, the right end of the end surface 261a of the left standing wall 261 is located below the second game ball B1, and the end surface 261a is inclined downward to the left. Then, on the left side of the left standing wall 261, there is a space through which the game ball B1 can pass. Therefore, the second game ball B1 that has not been taken into the intake port 262 flows down on the left side of the adjustment mechanism 220.

Since the game ball B1 that has not been taken into the take-in port 262 does not stay or stay near the take-in port 262, the game ball B1 can be smoothly taken into the take-in port 262.

Next, a mode in which the game ball B1 taken in from the take-in port 262 is conveyed to the lower part of the accommodation space as the rotating body 230 rotates will be described with reference to FIG. 45(d). As described above, the game ball B1 that is transported while being in contact with any of the first support surface 241, the second support surface 242, and the third support surface 243 exists on the front side (the window panel 52 side) in the front-rear direction. The game ball B1 that is conveyed while being in contact with the fourth support surface 244 exists on the rear side in the front-rear direction (the side of the base body 251).

Except for the existing position in the front-rear direction, the movement of the game ball B1 during conveyance is common regardless of the support surfaces 241-244 with which the game ball B1 is in contact during conveyance. Therefore, the case where the game ball B1 is conveyed while being in contact with the first support surface 241 will be described below as an example.

As shown in FIG. 45(d), the game ball B1 is transported while being in contact with the first support surface 241 and the first step surface 241a. The game ball B1 being conveyed is in a state in which a force is applied in the rotation direction from the first step surface 241a protruding in the radial direction of the rotating body 230.

As described above, the distance from the center of the rotating body 230 to each of the support surfaces 241 to 244 is long on the front side in the rotation direction (clockwise) of each of the support surfaces 241-244, and gradually increases toward the rear side of the rotation direction. It gets shorter. In addition, as described above, the distance from the center of the rotating body 230 to the standing walls 252, 253, 261 that partition the accommodation space of the rotating body 230 is constant.

Therefore, as shown in FIG. 45D, the distance from any one of the support surfaces 241-244 to the upstanding walls 252, 253, 261 is short on the front side in the rotation direction of the support surfaces 241-244, and the rotation direction is small. It gradually becomes longer as it goes to the rear side. Specifically, the width of the space sandwiched between any of the support surfaces 241-244 and the standing walls 252, 253, 261 is larger than the diameter of the game ball B1 on the front side in the rotation direction of the support surfaces 241-244. Is narrower, and becomes gradually wider as it goes backward in the rotation direction. The width of the space located in the rear approximately half in the space is wider than the diameter of the game ball B1. The distance from the front surface of the base body 251 to the window panel 52 (FIG. 1) is wider than the diameter of the game ball B1.

As shown in FIG. 45(d), in the space sandwiched between the first support surface 241 and the upper right standing wall 252, the space on the rear side in the rotation direction has a shape and size capable of accommodating the game ball B1. The space on the front side in the rotation direction is a space having a size that cannot accommodate the game ball B1. In a state where the game ball B1 is conveyed while being in contact with the first support surface 241, a space having a space in which the game ball B1 can exist is limited to a rear position of the first support surface 241.

When there is a wide space in which the game ball B1 can exist during transportation, the game ball B1 can exist at different positions even if the rotating state of the rotating body 230 is the same. In this case, even if the rotational speed of the rotating body 230 is constant and any step surface 241a to 244a exists at the discharge position each time the discharge timing is reached, the position of the game ball B1 at the discharge timing is changed every time. This is different, and the winning timing for the first through gate 35 is deviated.

On the other hand, there is a limited space in which the game ball B1 can exist during transportation, and at the discharge timing at which the step surfaces 241a to 244a carrying the game ball B1 reach the discharge position, the game is played. By configuring the ball B1 to be conveyed to a predetermined position every time, it is possible to prevent the timing for winning the first through gate 35 from being shifted.

In the state where the game ball B1 is located at the rear side position of any of the supporting surfaces 241-244, a space larger than the size of the game ball B1 exists around the game ball B1. Therefore, during transportation, the game ball B1 contacts the first step surface 241a, the first support surface 241, and any one of the standing walls 252, 253 located on the right side. It is not forcibly pushed and dragged to be transported.

Next, a configuration for the adjusting mechanism 220 to discharge the game ball B1 will be described. As shown in FIG. 41, the housing 250 is continuous with the accommodation space in which the rotating body 230 is accommodated, and the game ball B1 conveyed to the lower part of the accommodation space is located below the adjustment mechanism 220. A discharge passage 264 for discharging toward the 1-through gate 35 is formed. The discharge passage 264 has a passage cross section through which the game balls B1 can pass one by one, and a discharge port 256 is provided at the lower end of the discharge passage 264. The discharge passage 264 guides the game ball B1 passing through the discharge passage 264 so that the game ball B1 discharged from the discharge port 256 flows down toward the first through gate 35. As shown in FIG. 44(b), the discharge passage 264 shifts the position of the game ball B1 to the left on the upstream side, and directs the discharge direction of the game ball B1 to the lower first through gate 35 on the downstream side.

The discharge passage 264 is connected to the right of the center of the accommodation space. Therefore, the game ball B1 conveyed clockwise from the upper part of the accommodation space to the lower part advances to the discharge passage 264 before the game ball B1 makes a half turn around the rotating body 230.

The game ball B1 conveyed by the rotating body 230 has a downward velocity component from being taken in the upper part of the accommodation space until it makes a half turn, and has an upward velocity component after making a half turn. It will be. The game ball B1 is advanced to the discharge passage 264 at a timing before the conveyed game ball B1 changes from having a downward velocity component to having an upward velocity component. With such a configuration, the movement of the game ball B1 from the accommodation space to the discharge passage 264 can be made smooth.

As shown in FIG. 41, the housing 250 includes discharge standing walls 263 and 266 that define the discharge passage 264. The discharge standing walls 263, 266 are formed on the left and right sides of the discharge passage 264 from the front surface of the base body 251 to the vicinity of the rear surface of the window panel 52 (FIG. 1) so as to project forward. Of these, the right-side discharge upright wall 266, which defines the right-side passage shape of the discharge passage 264, is continuous with the lower-right upright wall 253 and extends diagonally downward to the left. As shown in FIG. 41, the passage wall surface of the discharge passage 264 defined by the right-side discharge upright wall 266 is a curve bulging obliquely upward to the left.

As shown in FIG. 41, the left-side discharge upright wall 263 defining the left-side passage shape of the discharge passage 264 is for the right-side discharge so that the passage width of the discharge passage 264 is slightly larger than the diameter of the game ball B1. It is formed so as to be separated from the standing wall 266. The passage width of the discharge passage 264 is set to be slightly narrowed from the upstream side to the downstream side, and is approximately 1.1 times the diameter of the game ball B1 in the downstream side.

As shown in FIG. 44(b), the game ball B1 passing through the discharge passage 264 is guided by the right-side discharge standing wall 266, and moves downward while moving leftward. Specifically, the game ball B1 is guided mainly to the left in the upstream of the discharge passage 264, and is guided downward mainly to the first through gate 35 in the downstream of the discharge passage 264. As a result, the discharge direction of the game ball B1 discharged from the discharge passage 264 is suppressed from shifting from the first through gate 35.

As shown in FIG. 41, the left-side discharge upstanding wall 263 has a discharge protrusion end 263a at the upper end thereof that protrudes into the accommodation space in which the rotating body 230 is accommodated. The distance from the center of the rotator 230 to the ejection end 263a is longer than the distance from the center of the rotator 230 to the outer ends of the step surfaces 241a to 244a, and the difference between the two distances is greater than the diameter of the game ball B1. Is also short. That is, when the stepped surfaces 241a to 244a of the rotating body 230 are closest to each other, the distance from the ejected projecting end 263a to the stepped surfaces 241a to 244a becomes shorter than the diameter of the game ball B1. It protrudes to the position.

Here, the projecting dimension of the ejection protruding end 263a is such that the ejection protruding end 263a does not contact the stepped surfaces 241a to 244a even when the stepped surfaces 241a to 244a come closest to each other. Therefore, the stepped surfaces 241a to 244a do not interfere with the rotation of the rotating body 230 due to the contact with the ejection protruding end 263a.

The ejection protruding end 263a guides the game ball B1 toward the ejection passage 264 by contacting the upper part of the game ball B1 conveyed to the lower part of the accommodation space by the rotating body 230. As shown in FIG. 44(b), the gravity that tends to fall downward acts on the game ball B1 conveyed to the lower part of the accommodation space. In the lower part of the accommodation space, there is a space that is slightly larger than the game ball B1. Therefore, the game ball B1 moves downward due to its own weight as compared with the state in which it is in contact with the supporting surfaces 241 to 244 of the rotating body 230.

As described above, the discharge passage 264 is connected to the right of the center of the lower portion of the accommodation space. Therefore, at the stage where the game ball B1 moves from the accommodation space to the discharge passage 264, the game ball B1 has a left speed component and a downward speed component. Then, the game ball B1 tries to move downward due to its own weight, and is pushed by the contacting step surfaces 241a to 244a to move leftward.

In the lower part of the accommodation space, when the downward velocity component of the game ball B1 is sufficiently larger than the leftward velocity component, the game ball B1 moves to the discharge passage 264 along the right discharge upright wall 266. On the other hand, in the lower part of the accommodation space, when the left-side velocity component of the game ball B1 is large, the game ball B1 tries to move to the left away from the right discharge upright wall 266.

On the other hand, as described above, the ejection protruding end 263a of the left ejection upright wall 263 is present in the accommodating space. The distance from the step surfaces 241a to 244a pushing the game ball B1 to the left to the ejection end 263a is shorter than the diameter of the game ball B1. Therefore, even the game ball B1 having a large velocity component in the left direction cannot move to the left of the ejection protruding end 263a.

Further, as shown in FIG. 44(b), even if the game ball B1 does not move downward and is in contact with the support surfaces 241-244, the ejection protruding end 263a and the step surface 241a- The straight line connecting the 244a is set such that the protruding position of the ejection protruding end 263a passes above the center of gravity of the game ball B1. Therefore, even if the game ball B1 is sandwiched in a state of being in contact with the discharge protruding end 263a and the step surfaces 241a to 244a, the force that the rotating body 230 tries to rotate clockwise discharges the game ball B1. It works in the direction of pushing toward the passage 264.

In the lower part of the accommodation space, even if the leftward velocity component of the game ball B1 is large, the game ball B1 that is in contact with the ejection protruding end 263a and the step surfaces 241a to 244a is a rotating body. It moves toward the discharge passage 264 with the rotation of 230. The game ball B1 is strongly sandwiched between the ejection protruding end 263a and the step surfaces 241a to 244a, and the rotation of the rotating body 230 does not stop.

Next, the case where the game ball B1 comes into contact with both of the step surfaces 241a to 244a and the end surface 252a of the upper right standing wall 252 at the intake port 262 will be described. As shown in FIG. 41, the upper right standing wall 252 in the initial position is provided with an end surface 252a inclined downward to the right at the free end of the upper right standing wall 252. With the rotation of the rotating body 230, the distance between the step surfaces 241a to 244a located around the intake port 262 and the end surface 252a of the upper right standing wall 252 becomes longer or shorter than the diameter of the game ball B1. To do.

At the timing when the interval between the step surfaces 241a to 244a located near the intake 262 and the end surface 252a of the upper right standing wall 252 changes from a state longer than the diameter of the game ball B1 to a shorter state than the diameter of the game sphere B1, the game ball enters the game 262. When B1 enters, the game ball B1 is sandwiched between the step surfaces 241a to 244a and the end surface 252a.

The behavior of the sandwiched game ball B1 is common regardless of the step surfaces 241a to 244a sandwiching the game ball B1. Therefore, hereinafter, a case where the game ball B1 is sandwiched between the second step surface 242a and the upper right standing wall 252 will be described with reference to FIGS. 46(a) to (c). 46(a) to (c) are front views of the game board 210 showing the periphery of the adjusting mechanism 220 in an enlarged manner.

As shown in FIG. 46(a), when the game ball B1 is in a state of being sandwiched between the second step surface 242a and the upper right standing wall 252, when the rotating body 230 rotates clockwise, the second step surface A rightward force is applied to the game ball B1 from 242a. Therefore, a rightward force is applied to the upper right standing wall 252 from the game ball B1. As described above, the upper right standing wall 252 can be rotated from the initial position around the rotation shaft 254 to the deformed position shown by shading in FIG. 46A when the rightward force is applied from the outside. Is.

As shown in FIG. 46( b ), as the upper right standing wall 252 rotates from the initial position to the deformed position, the distance from the center of the rotating body 230 to the end surface 252 a of the upper right standing wall 252 extends and is sandwiched. The game ball B1 is guided by the inclination of the end surface 252a and moves to the lower right. Next, as shown in FIG. 46(c), the game ball B1 is in contact with the inner surface of the upper right standing wall 252 from being in contact with the end surface 252a of the upper right standing wall 252. Here, the inner surface of the upper right standing wall 252 is a surface of the upper right standing wall 252 that faces the rotating body 230 and defines a housing space of the rotating body 230.

Then, the game ball B1 moves along the inner surface of the upper right standing wall 252 while being pushed by the second step surface 242a. As a result, the game ball B1 that is momentarily sandwiched by the intake port 262 can be transported to the discharge position at the same discharge timing as the game ball B1 that was not sandwiched by the intake port 262. ..

In this way, the adjustment mechanism 220, when the game ball B1 is sandwiched between the step surfaces 241a to 244a and the upper right standing wall 252, eliminates the state in which the game ball B1 is sandwiched and takes in the game ball B1. have. This reduces the possibility that the game ball B1 is sandwiched between the rotating body 230 and the upper right standing wall 252 and the rotating body 230 cannot rotate.

By shifting from the state where the game ball B1 is in contact with the upper right standing wall 252 to the state where it is in contact with the lower right standing wall 253, the rightward force applied to the upper right standing wall 252 from the game ball B1 is removed. Be done. Therefore, the upper right standing wall 252 that has rotated to the displaced position returns to the initial position by its own weight.

In the case of a structure in which a force for returning to the initial position is applied to the upper right standing wall 252 by using a spring or the like, the force required to rotate the upper right standing wall 252 from the initial position to the displaced position increases. On the other hand, by configuring the upper right standing wall 252 to return to the initial position by its own weight, the force required to rotate the upper right standing wall 252 is reduced, and the state in which the game ball B1 is sandwiched is momentarily. In addition, it is possible to prevent the adjustment drive unit 184 (FIG. 41) from being overloaded in the process of eliminating the state.

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

At the intake port 262 of the adjusting mechanism 220, the game ball B1 sandwiched between the step surfaces 241a to 244a of the rotating body 230 and the end surface 252a of the upper right standing wall 252 has an upper right standing wall 252 centered around the rotating shaft 254. The adjustment mechanism 220 is configured to be rotated by rotating from the position to the deformed position. Therefore, it is possible to prevent the sandwiched game ball B1 from being repelled upward and disturbing the flow of the game ball B1 around the intake port 262. Further, as compared with the configuration in which the sandwiched game ball B1 is allowed to escape to the outside of the adjustment mechanism 220, it is possible to take in more game balls B1 to the adjustment mechanism 220. Therefore, it is possible to prevent the game ball B1 that is periodically supplied to the first through gate 35 from being chipped. In addition, it is possible to avoid a situation in which the timing of becoming a regular train open winning is missed during the continuous winning period.

In the take-in port 262, when the game ball B1 is located on the front side (the front side in the rotation direction) of the supporting surfaces 241-244, the game ball B1 is on the rear side (the rear side in the rotating direction) of the support surfaces 241-244. It is a configuration in which the game ball B1 waits at the intake port 262 while moving downward until the game ball B1 is positioned. By keeping the game ball B1 standing by at the intake port 262 constantly moving, it is possible to prevent the movement of the game ball B1 from stopping, which can prevent the player's interest from becoming another trigger. By avoiding a situation in which the player's interest is lost in the process of the adjustment mechanism 220 taking in the game ball B1, it is possible to maintain the player's interest in the adjustment mechanism 220 and improve the interest of the game. it can.

The adjusting mechanism 220 is configured to take in the game balls B1 one by one from the take-in port 262. When two game balls B1 are taken in at the same time, one game ball B1 influences the winning timing of the other game ball B1, so that the first through gate 35 is won even during the continuous winning period. There is a possibility that the possible timing will deviate from the winning target period. On the other hand, by limiting the number of game balls B1 to be taken in at one time to one, there is a possibility that the game ball B1 will win the first through gate 35 at a timing that does not result in the normal electric open winning in the winning continuous period. It is possible to reduce the probability, and to increase the probability of occurrence of the universal electric open winning in the winning consecutive period. As a result, the player's expectation for the continuous winning period can be increased and the enjoyment of the game can be improved.

In the game board 210, a right guide nail 292 for guiding the game ball B1 to the inlet 262 is provided above the upper right standing wall 252, and the game ball B1 is left above the left standing wall 261. There is a gap that allows it to move in one direction. Therefore, when the game ball B1 already exists in the intake port 262, another game ball B1 can be released to the left of the adjustment mechanism 220. Therefore, the number of game balls B1 that have not been taken in is retained near the intake port 262, or disturb the flow of the game ball B1 upstream of the intake port 262 and are taken into the adjustment mechanism 220. Can be prevented from decreasing. In this way, by suppressing the lack of the game ball B1 that is periodically supplied to the first through gate 35, it is possible to avoid the situation where the timing of the normal electric open win is missed during the winning continuous period.

The adjusting mechanism 220 is provided with a projecting end 263a for discharging, and in the lower part of the adjusting mechanism 220, the game ball B1 is prevented from rising without being discharged. Thereby, the number of game balls B1 discharged toward the first through gate 35 continues to rotate without the discharge of the game balls B1 conveyed to the lower part of the adjusting mechanism 220 by the rotating body 230 being performed well. It can be prevented from decreasing. It is possible to prevent the player from being less interested in the adjusting mechanism 220 due to a decrease in the frequency with which the game ball B1 is discharged from the adjusting mechanism 220. Moreover, by adopting a configuration in which the game ball B1 taken in by the adjusting mechanism 220 is discharged within a fixed period, it is possible to prevent the pace at which a new game ball B1 is taken in by the adjusting mechanism 220 from falling. As a result, it is possible to avoid a decrease in the frequency with which the game ball B1 is taken into the adjustment mechanism 220 and a decrease in player's interest in the adjustment mechanism 220.

The first support surface 241, the second support surface 242, and the third support surface 243 are provided with an inclination for discharging the game ball B1 in a manner of flowing down on the front side, and the fourth support surface 244 is the game ball B1. Is provided with a slope for discharging in a manner of flowing down the back side. Then, as described above, the distance from the lower end of the adjusting mechanism 220 to the first through gate 35 is set to approximately 2.5 times the diameter of the game ball B1. For this reason, only the game ball B1 discharged from the adjustment mechanism 220 and flowing down on the far side collides with the distribution nail 271 and is removed from the first through gate 35. As a result, all of the game balls B1 taken into the adjusting mechanism 220 will be won in the first through gate 35, and the situation in which the player pays attention only to taking in the game balls B1 in the adjusting mechanism 220 and does not pay attention to the discharge is avoided. can do. The interest of the game can be improved by collecting the player's interest until the moment of winning the first through gate 35.

By changing the number and inclination of the support surfaces 241-244, the gaming ball B1 discharged from the adjusting mechanism 220 and winning the first through gate 35, and the gaming ball B1 removed from the first through gate 35, respectively. It is possible to set the frequency of occurrence at the design stage. Therefore, the probability that the game ball B1 discharged from the adjusting mechanism 220 will win the first through gate 35 can be set to a high value other than 100%. As a result, the player's interest in the adjusting mechanism 220 can be increased and the interest of the game can be improved.

<Another form in the second embodiment>
-In the second embodiment described above, a plurality of game balls B1 may be configured to stand by while moving downward at the intake port 262. For example, one nail 24b is arranged above the left end of the intake port 262, and in the state where the first game ball B1 has already entered the intake port 262, the second game ball B1 flows down. When it comes, the second game ball B1 may be held above the intake port 262. The second game ball B1 is in a state of waiting on the first game ball B1, but since the first game ball B1 continues to move downward until it is taken in, it comes into contact with the first game ball B1. The second game ball B1 on standby also continues to move downward.

In this way, by stocking while moving the game ball B1 in the intake port 262, the game ball B1 taken into the adjusting mechanism 220 is insufficient, and the game ball B1 is the first game ball despite the winning continuous period. It is possible to avoid a situation in which the frequency of winning the prize in the through gate 35 is low.

In the second embodiment described above, a nail may be used instead of the housing 250 as a structure for guiding the game ball B1 that moves while being pushed by the step surfaces 241a to 244a of the rotating body 230. Then, as a nail arranged near the intake port 262, when a rightward force is applied from the outside, the compression coil spring is in a deformed state and moves from the initial position to the rightward direction to remove the force from the outside. In such a case, a movable nail that returns to the initial position by the restoring force of the compression coil spring may be used. By using the movable nail, when the game ball B1 is sandwiched between the rotating body 230 and the movable nail, the movable nail is moved from the center of the rotating body 230 by using the rightward movement of the movable nail. It is possible to widen the distance up to and take in the sandwiched game ball B1.

In this way, the game ball B1 that moves in the rotation direction while being pressed by the step surfaces 241a to 244a of the rotating body 230 is guided by the nails, so that the game ball 210 has the game ball B1 in the first through gate 35. It is possible to reduce the area occupied by the means for supplying periodically. As a result, in the game board 210, the number of options for the position where the means for periodically supplying the game balls B1 to the first through gate 35 is increased, and the degree of freedom in design can be increased.

In the second embodiment described above, the support surfaces 241 to 244 of the rotating body 230 may not have the inclination in the front-rear direction. In this case, the four support surfaces 241 to 244 of the rotating body 230 have a common shape. Therefore, the game ball B1 is discharged from the discharge passage 264 in the same manner even if the game ball B1 is conveyed while being in contact with any of the support surfaces 241 to 244. The probability that the game ball B1 discharged from the adjusting mechanism 220 is located on the front side (window panel 52 side) and the rear side (game board 210 side) of the game area PA is the same as the game ball B1. It is constant regardless of the supporting surfaces 241-244 that are in contact.

With respect to all the support surfaces 241-244, the case where the game ball B1 conveyed while being in contact is positioned in front of the game area PA and wins the first through gate 35 without coming into contact with the sorting nail 271, and the game area. It is possible to adopt a configuration in which both the case of being located on the rear side of the PA and coming off the first through gate 35 by coming into contact with the distribution nail 271 can occur. As a result, the player's interest in the behavior of the game ball B1 around the distribution nail 271 can be increased and the interest of the game can be improved.

Further, in a configuration in which the support surfaces 241 to 244 of the rotating body 230 do not have an inclination in the front-rear direction, the distribution board 271 may not be provided in the game board 210. In this case, the course of the game ball B1 discharged from the discharge passage 264 is not influenced by the position of the game ball B1 in the front-rear direction. The discharged game ball B1 wins the first through gate 35 with a high probability. However, the distance from the discharge passage 264 to the first through gate 35 is set wider than the diameter of the game ball B1. Therefore, when the passage width at the lower end of the discharge passage 264 is wider than the game ball B1 by one turn or more, the discharge direction of the game ball B1 may shift to one of the left and right directions and the first through gate 35 may not be won. There is.

In this way, instead of providing the distribution nail 271 on the game board 210, as a configuration in which the relationship with the first through gate 35 in the discharge passage 264 is adjusted, all of the discharged game balls B1 are first. It may be configured so as to avoid the situation of winning the through gate 35.

In the above-described second embodiment, the distribution nail 271 may not exist in the course of the game ball B1 discharged from the adjusting mechanism 220 toward the first through gate 35. The first through gate 35 is provided at a place separated from the discharge port 256 of the adjusting mechanism 220 by the diameter of the game ball B1 or more. Therefore, depending on the discharging direction and the discharging speed of the game ball B1 at the discharge port 256, the game ball B1 discharged from the discharge port 256 may come off the first through gate 35. By adjusting the positional relationship between the adjustment mechanism 220 and the first through gate 35 so that a part of the game ball B1 discharged from the discharge port 256 comes off the first through gate 35, The player's interest can also be attracted to the behavior of the game ball B1.

<Third Embodiment>
In this embodiment, the configuration for periodically supplying the game ball B1 to the first through gate 35 is different from that of the first embodiment. The configuration different from that of the first embodiment will be described below. The description of the same configuration as the first embodiment is basically omitted.

The configuration around the first through gate 35 in the game board 320 of this embodiment will be described with reference to FIG. FIG. 47 is a front view of the game board 320 showing the first through gate 35 and the configuration above the first through gate 35 in an enlarged manner.

As shown in FIG. 47, the game board 320 includes an adjustment mechanism 330 above the first through gate 35. The adjusting mechanism 330 discharges the game ball B1 while guiding the game ball B1 to drop toward the first through gate 35. In the adjusting mechanism 330, the timing at which the game ball B1 can be discharged occurs in a cycle of 1 sec.

By generating the winning possible timing already described in the first embodiment in a cycle of 1 sec, it is possible to generate the non-winning continuous period when the winning possible timing does not overlap with the winning target period of the ordinary electric lottery. If the winning timing overlaps with the winning target period, a continuous winning period can be generated. The detailed configuration of the adjusting mechanism 330 will be described later.

As shown in FIG. 47, the distance between the adjusting mechanism 330 and the first through gate 35 is set to a distance equal to or larger than the diameter of the game ball B1. Specifically, the distance between the adjusting mechanism 330 and the first through gate 35 is set to be approximately twice the diameter of the game ball B1. In the game board 320, above the left side of the first through gate 35 and below the adjusting mechanism 330, a part of the game ball B1 discharged from the adjusting mechanism 330 is removed from the path toward the first through gate 35. Adjustment nails 376 are provided.

As shown in FIG. 47, the adjusting nail 376 is located on the left side of the path of the game ball B1 flowing down from the adjusting mechanism 330 and entering the first through gate 35. The adjusting nail 376 projects from the front surface of the game board 320 to the vicinity of the rear surface of the window panel 52 (FIG. 1). Therefore, the game ball B1 flowing down the path deviated to the left collides with the adjusting nail 376 regardless of the position in the front-rear direction in the game area PA (FIG. 3).

When the discharging direction of the game ball B1 discharged from the adjusting mechanism 330 is right below, the discharged game ball B1 wins the first through gate 35 without contacting the adjusting nail 376. On the other hand, when the discharging direction of the game ball B1 is displaced to the left of the position directly below, the discharged game ball B1 contacts the adjusting nail 376. As described above, since the space equal to or larger than the diameter of the game ball B1 is provided between the adjusting mechanism 330 and the first through gate 35, the game ball B1 contacting the adjusting nail 376 comes off the first through gate 35. ..

By avoiding that all of the game balls B1 discharged from the adjusting mechanism 330 enter the first through gate 35, the movement of the game balls B1 discharged from the adjusting mechanism 330 becomes monotonous and prevents the player from getting tired. You can

The adjusting mechanism 330 takes in the game ball B1 inside the adjusting mechanism 330 and guides it toward the first through gate 35, and the take-in range in which the game ball B1 can be taken in is the upper part of the adjusting mechanism 330. Is located in. As shown in FIG. 47, in the game board 320, a plurality of downstream guide nails 371 for guiding the game ball B1 flowing down from above to the adjusting mechanism 330 are provided upstream of the adjusting mechanism 330.

By arranging the downstream guide nails 371 on the game board 320, a row for guiding the game ball B1 flowing down from the upper right side of the adjusting mechanism 330 to the retrievable range of the adjusting mechanism 330, and the adjusting mechanism 330. , And a row for guiding the game ball B1 flowing down from the upper left side to the retrievable range of the adjusting mechanism 330. Here, as shown in FIG. 47, the area sandwiched between the two rows on the game board 320 is referred to as a downstream guide area 371a. The downstream guide nails 371 arranged in two rows guide the game ball B1 flowing down the downstream guide region 371a toward the upper portion of the adjustment mechanism 330.

As shown in FIG. 47, an electric nail 361 that is movable left and right is provided near the upper part of the right column of the downstream guide nail 371. Further, above the electric nail 361, in the game board 320, an upstream guide nail 372 for guiding most of the game ball B1 flowing down the region on the left side of the center frame 57 (FIG. 3) to the electric nail 361. Is provided in plural.

In the area on the left side of the center frame 57 in the game board 320, the upstream guide nails 372 are arranged, so that the game ball B1 flowing down the right side of the area at the upper part of the area is positioned below the electric motor. A row for guiding toward the nail 361 and a row for guiding the game ball B1 flowing down on the left side of the area toward the electric nail 361 located below are provided. As shown in FIG. 47, the region sandwiched between the two rows is the upstream guide region 372a.

The lateral width of the upstream guide area 372a is wide at the upper part of the upstream guide area 372a and becomes gradually narrower toward the lower side. At the lower part of the upstream guide area 372a (near the electric nail 361), one row of the game balls B1 is formed. Therefore, the distance is such that it can pass through.

As shown in FIG. 47, the electric nail 361 is connected to a nail driving portion 361a which is an electric actuator such as a solenoid via a link mechanism (not shown), and the game ball B1 guided by the row of the upstream guide nails 372 is It has a permission position that allows entry between the two rows of downstream guide nails 371 and a prohibition position that prohibits the game ball B1 from entering between the two rows of downstream guide nails 371. Here, the relationship between the position of the electric nail 361 and the path of the game ball B1 will be described with reference to FIGS. 48(a) and 48(b).

FIG. 48(a) is a front view of the game board 320 showing the periphery of the electric nail 361 in the permitted position in an enlarged manner, and FIG. 48(b) is an enlarged view showing the periphery of the electric nail 361 in the prohibited position. It is a front view of the board 320. As shown in FIG. 48(a), when the drive signal of the nail drive unit 361a is at the LOW level, the electric nail 361 takes the permission position. The electric nail 361 in the permission position is located on the upper right side of the downstream guide nail 371 located on the upper right side of the downstream guide area 371a, and is located on the lower right side of the upstream guide area 372a. It is located in the lower left of.

First, the case where the electric nail 361 is in the permission position will be described. As shown in FIG. 48(a), a region on the right side in the downstream guide region 371a exists below the region on the left side in the upstream guide region 372a. Therefore, the game ball B1 flowing down from the left side area in the upstream guide area 372a enters the right side area in the downstream guide area 371a. Further, the electric nail 361 in the permission position is present below the right side area of the upstream guide area 372a. Therefore, the game ball B1 flowing downward from the right side region of the upstream guide region 372a collides with the electric nail 361 and enters the downstream guide region 371a.

Next, a case where the electric nail 361 is in the prohibited position will be described. As shown in FIG. 48(b), the electric nail 361 in the prohibited position exists below the left side region of the upstream guide region 372a. Therefore, the game ball B1 that has flowed downward from the left side region of the upstream guide region 372a collides with the electric nail 361 and flows to the right of the downstream guide nail 371. The lower part of the right side region of the upstream guide region 372a corresponds to the right side of the downstream guide region 371a. Therefore, the game ball B1 flowing down from the right side area in the upstream guide area 372a flows down to the right side than the downstream guide area 371a.

As shown in FIGS. 48(a) and 48(b), the distance between the electric nail 361 in the permitted position and the upstream guide nail 372 at the lower right end of the upstream guide area 372a, and the electric nail 361 in the prohibited position and the upstream guide. The interval with the upstream guide nail 372 at the lower left end of the region 372a is set to be slightly wider than the diameter of the game ball B1. Therefore, when the electric nail 361 moves left and right, the game ball B1 is not sandwiched between the electric nail 361 and the upstream guide nail 372. In addition, the distance between the electric nail 361 in the permitted position and the downstream guide nail 371 at the upper right end of the downstream guide area 371a, and the electric nail 361 in the prohibited position and the downstream guide nail 371 at the upper right end of the downstream guide area 371a. The interval is so narrow that the game ball B1 cannot enter. Therefore, when the electric nail 361 moves left and right, the game ball B1 is not sandwiched between the electric nail 361 and the downstream guide nail 371.

As shown in FIG. 47, above the left side area in the downstream guide area 371a, the nail 24b is provided in order to prevent the game ball B1 flowing down leftward from the upstream guide area 372a from entering the downstream guide area 371a. Is provided. Therefore, the game ball B1 that can enter the downstream guide area 371a is limited to the game ball B1 that flows down from the upstream guide area 372a. In this way, the game ball B1 entering the downstream guide area 371a is limited to the game ball B1 flowing down from the upstream guide area 372a, and the electric ball 361 flows down from the upstream guide area 372a by moving to the prohibited position. It is a configuration that can guide the coming game ball B1 to the right of the downstream guide region 371a. As a result, it is possible to control the frequency with which the game ball B1 enters the downstream guide region 371a and is taken into the adjustment mechanism 330.

The drive signal of the nail drive unit 361a is a periodic signal in which the HI level is repeated for 0.2 sec with an interval of 0.8 sec. Therefore, the electric nail 361 takes the prohibited position only for 0.2 sec out of 1 sec. When two or more game balls B1 that can be fired at 0.6 sec intervals from the game ball firing mechanism 27 attempt to enter the downstream guide area 371a in succession, there is a high probability that the two game balls B1 Either one of them collides with the electric nail 361 that has moved to the prohibited position and flows down to the right of the downstream guide region 371a. By using the electric nail 361, it is suppressed that the plurality of gaming balls B1 are connected to each other and enter the downstream guide region 371a to be taken into the adjustment mechanism 330.

Next, a detailed configuration of the adjusting mechanism 330 will be described below. As shown in FIG. 47, the adjusting mechanism 330 is for rotating the rotating body 340 that conveys the game ball B1 from the upper portion to the lower portion of the adjusting mechanism 330, and rotating the rotating body 340 in the clockwise direction. In the embodiment described above, the adjustment drive unit 184 and the rotating body 340 are provided on the right side, and the game ball B1 discharged from the adjustment mechanism 330 is discharged before the discharge so as to be directed to the first through gate 35. And a guide member 350 for guiding the direction. The adjustment drive unit 184 gives the rotating body 340 a driving force for the rotating body 340 to make one rotation in 6 seconds.

As shown in FIG. 47, the rotating body 340 includes a substantially disc-shaped rotating body main body 342, and six plate-shaped blade members 343 protruding radially from the outer periphery of the rotating body main body 342. ing. The rotor body 342 and the blade member 343 are resin members. The game ball B1 taken into the adjusting mechanism 330 is conveyed to the lower part of the adjusting mechanism 330 while being supported from below by one of the blade members 343 forming the rotating body 340.

First, the configuration of the rotating body 340 in the adjusting mechanism 330 will be described with reference to FIG. 47. As shown in FIG. 47, the rotating body main body 342 includes six rotating shafts 344 on the outer circumference thereof. The rotation shaft 344 is provided at an angle orthogonal to the front surface of the game board 320. The blade member 343 is fixed to the outer periphery of the rotary body 342 such that the blade member 343 can rotate counterclockwise about the rotary shaft 344. The six blade members 343 are the same member having the same shape and size, and are arranged on the outer periphery of the rotating body main part 342 at equal intervals in the rotation direction.

As shown in FIG. 47, an adjustment drive unit 184 is disposed behind the rotary body main unit 342. The front surface of the adjustment drive unit 184 is parallel to the front surface of the game board 320, and the output shaft 184a of the adjustment drive unit 184 extends forward in a manner orthogonal to the front surface of the adjustment drive unit 184. The rotating body main body 342 is connected to the output shaft 184a such that the axis of the rotating body main body 342 is located on the same straight line as the output shaft 184a of the adjustment drive unit 184. When the adjustment drive unit 184 is driven, the rotary body main unit 342 rotates clockwise at an angular velocity of 60° for 1 second. In the state where the rotating body 340 is mounted on the game board 320, the rotating body main body 342 exists from the vicinity of the front surface of the game board 320 to the vicinity of the rear surface of the window panel 52 (FIG. 1).

Here, a manner of fixing the blade member 343 to the rotating body main body 342 will be described. As shown in FIG. 47, the state in which the blade member 343 projects in the radial direction from the outer edge of the rotor body 342 is the initial state of the blade member 343. Around the rotation shaft 344, a recess (not shown) is formed to prevent the blade member 343 in the initial state from rotating around the rotation shaft 344 in the clockwise direction. Even if a force for rotating the blade member 343 in the clockwise direction with respect to the blade member 343 in the initial state acts from the outside, the blade member 343 is in contact with the wall of the recessed portion, so that the blade member 343 rotates. do not do.

A biasing member (not shown) (for example, a torsion coil spring) is mounted around the rotating shaft 344. The biasing member is in a natural state in which it is not deformed when the blade member 343 is in the initial state, and when the blade member 343 rotates counterclockwise around the rotation shaft 344 and is in a displaced state. It will be in a deformed state. The restoring force of the biasing member that tries to return from the deformed state to the natural state acts on the blade member 343 in the displaced state. The blade member 343 rotates counterclockwise to a displaced state when a force is applied from the outside, and rotates clockwise due to a restoring force when the force from the outside is removed to an initial state. Return to.

Next, the configuration of the guide member 350 will be described with reference to FIG. As shown in FIG. 47, the guide member 350 includes a plate-shaped base body 351. Further, on the right side of the rotating body 340 in the game board 320, a fixing recess (not shown) for accommodating the base body 351 without a gap is formed. The guide member 350 is fixed by nailing the base body 351 to the game board in a state where the base body 351 is accommodated in the fixing recess. When the guide member 350 is attached to the game board 320, the front surface of the base body 351 is flush with the front surface of the game board 320.

As shown in FIG. 47, the guide member 350 includes a standing wall 352 that vertically protrudes from the front surface of the base body 351 toward the front. The upright wall 352 extends to the vicinity of the back surface of the window panel 52. The upper end of the standing wall 352 is located above the upper end of the rotating body 340, and the lower end of the standing wall 352 is located at substantially the same height as the lower end of the rotating body body 342.

As shown in FIG. 47, the left side surface 352a of the standing wall 352, which faces the rotary body 342 at a distance, is a gentle arcuate curved surface and is recessed rightward. The distance from the rotator body 342 to the standing wall 352 is set longer than the diameter of the game ball B1. Further, the distance from the upper end of the standing wall 352 to the blade member 343 existing at the position closest to the upper end is set to be longer than the diameter of the game ball B1 regardless of the rotating state of the rotating body 340.

As shown in FIG. 47, in the adjusting mechanism 330, an area sandwiched between the rotating body main body 342 and the standing wall 352 is referred to as an adjusting area 330a. In the lower area of the adjustment area 330a, the distance from the blade member 343 to the standing wall 352 is shorter than the diameter of the game ball B1. As described above, the blade members 343 project from the circumferential surface of the rotating body 340 in the radial direction of the rotating body 340 at intervals of 60°.

Therefore, one of the blade members 343 of the rotating body 340 always exists in the lower region of the adjustment region 330a. The game ball B1 flowing down the adjustment area 330a always contacts the blade member 343 existing in the area below the adjustment area 330a. The game ball B1 that has entered the adjustment region 330a is prevented from passing through without contacting the blade member 343, so that the game ball B1 taken into the adjustment mechanism 330 is the first through gate at a timing other than the discharge timing. It is possible to prevent the discharge toward 35.

Here, a mode in which the game ball B1 is discharged from the adjustment area 330a will be described with reference to FIGS. 49(a) to 49(c). 49A to 49C are front views of the game board 320 showing the periphery of the adjusting mechanism 330 in an enlarged manner.

As shown in FIG. 49(a), in the lower area of the adjustment area 330a, the game ball B1 is in a state of being supported from below by the blade members existing in the area. Then, as the rotator 340 rotates, the rotator 340 is conveyed to a lower discharge position. The game ball B1 is conveyed while being in contact with the standing wall 352, so that the course of the game ball B1 in the adjustment area 330a is guided.

Above the first through gate 35, the game ball B1 which is in a state of being supported by the blade member 343 and the standing wall 352 rotates the rotating body 340, and as shown in FIG. 49(b), the game ball B1. When the gap between the free end of the blade member 343 supporting B1 and the lower end of the standing wall 352 becomes wider than the diameter of the game ball B1, the game ball B1 goes from the gap toward the first through gate 35 below. And fall.

As described above, the adjustment drive unit 184 (FIG. 47) rotates the rotating body 340 at a rotation speed of one rotation for 6 seconds. Therefore, in the lower portion of the adjusting mechanism 330, the gap between the free end of the blade member 343 and the lower end of the standing wall 352 changes from a state shorter than the diameter of the game ball B1 to a state longer than the diameter of the game ball B1. The timing is generated in a cycle of 1 sec. In this way, the adjustment mechanism 330 can discharge the game ball B1 toward the first through gate 35 in a cycle of 1 sec.

The game ball B1 entering the adjustment area 330a comes into contact with the blade member 343 and the standing wall 352 while having a downward speed. Therefore, when the game ball B1 collides with the blade member 343 and bounces, the game ball B1 is temporarily not in contact with the blade member 343. Further, when the game ball B1 collides with the standing wall 352 and bounces, the game ball B1 is temporarily not in contact with the standing wall 352. As shown in FIG. 49(c), when the discharge timing comes while the game ball B1 is not in contact with the blade member 343 or the standing wall 352, the game ball B1 is discharged at a timing slightly delayed from the discharge timing. The Rukoto.

In this case, since the rotating body 340 continues to rotate between the discharge timing and the timing at which the game ball B1 is actually discharged, the course of the game ball B1 after discharge is shifted to the left. As described above, a space equal to or larger than the diameter of the game ball B1 is provided between the adjustment mechanism 330 and the first through gate 35. Therefore, the game ball B1 flowing down the path deviated to the left collides with the upper right side of the adjusting nail 376 provided on the upper left side of the first through gate 35 and bounces back to the right by the first through gate. It may come off from 35.

Next, a case where the game ball B1 is sandwiched between the free end of the blade member 343 and the left side surface 352a of the standing wall 352 will be described with reference to FIGS. 50(a) to (c) are front views of the game board 320 showing the periphery of the adjusting mechanism 330 in an enlarged manner.

When the game ball B1 enters the adjustment area 330a at a timing when the distance from the free end of the blade member 343 to the left side surface 352a of the standing wall 352 is substantially the same as the diameter of the game ball B1, as shown in FIG. 50(a). In addition, the game ball B1 is sandwiched between the blade member 343 and the standing wall 352.

As shown in FIG. 50A, the rotating body 340 continues to rotate clockwise even when the game ball B1 is sandwiched between the blade member 343 and the standing wall 352. Therefore, as shown in FIG. 50( b ), as the rotating body 340 rotates, a force is applied to the blade member 343 to rotate the blade member 343 counterclockwise. As a result, the blade member 343 rotates counterclockwise about the rotation shaft 344 and is placed in a displaced state.

A restoring force for returning the blade member 343 to the initial state acts on the blade member 343 in the displaced state from an urging member (not shown). However, the restoring force of the biasing member that acts on the blade member 343 in the displaced state is a weak force that enables the blade member 343 to return to the initial state when no external force is applied to the blade member 343. Therefore, the force of pushing the game ball B1 to the right in an attempt to return the displaced blade member 343 to the initial state is not so strong as to completely stop the movement of the game ball B1.

The displacement amount of the blade member 343 increases as the rotation of the rotating body 340 progresses. During this time, the game ball B1 slowly drops downward due to its own weight. The falling speed of the game ball B1 that is in contact with the blade member 343 and the standing wall 352 is slower than the speed at which the blade member 343 advances in the rotation direction as the rotating body 340 rotates. Therefore, as the rotation of the rotating body 340 progresses, the free end of the blade member 343 is located below the game ball B1. As a result, as shown in FIG. 50(c), the force applied from the game ball B1 to the blade member 343 is released, and the blade member 343 returns from the displaced state to the initial state. The game ball B1 is transported while being supported on the upper surface of the blade member 343 which has returned to the initial state, and is discharged from the adjusting mechanism 330 toward the first through gate 35 without being displaced from the discharge timing of the 1 sec cycle. Is possible.

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

The adjusting mechanism 330 directs one game ball B1 guided to the adjustment area 330a toward the first through gate 35 at a discharge timing of 1 sec regardless of the timing at which the game ball B1 is guided to the adjustment area 330a. To discharge. Therefore, upstream of the adjustment area 330a, the game ball B1 can be discharged at the discharge timing of a cycle of 1 sec without adjusting the timing at which the game ball B1 enters the adjustment area 330a. Therefore, as compared with the configuration in which the timing at which the game ball B1 enters the adjustment area 330a is adjusted, the winning continuous period can be generated in the low frequency support mode while reducing the processing load of the main CPU 63.

When the game ball B1 is taken in by the adjusting mechanism 330, when the game ball B1 is sandwiched between the free end of the blade member 343 and the left side surface 352a of the standing wall 352, the rotating body 340 is deformed to sandwich the game ball B1. This is a configuration that eliminates the state that is set. Therefore, avoiding a situation in which the game ball B1 does not move in a state of being sandwiched between the blade member 343 and the standing wall 352, the rotating body 340 cannot rotate, and the adjustment mechanism 330 cannot discharge the game ball B1. can do. This reduces the possibility that a problem will occur during the game and that the game must be interrupted to take measures to resolve the problem.

The deformation of the rotating body 340 that is performed in order to eliminate the state where the game ball B1 is sandwiched is a configuration that is performed by the rotation of the rotating body 340. Therefore, it is not necessary to previously provide a dedicated member in order to eliminate the state where the game ball B1 is sandwiched. Accordingly, it is possible to suppress an increase in the number of members that configure the adjusting mechanism 330, simplify the configuration of the adjusting mechanism 330, and reduce the manufacturing cost of the adjusting mechanism 330.

The deformation of the rotating body 340 that is performed to eliminate the state where the game ball B1 is sandwiched is automatically performed in the same state as the control of the rotating body 340 when the game ball B1 is not sandwiched. .. For this reason, the control means of the pachinko machine 10 does not need a means for grasping that the game ball B1 is sandwiched. As a result, when the game ball B1 is sandwiched, the control mechanism of the rotating body 340 is changed to eliminate the state where the game ball B1 is sandwiched. It is possible to suppress an increase in the number of the adjustment mechanism 330, simplify the configuration of the adjustment mechanism 330, and reduce the manufacturing cost of the adjustment mechanism 330.

A space equal to or larger than the diameter of the game ball B1 is provided between the adjusting mechanism 330 and the first through gate 35. In addition, the game board 320 is provided with an adjusting nail 376 that prevents the game ball B1 discharged from the adjusting mechanism 330 from winning in the first through gate 35 when the game ball B1 is out of a predetermined course. Has been. For this reason, all of the game balls B1 that have entered the adjustment area 330a enter the first through gate 35, and it is possible to avoid a situation in which the player does not pay attention to the discharge of the game balls B1 in the adjustment mechanism 330. Thereby, the interest of the player can be improved by collecting the interest of the player until the first through gate 35 is won.

In the game board 320, an electric nail 361 that suppresses one of the game balls B1 from entering the downstream guide area 371a when the two game balls B1 are connected to each other to try to enter the downstream guide area 371a. It is provided. Therefore, it is possible to reduce the possibility that the plurality of game balls B1 are guided to the adjustment area 330a at one time.

The game ball B1 that can be launched from the game ball launching mechanism 27 is one in 0.6 sec, and the game ball B1 that can be discharged in the adjusting mechanism 330 is one in 1 sec. Therefore, when the number of game balls B1 entering the adjustment area 330a continues to be larger than the number of game balls B1 moving from the adjustment area 330a to the adjustment area 330a, the game balls B1 stay in the adjustment area 330a. there is a possibility. On the other hand, by using the electric nail 361 to limit the game ball B1 that can enter the downstream guide region 371a located upstream of the adjustment region 330a, the game ball B1 stays in the adjustment region 330a. The possibility can be reduced.

The electric nail 361 has a width that allows one game ball B1 to pass through and is provided upstream of the downstream guide region 371a that guides the game ball B1 to the adjustment region 330a. The electric nail 361 moves between a permission position that allows the game ball B1 to enter the downstream guide area 371a and a prohibition position that prohibits the game ball B1 from entering the downstream guide area 371a. Is. The electric nail 361 that has moved to the prohibited position is configured to move the game ball B1 that has been prevented from entering the downstream guide area 371a to the right of the downstream guide area 371a. Therefore, when the electric nail 361 takes the prohibited position, it is possible to prevent the game ball B1 from staying around the electric nail 361. In this way, by appropriately distributing the game balls B1 upstream of the adjustment region 330a, it is possible to prevent the game balls B1 from entering the adjustment region 330a in a state of being connected to each other.

<Another form in the third embodiment>
-In 3rd Embodiment mentioned above, the structure which limits the number of the game balls B1 which enter into the downstream guide area 371a is not restricted to the electric nail 361. For example, as the configuration, an adjusting rotating body having a protruding portion may be used. The protruding portion of the adjusting rotator takes a permission position that allows the game ball B1 to enter the downstream guide area 371a and the game ball B1 enters the downstream guide area 371a according to the rotating state of the adjusting rotor. In some cases, it may take a prohibited position. Therefore, it is possible to limit the number of game balls B1 entering the downstream guide area 371a by using the adjusting rotating body that rotates at a constant speed.

In the above-described third embodiment, the adjusting nail 376 may not be present in the course of the game ball B1 discharged from the adjusting mechanism 330 toward the first through gate 35. The first through gate 35 is provided at a position away from the adjusting mechanism 330 by a diameter of the game ball B1 or more. Therefore, the discharged game ball B1 may come off the first through gate 35 depending on the discharge direction and the discharge speed of the game ball B1 discharged from the adjustment mechanism 330. By adjusting the positional relationship between the adjusting mechanism 330 and the first through gate 35 so that a part of the game ball B1 discharged from the adjusting mechanism 330 comes off the first through gate 35, The player's interest can also be attracted to the behavior of the game ball B1.

<Fourth Embodiment>
In this embodiment, the configuration for periodically supplying the game ball B1 to the first through gate 35 is different from that of the first embodiment. The configuration different from that of the first embodiment will be described below. The description of the same configuration as the first embodiment is basically omitted.

In the present embodiment, the game board 420 is provided with an adjusting mechanism 430 for periodically supplying the game ball B1 to the first through gate 35. The configuration of the adjusting mechanism 430 will be described with reference to FIGS. 51 and 52. FIG. 51 is a front view of the game board 420 showing the periphery of the adjusting mechanism 430 in an enlarged manner.

As shown in FIG. 51, in the game board 420, an adjusting mechanism 430 is provided above the first through gate 35. The adjustment mechanism 430 is provided at a position separated from the first through gate 35 by the diameter of the game ball B1 or more. Specifically, the adjusting mechanism 430 is provided at a position where the game ball B1 discharged from the adjusting mechanism 430 reaches the first through gate 35 after flowing down a distance approximately 1.5 times the diameter of the game ball B1. ing. The detailed configuration of the adjusting mechanism 430 will be described below.

As shown in FIG. 51, the adjusting mechanism 430 includes a rotating body 440 that takes in and ejects the game ball B1, and a guide member 450 that adjusts the ejection timing at which the game ball B1 is ejected from the rotating body 440. There is. Further, as shown in FIG. 52, the adjustment mechanism 430 includes the adjustment drive unit 184 already described in the first embodiment. The adjustment drive unit 184 in the present embodiment rotates the rotating body 440 once in 6 seconds.

First, the configuration of the rotating body 440 will be described based on FIGS. 51 and 52. FIG. 52 is a vertical cross-sectional view of the rotary body 440 and the adjustment drive unit 184 when the rotary body 440 is cut along a plane perpendicular to the front surface of the game board 420. As shown in FIG. 51, the rotating body 440 includes a substantially disc-shaped passage forming portion 443, and the passage forming portion 443 has three adjustment passages 444 having a passage width through which the game ball B1 can pass. ~446 are formed. The rotating body 440 takes in the game ball B1 in one of the adjustment passages 444 to 446 and discharges it from the adjustment passages 444 to 446 different from the adjustment passages 444 to 446 in which the game ball B1 is taken in.

Further, as shown in FIG. 52, the rotating body 440 is a rotation base body that prevents the game ball B1 in the adjustment passages 444 to 446 from moving rearward of the front surface of the game board 420 behind the passage forming portion 443. 441 is provided. The rotation base body 441 is a substantially disk-shaped resin member having a predetermined thickness, and is integrally formed with the passage forming portion 443.

As shown in FIG. 52, the game board 420 is formed with a recessed portion 421 for accommodating the rotation base body 441 in a rotatable manner. As for the rotation body 440, the rotation base body 441 is accommodated in the recessed portion 421. It is rotatably fixed in the closed state. The passage forming portion 443 exists from the front surface of the rotation base body 441 to the vicinity of the rear surface of the window panel 52.

As shown in FIG. 52, an adjustment drive unit 184 including an output shaft 184a is arranged behind the rotary base body 441. The rotary body 440 is connected to the output shaft 184a such that the axis of the rotary base body 441 is located on the same straight line as the output shaft 184a of the adjustment drive unit 184.

The axis line of the rotation base body 441 of the rotation body 440 is orthogonal to the front surface of the game board 420, and the rotation body 440 is rotated clockwise at an angular velocity of 60° in 1 sec by the adjustment drive unit 184 being in a driving state. Rotate. The adjustment drive unit 184 in the present embodiment uses the same stepping motor as the adjustment drive unit 184 in the first embodiment. The adjustment drive unit 184 has a configuration in which the output shaft 184a makes one round by the excitation signal being transmitted by the main controller 60 for 500 pulses, and the angle change based on the excitation signal of one pulse, that is, the angle change per step. Is 0.72°.

As shown in FIG. 51, three inlets/outlets 444a to 446a are formed on the outer peripheral surface of the passage forming portion 443 as openings that are open to the outside. The three inlets/outlets 444a to 446a are formed such that the centers of the inlets/outlets 444a to 446a are present at equal intervals in the circumferential direction of the passage forming portion 443. The three gateways 444a to 446a are formed on the outer peripheral surface of the passage forming portion 443 in the order of the first gateway 444a→the second gateway 445a→the third gateway 446a.

The first doorway 444a and the second doorway 445a have a width of 14 mm, which is larger than the diameter (11 mm) of the game ball B1. On the other hand, the third gateway 446a has a width of 11.5 mm, which is smaller than the first gateway 444a and the second gateway 445a and larger than the diameter of the game ball B1.

The first adjusting passage 444 is formed from the first inlet/outlet 444a toward the central area of the rotating body 440, and the second adjusting passage 445 is formed from the second inlet/outlet 445a toward the central area of the rotating body 440. .. Further, the third adjustment passage 446 is formed from the third inlet/outlet 446 a toward the central region of the rotating body 440.

The first adjustment passage 444 has a passage width of 12 mm, and the passage width gradually widens toward the first inlet/outlet 444a near the first inlet/outlet 444a. Similarly, the second adjustment passage 445 has a passage width of 12 mm, and the passage width gradually widens toward the second inlet/outlet port 445a in the vicinity of the second inlet/outlet port 445a. On the other hand, the third adjustment passage 446 has a passage width of 12 mm, and the passage width gradually narrows toward the third inlet/outlet port 446a near the third inlet/outlet port 446a.

If the configurations near the three entrances/exits 444a to 446a are all the same, the movement of the game ball B1 discharged from the rotating body 440 becomes monotonous. On the other hand, by making the shape near the third doorway 446a different from the shape near the first doorway 444a and the second doorway 445a, the player's movement with respect to the movement of the game ball B1 ejected from the rotating body 440 is You can raise the degree of attention.

As shown in FIG. 51, the first adjusting passage 444, the second adjusting passage 445, and the third adjusting passage 446 formed in the passage forming portion 443 are straight passages that are open toward the front. As shown in FIG. 52, the rear sides of the three adjustment passages 444 to 446 are defined by the front surface of the rotation base body 441, and the front side is defined by the back surface of the window panel 52.

As shown in FIG. 51, an intersection space 443a which is slightly larger than the game ball B1 is provided at the center of the passage forming portion 443. The first adjusting passage 444 is a passage connecting the first entrance/exit 444a and the intersecting space 443a, and the second adjusting passage 445 is a passage connecting the second entrance/exit 445a and the intersecting space 443a. The third adjustment passage 446 is a passage that connects the third entrance/exit 446a and the intersecting space 443a.

The game ball B1 can be moved from each adjustment passage 444 to 446 to the intersection space 443a, and can be moved from the intersection space 443a to each adjustment passage 444 to 446. Further, each of the adjustment passages 444 to 446 has a passage length capable of accommodating the two game balls B1.

As shown in FIG. 51, the passage widths of the respective adjustment passages 444 to 446 are constant except for the vicinity of the respective inlets/outlets 444a to 446a. Here, the reference line passing through the center of the first adjustment passage 444 is the first center line 444b, and the reference line passing through the center of the second adjustment passage 445 is the second center line 445b. A reference line passing through the center of the third adjustment passage 446 is a third center line 446b.

The first adjustment passage 444 extends in a direction in which the first center line 444b intersects the inner wall of the second adjustment passage 445, and the second adjustment passage 445 has the second center line 445b of the inner wall of the third adjustment passage 446. It extends in the direction intersecting with. The third adjustment passage 446 extends in the direction in which the third center line 446b intersects the inner wall of the first adjustment passage 444.

That is, the passage wall of the second adjustment passage 445 exists at the destination of the game ball B1 moving along the first adjustment passage 444, and the destination of the game ball B1 moving along the second adjustment passage 445 exists. Has a passage wall of the third adjusting passage 446. Further, the passage wall of the first adjustment passage 444 exists at the destination of the game ball B1 that moves along the third adjustment passage 446. Here, as shown in FIG. 51, the center lines 444b to 446b pass near the center of the passage forming portion 443.

Next, the guide member 450 provided on the game board 420 so as to approach the rotating body 440 will be described with reference to FIG. As shown in FIG. 51, the guide member 450 is provided at the lower right of the rotating body 440.

As shown in FIG. 51, the guide member 450 includes a plate-shaped guide base body 451 having a predetermined thickness. In addition, the game board 420 is formed with a guide recess (not shown) for accommodating the guide base body 451 without a gap. The guide member 450 is fixed to the game board 420 by nailing the guide base body 451 in a state where the guide base body 451 is housed in the guide recess. Then, in the state where the guide member 450 is fixed to the game board 420, the front surface of the guide base body 451 is flush with the front surface of the game board 420.

In addition, the guide member 450 includes a standing wall 452 that vertically protrudes forward from the front surface of the guide base body 451. The upright wall 452 is formed integrally with the guide base body 451 and extends to the vicinity of the rear surface of the window panel 52 (FIG. 1). As shown in FIG. 51, the standing wall 452 is formed along the outer periphery of the rotating body 440 from the right side to the lower right side of the rotation center 440a of the rotating body 440.

Therefore, the standing wall 452 is changed from a rotational state in which one of the inlets/outlets 444a to 446a of the rotating body 440 is opened to the right to a rotational state in which the inlet/outlet ports 444a to 446a are opened obliquely downward to the right. Until then, the doorways 444a to 446a are closed. As a result, the game ball B1 existing in the entrance/exit 444a to 446a is prevented from falling down.

Next, the movement of the game ball B1 around the adjusting mechanism 430 will be described. As shown in FIG. 51, in the game board 420, in the vicinity of the upper portion of the rotating body 440, a guide nail 472 for guiding the game ball B1 flowing down from above to any one of the entrances and exits 444a to 446a of the rotating body 440. Is provided in plural.

With a plurality of guide nails 472, a left guide nail row 473 that guides the game ball B1 that is above the rotating body 440 and flows to the left of the center of the rotating body 440 toward the center of the upper portion of the rotating body 440, and rotates. A right guide nail row 474 is formed to guide the game ball B1 which is above the body 440 and flows to the right of the center of the rotating body 440 toward the center of the upper portion of the rotating body 440.

The distance between the guide nail 472 located at the bottom of the left guide nail row 473 and the guide nail 472 located at the bottom of the right guide nail row 474 is slightly larger than the diameter of the game ball B1. Therefore, in the rotating body 440, when any of the gateways 444a to 446a is opened upward, the game ball B1 guided by the guide nail 472 enters from the gateways 444a to 446a.

As shown in FIG. 51, the distance from the guide nail 472 located at the lowest position in the left guide nail row 473 and the right guide nail row 474 to the outer circumference of the rotating body 440 is set to be slightly wider than the diameter of the game ball B1. ing. In a rotating state in which none of the entrances 444a to 446a of the rotating body 440 are open upward, the game ball B1 guided to the upper part of the rotating body 440 by the guide nail 472 enters the entrances 444a to 446a. I can't.

In this case, a gap through which the game ball B1 can pass is provided between the guide nail 472 located at the lowest position in the left guide nail row 473 and the right guide nail row 474 and the outer circumference of the rotating body 440. The game ball B1 not taken into the inside of the rotating body 440 from the entrances 444a to 446a can be released to the left and right game areas PA of the rotating body 440. Therefore, the game ball B1 that could not enter the upper portion of the rotating body 440 does not stay.

As shown in FIG. 51, in the game board 420, on the upper left side of the rotating body 440, the doorway in a state in which the game ball B1 flowing down obliquely from the upper left side of the rotating body 440 is open toward the upper left side. A left side guard nail 475 for preventing the ball from entering from 444a to 446a is provided, and above the right side of the rotating body 440, the game ball B1 flowing down from diagonally above the rotating body 440 is in the upper right side. A right-side guard nail 476 is provided to prevent the ball from entering from the entrances 444a to 446a that are open toward one side.

Due to the left guard nail 475 and the right guard nail 476, the entrances 444a to 446a that can take in the game ball B1 are limited to the entrances 444a to 446a that are open upward. This prevents the plurality of gaming balls B1 from being taken into the inside of the rotating body 440 from the plurality of gateways 444a to 446a at one time.

As shown in FIG. 51, a space wider than the diameter of the game ball B1 is provided between the left guard nail 475 and the right guard nail 476 and the rotating body 440. Therefore, the game ball B1 which is guided to the upper part of the adjustment mechanism 430 by the left guide nail row 473 or the right guide nail row 474 and is not taken in is the space between the rotating body 440 and the left guard nail 475, or the rotating body. The space between 440 and the right guard nail 476 can flow down downstream.

As shown in FIG. 51, at the upper right of the first through gate 35 and at the lower right of the adjusting mechanism 430, game balls B1 other than the game ball B1 discharged from the adjusting mechanism 430 are provided with the adjusting mechanism 430 and the first through. A guard nail 471 is provided to prevent the player from entering between the gate 35 and the first through gate 35.

By limiting the game balls B1 that can be won in the first through gate 35 to the game balls B1 discharged from the adjusting mechanism 430, the game balls B1 are transferred to the first through gate 35 at timings other than the winning target timing in the continuous winning period. You can prevent winning. Thereby, it is possible to adopt a configuration in which the universal electric open winning is continuously generated in the universal electric open lottery executed during the continuous winning period.

On the other hand, at the upper left of the first through gate 35 and at the lower left of the adjusting mechanism 430, the game ball B1 that is discharged from the adjusting mechanism 430 toward the lower left and comes off without winning the first through gate 35 is the first through. Guard nails 471 are provided to the left of the gate 35 at intervals so as to allow them to escape.

The guard nail 471 prevents the game balls B1 other than the game ball B1 discharged from the adjusting mechanism 430 from flowing down from the upper left of the first through gate 35 and winning the first through gate 35. Further, the game ball B1 discharged from the adjusting mechanism 430 and leftward from the first through gate 35 does not collide with the guard nail 471 and bounce back toward the first through gate 35 again.

Next, in the upper part of the adjusting mechanism 430, the movement of the game ball B1 entered from any of the entrances and exits 444a to 446a of the rotating body 440 will be described. First, the movement of the game ball B1 entering from the first entrance 444a will be described with reference to FIGS. 53(a) to (d). 53A to 53D are front views of the game board 420 showing the adjustment mechanism 430 and the first through gate 35 in an enlarged manner.

FIG. 53A shows a rotating state in which the first inlet/outlet port 444a is opened upward. As shown in FIG. 53(a), the game ball B1 is guided to the center of the upper part of the rotating body 440 by the guide nail 472 (FIG. 51) in the rotating state in which the first doorway 444a is opened upward. As a result, the ball can enter the first doorway 444a. The game ball B1 entered from the first entrance/exit 444a moves in the first adjustment passage 444.

In a state where the first entrance/exit 444a is opened upward, the first adjustment passage 444 is inclined downward, and the game ball B1 is directed from the upper first entrance/exit 444a toward the lower intersecting space 443a. invite. As described above with reference to FIG. 51, the first center line 444 b of the first adjusting passage 444 intersects with the passage wall of the second adjusting passage 445. Therefore, the moving direction of the game ball B1 that moves in the first adjustment passage 444 is the direction in which it contacts the passage wall of the second adjustment passage 445.

FIG. 53B shows the movement of the game ball B1 after being guided to the intersection space 443a. As shown in FIG. 53(b), the game ball B1 entered from the first doorway 444a reaches the intersection space 443a through the first adjustment passage 444 having a passage length approximately twice the diameter of the game ball B1. While rotating, the rotating body 440 rotates clockwise.

Even if the rotator 440 rotates, the positional relationship that the passage wall of the second adjustment passage 445 exists on the extension line of the first adjustment passage 444 does not change. Further, as described above, the second inlet/outlet port 445a exists at a position obtained by rotating the first inlet/outlet port 444a by 120° around the center of the rotating body 440. Therefore, as shown in FIG. 53(b), at the timing when the game ball B1 exists in the intersection space 443a, the second adjustment passage 445 has an inclination from the intersection space 443a to the lower right.

As shown in FIG. 53( b ), after entering the intersecting space 443 a from the first adjustment passage 444, the game ball B 1 that has come into contact with the passage wall of the second adjustment passage 445 is guided to the second adjustment passage 445 and is then moved to the second adjustment passage 445. Heading to the doorway 445a.

FIG. 53C shows the game ball B1 that has reached the second doorway 445a. As shown in FIG. 53C, at the timing when the game ball B1 is guided to the second doorway 445a by the second adjustment passage 445, at least a part of the second doorway 445a is blocked by the standing wall 452. At this timing, there is no gap through which the game ball B1 can pass in the second doorway 445a.

Therefore, the game ball B1 moves in the rotation direction with the rotation of the rotating body 440 and waits until there is a gap that can be passed through the second gateway 445a. As described above, the rotation speed of the rotating body 440 is constant. Further, the position of the standing wall 452 does not change. Therefore, in the state where the game ball B1 is waiting at the second entrance/exit 445a, a timing at which a clearance through which the game ball B1 can pass is also periodically generated at the second entrance/exit 445a.

As shown in FIGS. 53A and 53B, in the state where the first entrance/exit 444a is opened upward, the second entrance/exit 445a is already closed by the standing wall 452. The standing wall 452 blocks at least a part of the entrances 444a to 446a in a state where the entrances 444a to 446a are opened to the right, and prevents the game ball B1 from being discharged toward the right. Therefore, the game ball B1 taken into the rotating body 440 is not discharged from above the standing wall 452.

FIG. 53(d) shows the movement of the game ball B1 after the clearance through which the game ball B1 can pass is formed in the second doorway 445a. As shown in FIG. 53(d), when a gap through which the game ball B1 can pass is formed in the second doorway 445a, the game ball B1 loses its support and falls downward due to its own weight.

The discharge timing at which a gap through which the game ball B1 can pass is generated in the second doorway 445a and the discharge position at the discharge timing is constant. The adjusting mechanism 430 is set so that the discharge position is right above the first through gate 35. Therefore, as shown in FIG. 53(d), the game ball B1 discharged from the discharge position at the discharge timing from the second doorway 445a falls downward and wins the first through gate 35.

However, at the discharge timing, the distance from the second doorway 445a to the first through gate 35 is set longer than the diameter of the game ball B1. Therefore, the game ball B1 discharged from the second doorway 445a wins the first through gate 35 with a high probability, but the winning probability is not 100%.

Next, the movement of the game ball B1 entered from the third entrance 446a will be described. In a state where the third entrance/exit 446a is opened upward, the game ball B1 guided to the upper center of the rotating body 440 by the guide nail 472 (FIG. 51) moves from the third entrance/exit 446a to the third adjustment passage 446. Enter the ball.

The inclination of the third adjustment passage 446 in the state where the third inlet/outlet 446a is opened upward is the same as the inclination of the first adjustment passage 444 described above with reference to FIG. 53(a). Therefore, the passage wall of the first adjustment passage 444 exists ahead of the moving direction of the game ball B1 moving in the third adjustment passage 446.

The positional relationship between the third adjusting passage 446 and the first adjusting passage 444 is the same as the positional relationship between the first adjusting passage 444 and the second adjusting passage 445 which has already been described with reference to FIG. Therefore, the game ball B1 that has passed through the third adjustment passage 446 and entered the intersection space 443a comes into contact with the passage wall of the first adjustment passage 444 and is guided toward the first entrance/exit opening 444a.

As described above, the shape of the first entrance/exit 444a is the same as the shape of the second entrance/exit 445a. Therefore, the discharge timing and the discharge position of the game ball B1 discharged from the first entrance/exit 444a are the discharge timing and the discharge of the game ball B1 discharged from the second entrance/exit 445a already described with reference to FIG. 53D. Same as position. The game ball B1 discharged from the first doorway 444a wins the first through gate 35 with a high probability.

Next, the movement of the game ball B1 entered from the second doorway 445a will be described. In the state where the second entrance/exit 445a is opened upward, the game ball B1 guided to the upper center of the rotating body 440 by the guide nail 472 (FIG. 51) moves from the second entrance/exit 445a to the second adjustment passage 445. Enter the ball.

The inclination of the second adjustment passage 445 in the state where the second inlet/outlet 445a is opened upward is the same as the inclination of the first adjustment passage 444 described above with reference to FIG. 53(a). The positional relationship between the second adjusting passage 445 and the third adjusting passage 446 is the same as the positional relationship between the first adjusting passage 444 and the second adjusting passage 445 which has already been described with reference to FIG. 53(b). .. Therefore, the game ball B1 that has passed through the second adjustment passage 445 and entered the intersecting space 443a comes into contact with the passage wall of the third adjustment passage 446 and is guided toward the third entrance/exit 446a.

Here, the movement of the game ball B1 discharged from the third doorway 446a will be described with reference to FIGS. 54(a) and 54(b). 54A and 54B are front views of the game board 420 showing the adjusting mechanism 430 and the first through gate 35 in an enlarged manner.

FIG. 54(a) shows the game ball B1 that has reached the third doorway 446a. As shown in FIG. 54A, the game ball B1 is guided to the third gateway 446a by the third adjustment passage 446. At the timing when the game ball B1 reaches the third entrance/exit 446a, at least part of the third entrance/exit 446a is blocked by the standing wall 452. There is no gap through which the game ball B1 can pass in the third gateway 446a. Therefore, the game ball B1 waits at the third doorway 446a until a gap that allows the game ball B1 to pass is generated.

FIG. 54(b) shows the movement of the game ball B1 discharged from the third doorway 446a. As described above, the third gateway 446a is formed narrower than the first gateway 444a and the second gateway 445a. Therefore, when the game ball B1 is discharged from the third gateway 446a, the game ball B1 is easily influenced by the passage wall existing on the rear side in the rotation direction of the third adjustment passage 446.

As described above, there is a space equal to or larger than the diameter of the game ball B1 between the discharge position of the game ball B1 in the adjustment mechanism 430 and the first through gate 35. As shown in FIG. 54(b), at the discharge timing of the game ball B1, the game ball B1 is pushed leftward from the passage wall of the third adjustment passage 446, so that the course of the game ball B1 after discharge is changed. It may shift to the left and come off the first through gate 35. Therefore, the winning probability of the game ball B1 entering the second entrance 445a and ejected from the third entrance 446a to the first through gate 35 is the entrance probability from the first entrance 444a and the exit from the second entrance 445a. It is lower than the winning probability to the first through gate 35 of the played game ball B1 and the winning probability to the first through gate 35 of the game ball B1 which is entered from the third entrance 446a and discharged from the first entrance 444a. ..

Here, when the game balls B1 flow down in a row, the same doorways 444a to 446a in which both the first game ball B1 and the second game ball B1 face upward There is a possibility of entering the. In this case, the two game balls B1 are guided to the same gateways 444a to 446a and discharged from the same gateways 444a to 446a. The discharge timing and the discharge direction of the first game ball B1 are as already described in FIG. 53(d) and FIG. 54(b), and are discharged from the first gateway 444a or the second gateway 445a. The game ball B1 to be won enters the first through gate 35 with a high probability, and the game ball B1 discharged from the third doorway 446a is removed from the first through gate 35 with a high probability.

On the other hand, the second game ball B1 is located inside the rotating body 440 with respect to the first game ball B1 at the timing when the first game ball B1 is discharged. Therefore, the discharge timing of the second game ball B1 is delayed from the discharge timing of the first game ball B1. In this case, the rotation of the rotating body 440 advances from the discharge timing of the first game ball B1, and the second game ball B1 is discharged in the state where the discharge direction has moved to the left. .. Therefore, the second game ball B1 is highly likely to be disengaged to the left of the first through gate 35 regardless of which of the outlet ports 444a to 446a is the discharge source.

In this way, even if the two game balls B1 flow down in a state where the game areas PA are continuous, there is a possibility that the game ball B1 will win the first through gate 35 at a timing other than the winning target period in the winning continuous period. It is set to be low. Therefore, even when the adjustment mechanism 430 according to the present embodiment is used, if the continuous winning period is reached, the universal electric open winning occurs continuously.

The adjustment drive unit 184 rotates the rotating body 440 so that the timing at which the game ball B1 can be discharged from the rotating body 440 occurs once every 2 seconds. By the configuration in which the adjustment drive unit 184 slowly rotates the rotating body 440, the game ball B1 that collides with the entrances 444a to 446a moving in the rotation direction in the upper part of the adjustment mechanism 430 is strongly directed to the right. It is possible to avoid a situation in which the player is bounced back and feels uncomfortable.

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

The game ball B1 is taken into any one of the adjustment passages 444 to 446 and is discharged from the entrances 444a to 446a different from the adjustment passages 444 to 446 in which the game ball B1 is taken. In the configuration in which the rotating body 440 is rotated while the game ball B1 is held in the entrances 444a to 446a in which the game balls B1 are taken in, in order to prevent the game balls B1 from falling from the entrances 444a to 446a during rotation. Fall prevention means provided around the rotating body 440 is required. In this case, the game ball B1 may be sandwiched between the rotating body 440 and the fall prevention means, and the rotation of the rotating body 440 may be hindered.

On the other hand, by causing the game ball B1 to pass through the inside of the passage forming portion 443 and be discharged from the entrances 444a to 446a different from the taken entrances 444a to 446a, a problem occurs during the game, and the game is played. It is possible to reduce the possibility that a countermeasure for canceling the problem and resolving the problem is required. Further, by suppressing an increase in the number of members forming the adjusting mechanism 430, it is possible to simplify the structure of the adjusting mechanism 430 and reduce the manufacturing cost of the adjusting mechanism 430.

The rotating body 440 is configured to discharge the game ball B1 before the entrances 444a to 446a that have taken in the game ball B1 in the upward direction are in a direction in which the game ball B1 can be discharged. Therefore, as compared with the configuration in which the rotating body 440 rotates while the game ball B1 is held in the doorways 444a to 446a in which the game ball B1 is taken in, it is possible to shorten the time taken from the intake of the game ball B1 to the discharge. You can As a result, it is possible to reduce the possibility that the player's interest is transferred to another place from the time the game ball B1 is taken in to the time it is discharged, and the player's attention to the adjustment mechanism 430 is lowered.

The adjusting mechanism 430 includes a standing wall 452 that prevents the game ball B1 from falling downward until the game ball B1 guided to the entrances/exits 444a to 446a reaches the discharge timing at which the game ball B1 can win the first through gate 35. .. By using the upright wall 452, it is possible to reduce the number of game balls B1 discharged downward from the first through gate 35 at a timing earlier than the discharge timing. Therefore, it is possible to reduce the possibility that the game ball B1 will be shifted to the first through gate 35 in the winning continuous period from the winning target period, and to increase the probability of the winning being open when the winning occurs in the winning consecutive period. You can As a result, it is possible to increase the player's expectation for the winning consecutive period and to improve the interest of the game.

Since the distance between the discharge position of the game ball B1 in the adjustment mechanism 430 and the first through gate 35 is equal to or larger than the diameter of the game ball B1, depending on the discharge direction and discharge speed of the game ball B1 discharged from the adjustment mechanism 430. , The discharged game ball B1 is removed from the first through gate 35. The width of the third entrance/exit 446a is set narrower than the width of the first entrance/exit 444a and the width of the second entrance/exit 445a. Therefore, the possibility that the game ball B1 discharged from the third gateway 446a will come off the first through gate 35, the possibility that the game ball B1 discharged from the second gateway 445a will come off the first through gate 35, and It is higher than the possibility that the game ball B1 taken out from the 3 entrance 446a is discharged from the first through gate 35. This avoids a situation in which all of the game balls B1 taken into the adjusting mechanism 430 enter the first through gate 35 and the player pays attention only to taking in the game balls B1 in the adjusting mechanism 430 and does not pay attention to the discharge. be able to. Then, the interest of the player can be improved by collecting the player's interest until the moment of winning the first through gate 35.

The game ball B1 taken into the first adjustment passage 444 from the first entrance/exit 444a is configured to be guided to the second adjustment passage 445 and discharged from the second entrance/exit 445a, and also from the second entrance/exit 445a to the second adjustment passage 445. The game ball B1 taken in is guided to the third adjustment passage 446 and discharged from the third entrance/exit 446a. Further, the game ball B1 taken into the third adjusting passage 446 from the third inlet/outlet 446a is guided to the first adjusting passage 444 and discharged from the first inlet/outlet 444a. In this way, the game ball B1 taken in from the entrances 444a to 446a is configured to move through the combination adjustment passages 444 to 446 capable of discharging the game ball B1 at the shortest distance, so that the rotating body 440 is rotated. It is possible to avoid the situation in which the taken game ball B1 is not easily discharged and the ascending and descending are repeated in the adjusting passages 444 to 446. As a result, it is possible to prevent the number of game balls B1 discharged from the adjustment mechanism 430 toward the first through gate 35 from decreasing and prevent the player from losing interest in the adjustment mechanism 430.

<Fifth Embodiment>
In this embodiment, the configuration for periodically supplying the game ball B1 to the first through gate 35 is different from that of the first embodiment. The configuration different from that of the first embodiment will be described below. The description of the same configuration as the first embodiment is basically omitted.

The game board 520 of the present embodiment is provided with an adjusting device 540 for adjusting the timing at which the game ball B1 is supplied to the first through gate 35. The configuration around the adjusting device 540 and the adjusting device 540 will be described with reference to FIG. 55. FIG. 55 is a front view of the game board 520 showing the vicinity of the first through gate 35 and the adjusting device 540 in an enlarged manner.

As shown in FIG. 55, in the game board 520, above the first through gate 35, the adjusting device 540 and a part of the game ball B1 discharged from the adjusting device 540 toward the first through gate 35 are the first. An adjusting mechanism 530 including an electric nail 560 that prevents the player from winning the through gate 35 is provided. Here, the electric nail 560 is the same member as the electric nail 361 already described in FIG. 47 of the third embodiment.

First, the adjusting device 540 will be described with reference to FIG. 55. As shown in FIG. 55, the adjusting device 540 allows the game ball B1 to enter the adjusting device 540 when it is in the open state and also allows the game ball B1 to enter the adjusting device 540 when it is in the closed state. The adjustment unit 546 for prohibiting the adjustment, the adjustment drive unit 547 for executing the transition from the closed state to the open state in the adjustment unit 546, and the transition from the open state to the closed state, and the game ball B1 incorporated in the adjustment device 540. And a guide member 541 for guiding toward the first through gate 35.

As shown in FIG. 55, the adjusting device 540 includes a plate-shaped base body 542 having a predetermined thickness. Further, the game board 520 is provided with a base recess (not shown) capable of accommodating the base body 542 without a gap. The adjusting device 540 is fixed by nailing the base body 542 to the game board 520 in a state where the base body 542 is housed in the base recess portion. In the state where the guide member 541 is fixed to the game board 520, the front surface of the base body 542 is flush with the front surface of the game board 520.

As shown in FIG. 55, the guide member 541 includes a passage forming portion 543 formed so as to vertically project from the front surface of the base body 542 toward the front. The passage forming portion 543 extends from the central portion of the front surface of the base body 542 in the vertical direction to the lower portion thereof, and extends from the front surface of the base body 542 to the vicinity of the back surface of the window panel 52 (FIG. 1). There is. A guide passage 545 for guiding the game ball B1 toward the first through gate 35 is formed in the passage forming portion 543.

The guide passage 545 is formed by providing a through hole that vertically penetrates the passage forming portion 543 with respect to the passage forming portion 543, and allows one gaming ball B1 to pass through. , Has a passage section that makes it impossible for a plurality of game balls B1 to pass through at the same time.

As shown in FIG. 55, the guide passage 545 is a straight passage toward the first through gate 35. The guide passage 545 has a passage length approximately 1.2 times the diameter of the game ball B1 and can direct the game ball B1 to be discharged. The distance from the lower end of the guide passage 525 to the upper end of the first through gate 35 is set to be approximately twice the diameter of the game ball B1, and the game ball B1 discharged from the guide passage 545 is at the position of the electric nail 560. Depending on the case, there are cases where the first through gate 35 is won and cases where no prize is won.

As shown in FIG. 55, the adjusting portion 546 is an upper portion of the base body 542 and is provided in front of the front surface of the base body 542. Further, the adjustment drive part 547 is arranged behind the adjustment part 546 and behind the base body 542. The adjustment unit 546 is connected to the adjustment drive unit 547 mounted on the back side of the game board 520, and is driven by the adjustment drive unit 547 to take either a closed state or an open state. When the adjusting unit 546 is closed, the game ball B1 cannot enter the guide passage 545, and when the adjusting unit 546 is open, the game ball B1 can enter the guide passage 545.

The adjustment drive unit 547 is connected to the output port of the MPU 62 (FIG. 12), and the drive signal output from the MPU 62 is input to the adjustment drive unit 547. The adjustment drive unit 547 keeps the adjustment unit 546 closed when the drive signal is in the LOW state, and opens the adjustment unit 546 when the drive signal is in the HI state.

The main CPU 63 (FIG. 12) instructs the adjustment drive unit 547 on the condition that it is the switching timing for shifting the adjustment unit 546 from the closed state to the open state in the timer interrupt processing (FIG. 18) executed in the 4 msec cycle. The drive signal output to the adjustment drive unit 547 is set to HI on the condition that the output signal is raised from the LOW state to the HI state and the adjustment unit 546 is changed from the open state to the closed state. From the state to the LOW state.

Based on the drive signal input from the main CPU 63, the adjustment drive unit 547 repeats the opening/closing operation of the adjustment unit 546, which keeps the adjustment unit 546 closed for 0.95 sec and opens for 0.05 sec. Therefore, the guide passage 545 is in a state in which the game ball B1 can be taken in at a cycle of 1 sec, and the game ball B1 can be discharged toward the first through gate 35 at a cycle of approximately 1 sec.

Here, the closed state and the open state of the adjustment unit 546 will be described with reference to FIGS. 56(a) and 56(b). 56(a) is a front view of the adjusting device 540 in the closed state, and FIG. 56(b) is a front view of the adjusting device 540 in the open state.

As shown in FIG. 56( a ), the adjusting portion 546 is located at the upper left of the guide passage 545 in the base body 542, and extends in the front-rear direction on the left rotation shaft 548 and the left rotation shaft 548. And a left side adjustment member 549 having a substantially rectangular parallelepiped shape that is fixed in a rotatable manner. The left side adjustment member 549 exists from the front surface of the game board 520 (FIG. 55) to the vicinity of the rear surface of the window panel 52 (FIG. 1).

As shown in FIG. 56A, the left side adjustment member 549 includes a right side surface 549a located inside the adjustment portion 546 in the closed state and a left side surface 549b located outside. In the adjustment unit 546 in the closed state, the right side surface 549a and the left side surface 549b are inclined downward to the left.

As shown in FIG. 56( b ), the left side adjustment member 549 rotates counterclockwise around the left side rotation shaft 548 when the adjustment portion 546 shifts from the closed state to the open state. Then, in the opened state of the adjusting portion 546, the left side adjusting member 549 is in a state in which the right side surface 549a thereof is inclined downward to the right and the left side surface 549b is inclined downward to the right. It will be in the state of being.

Further, as shown in FIG. 56( a ), the adjusting portion 546 is located in the upper right of the guide passage 545 in the base body 542, and extends in the front-rear direction. A right side adjustment member 552 having a substantially rectangular parallelepiped shape that is fixed to the shaft 551 in a rotatable manner. The right side adjustment member 552 exists from the front surface of the game board 520 to the vicinity of the back surface of the window panel 52.

As shown in FIG. 56A, the right side adjustment member 552 includes a left side surface 552a located inside the adjustment section 546 in the closed state and a right side surface 552b located outside. In the adjustment unit 546 in the closed state, the left side surface 552a and the right side surface 552b are inclined rightward downward.

As shown in FIG. 56( b ), the right adjustment member 552 rotates around the right rotation shaft 551 in the clockwise direction when the adjustment portion 546 shifts from the closed state to the open state. Then, in the open state of the adjusting portion 546, the left side surface 552a of the right adjusting member 552 is inclined downward to the left, and the right side surface 552b is inclined downward to the left. It will be in the state of being.

As shown in FIG. 56(a), in the closed adjusting portion 546, the distance between the upper end of the left adjusting member 549 and the upper end of the right adjusting member 552 is such that the game ball B1 cannot fit into the gap. Narrow to the extent. Then, as described above, in the closed state of the adjusting portion 546, the left side surface 549b of the left side adjusting member 549 is inclined downward to the left, and the game ball B1 contacting the left side surface 549b is moved to the lower left side. Let it escape. Further, the right side surface 552b of the right side adjusting member 552 is inclined downward to the right, and allows the game ball B1 that contacts the right side surface 552b to escape to the lower right.

On the other hand, as shown in FIG. 56(b), in the adjustment unit 546 in the open state, between the right side surface 549a of the left side adjustment member 549 and the left side surface 552a of the right side adjustment member 552, the diameter of the game ball B1 is smaller than the diameter of the game ball B1. There is a wide space. Then, as described above, in the opened state of the adjusting portion 546, the right side surface 549a of the left side adjusting member 549 is inclined downward to the right, and the game ball B1 contacting the right side surface 549a is moved to the lower right side. It bounces and enters the guide passage 545. Further, the left side surface 552a of the right side adjusting member 552 is inclined downward to the left, and the game ball B1 contacting the left side surface 552a is bounced back to the lower left to enter the guide passage 545.

In addition, in the process of the adjustment unit 546 transitioning from the open state to the closed state, the interval between the upper end of the left adjusting member 549 and the upper end of the right adjusting member 552 gradually narrows. The adjusting portion 546 is arranged such that the right side surface 549a of the left adjusting member 549 is directed downward at a timing before the distance between the upper end of the left adjusting member 549 and the upper end of the right adjusting member 552 becomes smaller than the diameter of the game ball B1. The left side surface 552a of the right adjustment member 552 has a shape in which the left side surface 552a is inclined downward and rightward.

As shown in FIG. 55, the electric nail 560 is connected to the nail drive unit 560a, contacts the game ball B1 discharged from the guide passage 525, and changes the course of the game ball B1 to cause the game ball B1 to move. A prohibited position that prevents the player from winning the first through gate 35, and a permission position that allows the game ball B1 to enter the first through gate 35 by deviating from the course of the game ball B1 discharged from the guide passage 525. And take.

The nail drive signal output from the output port of the MPU 62 is input to the nail drive unit 560a. The nail drive unit 560a keeps the electric nail 560 in the prohibited position when the nail drive signal is in the LOW state, and moves the electric nail 560 to the permitted position when the nail drive signal is in the HI state. The switching between the prohibited position and the permitted position of the electric nail 560 in the nail drive unit 560a is performed in conjunction with the switching between the closed state and the open state of the adjustment unit 546 in the adjustment drive unit 547.

Specifically, in the main CPU 63, the rising of the nail drive signal from the LOW state to the HI state is performed in synchronization with the rising of the drive signal from the LOW state to the HI state. Therefore, the electric nail 560 moves from the prohibited position to the permitted position in synchronization with the timing when the adjustment unit 546 shifts from the closed state to the open state. The electric nail 560 is always in the permission position during the period when the adjustment unit 546 is in the open state. Therefore, while the adjusting unit 546 is in the open state, the game ball B1 discharged from the adjusting device 540 can enter the first through gate 35.

In the main CPU 63, the fall of the nail drive signal from the HI state to the LOW state is executed at a timing later than the timing at which the fall of the drive signal from the HI state to the LOW state is executed. Therefore, the electric nail 560 returns from the permission position to the prohibition position slightly later than the timing when the adjustment unit 546 returns from the open state to the closed state. The timing at which the electric nail 560 returns to the prohibited position is allowed by the game ball B1 that has entered the guide passage 525 within 0.04 seconds from the start timing of the opening state in the opened state of the adjustment unit 546 that continues for 0.05 seconds. It is a timing at which it is possible to pass the electric nail 560 at the position to the left and win the first through gate 35.

Further, the timing at which the electric nail 560 returns to the prohibited position is such that the electric nail 560 is once sandwiched by the adjusting portion 546 until the adjusting portion 546 in the open state returns to the closed state, and then taken into the guide passage 525. It is the timing to prevent the game ball B1 from winning the first through gate 35.

Here, a situation in which the winning of the game ball B1 discharged from the adjusting device 540 to the first through gate 35 is blocked by the electric nail 560 will be described with reference to FIGS. 57(a) to 57(d). 57(a) to 57(d) are front views of the game board 520 showing the periphery of the adjusting mechanism 530 in an enlarged manner.

As shown in FIG. 57(a), when the game ball B1 enters the adjustment unit 546 in the intermediate state where the game ball B1 moves from the open state to the closed state, the game ball B1 is the right side surface 549a of the left side adjustment member 549 and the right side adjustment member. There is a possibility of being sandwiched between the left side surface 552a of 552. In this state, the right side surface 549a of the left adjusting member 549 is inclined downward to the left, and the left side surface 552a of the right adjusting member 552 is inclined downward to the right, If the condition that the contact position with the adjusting unit 546 is above the center of gravity of the game ball B1 and the condition is satisfied, the sandwiched game ball B1 moves downward due to the force of the adjusting unit 546 to return to the closed state. It is pushed and enters the guide passage 525.

As shown in FIG. 57(b), the electric nail 560 returns to the prohibited position before the game ball B1 sandwiched between the adjusting portions 546 passes the position of the electric nail 560. Therefore, in the intermediate state, the game ball B1 sandwiched by the adjusting portion 546 collides with the electric nail 560 that has returned to the prohibited position, and is disengaged to the left of the first through gate 35, downstream of the guide passage 525.

As already described in the first embodiment, the minimum interval for the game balls B1 to be fired in the game ball firing mechanism 27 (FIG. 2) is 0.6 sec. The game ball B1 may flow down toward the adjustment unit 546 of the adjustment device 540 in a state where a plurality of the game balls B1 are connected. As described above, the duration of the open state of the adjusting unit 546 is set to 0.05 sec. For this reason, when two game balls B1 are continuously connected to each other for 0.05 seconds to enter the adjusting unit 546, as shown in FIG. 57(c), the first game ball B1 is adjusted by the adjusting unit 546. After entering the guide passage 525 in the open state, there is a possibility that the second game ball B1 is in a state of being sandwiched by the adjusting portion 546 that tries to return from the open state to the closed state.

In this case, when the second game ball B1 sandwiched between the adjusting parts 546 enters the guide passage 525, the electric nail 560 has the first game ball B1 reach the position of the electric nail 560. It is in the permitted position at the timing. Therefore, the first game ball B1 can pass the left side of the electric nail 560 and win the first through gate 35.

On the other hand, as shown in FIG. 57(d), the electric nail 560 returns to the prohibited position before the second game ball B1 sandwiched by the adjusting portions 546 reaches the position of the electric nail 560. Therefore, the second game ball B1 collides with the electric nail 560. In this way, the winning of the game ball B1 sandwiched between the adjusting parts 546 to the first through gate 35 is blocked by the electric nail 560. As a result, it is possible to prevent the second gaming ball B1 from winning a prize in the first through gate 35 at a timing deviating from the winning target period in the winning consecutive period, which results in a failure result in the ordinary electric open lottery. You can

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

The adjusting mechanism 530 is a configuration that does not allow the game ball B1 to enter the guide passage 525 when the adjusting portion 546 is closed. Therefore, it is possible to reduce the possibility that the game ball B1 will win the first through gate 35 at a timing at which the normal electric train open win does not occur in the continuous winning period. As a result, it is possible to increase the probability of the occurrence of the universal electric open winning in the winning continuous period. In this way, the interest of the game can be improved by increasing the expectation of the player for the continuous winning period.

The guide passage 525 and the first through gate 35 are separated from each other by a diameter of the game ball B1 or more, and the game ball B1 discharged from the guide passage 525 flows down toward the first through gate 35 in the middle of the path. An electric nail 560 that moves between a prohibition position that closes the path and a permission position that allows passage of the path is provided, and the electric nail 560 is at the end of the period in which the open state of the adjustment unit 546 continues. The game ball B1 entering the guide passage 525 is prevented from winning in the first through gate 35.

When all of the game balls B1 taken into the guide passage 525 enter the first through gate 35, the player may pay attention only to taking in the game balls B1 in the adjusting mechanism 530 and not paying attention to the discharge. On the other hand, the player's adjustment is made until the moment when the player wins the first through gate 35 by preventing the winning of the part of the game ball B1 taken into the guide passage 525 to the first through gate 35. It is possible to maintain interest in the periphery of the mechanism 530 and improve the interest of the game.

The adjusting mechanism 530, in the opened state of the adjusting unit 546, after the first game ball B1 is taken into the guide passage 525, the second game ball B1 connected to the first game ball B1 is When it is sandwiched by the adjusting unit 546 in the intermediate state, the electric nail 560 at the prohibited position blocks the winning of the second game ball B1 to the first through gate 35. Therefore, it is possible to reduce the possibility that the game ball B1 will win the first through gate 35 at a timing at which the normal electric train open win does not occur in the continuous winning period. As a result, it is possible to increase the probability of the occurrence of the universal electric open winning in the winning continuous period. In this way, the interest of the game can be improved by increasing the expectation of the player for the continuous winning period.

<Another form in the fifth embodiment>
In the fifth embodiment described above, the adjustment drive unit 547 may not be provided, and the adjustment unit 546 may be in the open state and may not move. In this case, since the adjusting portion 546 does not take the closed state, the game ball B1 can always enter the guide passage 525. The game ball B1 discharged from the guide passage 525 collides with the electric nail 560 when the electric nail 560 is in the prohibited position, so that it is deviated from the path toward the first through gate 35. On the other hand, when the electric nail 560 is in the permitted position, it is possible to pass the electric nail 560 to the left and win the first through gate 35. For example, when the electric nail 560 is configured to repeat the forbidden position for 0.95 sec and the permitted position for 0.05 sec by the nail driving unit 560 a, the adjusting mechanism 530 causes the first through gate 35 to move. It is possible to provide the game ball B1 in a cycle of 1 sec.

In the fifth embodiment described above, an escape passage may be formed in the rear of the game board 520, and the game ball B1 sandwiched by the adjusting portions 546 may be released in the rear of the game board 520. Specifically, a passage entrance is formed as a frontward opening in a region located behind the adjusting portion 546 on the game board 520. The game board 520 includes an escape passage that guides the game ball B1 taken in from the passage entrance downward, and a passage outlet that discharges the game ball B1 guided in the escape passage to the front of the game board 520.

While the adjusting portion 546 sandwiches the game ball B1, the right side surface of the left adjusting member 549 is inclined rearward to the left, and the left side surface of the right adjusting member 552 is rearward to the right. It is tilted toward Therefore, the game ball B1 sandwiched between the adjusting portions 546 is guided to the passage entrance formed behind the adjusting portion 546 with the transition of the adjusting portion 546 to the closed state. The game ball B1 that has entered the escape passage from the passage entrance is guided downward by the escape passage. The game ball B1 is discharged from the passage outlet and is again positioned in front of the game board 520.

In the fifth embodiment described above, by adjusting the relationship between the guide passage 525 and the first through gate 35, the case where the game ball B1 discharged from the guide passage 525 wins the first through gate 35 and the winning. It may be configured such that there are cases where it is not performed. Specifically, the guide passage 525 is provided diagonally above and to the left of the first through gate 35, and a space equal to or larger than the diameter of the game ball B1 is provided between the guide passage 525 and the first through gate 35. ing. In this case, even if the electric nail 560 does not exist between the guide passage 525 and the first through gate 35, the discharged game according to the speed at the time of discharging the game ball B1 discharged from the guide passage 525. The case where the ball B1 wins the first through gate 35 and the case where no ball wins can be generated. By leaving the possibility that the game ball B1 discharged from the guide passage 525 comes off the first through gate 35, the behavior of the game ball B1 after discharge can also attract the player's attention.

<Sixth Embodiment>
In the present embodiment, the second operation port 582 is provided in the right side area PA3 of the game area PA, and the distribution winning device 583 is provided below the second operation port 582. The configuration different from that of the first embodiment will be described below. The description of the same configuration as the first embodiment is basically omitted.

First, the configuration of the game board 580 in this embodiment will be described with reference to FIG. FIG. 58 is a front view of the game board 580. As shown in FIG. 58, the game area PA includes an upper area PA1 located above the variable display unit 36, a left area PA2 located on the left side of the variable display unit 36, and a right area PA3 located on the right side of the variable display unit 36. , And a lower area PA4 located below the variable display unit 36.

As described in the first embodiment, the first through gate 35 is provided in the left side area PA2, and the adjusting mechanism 180 is provided above the first through gate 35. The prize winning timing at which the game ball B1 discharged from the adjusting mechanism 180 can enter the first through gate 35 occurs in a cycle of 1 sec. In addition, the winning target period, which is the winning of the ordinary electric open, is also generated in a cycle of 1 sec in the ordinary electric open lottery that is triggered by winning the first through gate 35. Therefore, when the winning possible timing overlaps the winning target period, the winning continuous period is set, and when the winning possible timing does not overlap the target period, the non-winning consecutive period is set.

As shown in FIG. 58, the game board 580 is provided with a passage entrance 171, an escape passage 172, a passage exit 173, and an exit roof 174 around the adjustment mechanism 180, similarly to the game board 24 in the first embodiment. ing. Therefore, the game ball B1 which has flowed down toward the adjusting mechanism 180 but has not been taken into the adjusting mechanism 180 enters the escape passage 172 from the passage inlet 171. Then, the game ball B1 is guided to the passage outlet 173 by the escape passage 172 and discharged from the passage outlet 173 toward the front of the game board 580.

As shown in FIG. 58, a first operation port 581 is provided in the lower area PA4. The first operating port 581 does not include a member that opens and closes the first operating port 581, and is open upward. As shown in FIG. 58, the variable display unit 36 includes a stage 36a through which the game ball B1 can pass and the game ball B1 can be discharged. The variable display unit 36 has a guide passage for allowing the game ball B1 to flow into the stage 36a. The game ball B1 that flows into the stage 36a and is discharged from the center of the stage 36a to the outside of the variable display unit 36 drops from directly above the first operating port 581 toward the first operating port 581. Therefore, the game ball B1 ejected from the center of the stage 36a is likely to enter the first operating port 581.

Since the first operating port 581 is provided in the lower area PA4, when the firing operation device 28 (FIG. 2) is operated so that the game ball B1 flows down the left area PA2, and the right area PA3 is set. In any case where the firing operation device 28 is operated so that the game ball B1 flows down, it is possible to win the game ball B1 into the first operating port 581. However, when the inlet of the guide passage to the stage 36a is provided for the left side area PA2 and not for the right side area PA3, the side that flows down the left side area PA2 flows down the right side area PA3. As compared with the above, winning in the first operating port 581 is more likely to occur. Also, regarding the arrangement of the game parts and the nails 24b in the left side area PA2 and the right side area PA3, it is easier for the winning to occur in the first operating port 581 when the left side area PA2 flows down than when the right side area PA3 flows down. Is set to. Then, the game ball B1 that has flowed down the right side area PA3 is configured so that the winning in the first operating port 581 hardly occurs.

As shown in FIG. 58, a second operation port 582 is provided in the right side area PA3. The second actuation port 582 cannot win when the firing operating device 28 (FIG. 2) is operated so that the game ball B1 flows down the left side area PA2, so that the game ball B1 flows down the right side area PA3. When the firing operation device 28 is operated, the player can win the prize.

The configuration of the second operation port 582 will be described with reference to FIG. 59. 59(a) and 59(b) are schematic views showing the configuration of the second operation port 582. The second actuating port 582 is provided with a general electric accessory 582a as a guide piece (support piece) composed of a pair of left and right movable pieces.

The ordinary electric accessory 582a is connected to a general electric drive unit 582b mounted on the back side of the game board 580, and is driven by the general electric drive unit 582b to be in the closed state shown in FIG. 59(a). 59 and the open state shown in FIG. 59(b). The game ball B1 cannot win the second operating port 582 in the closed state of the universal electric object 582a, and the winning in the second operating port 582 can be achieved by opening the ordinary electric substance object 582a. By the way, when it is in the open state, the universal electric accessory 582a projects to the game area PA side and guides the winning to the second operating port 582. The second operating port 582 is provided with a detection sensor 582c for detecting the game ball B1 that has won the second operating port 582. The detection sensor 582c is connected to the input port of the MPU 62 (FIG. 12), and the main CPU 63 (FIG. 12) detects the winning of the second operating port 582 based on the detection information from the detection sensor 582c. ..

As shown in FIG. 58, a second through gate 39 is provided above the second operating port 582 in the right side area PA3. The second through gate 39 is not winable when the firing operation device 28 (FIG. 2) is operated so that the game ball B1 flows down the left side area PA2, and the game ball B1 flows down the right side area PA3. It is provided at a position where the player can win a prize when the firing operation device 28 is operated. The second through gate 39 has a through hole (not shown) penetrating in the vertical direction, and the game ball B1 that has won the second through gate 39 flows down in the game area PA after winning. As a result, the game ball B1 that has won the second through gate 39 can enter the second operating port 582. The second through gate 39 is provided with a detection sensor for detecting the game ball B1 that has won the second through gate 39. The detection sensor is connected to the input port of the MPU 62 (FIG. 12), and the main CPU 63 (FIG. 12) detects the winning of the second through gate 39 based on the detection information from the detection sensor.

As already described in the first embodiment, the ordinary electric open lottery is executed in response to the winning of one of the first through gate 35 and the second through gate 39 of the game ball B1. Then, in the case where the ordinary electric power open lottery is successful, the ordinary electric power accessory 582a of the second operating port 582 is switched from the closed state to the open state.

As shown in FIG. 58, a first special figure display portion 584 and a second special figure display portion 585 are provided at the lower right of the game board 580. In the first special map display portion 584, a winning lottery is carried out upon the winning of the first working opening 581, whereby a variable display or a predetermined display of the pattern is performed and a result corresponding to the lottery result is displayed. Be seen. In addition, in the second special figure display unit 585, a winning or lottery is performed when the winning of the second operating port 582 is performed, so that a variable display or a predetermined display of the pattern is performed and a result corresponding to the lottery result is displayed. Is done.

As shown in FIG. 58, a first special figure reservation display section 586 is provided at a position adjacent to the first special figure display section 584, and a second special figure display section 585 is provided at a second position. A special figure reservation display portion 587 is provided. The first special figure reservation display portion 586 displays the maximum number of the game balls B1 that have won in the first operation opening 581 up to four, and the second special figure reservation display portion 587 displays the second operation opening 582. The maximum number of winning game balls B1 is displayed as a maximum of four.

As shown in FIG. 58, in the lower area PA4, the special electric prize winning device 32 already described in the first embodiment is provided at a position below the first operating port 581 and above the out port 24a. Has been. In the special electric prize winning device 32, when the firing operation device 28 is operated so that the game ball B1 flows down in the left side area PA2, and the firing operation device 28 is operated so that the game ball B1 flows down in the right side area PA3. You can win the prize in any case.

As shown in FIG. 58, a distribution winning device 583 is provided below the second operating port 582 in the right area PA3. The distribution prize winning device 583 cannot win a prize when the shooting operation device 28 is operated so that the game ball B1 flows down the left side area PA2, and the shooting operation device so that the game ball B1 flows down the right side area PA3. When 28 is operated, winning is possible.

The winning lottery is executed in response to the winning of either the first operating port 581 or the second operating port 582. When a big hit result is obtained in the winning lottery, the opening/closing execution mode described in the first embodiment is entered. As a result, the special electric prize winning device 32 is opened, and it becomes possible to win the special electric prize winning device 32 of the game ball B1. In addition to the big hit result, the small hit result is also provided in the win lottery executed when the winning of the second operating port 582 is won. When the small hit result is obtained in the winning lottery executed when the winning of the second operation port 582 is won, the process shifts to the branch execution mode in which the winning of the distribution winning device 583 is possible.

Here, the distribution winning apparatus 583 will be described with reference to FIGS. 60(a) and 60(b). FIG. 60A is a vertical cross-sectional view of the distribution winning apparatus 583 as viewed from the side, and FIG. 60B is a vertical cross-sectional view of the distribution winning apparatus 583 as viewed from the rear side.

As shown in FIG. 60(a), the distribution winning device 583 is formed with a distribution entrance 591 having a size through which the game ball B1 can pass, and the game ball B1 passes through the distribution entrance 591. There is provided a distribution side opening/closing member 592 for switching between a closed state which is impossible and an open state which allows the game ball B1 to pass. The distribution side opening/closing member 592 is opened by being driven by a distribution entrance drive unit 593 through a link mechanism (not shown). The distribution inlet 591 constitutes an inlet of the guide passage 594, and the game ball B1 flowing in from the distribution inlet 591 flows down the guide passage 594 to the downstream side.

As shown in FIG. 60( b ), the guide passage 594 bifurcates from its middle position, and constitutes an upstream region 595 that constitutes the upstream side of the branch position and one of the downstream sides of the branch position. V winning area 596 and a discharging area 597 that constitutes the other downstream side from the branch position. Further, at the branch position, a shutter 598 is provided as a distribution unit that distributes the game ball B1 reaching the branch position from the upstream area 595 to either the V winning area 596 or the discharging area 597. When the shutter 598 is not driven by the shutter drive unit 599, the game ball B1 that has reached the branch position flows into the discharge area 597, and the shutter 598 is driven by the shutter drive unit 599. Then, the game ball B1 that has reached the branch position will flow into the V winning area 596.

A detection sensor 595a for counting is provided so that the detection area exists at a position where the game ball B1 flowing into the upstream area 595 always passes. Based on the fact that the game ball B1 is detected by the detection sensor 595a for counting, the payout of prize balls corresponding to the winning of the distribution prize winning device 583 is executed. In addition, a V-winning detection sensor 596a is provided such that the detection region exists at a position where the game ball B1 flowing into the V-winning region 596 always passes. Based on the fact that the game ball B1 is detected by the V prize detection sensor 596a, the special electric prize winning device 32 is opened/closed and the opening/closing execution mode is entered. Further, the discharge detection sensor 597a is provided so that the detection area exists at a position where the game ball B1 flowing into the discharge area 597 always passes. Based on the detection results from the discharge detection sensor 597a and the V winning detection sensor 596a, it is determined whether or not the game ball B1 remains in the distribution winning apparatus 583.

By the way, the drive timing of the drive unit 599 for the shutter is set so that the gaming ball B1 that has won the distribution winning apparatus 583 is guided to the V winning area 596 with a probability of 80%. Is optional, and the probability of being guided to the discharge area 597 is higher. However, in order to increase the advantage of winning in the jackpot lottery based on the winning of the second working opening 582, the probability of shifting to the branch execution mode based on the winning of the second working opening 582 and the distribution winning apparatus. The shutter 598 is shaken so that the product of the probability that the game ball B1 that has won the prize 583 will flow into the V prize area 596 will be higher than the probability that the game ball B1 will be won in the jackpot lottery based on the prize for the first operation opening 581. It is preferable that the minute probability is set. For example, it is preferable that the probability of being guided to the V winning area 596 is set to be higher, and it is more preferable to be guided to the V winning area 596 with a probability of 75% or more and less than 100%.

In addition, the distribution winning device 583 is preferably formed so that it can be visually recognized from the front of the pachinko machine 10 which of the V winning area 596 and the discharging area 597 the winning game ball B1 is distributed to. Specifically, it is preferable that the front side of the distribution winning apparatus 583 is formed to be colored transparent or colorless transparent.

In the branch execution mode, when the game ball B1 enters the distribution winning apparatus 583, flows into the V winning area 596, and is detected by the V winning detection sensor 597a, a V winning occurs. On the other hand, in the branch execution mode, if the game ball B1 is not detected by the V winning detection sensor 597a, the V winning is not generated.

Next, the winning lottery in this embodiment will be described. First, an electrical configuration for performing a winning lottery in the main CPU 63 (FIG. 13) will be described.

The holding storage area 65a (FIG. 13) of this embodiment includes a first holding area and a second holding area. The first holding area is numerical information of the random number counter C1 (FIG. 13), the big hit type counter C2 (FIG. 13), and the reach random number counter C3 (FIG. 13) in accordance with the winning history of the first operating port 581. The second holding area is a numerical value of each of the hit random number counter C1, the big hit type counter C2, and the reach random number counter C3 in accordance with the winning history of the second operating port 582. This is an area where a combination of information is stored as reservation information.

In each of the first holding area and the second holding area, a maximum of four winning histories are held and stored. Each numerical value information stored in the first holding area and the second holding area is moved to the execution area AE (FIG. 13). The main CPU 63 executes a winning lottery based on various numerical information stored in the execution area AE at the start of one game.

Next, various tables used in the winning lottery will be described. The main ROM 64 (FIG. 12) stores a low-frequency left table, a regular right table, and a non-regular right table as tables used in the winning lottery.

In each table for winning lottery, the probability of a big hit result is set to be the same. In the pachinko machine 10 of the present embodiment, the high-probability mode and the low-probability mode described in the first embodiment are not set, and the main ROM 64 has a low-frequency left table, a regular right table, and One non-regular right table is stored for each type.

First, the low frequency left table will be described. When the support mode of the second operating port 582 is the low-frequency support mode, the holding information stored in the first holding area when the winning of the first operating port 581 occurs is referred to as the low-frequency left-side holding information. To do. The low-frequency left-side hold information includes information indicating that the hold information is stored in the low-frequency support mode and that the hold information is stored based on winning of the first operating port 581. There is. The low-frequency left-side table is a table that is read when the pending information stored in the execution area AE is the low-frequency left-side pending information.

In the left table for low frequency, only the big hit result is set, and the small hit result is not set. In the left table for low frequency, as a big hit result, a high frequency result that becomes the high frequency support mode after the opening/closing execution mode and a low frequency result that becomes the low frequency support mode after the opening/closing execution mode are set.

In the case where a win is generated in the first operating port 581 in the low frequency support mode and the jackpot result based on the win is a jackpot result, the jackpot result this time is a high frequency result and the first execution described above. When "1" is not set in the high-frequency flag described in the form, "1" is set in the high-frequency flag. If the result of the big hit this time is a low frequency result and the high frequency flag is set to "1", the high frequency flag is cleared to "0". When a big hit result is obtained in the winning lottery, the mode is changed to the opening/closing execution mode. After the opening/closing execution mode is finished, if the high-frequency flag is set to "1", the support mode of the second operating port 582 becomes the high-frequency support mode, and the value of the high-frequency flag is "0". In the case of “”, the support mode of the second operating port 582 becomes the low frequency support mode.

Next, the regular right table will be described. The holding information stored in the second holding area when the winning of the second operating opening 582 occurs in the high frequency support mode is defined as the right-side holding information for regular use. The regular right holding information includes holding information that is stored based on winning in the second operating port 582, and information indicating that winning in the second operating port 582 is generated by a regular flow. include. The right-side regular holding information is stored in the second holding area even when a winning is made to the second operating port 582 during the winning continuous period in the low frequency support mode. The regular right table is a table that is read when the suspension information stored in the execution area AE is the regular right suspension information.

Here, with the regular flow, the game ball B1 is shot toward the right side area PA3, triggered by one of the high frequency support mode and the winning continuous period of the low frequency support mode. It is the flow of the game in which the operation is performed. On the other hand, in the non-winning continuous period of the low frequency support mode, the flow of the game in which the operation of firing the game ball B1 toward the right side area PA3 is performed is an irregular flow.

The big hit result and the small hit result are set in the regular right table. The above-mentioned high-frequency result and low-frequency result are set in the regular right table as the jackpot result.

In the right table for regular use, the probability of occurrence of the small hit result is set so that when the result of the big hit is not reached, the result of the small hit is almost 100%. Note that the probability of occurrence of the small hit result when the big hit result is not set may be set to 100%. In the right table for regular use, as a small hit result, a high-frequency small hit result and a low-frequency small hit result described later are set.

In the case where a winning is generated in the second operating port 582 in either the continuous winning period of the low frequency support mode or the high frequency support mode, and the jackpot result is obtained in the winning lottery based on the prize, the jackpot result of this time Is a high frequency result and the high frequency flag is not set to “1”, the high frequency flag is set to “1”. Further, if the result of the big hit this time is a low frequency result and the high frequency flag is set to "1", the high frequency flag is cleared to "0". When a big hit result is obtained by the winning lottery, the mode is changed to the opening/closing execution mode.

Further, when the small hit result is obtained in the present winning lottery, if the small hit result of this time is the high frequency small hit result and the high frequency flag is not set to “1”, the high frequency “1” is set in the flag. Further, when the small hit result of this time is the low frequency small hit result and the high frequency flag is set to "1", the high frequency flag is cleared to "0". When the small hit result is obtained in the winning lottery, the above-described branch execution mode is entered, and when a V winning is generated in the branch execution mode, the open-close execution mode is entered.

After the opening/closing execution mode ends, if the high-frequency flag is set to "1", the support mode of the second operating port 582 becomes the high-frequency support mode and the value of the high-frequency flag is "0". When it is, the support mode of the second operating port 582 becomes the low frequency support mode. Further, when the branch execution mode is finished without generating the V winning, the high frequency flag is cleared to "0". Therefore, the support mode of the second operating port 582 becomes the low frequency support mode after the branch execution mode.

As described above, the winning continuation period in the low-frequency support mode allows the normal electric power open winning in which the second operating port 582 is opened to continuously occur. In this case, the winning lottery executed upon the winning of the second operating port 582 is the same as the winning lottery executed upon receiving the winning of the second operating port 582 in the high frequency support mode.

As described above, the probability that the jackpot result will occur in the winning lottery using the low-frequency left table is the same as the probability that the jackpot result will occur in the winning lottery using the regular right table. In addition, in the case where the big hit result is not obtained in the winning lottery using the low-frequency left table, a deviating result is obtained, whereas when the big win result is not obtained in the winning lottery using the regular right table, approximately 100 is obtained. The branch execution mode is entered with a probability of %. Therefore, the low frequency support mode is a disadvantageous support mode for the player as compared with the high frequency support mode.

Even in the low frequency support mode, which is more disadvantageous to the player than the high frequency support mode, when the winning continuous period is reached, the same winning lottery as in the high frequency support mode is executed. As already described in the first embodiment, the generation timing of the winning continuous period is not notified to the player. Therefore, in the low frequency support mode, the player may be in an advantageous state at a timing that is not expected by the player. As described above, in the low-frequency support mode, by making the player have an expectation that a continuous winning period will occur, it is possible to improve the enjoyment of the game.

Next, the non-regular right table will be described. The holding information stored in the second holding area triggered by the winning of the second working opening 582 in the non-winning continuous period of the low frequency support mode is set as the non-genuine right holding information. The non-genuine right-side hold information indicates that the hold information is stored when the winning of the second operating port 582 is won, and that the winning of the second operating port 582 is generated by an irregular flow. Contains information. The non-regular right side table is a table that is read when the pending information stored in the execution area AE is the non-regular right side pending information.

Big hit results and small hit results are set in the non-regular right table. The jackpot result set in the non-regular right table is the low frequency result described above, and the small hit result set in the non-regular right table is the low frequency small hit result described above. In the non-regular right table, the probability of occurrence of the small hit result is set so that the small hit result is approximately 100% when the big hit result is not obtained. Note that the probability of occurrence of the small hit result when the big hit result is not set may be set to 100%.

When a winning is generated in the second working opening 582 in the non-winning continuous period of the low frequency support mode, a winning lottery is performed. When the big hit result in the winning lottery or the small hit result results in a V winning due to the branch execution mode, opening and closing with the value of the high-frequency flag kept at "0" Switch to run mode. Therefore, after the opening/closing execution mode, the support mode of the second operating port 582 becomes the low frequency support mode. In addition, the value of the high frequency flag is maintained at "0" even when the branch execution mode is ended without generating the V winning, and the support mode of the second operating port 582 becomes the low frequency support mode.

A player who does not accurately grasp the flow of the game may unintentionally execute the above-mentioned irregular flow. As already described in the first embodiment, the possibility of becoming a general electric open lottery in the low frequency support mode general electric power open lottery becomes a general electric power open prize in the high frequency support mode ordinary electric power open lottery. It is set lower than possible. Therefore, the situation in which the game is played in a non-regular flow is more disadvantageous to the player than the situation in which the game is played in the regular flow, and a player who does not accurately grasp the flow of the game loses money. Becomes

On the other hand, in the non-winning continuous period of the low frequency support mode, even if the firing operation device 28 is operated so that the game ball B1 flows down the right side area PA3, a prize is generated in the second operating port 582. In this case, by adopting a configuration in which there is a high probability of shifting to the branch execution mode, it becomes possible to provide a relief measure to a player who does not accurately grasp the flow of the game. However, the low frequency support mode is always set after the open/close execution mode executed in an irregular flow. Thereby, it is possible to adopt a configuration in which it is not possible for the player to play a game in an irregular flow after grasping the flow of the game.

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

During the continuous winning period in the low frequency support mode, the winning lottery executed when the second operating port 582 wins, and the winning when the second operating port 582 wins in the high frequency support mode The lottery is executed based on the common right table for regular use. In the low-frequency support mode, which is disadvantageous to the player as compared to the high-frequency support mode, the opening and closing execution mode is set and the opening and closing is performed by the configuration in which the player's advantageous state occurs at a timing unexpected by the player. It is possible to make the player have an expectation that the high-frequency support mode will be set after the execution mode.

In a situation where the low frequency support mode is a non-winning continuous period, the game ball B1 flows down the right side area PA3 when the firing operation device 28 is operated so that the game ball B1 flows down the left side area PA2. This is a configuration that is more advantageous to the player than when operating the firing operation device 28. In the non-winning continuous period of the low frequency support mode, even when the launch operating device 28 is operated so that the game ball B1 flows down the right side area PA3, if a winning is generated in the second working opening 582, The configuration is such that there is a high probability of shifting to the open/close execution mode. Therefore, a relief measure can be given to an unfamiliar player who does not accurately grasp the flow of the game.

In the continuous winning period in the low frequency support mode, there is a possibility that a high frequency big hit result and a high frequency small hit result will be obtained in the winning lottery that is performed when the second operation opening 582 is won. Relative to the winning lottery that is triggered by winning the second operating port 582 in the non-winning continuous period of the low frequency support mode, the winning is performed in the second operating port 582 during the continuous winning period of the low frequency support mode. The winning lottery is likely to result in more advantageous results for the player. With such a configuration, it is possible to enhance the interest of the game by making the winning continuous period attractive. Further, when a player who understands the flow of the regular game dares to play the game in the non-regular flow, the non-regular flow is prevented from leading to an advantageous result for the player.

<Another form in the sixth embodiment>
In the above-described sixth embodiment, when the branch execution mode ends without V winning, the support mode of the second operation port 582 may not change before and after the branch execution mode. When a prize is generated in the second operation port 582 and a small win result is obtained in the winning lottery based on the prize, the process shifts to the branch execution mode while the value of the high frequency flag is maintained. Then, when the V winning is not generated in the branch execution mode, the current value of the high frequency flag is maintained as it is.

When a winning is generated in the second operating port 582 in the high frequency support mode, "1" is set in the high frequency flag when the winning occurs. The value of the high-frequency flag is a small win result in the winning lottery, and is maintained as it is when the branch execution mode ends without the V winning. In this case, the support mode of the second operating port 582 after the branch execution mode is maintained in the high frequency support mode.

Further, when a prize is generated in the second operating port 582 in the low frequency support mode, the value of the high frequency flag is "0" when the prize is generated. The value of the high-frequency flag is a small win result in the winning lottery, and is maintained as it is when the branch execution mode ends without the V winning. In this case, the support mode of the second operating port 582 after the branch execution mode is maintained in the low frequency support mode.

As described above, when the branch execution mode is terminated without generating the V winning, the support mode before shifting to the branch execution mode is maintained after the branch execution mode. The winning continuous period in the frequency support mode can be in a more advantageous state for the player than the non-winning consecutive period in the low frequency support mode, and can be in a more disadvantageous state for the player than in the high frequency support mode. While maintaining the superiority of the high frequency support mode over the low frequency support mode, the winning continuous period can be set as a state advantageous to the player in the low frequency support mode.

The winning of the same content as the non-regular right table in the winning lottery executed when the winning of the second operating port 582 occurs in the winning continuous period of the low frequency support mode in the sixth embodiment described above. A configuration in which a continuous table is used may be used. The big hit results set in the winning continuous table are only low frequency results, and the small hit results set in the winning continuous table are only low frequency small hit results. Therefore, even if the opening/closing execution mode is switched to by the winning lottery based on the winning continuous table, the support mode after the opening/closing execution mode does not become the high frequency support mode.

The winning lottery executed when the second operating port 582 wins during the winning continuous period of the low frequency support mode is the winning lottery that is executed when the second operating port 582 wins in the high frequency support mode. Compared with, the lottery is disadvantageous to the player. As a result, it is possible to maintain the superiority of the high frequency support mode over the low frequency support mode.

In the low-frequency support mode, when playing a game in a regular flow, it can be expected to shift to the opening/closing execution mode triggered by winning the first operation opening 581, and in the case where the winning continuous period is reached, It can be expected that the opening/closing execution mode will be triggered by the winning of the second operating port 582. On the other hand, when playing a game in an irregular flow, it can only be expected to shift to the opening/closing execution mode triggered by the winning of the second operating port 582. Then, the probability of occurrence of the universal electric open win, which is a condition for generating a prize in the second operating port 582, is low. For this reason, in the low-frequency support mode, the advantage of playing the game in the regular flow over that in the non-regular flow is maintained, and the player who knows the flow of the game intentionally decides to The possibility of playing a game in a regular flow is reduced.

In the above-described sixth embodiment, when a prize for the second through gate 39 occurs in an irregular flow, the player may be warned to play a regular flow. .. The warning to the player is given when a prize is awarded to the second through gate 39 in the non-winning continuous period of the low frequency support mode. Specifically, when the main CPU 63 detects a win to the second through gate 39, the value of the winning continuous flag already described in the first embodiment is “0”, and the high frequency. On condition that the value of the flag is “0”, the process for transmitting the warning command to the sound emission control device 81 is executed. Upon receiving the warning command, the sound emission control device 81 sends a command to the display control device 82 to display a warning to the player to operate the game ball launching device aiming at the first through gate 35. It is displayed on the display surface 41a of the symbol display device 41. In addition, the sound emission control device 81 controls the speaker unit 54 to perform sound output of a content that warns the player to operate the game ball launching device aiming at the first through gate 35. As a result, it is possible to reduce the possibility that a player who does not accurately grasp the flow of the game will generate a prize in the second operating port 582 in an irregular flow. Here, as already described in the first embodiment, when the non-winning continuous period shifts to the winning continuous period in the low frequency support mode, the winning continuous flag is set to "1". Therefore, if the operation mode of the game ball launching device is switched so that the game ball B1 flows down the right side area PA3 in response to the winning continuous period, no warning is given to the player.

In the above-described sixth embodiment, the opening mode of the special electric prize winning device 32 in the opening/closing execution mode performed in the non-regular flow is different from the opening mode of the special electric prize winning device 32 in the opening/closing execution mode performed in the regular flow. May be The main CPU 63 determines that the value of the winning continuous flag is “0” and the value of the high-frequency flag is “0” when the winning of the second operating opening 582 occurs. "1" is set to the non-genuine flag indicating that the prize is generated in an irregular flow. In addition, when the non-regular flag is set to "1" in the opening/closing execution mode, the main CPU 63 executes the opening/closing operation of the special electric prize winning device 32 in the non-regular mode and sets the non-regular flag to "1". If is not set, the opening/closing operation of the special power winning device 32 is executed in the regular mode. In the non-regular mode, the closing time from the end of the open state of the special electric prize winning device 32 to the next open state is set to be longer than in the regular mode. Therefore, in the non-regular mode, the amount of the game ball B1 consumed during the opening/closing execution mode is larger than that in the regular mode. In the non-winning continuous period of the low-frequency support mode, the game ball B1 is operated so as to flow down the left side area PA2, and when the winning continuous period is reached, the game ball B1 is discharged so as to flow down the right side area PA3. The regular flow in which the operation is switched is more advantageous to the player than the non-regular flow in which the game ball B1 flows down in the right side area PA3 during the non-winning continuous period of the low-frequency support mode. By doing so, it is possible to prevent the player who knows the flow of the game from intentionally playing the game in an irregular flow.

<Seventh Embodiment>
In this embodiment, the configuration for ejecting the game ball B1 in the adjusting mechanism 620 and the inclination of the opening of the first through gate 35 in the game board 610 are different from those in the first embodiment. The configuration different from that of the first embodiment will be described below. The description of the same configuration as the first embodiment is basically omitted.

First, the configuration of the adjusting mechanism 620 in the present embodiment will be described based on FIG. 61. The adjusting mechanism 620 periodically supplies the game ball B1 to the first through gate 35. FIG. 61 is a front view of the game board 610 showing the first through gate 35 and the configuration above the first through gate 35 in an enlarged manner. As shown in FIG. 61, in the game board 610 of the present embodiment, an adjusting mechanism 620 is provided above the first through gate 35 in place of the adjusting mechanism 180 of the first embodiment.

As shown in FIG. 61, in the adjusting mechanism 620 of the present embodiment, the accommodating portion 181 includes the left standing wall 181h and the right standing wall 181d described in the first embodiment, and accommodates the rotating body 183. The accommodation space is divided.

The left upright wall 181h and the right upright wall 181d are formed at intervals in the circumferential direction of the base body 181a so as to project from the front surface of the base body 181a toward the front. As shown in FIG. 61, the left upright wall 181h and the right upright wall 181d are separated from each other, so that the intake port 185 described in the first embodiment is present above the adjustment mechanism 620. A discharge port 621 exists in the lower right part of the adjusting mechanism 620. As shown in FIG. 61, the outlet 621 has a width slightly larger than the diameter of the game ball B1.

As shown in FIG. 61, the adjustment mechanism 620 includes the adjustment drive unit 184 described in the first embodiment at the rear of the rotating body 183. The adjustment drive unit 184 is connected to the output port of the MPU 62 (FIG. 12). In the present embodiment, the adjustment drive unit 184 slowly rotates the rotating body 183 in the clockwise direction at the angular velocity of 90° for 5 seconds by being supplied with the drive signal and in the drive state.

When any of the recessed portions 183b to 183e of the rotating body 183 is opened upward at the intake port 185 located at the upper part of the adjustment mechanism 620, the adjustment mechanism 620 can take in the game ball B1. In addition, when any of the recessed portions 183b to 183e is opened to the lower right at the discharge port 621 located at the lower right of the adjustment mechanism 620, the adjustment mechanism 620 can discharge the game ball B1. It becomes a state.

The duration of a state in which the game ball B1 can be taken in at the intake port 185 and the duration of a state in which the game ball B1 can be discharged at the discharge port 621 are determined depending on the rotation speed of the rotating body 183. When the rotation speed of the rotator 183 is low, the recesses 183b to 183e in the intake port 185 and the discharge port 621 are open for a long time. This extends the duration of the state in which the game ball B1 can be taken in and discharged.

In the present embodiment, the rotation speed of the rotating body 183 is set to be sufficiently slow so that the state in which the game ball B1 can be discharged continues until the discharge of the game ball B1 is completed. The flow of discharging the game ball B1 from the discharge port 621 is common even when the discharged game ball B1 is taken in any of the recesses 183b to 183e. Therefore, in the following, the discharge mode of the game ball B1 in the adjusting mechanism 620 will be described with reference to FIG. 61, taking the game ball B1 taken into the first recess 183b as an example.

As shown in FIG. 61, the game ball B1 taken into the first recess 183b and conveyed clockwise in the circumferential direction of the base body 181a has the discharge port 621 and the first recess 183b in the lower right portion of the adjusting mechanism 620. Are overlapped with each other, and the first recessed portion 183b is discharged when it is opened to the lower right.

Specifically, by rotating the rotating body 183, even if the first recessed portion 183b starts to overlap with the discharge port 621, the width of the area open to the outside in the first recessed portion 183b is a game ball. If the diameter is smaller than B1, the game ball B1 in the first recess 183b is not discharged to the outside. In this state, the game ball B1 in the first recess 183b is prevented from falling downward by being supported by the inner wall of the first recess 183b and the right standing wall 181d.

As the rotation of the rotating body 183 progresses, the distance between the inner wall of the first recess 183b supporting the game ball B1 and the right standing wall 181d becomes longer, so that the first recess 183b is opened to the outside. The area becomes wider. Then, when the distance between the inner wall of the first recess 183b and the right standing wall 181d becomes longer than the diameter of the game ball B1, the game ball B1 loses its support and falls downward.

When the rotation body 183 rotates quickly, the rotation body is in the discharge port 621 from the state where the first recessed portion 183b is opened toward the outside until the game ball B1 is actually discharged. As the rotation of 183 progresses, the game ball B1 in the middle of discharging is sandwiched between the rotating body 183 and the left standing wall 181h, or the first recess 183b is opened to the outside before the game ball B1 is discharged. It may end. On the other hand, in the present embodiment, the rotation speed of the rotating body 183 is set sufficiently slow. Therefore, the game ball B1 is discharged from the state in which the first recess 183b is open toward the outside until the state is finished.

As already described in the first embodiment, the take-in port 185 can take in the game ball B1 when any of the recessed portions 183b to 183e of the rotating body 183 is opened upward. It will be in the permitted state. When the rotation speed of the rotator 183 is set to be slow, the duration of one intake permission state at the intake port 185 becomes long. Therefore, it is possible to reduce the possibility that the take-in permission state ends without the game ball B1 taken into the recesses 183b to 183e that are open upward. As a result, when the adjustment mechanism 620 reaches the discharge timing, it is possible to reduce the frequency with which the game ball B1 discharged from the adjustment mechanism 620 toward the first through gate 35 does not exist.

As already described in the first embodiment, the number of game balls B1 that can be taken into any one of the recesses 183b to 183e of the rotating body 183 during one take-in permitted state is limited to one. .. When the rotation speed of the rotating body 183 is set to be slow, the frequency of the adjustment mechanism 620 being in the take-in permission state per unit time is reduced, and thus the number of the game balls B1 that the adjustment mechanism 620 can take in per unit time is also reduced. It will be.

On the other hand, as already described in the first embodiment, the adjusting mechanism 620 causes the game ball B1 that has flowed near the intake port 185 between the nail 24b and the left standing wall 181h, Alternatively, it can be discharged from the space between the nail 24b and the right standing wall 181d to the left and right spaces of the adjusting mechanism 180, and is discharged toward the escape passage 172 from the passage inlet 171 provided at the rear of the intake port 185. be able to. Therefore, even if the number of game balls B1 that flowed down near the intake port 185 and were not taken into the intake port 185 increases, it is possible to prevent the game ball B1 from staying near the intake port 185.

In addition, as described above, the outlet 621 exists in the lower right part of the adjusting mechanism 620, and the game ball B1 taken in by the upper part of the adjusting mechanism 620 rotates 180° around the center of the rotating body 183. It is discharged to the outside at an earlier timing. The game ball B1 taken in at the upper part of the adjusting mechanism 620 does not rotate around the center of the rotating body 183 by 180° or more. Therefore, the game ball B1 reaching the lower part of the adjusting mechanism 620 does not rise again due to the rotation of the rotating body 183.

As shown in FIG. 61, the left standing wall 181h is provided with an end surface 181i that comes into contact with the game ball B1 falling downward from the discharge port 621. The end surface 181i is inclined downward to the right, contacts the game ball B1 discharged from the discharge port 621, and guides the game ball B1 to the lower right.

As described above, the width of the discharge port 621 is slightly larger than the diameter of the game ball B1 and is set relatively narrow. Therefore, the variation in the discharge start position of the game ball B1 in the discharge port 621 can be suppressed to be small. Further, since the variation in the discharge start position of the game ball B1 is small, most of the game ball B1 discharged from the discharge port 621 can be brought into contact with the end surface 181i of the left standing wall 261. Thereby, the variation in the discharging direction of the game ball B1 can be suppressed to be small.

As shown in FIG. 61, in the game board 610, the first through gate 35 is located below the discharge port 621. The distance from the outlet 621 to the first through gate 35 is set to be slightly longer than the diameter of the game ball B1. Since there is a gap between the discharge port 621 and the first through gate 35 through which the game ball B1 can pass, there is a possibility that a part of the game ball B1 discharged from the discharge port 621 will come off the first through gate 35. There is. For example, when the course of the game ball B1 discharged from the discharge port 621 is shifted to the left or right and the game ball B1 collides with the edge of the first through gate 35, a prize for the first through gate 35 is generated. May not.

By avoiding the configuration in which all of the game balls B1 discharged from the adjusting mechanism 620 enter the first through gate 35, it is possible to avoid the player's interest in the adjusting mechanism 620 being limited to only capturing the game ball B1. it can. Further, by setting the distance from the discharge port 621 to the first through gate 35 to be short, the influence of the discharge speed of the game ball B1 on the timing at which the game ball B1 discharged from the discharge port 621 wins the first through gate 35. Can be suppressed.

As shown in FIG. 61, the first through gate 35 in the present embodiment facilitates the entry of the game ball B1 that is guided to the end surface 181i of the left standing wall 181h and drops toward the lower right in the discharge port 621. To this end, the game board 610 is provided in such a manner that it is inclined downward to the left.

As shown in FIG. 61, in the discharge port 621, the game ball B1 guided toward the end surface 181i of the left-side standing wall 181h and discharged downward to the right gradually corrects its course downward due to the influence of attractive force. While falling. The inclination angle of the first through gate 35 is set to be substantially perpendicular to the course of the game ball B1 discharged from the discharge port 621 at the height position of the first through gate 35. This increases the possibility that the game ball B1 will win smoothly without colliding with the edge of the first through gate 35. By preventing the game ball B1 from coming into contact with the edge of the first through gate 35 immediately before entering the first through gate 35, the winning timing of the game ball B1 coming into contact with the edge of the first through gate 35 is shifted, It is possible to reduce the possibility that the game ball B1 will come off from the first through gate 35.

As described above, since the variation in the discharge start position of the game ball B1 in the discharge port 621 and the variation in the discharge direction are suppressed to be small, most of the game ball B1 discharged from the discharge port 621 is the first through gate 35. It is possible to make a prize smoothly.

Next, the low frequency winning determination value table in the present embodiment will be described. As described in the first embodiment, the low-frequency win determination value table stored in the main ROM 64 (FIG. 12) includes the normal-power open win in the normal-power open lottery executed in the low-frequency support mode. The winning decision value targeted for is recorded. The low-frequency winning determination value table of this embodiment includes the winning determination values set in the low-frequency winning determination value table T1 described with reference to FIG. 14A in the first embodiment. Are set to different values.

In the low frequency winning determination value table of the present embodiment, the winning determination value of the ordinary electric open lottery is set to (1250×n−5) to (1250×n). Here, the variable n is a natural number of 1 to 52. The probability of winning the general electric open prize in the general electric open lottery executed in the low frequency support mode is approximately 1/210.

The winning judgment value that is the target of the Hoden Open winning is a sequential number in units of six. Further, the updating cycle of the random number for opening in the general electric utility article opening counter C4 (FIG. 13) is 4 msec. For this reason, in the general electric outlet opening counter C4, the period during which the updated random number for opening is the winning determination value of the general electric opening winning target in the general electric open lottery in the low frequency support mode continues for 24 msec.

In the low-frequency support mode, the winning target period in which the winning determination value that is the target of the universal electric open winning continues for 24 msec occurs in a cycle of 5 sec. As described above, the cycle in which the winning possible timing when the game ball B1 discharged from the adjusting mechanism 620 wins the first through gate 35 is the same as the cycle in which the winning target period is generated in the low frequency support mode is 5 seconds. is there.

Therefore, in the low frequency support mode, the winning timing overlaps with the winning target period, so that the regular electric open winning is a continuous winning period. The winning continuous period continues until the initial value of the general electric utility open counter C4 is updated and the generation timing of the winning period shifts. When the generation timing of the winning target period is deviated, it is a non-winning continuous period in which the failure result continues in the normal electric open lottery executed in the low frequency support mode until the winning target period and the winning possible timing overlap again.

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

The discharge port 621 is provided at a position where the game ball B1 taken in at the upper part of the adjustment mechanism 620 reaches before the game ball B1 is rotated by 180° around the center of the rotating body 183. Further, in the discharge port 621, when the game ball B1 can be discharged from the recessed portions 183b to 183e, the adjustment drive unit 184 does not end before the discharge of the game ball B1 is completed. Drive controlled. This prevents the game ball B1 conveyed downward from the upper part of the adjusting mechanism 620 by rotating 180° or more around the center of the rotating body 183 and rising again.

The left standing wall 181h is provided with an end surface 181i that contacts the game ball B1 that is about to fall downward from the discharge port 621 by its own weight and guides the game ball B1 to the lower right. The width of the outlet 621 is set to be slightly larger than the diameter of the game ball B1. Since the width of the discharge port 621 is set to be relatively narrow, the variation in the discharge start position of the game ball B1 discharged from the discharge port 621 is small, and most of the game ball B1 discharged from the discharge port 621 stands up to the left. The end face 181i of the wall 261 can be brought into contact with and guided to the lower right. Therefore, it is possible to reduce variations in the discharge direction of the game ball B1 discharged from the discharge port 621.

The variation in the ejection start position of the game ball B1 ejected from the adjusting mechanism 620 is small and the variation in the ejection direction is small. Therefore, the variation in the moving direction when the game ball B1 discharged from the adjusting mechanism 620 falls to the height position of the first through gate 35 is small. The first through gate 35 is discharged downward from the adjusting mechanism 620 and is directed downward to the left so as to form an opening perpendicular to the moving direction of the game ball B1 that has flown down to the height position of the first through gate 35. It is inclined. Therefore, the game ball B1 discharged from the adjusting mechanism 620 is easily taken in smoothly without colliding with the edge of the first through gate 35. This prevents the gaming ball B1 from colliding with the edge of the first through gate 35 immediately before winning the first through gate 35 and the winning timing being deviated, or the game ball B1 being separated from the first through gate 35.

The distance from the outlet 621 of the adjusting mechanism 620 to the first through gate 35 is set to be slightly longer than the diameter of the game ball B1. Since there is a gap larger than the diameter of the game ball B1 between the discharge port 621 and the first through gate 35, all the game balls B1 discharged from the adjusting mechanism 620 enter the first through gate 35. Can be avoided. Further, since the distance from the discharge port 621 to the first through gate 35 is relatively short, even if the game ball B1 is discharged at a different discharge speed each time, the difference in the discharge speed is due to the winning timing of the first through gate 35. Can be configured so as not to significantly affect As a result, it is possible to avoid a situation in which the winning timing to the first through gate 35 is deviated due to the difference in the discharge speed and the normal electric open winning is not achieved during the winning continuous period.

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

FIG. 62 is an explanatory diagram for explaining the configuration of the input port 121 of the management-side I/F 111 in this embodiment.

A signal of the same type as that of the first embodiment is input to the first to seventh buffers 122a to 122g and the 16th buffer 122p. Specifically, the first signal corresponding to the detection result of the first winning opening detection sensor 42a is input to the first buffer 122a, and the first signal corresponding to the detection result of the second winning opening detection sensor 43a is input to the second buffer 122b. Two signals are input, a third signal corresponding to the detection result of the third winning hole detection sensor 44a is input to the third buffer 122c, and a fourth signal corresponding to the detection result of the special electric power detection sensor 45a is input to the fourth buffer 122d. A signal is input, a fifth signal corresponding to the detection result of the first working port detection sensor 46a is input to the fifth buffer 122e, and a fifth signal corresponding to the detection result of the second working port detection sensor 47a is input to the sixth buffer 122f. The sixth signal is input, the seventh signal corresponding to the detection result of the outlet detection sensor 48a is input to the seventh buffer 122g, and the output instruction signal is input to the sixteenth buffer 122p.

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

An open/close execution mode signal is input to the 13th buffer 122m, a high frequency support mode signal is input to the 14th buffer 122n, a door opening signal is input to the 15th buffer 122o, and It is decided at the design stage of the management IC 66 that the output instruction signal is input to the 16th buffer 122p, and the management side CPU 112 receives the instructions from the main side CPU 63 and the 13th to 16th buffers 122m to 122p. It is possible to specify that each of the above signals corresponding to each is input. On the other hand, what kind 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 kind of these signals is instructed by the main CPU 63. As a result, the CPU 112 on the management side specifies. The process for specifying the type of the 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. 63 is a flowchart showing the recognition processing of this embodiment executed by the main CPU 63. The recognition process is executed in step S110 in the main process (FIG. 17) as in the first embodiment.

First, "12", which is the number of the first to twelfth buffers 122a to 122l to be the target of signal type recognition, is set in the recognition output counter of the main RAM 65 (step S1701). After that, the output processing of the identification start signal is executed (step S1702). In the output process, 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 input signal input to the fourteenth buffer 122n. Is set to the HI level, the output of the identification start signal is started. The period in which these signals are maintained at the HI level is set to a period sufficient for the management-side CPU 112 to recognize the output states of these signals.

After that, the information on the output count 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 output count information is set in the output counter provided in the main RAM 65 ( Step S1703). The output number counter is a counter for the main CPU 63 to specify the output number of the type identification signal.

In the present embodiment, when the management-side CPU 112 recognizes the types of signals input to the first buffer 122a to the twelfth buffer 122l, the number of prize balls set for the ball entering portion corresponding to the signal type. And the type identification signal is output the same number of times as. The management-side CPU 112 stores information corresponding to the number of times the type identification signal is received for each of the first buffer 122a to the twelfth buffer 122l in the first to twelfth correspondence area 123a to 123l of the correspondence memory 116. .. That is, the types of signals input to the first buffer 122a to the twelfth buffer 122l are grasped as the number of prize balls set for the ball entering portion corresponding to the types of the signals.

In step S1703, when the value of the recognition output counter is any of "12", "11", and "10", "10" corresponding to the number of prize balls of 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 winning device 32 is set in the output counter. Further, when the value of the recognition output counter is “8”, “1” corresponding to the number of prize balls of the first operating port 33 is set in the output number counter. Further, when the value of the recognition output counter is "7", "1" corresponding to the number of prize balls of the second working port 34 is set in the output number counter. When the value of the output counter for recognition is “6”, the payout of the game ball is not executed even if the game ball enters the out port 24a although it corresponds to the out port 24a. Therefore, the output number counter Set "0" to. Further, when the value of the recognition output counter is any of "5" to "1", the corresponding ball input portion does not exist and is blank, so "0" is set to the output number counter.

After that, the output process of the start trigger signal is executed (step S1704). 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 in which the first signal is maintained at the HI level is set to a period sufficient for the management-side CPU 112 to recognize the output state of the first signal.

After that, on the condition that the value of the output counter of the main RAM 65 is not "0" (step S1705: YES), that is, on the condition that a value of 1 or more is set on the output counter in step S1703, The process advances to step S1706. In step S1706, output processing of the type identification signal is executed. In the output process, the output state 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 in which the second signal is maintained at the HI level is set to a period sufficient for the management-side CPU 112 to recognize the output state of the second signal.

After that, the value of the output counter of the main RAM 65 is decremented by 1 (step S1707), and it is determined whether the value of the output counter after the decrement is 1 is "0" (step S1708). When the value of the output number counter is 1 or more (step S1708: NO), the process returns to step S1706.

If an affirmative decision is made in step S1705, or if an affirmative decision is made in step S1708, output processing of the termination trigger signal is executed (step S1709). In the output process, the output of the termination 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 during which the third signal is maintained at the HI level is set to a period sufficient for the management-side CPU 112 to recognize the output state of the third signal.

After that, the value of the recognition output counter of the main RAM 65 is decremented by 1 (step S1710), and it is determined whether the value of the recognition output counter after the decrement by 1 is "0" (step S1711). If the value of the recognition output counter is 1 or more (step S1711: NO), the process returns to step S1703 to execute processing for recognizing the type of signal corresponding to the value of the recognition output counter after subtraction by one. To do.

On the other hand, when the value of the recognition output counter is "0" (step S1711: YES), the output processing of the identification end signal is executed (step S1712). In the output process, 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 input signal input to the fourteenth buffer 122n. Is set to the HI level, the output of the identification end signal is started. The period in which these signals are maintained at the HI level is set to a period sufficient for the management-side CPU 112 to recognize the output states of these signals.

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

When the reception of the identification start signal from the main CPU 63 is completed (step S1801: YES), the value of the setting target counter of the management RAM 114 is cleared to "0" (step S1802). After that, on condition that the start trigger signal is received from the main CPU 63 (step S1803: YES), the process proceeds to step S1804. In step S1804, it is determined whether the type identification signal is received from the main CPU 63. When the type identification signal is received (step S1804: YES), the value of the reception number counter provided in the management side RAM 114 is incremented by 1 (step S1805). The reception number 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. The value of the reception number counter is cleared to "0" when a positive determination is made in step S1803.

When a negative determination is made in step S1804 or when the processing of step S1805 is executed, it is determined whether or not an end trigger signal is received from the main CPU 63 (step S1806). When the termination trigger signal is not received (step S1806: NO), the process returns to step S1804, and when the termination trigger signal is received (step S1806: YES), the correspondence relationship setting process is executed (step S1807). In the correspondence relation setting process, among the first to twelfth correspondence relation areas 123a to 123l of the correspondence relation memory 116, the correspondence relation area corresponding to the current value in the setting target counter of the management side RAM 114 is set in the reception number counter. Stores the value that is set. In this case, "10" corresponding to the number of prize balls of the general winning opening 31 is set in the first correspondence area 123a, the second correspondence area 123b, and the third correspondence area 123c, and the fourth correspondence area 123d is set. Is set to "15" corresponding to the number of prize balls of the special electric prize winning device 32, "5" corresponding to the number of prize balls of the first working port 33 is set to the fifth correspondence area 123e, and the sixth correspondence relationship In the area 123f, "1" corresponding to the number of prize balls of the second operating port 34 is set. Further, "0" is set in the seventh to twelfth correspondence areas 123g to 123l. After that, the value of the setting target counter of the management side RAM 114 is incremented by 1 (step S1808).

If a negative determination is made in step S1803, or if the processing of step S1808 is executed, it is determined whether the reception of the identification end signal from the main CPU 63 has ended (step S1809). If the reception of the identification end signal has not ended (step S1809: NO), the process returns to step S1803, and on condition that the start trigger signal is received from the main CPU 63 (step S1803: YES), the processes after step S1804 are performed. Execute. When the reception of the identification end signal from the main CPU 63 has been completed (step S1809: YES), the history setting process of step S1810 and the external output process of step S1811 are repeatedly executed.

FIG. 65 is a time chart showing a state in which information on the correspondence relationship between the first to twelfth buffers 122a to 122l and the types of signals input to these buffers 122a to 122l is stored in the correspondence relationship memory 116. 65(a) shows a period in which the output state of the first signal is at the HI level, FIG. 65(b) shows a period in which the output state of the second signal is at the HI level, and FIG. ) Indicates a period during which the output state of the third signal is at the HI level, FIG. 65(d) indicates a period during which the output state of the signal in the open/close execution mode is at the HI level, and FIG. FIG. 65(f) shows the first to twelfth buffers 122a to 122l and the types of signals input to these buffers 122a to 122l during the high frequency support mode during which the output state of the signal is at the HI level. FIG. 65(g) shows the timing at which the value of the reception counter of the management side RAM 114 is incremented by 1, and FIG. 65(h) shows the execution period of the identification state in which the process for identifying the correspondence is executed. The timing at which the management CPU 112 executes the correspondence setting process (step S1807) is shown.

When the supply of operating power to the main CPU 63 and the management CPU 112 is started, the first signal is output at the timing of t1 as shown in FIGS. 65(a), 65(d) and 65(e). 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. As a result, the output of the identification start signal from the main CPU 63 to the management CPU 112 is started. Then, at the timing of t2, the output states of the first signal, the open/close execution mode signal, and the high-frequency support mode signal are changed from the HI level to the LOW bell. As a result, 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 decision in step S1801 of the management process (FIG. 64) to enter the identification state as shown in FIG. 65(f).

After that, from the timing of t3 to the timing of t4, the output state of the first signal is maintained at the HI level as shown in FIG. As a result, the start trigger signal is output to the management-side CPU 112. Then, from the timing t5 to the timing t7, the output state of the second signal is maintained at the HI level as shown in FIG. 65(b). As a result, the type identification signal is output once to the management-side CPU 112. In this case, the value of the reception number counter of the management side RAM 114 is incremented by 1 at the timing of t6 as shown in FIG.

After that, from the timing of t8 to the timing of t10, the output state of the third signal is maintained at the HI level as shown in FIG. 65(c). As a result, the termination trigger signal is output to the management-side CPU 112. In this case, at the timing of t9, the management side CPU 112 executes the correspondence setting process as shown in FIG. Since the value of the reception number counter is "1" at the timing when the correspondence setting process is executed, the correspondence information "1" is stored in the correspondence areas 123a to 123l of the correspondence memory 116 for the setting this time. Information is stored.

After that, from the timing of t11 to the timing of t12, the output state of the first signal is maintained at the HI level as shown in FIG. As a result, the start trigger signal is output to the management-side CPU 112. Then, as shown in FIG. 65( b ), the timing t13 to timing t15, the timing t16 to timing t18, the timing t19 to timing t21, and the timing t22 to timing t24 are changed as shown in FIG. The output state of the signal is maintained at the HI level. As a result, the type identification signal is output to the management-side CPU 112 once. In this case, the value of the reception number counter of the management side RAM 114 is incremented by 1 as shown in FIG. 65(g) at each of the timing t14, the timing t17, the timing t20, and the timing t23.

After that, from the timing of t25 to the timing of t27, the output state of the third signal is maintained at the HI level as shown in FIG. 65(c). As a result, the termination trigger signal is output to the management-side CPU 112. In this case, at the timing of t26, the management side CPU 112 executes the correspondence setting process as shown in FIG. Since the value of the reception number counter is “10” at the timing when the correspondence setting process is executed, “10” is set as the correspondence information in the correspondence areas 123 a to 123 l of the current setting target in the correspondence memory 116. Information is stored.

Thereafter, at the timing of t28, as shown in FIGS. 65(c), 65(d) and 65(e), the output states of the third signal, the open/close execution mode signal and the high frequency support mode signal are LOW. Level is changed to HI level. As a result, the main CPU 63 starts outputting the identification end signal to the management CPU 112. After that, at the timing of t29, the output states of the third signal, the open/close execution mode signal, and the high-frequency support mode signal are changed from the HI level to the LOW bell. As a result, 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-side CPU 112 makes an affirmative decision in step S1809 of the management process (FIG. 64) to cancel the identification state as shown in FIG. 65(f).

In this embodiment, since the number of prize balls is stored as the correspondence information, the history information stored in the history memory 117 is stored in the history information 117. Information on the number of pieces is included as correspondence information. In this configuration, when there are a plurality of types of ball entry parts having the same number of prize balls, it is not possible to distinguish the ball entry parts in the history information. Specifically, since the number of prize balls in each of the first operating port 33 and the second operating port 34 is one, it is possible to distinguish the first operating port 33 and the second operating port 34 in the history information. Can not. In such a situation, the number of prize balls may be different between the first operating port 33 and the second operating port 34. This makes it possible to distinguish the first operating port 33 and the second operating port 34 in the history information even if the history information is stored as in the eighth embodiment.

Further, in the present embodiment, “15” is set in the check target counter of the management side RAM 114 in step S801 of the history setting process. As a result, all 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 the open/close execution mode is in progress, information corresponding to whether the high frequency support mode is in progress, and the front door Regarding the information corresponding to whether or not the frame 14 is open, the management CPU 112 can specify that the signal path corresponds to the information without receiving the correspondence information from the main CPU 63. Is becoming In this case, only the information corresponding to the detection result of each of the ball entrance detection sensors 42a to 48a is the information required to cause the management CPU 112 to recognize the correspondence between each information and each signal path 118a to 118g. Become. When causing the management-side CPU 112 to recognize the correspondence information, the same number of pulse signals as the number of prize balls corresponding to each of the ball detection sensors 42a to 48a is transmitted from the main-side CPU 63 to the management-side CPU 112 using the second signal. Is output to. This makes it possible to simplify the configuration related to the transmission of the correspondence information.

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

FIG. 66 is a block diagram for explaining the electrical configuration of the management IC 66 in this 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, an RTC 115, a correspondence relationship memory 116 and a history memory 117, as in the first embodiment. 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 631. In the present embodiment, as will be described later in detail, when a calculation trigger occurs, various parameters are calculated by the management-side CPU 112 using the history information stored in the history memory 117 at that time. Then, the calculated various parameters are sequentially stored in the calculation result memory 631. The various parameters stored in the calculation result memory 631 are output to the reading device electrically connected to the reading terminal 102.

The timing for calculating various parameters occurs before the timing at which the reading device is electrically connected to the reading terminal 102. As a result, it is possible to make the timing of calculating various parameters different from the timing of external output to the reading device, and it is possible to disperse the processing load.

Further, since the calculation result memory 631 for storing the calculation results of various parameters is provided, not only various parameters for one calculation occasion but also various parameters for multiple calculation occasions 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 trigger.

FIG. 67 is an explanatory diagram for explaining the configuration of the input port 121 of the management-side I/F 111 in this embodiment.

The same type of signal as that of the first embodiment is input to the first to tenth buffers 122a to 122j and the sixteenth buffer 122p. Specifically, the first signal corresponding to the detection result of the first winning opening detection sensor 42a is input to the first buffer 122a, and the first signal corresponding to the detection result of the second winning opening detection sensor 43a is input to the second buffer 122b. Two signals are input, a third signal corresponding to the detection result of the third winning hole detection sensor 44a is input to the third buffer 122c, and a fourth signal corresponding to the detection result of the special electric power detection sensor 45a is input to the fourth buffer 122d. A signal is input, a fifth signal corresponding to the detection result of the first working port detection sensor 46a is input to the fifth buffer 122e, and a fifth signal corresponding to the detection result of the second working port detection sensor 47a is input to the sixth buffer 122f. The sixth signal is input, the seventh buffer 122g is input with the seventh signal corresponding to the detection result of the outlet detection sensor 48a, the eighth buffer 122h is input with the signal corresponding to the open/close execution mode, and the ninth signal is input. A signal corresponding to the high frequency support mode is input to the buffer 122i, a signal corresponding to the front door frame 14 is input to the tenth buffer 122j, and an output instruction signal is input to the sixteenth buffer 122p.

In the present embodiment, in addition to the various signals described above, a calculation instruction signal is input to the fifteenth buffer 122o. The calculation instruction signal is a signal output from the main CPU 63 in order to provide the management CPU 112 with a calculation trigger for various parameters. The input of the operation instruction signal to the fifteenth buffer 122o is determined at the design stage of the management IC 66, similarly to the input of the output instruction signal to the sixteenth buffer 122p, and the instruction from the main CPU 63 is given. Without receiving this, the management-side CPU 112 can specify that the respective signals corresponding to the 15th to 16th buffers 122o to 122p are input. 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 these kinds of signals are instructed by the main CPU 63. As a result, the CPU 112 on the management side specifies. The process for specifying the type of the 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 processing configuration for causing the management-side CPU 112 to execute the calculation of various parameters in response to the occurrence of a calculation trigger will be described. FIG. 68 is a flowchart showing the power failure information storage processing executed by the main CPU 63. The power failure information storage process is executed in step S201 in the timer interrupt process (FIG. 18).

In the power failure information storage processing, when the power failure signal corresponding to the occurrence of power shutdown is received from the power failure monitoring board 67 (step S1901: YES), the calculation instruction signal output processing is executed (step S1902). 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 a period sufficient for the management side CPU 112 to recognize that the output state of the calculation instruction signal is at the HI level. After that, after the power failure process is executed in step S1903, an infinite loop is formed, and the operation waits until the supply of operating power to the main CPU 63 is completely stopped. In the power failure process, the power failure flag of the main RAM 65 is set to "1", the checksum is calculated, and the calculated checksum is saved.

FIG. 69 is a flowchart showing a power failure handling process executed by the management side CPU 112. The power failure handling process is configured to be executed after the external output process in the management process (FIG. 34), and in the management process, after the identification end command is received from the main CPU 63 (step S1006: YES), step S1007. The history setting process, the external output process in step S1008, and the power failure handling process are repeatedly executed in this order.

In the power failure handling process, when the output state of the calculation instruction signal received from the main CPU 63 becomes the HI level (step S2001: YES), the external output in the first embodiment is performed in steps S2002 to S2006. Similar to steps S1602 to S1606 of the processing (FIG. 40), the number of balls entered for each of the outlet 24a, the general winning opening 31, the special electricity winning device 32, the first working opening 33, and the second working opening 34 is calculated. .. Further, in step S2007, similar to step S1607 of the external output process (FIG. 40) in the first embodiment, the number of various balls entered in the situation where the front door frame 14 is open is calculated. Further, in step S2008, as in step S1608 of the external output process (FIG. 40) in the first embodiment, various parameters are calculated, and in step S2009, the external output process in the first embodiment is performed. Similar to step S1609 of the process (FIG. 40), the total time is calculated. Then, the information of the calculation result of step S2008 and the information of the calculation result of step S2009 are written in the calculation result memory 631 (step S2010). In this case, when the information of another operation result is already stored in the operation result memory 631, the operation result information is written so as not to overwrite the already stored operation result information. To do. Further, the current date information and the current time information are read from the RTC 115, and the read date information and the time information are attached to the information of the calculation 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, in step S2011, as in step S1611 of the external output process (FIG. 40) in the first embodiment, the number of various incoming balls in the open/close execution mode is calculated, and in step S2012, the first Similar to step S1612 of the external output process (FIG. 40) in the above embodiment, the number of various balls entered in the open/close execution mode and the front door frame 14 is open is calculated. Further, in step S2013, various parameters are calculated as in step S1613 of the external output process (FIG. 40) in the first embodiment. Then, the information of the calculation result of step S2014 is written in the calculation result memory 631 (step S2014). In this case, the calculation result information is written so as not to overwrite the other calculation result information already stored in the calculation result memory 631. Further, the current date information and the current time information are read from the RTC 115, and the read date information and the time information are attached to the information of the calculation 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, in step S2015, as in step S1615 of the external output process (FIG. 40) in the first embodiment, the number of various incoming balls in the high frequency support mode is calculated, and in step S2016, the Similar to step S1616 of the external output process (FIG. 40) in the first embodiment, the number of various balls entered in the high frequency support mode and the front door frame 14 is open is calculated. Further, in step S2017, various parameters are calculated as in step S1617 of the external output process (FIG. 40) in the first embodiment. Then, the information on the calculation result of step S2017 is written in the calculation result memory 631 (step S2018). In this case, the calculation result information is written so as not to overwrite the other calculation result information already stored in the calculation result memory 631. Further, the current date information and the current time information are read from the RTC 115, and the read date information and the time information are attached to the information of the calculation 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, an infinite loop is formed, and the operation waits until the supply of operating power to the management CPU 112 is completely stopped.

FIG. 70 is a flowchart showing an external output process executed by the management CPU 112. The external output process is executed in step S1208 of the management process (FIG. 34).

When the output state of the output instruction signal from the main CPU 63 becomes the HI level (step S2101: YES), output processing of the calculation result is executed (step S2102). In the output process, various calculation results stored in the calculation result memory 631 are output to the reading terminal 102. As a result, the reading device electrically connected to the reading terminal 102 can read the various calculation results stored in the calculation result memory 631. In this case, when only the various calculation results corresponding to the occurrence of one calculation trigger are stored in the calculation result memory 631, only the various calculation results corresponding to the occurrence of the one calculation trigger are stored in the reading device. When the operation result memory 631 stores various operation results corresponding to the occurrence of the operation triggers multiple times, the reading device reads the various operation results corresponding to the occurrences of the operation triggers multiple times. .

After that, the output process of the history information is executed (step S2103). 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 reading device electrically connected to the reading terminal 102 can read various history information stored in the history area 124. By outputting not only the various calculation results but also the history information in this way, it becomes possible for a worker who uses the reading device to perform a detailed analysis of the various calculation results.

After that, clear processing is executed (step S2104). In the clear processing, all the history information storage area 125 of the history memory 117 is cleared to “0” and the pointer area 126 is cleared to “0”. As a result, the history area 124 is in the initialized state. In the clearing process, all areas of the calculation result memory 631 are cleared to "0". As a result, the calculation result memory 631 is in the initialized state.

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

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 on a business day basis.

When the main CPU 63 specifies that the supply of the operating power is stopped, the output state of the calculation instruction signal is changed to the HI level, so that the management CPU 112 calculates various parameters. As a result, it becomes possible for the management-side CPU 112 to calculate various parameters based on an instruction from the main-side CPU 63.

Various parameters calculated by the management CPU 112 are sequentially written in the calculation result memory 631. As a result, the various parameters can be accumulated in the management IC 66, and when the various parameters are read by the reading device, the various parameters for a plurality of business days can be collectively read.

When various parameters are written in the calculation result memory 631, information for identifying the time when the various parameters are calculated is written in the calculation result memory 631 along with the various parameters. This makes it possible to analyze various parameter information while grasping the time when various parameters are calculated.

It should be noted that when a calculation trigger occurs and the calculation results of various parameters corresponding thereto are written in the calculation result memory 631, the history memory 117 may be cleared to “0”. This makes it difficult for new history information to be written to the history memory 117 when the maximum number of storable history information is already stored in the history memory 117.

Further, the target information to be externally output to the reading device is only the information of various parameters stored in the calculation result memory 631, and the history information stored in the history memory 117 may not be externally output. . This makes it possible to reduce the amount of information output to the outside.

<Tenth Embodiment>
In the present embodiment, the processing configuration of the power failure handling processing executed by the management side CPU 112 is different from that of the ninth embodiment. The configuration different from that of the ninth embodiment will be described below. The description of the same configuration as the ninth embodiment is basically omitted.

FIG. 71 is a flowchart showing a power failure handling process executed by the management-side CPU 112 in this embodiment.

When the output state of the calculation instruction signal received from the main CPU 63 becomes the HI level (step S2201: YES), various calculation processes are executed (step S2202). In the various calculation processes, each process of step S2002 to step S2009, step S2011 to step S2013, and step S2015 to step S2017 of the power failure handling process (FIG. 69) in the ninth embodiment is executed.

After that, it is determined whether a predetermined parameter among the various parameters calculated in step S2202 is within the reference range (step S2203). In particular,
・Seventh parameter: (K3דnumber of prize balls for winning in special electric prize winning device 32”+K5דnumber of prize balls for winning in second operation port 34”)/total payout number of game balls (K2דgeneral”) "Number of prize balls for winning in prize hole 31" + K3 x "Number of prize balls for winning in special electric prize winning device 32" + K4 x "Number of prize balls for prize in first operating port 33" + K5 x "Second operating port 34" 8th parameter: K3 x "number of prize balls for winning in special electric prize winning device 32" / total payout number of gaming balls (K2 x for winning in general winning hole 31) "Number of prize balls" + K3 x "Number of prize balls for winning the special electric prize winning device 32" + K4 x "Number of prize balls for winning the first operating port 33" + K5 x "Number of prize balls for winning the second operating port 34" )) is set as a parameter to be determined whether or not it is within the reference range. Then, when the value of the seventh parameter is 0.7 or less and the value of the eighth parameter is 0.6 or less, it is determined in step S2203 that the predetermined parameter is within 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 the predetermined parameter to be determined in step S2203 may be calculated by various calculation processes in step S2202.

When the predetermined parameter is not within the reference range (step S2203: NO), the various parameters calculated in step S2202 are written in the calculation result memory 631 (step S2204). In this case, when the information of another operation result is already stored in the operation result memory 631, the operation result information is written so as not to overwrite the already stored operation result information. To do. Further, the current date information and the current time information are read from the RTC 115, and the read date information and the time information are attached to the information of the calculation 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 S2203: YES), the process of step S2204 is not executed. As a result, only various parameters in the case where the predetermined parameter is not within the reference range are written in the calculation result memory 631. Therefore, when an abnormal situation occurs, the storage capacity required for the operation result memory 631 can be suppressed while leaving the history in the operation result memory 631.

If an affirmative decision is made in step S2203, or if the processing of step S2204 has been executed, clear processing of the history memory 117 is executed (step S2205). In the clearing process, all the history information storage area 125 of the history memory 117 is cleared to "0" and the pointer area 126 is cleared to "0". As a result, the history area 124 is in the initialized state. After executing the processing of step S2205, an infinite loop is formed, and the operation waits until the supply of operating power to the management-side CPU 112 is completely stopped.

According to the present embodiment described in detail above, it is determined whether or not the contents of various calculated parameters are included in the reference range, and only the various parameters that are determined to be included in the reference range are stored in the calculation result memory 631. Written. As a result, the amount of various parameters to be stored in the calculation result memory 631 can be suppressed, and the storage capacity required in the calculation result memory 631 can be suppressed.

<Eleventh Embodiment>
In the present embodiment, the content of the calculation trigger that causes the management-side CPU 112 to execute the calculation of various parameters is different from that of the ninth embodiment. The configuration different from that of the ninth embodiment will be described below. The description of the same configuration as the ninth embodiment is basically omitted.

FIG. 72A is a flowchart showing the trigger specifying process executed by the main CPU 63. The trigger specifying process is executed as a process when an affirmative determination is made in step S1312 in the management output process (FIG. 36).

It is determined whether or not a game ball has entered the outlet 24a, the general winning opening 31, the special electric winning device 32, the first operating opening 33, or the second operating opening 34 (step S2301). When an affirmative determination is made in step S2301, the addition processing of the entry counter provided in the main RAM 65 is executed (step S2302). In the addition process, the number of game balls that have entered the out port 24a, the general winning opening 31, the special electric winning device 32, the first operating opening 33, and the second operating opening 34 is calculated as It is specified based on the number of times step S1305 is executed in the management output process (FIG. 36). Then, the number of the specified game balls is added to the incoming ball counter.

After that, it is determined whether or not the value of the incoming ball counter is equal to or greater than the trigger reference number "500" (step S2303). If it is equal to or larger than "500" (step S2303: YES), the subtraction process of the entry counter of the main RAM 65 is executed (step S2304). In the subtraction process, the value of the entrance counter is subtracted by "500". Then, the output processing of the calculation instruction signal is executed (step S2305). 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 a period sufficient for the management side CPU 112 to recognize that the output state of the calculation instruction signal is at the HI level.

FIG. 72B is a flowchart showing the arithmetic processing executed by the management CPU 112. The calculation process is a process executed instead of the power failure handling process in the ninth embodiment. Therefore, the arithmetic processing is configured to be executed after the external output processing in the management processing (FIG. 34). In the management processing, after the identification end command is received from the main CPU 63 (step S1206: YES), the processing of step S1207 is performed. The history setting process, the external output process of step S1208, and the arithmetic 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 S2401: YES), various calculation processes are executed (step S2402). In various arithmetic processing, the same processing as steps S2002 to S2018 of the power failure handling processing (FIG. 69) in the ninth embodiment is executed.

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

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

<Twelfth Embodiment>
In the present embodiment, the content of the calculation trigger that causes the management-side CPU 112 to execute the calculation of various parameters is different from that of the eleventh embodiment. The configuration different from that of the eleventh embodiment will be described below. The description of the same configuration as the eleventh embodiment is basically omitted.

FIG. 73 is a flowchart showing the trigger specifying process executed by the main CPU 63. The trigger specifying process is executed as a process when an affirmative determination is made in step S1312 in the management output process (FIG. 36).

It is determined whether or not a game ball has entered the outlet 24a, the general winning opening 31, the special electric winning device 32, the first operating opening 33, or the second operating opening 34 (step S2501). When a negative determination is made in step S2501, the value of the continuation counter provided in the main RAM 65 is incremented by 1 (step S2502). The continuation counter is a CPU 63 on the main side for a period in which the game ball does not enter any of the outlet 24a, the general winning opening 31, the special electric winning device 32, the first operating opening 33 and the second operating opening 34. It is a counter for specifying in.

If the value of the continuation counter after adding 1 is greater than or equal to the stop reference value (step S2503: YES), the time measurement flag provided in the main RAM 65 is cleared to "0" (step S2504). When the state in which the game ball does not enter any of the outlet 24a, the general winning opening 31, the special electric winning device 32, the first operating opening 33 and the second operating opening 34 continues for 5 seconds, a positive determination is made in step S2503. The stop reference value is set like this. The time measurement flag is a flag for the main CPU 63 to specify whether or not to measure the time for specifying the timing of switching the output state of the calculation instruction signal to the HI level. When the value of is 0, the time is not measured, and when the value of the time measurement flag is 1, the time is measured. When a positive determination is made in step S2501, the time measurement flag is set to "1" (step S2505).

If a negative determination is made in step S2503, the process of step S2504 is executed, or the process of step S2505 is executed, "1" is set to the time measurement flag of the main RAM 65 as a condition ( Step S2506: YES), 1 is added to the value of the measurement counter provided in the main RAM 65 (step S2507). The measurement counter is a counter used for measuring the time for specifying the timing of 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 larger than the instruction reference value (step S2508). The instruction reference value is set so that a positive determination is made in step S2508 when the time measured by the measurement counter reaches 10 hours. When an affirmative determination is made in step S2508, the value of the measurement counter is cleared to "0" (step S2509), and the calculation instruction signal output process is executed (step S2510). 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 a period sufficient for the management side CPU 112 to recognize that the output state of the calculation instruction signal is at the HI level.

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

It should be noted that instead of the configuration in which the measurement counter is used to measure whether or not the predetermined period has elapsed, the RTC 115 may be used in the configuration.

<Thirteenth Embodiment>
In the present embodiment, the content of the calculation trigger that causes the management-side CPU 112 to execute the calculation of various parameters is different from that of the first embodiment, and whether or not the calculation trigger has occurred is specified by the main-side CPU 63. It is performed independently by the management side CPU 112 instead of the above. The configuration different from that of the first embodiment will be described below. The description of the same configuration as the first embodiment is basically omitted.

FIG. 74 is a flowchart showing the arithmetic processing executed by the management CPU 112. The calculation process is executed when an affirmative determination is made in step S1412 in the history setting process (FIG. 37).

Corresponding to the occurrence of a game ball entering any of the outlet 24a, the general winning opening 31, the special electricity winning device 32, the first operating opening 33 and the second operating opening 34 in the history setting processing of this processing time It is determined whether or not the history information to be stored is stored in the history memory 117 (step S2601). When an affirmative determination is made in step S2601, addition processing of the entrance counter provided in the management side RAM 114 is executed (step S2602). In the addition process, the number of game balls that have entered the out port 24a, the general winning opening 31, the special electric winning device 32, the first operating opening 33, and the second operating opening 34 is calculated as In the history setting process, the history information corresponding to the occurrence of a game ball is identified based on the number of times stored. Then, the number of the specified game balls is added to the entrance counter.

After that, it is determined whether or not the value of the entrance counter is equal to or larger than the trigger reference number "500" (step S2603). If it is equal to or larger than "500" (step S2603: YES), the subtraction process of the entry counter of the main RAM 65 is executed (step S2604). In the subtraction process, the value of the entrance counter is subtracted by "500". After that, various arithmetic processes are executed (step S2605). In various arithmetic processing, the same processing as steps S2002 to S2018 of the power failure handling processing (FIG. 69) in the ninth embodiment is executed.

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

Further, since various parameters are calculated based on whether the total number of game balls discharged from the game area PA has become equal to or greater than the trigger reference number, various parameters are provided on the condition that the game is being executed. Is calculated. This makes it possible to prevent meaningless calculation of various parameters 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 side CPU 112, and the management side CPU 112 determines whether or not the total number is equal to or greater than the trigger reference number. That is, the management side CPU 112 independently determines the timing of calculation of various parameters. As a result, it is not necessary for the main CPU 63 to execute the processing for determining the timing of calculation of various parameters, so that the processing load on the main CPU 63 can be reduced.

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

In the present embodiment, as in the ninth embodiment, the management IC 66 is provided with a calculation result memory 631 (see FIG. 66). When the calculation trigger occurs, the management side CPU 112 calculates various parameters by using the history information stored in the history memory 117, and writes the various parameters of the calculation result in the calculation result memory 631. Further, in the present embodiment, a signal indicating that the opening/closing execution mode has been started, a signal indicating that the opening/closing execution mode has ended, a signal indicating that the high frequency support mode has been started, and a high frequency support mode are A signal indicating that the front door frame 14 has been opened, a signal indicating that the front door frame 14 has been opened, and a signal indicating that the front door frame 14 has been completely opened are individually transmitted from the main CPU 63 to the management IC 66. Sent to.

FIG. 75 is a flowchart showing the history setting process executed by the management CPU 112 in this embodiment.

First, the number of confirmation target buffers in the management CPU 112 of the first to fifteenth buffers 122a to 122o is set in the confirmation target counter of the management RAM 114 (step S2701). Specifically, of the first to fifteenth correspondence areas 123a to 123o in the correspondence memory 116, the number of correspondence areas in which information other than the information indicating blank is stored is specified, and the identification is performed. The information of the number that was set is set in the check target counter. In the present embodiment, information indicating that one of the first to seventh correspondence areas 123a to 123g corresponds to one of the ball entering portions is stored, and the eighth correspondence area 123h indicates the start of the opening/closing execution mode. Corresponding information is stored, information corresponding to the end of the open/close execution mode is stored in the ninth correspondence area 123i, and information corresponding to the start of the high frequency support mode is stored in the tenth correspondence area 123j. Information corresponding to the end of the high frequency support mode is stored in the eleventh correspondence area 123k, and information corresponding to the opening start of the front door frame 14 is stored in the twelfth correspondence area 123l. Information corresponding to the end of opening the front door frame 14 is stored in the thirteenth correspondence area 123m. Therefore, in step S2701, "13" is set in the check target counter.

After that, it is necessary to confirm whether 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". Then, 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 S2702). When the value of the check target counter is "n", the nth buffers 122a to 122o are the check targets of the numerical information. For example, if the value of the check target counter is “10”, the tenth buffer 122j is the check target of the numerical information, and if the value of the check target counter is “5”, the fifth buffer 122e is the check target of the numerical information. ..

If an affirmative decision is made in step S2702, the RTC information, which is date information and time information, is read from the RTC 115 (step S2703). Then, the writing process to the history memory 117 is executed (step S2704). In the writing process, the pointer area 126 of the history memory 117 is referred to identify the pointer information of the history area 124 that is the current writing target, and the pointer information corresponds to the writing target pointer information. The RTC information read in step S2703 is written in the history information storage area 125 of the history area 124. Also, the correspondence information is read from the correspondence areas 123a to 123o corresponding to the current value of the check target counter, and the correspondence information is written in the history information storage area 125 corresponding to the pointer information to be written. When the value of the confirmation target counter is “n”, the n-th correspondence relationship areas 123a to 123o are targets for reading correspondence information. For example, if the value of the check target counter is "10", the tenth correspondence area 123j is the read target of the correspondence information, and if the value of the check target counter is "5", the fifth correspondence area 123e is the correspondence relationship. It is a target for reading information.

After that, the value of the target pointer is incremented by 1 (step S2705). 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 S2706).

When it exceeds the maximum value (step S2706: YES), various arithmetic processes are executed (step S2707). In various arithmetic processing, the same processing as step S1402 to step S1409, step S1411 to step S1413, and step S1415 to step S1417 of the external output processing (FIG. 40) in the first embodiment is executed. Then, the various parameters of the calculation result and the information of the total time are written in the calculation result memory 631 (step S2708). In this case, when the information of another operation result is already stored in the operation result memory 631, the operation result information is written so as not to overwrite the already stored operation result information. To do. Further, the current date information and the current time information are read from the RTC 115, and the read date information and the time information are attached to the information of the calculation 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, the state information takeover process is executed (step S2709). In the takeover process, based on the history information stored in the history memory 117, whether the current state is the open/close execution mode, the high frequency support mode, and the front door frame 14 is open. Or not. Then, the status information is written in the management RAM 114.

After that, the history memory 117 is cleared (step S2710). In the clearing process, all the history information storage area 125 of the history memory 117 is cleared to "0" and the pointer area 126 is cleared to "0". As a result, the history area 124 is in the initialized state. After executing the clearing process, the state information written in the management side RAM 114 in step S2709 is read out. When the state information indicating that the open/close execution mode is being stored, the history information indicating that the open/close execution mode is being stored is stored in the history information storage area 125 corresponding to the pointer information to be written. While writing, the pointer information to be written is incremented by 1. Further, when the status information indicating that the high frequency support mode is being stored, the 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 At the same time as writing to 125, the pointer information to be written is incremented by 1. When the state information indicating that the front door frame 14 is open is stored, the history information indicating that the front door frame 14 is open corresponds to the pointer information to be written. The pointer information to be written is incremented by 1 while being written in the history information storage area 125.

When a negative determination is made in step S2702, a negative determination is made in step S2706, or when the processing of step S2710 is executed, the value of the confirmation target counter of the management side RAM 114 is decremented by 1 (step S2711). Then, it is determined whether or not the value of the check target counter after the subtraction of 1 is "0" (step S2712). When the value of the check target counter is 1 or more (step S2712: NO), the process from step S2702 is executed for the check target corresponding to the new check target counter value.

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 exceeds the upper limit number that can be stored in the history memory 117 and the history information becomes a storage target, and various parameters cannot be accurately calculated.

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

Further, even if the history memory 117 is initialized, the state information takeover process is executed. This makes it possible to appropriately manage the state information.

<Fifteenth 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 of the first embodiment. The configuration different from that of the first embodiment will be described below. The description of the same configuration as the first embodiment is basically omitted.

FIG. 76 is an explanatory diagram for explaining the configuration of the history memory 117 in this embodiment. The history memory 117 is provided with a total area 641, a first state area 642, a second state area 643, and a third state area 644. First to fifteenth counters 641a to 641o, 642a to 642o, 643a to 643o, 644a to 644o are provided in the areas 641 to 644, respectively. 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 641a to 644a of each of the areas 641 to 644. 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 641b to 644b in each of the areas 641 to 644. 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 641c to 644c of each of the areas 641 to 644. 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 641d to 644d of the areas 641 to 644, respectively. Information about 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 641e to 644e of each of the areas 641 to 644. The sixth counters 641f to 644f of the areas 641 to 644 store 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. 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 641g to 644g in each of the areas 641 to 644. The eighth counters 641h to 644h of the areas 641 to 644 store 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. 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 641i to 644i of each of the areas 641 to 644. 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 641j to 644j in each of the areas 641 to 644. 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 641k to 644k in each of the areas 641 to 644. 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 641l to 644l of the areas 641 to 644, respectively. The thirteenth counters 641m to 644m of each area 641 to 644 store 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. The 14th counters 641n to 644n of the areas 641 to 644 store information on the number of times the output state of the 14th signal input to the 14th buffer 122n is changed from the LOW level to the HI level. The fifteenth counters 641o to 644o of the areas 641 to 644 store information on the number of times the output state of the fifteenth signal input to the fifteenth buffer 122o is changed from the LOW level to the HI level.

However, the measurement targets using the first to fifteenth counters 641a to 641o, 642a to 642o, 643a to 643o, 644a to 644o are the outlet 24a, the general winning opening 31, the special electricity winning device 32, and the first operation. It is the first to seventh buffers 122a to 122g to which a signal corresponding to the result of the ball entering either the mouth 33 or the second operating opening 34 is input. Therefore, the signals corresponding to the status information such as whether the open/close execution mode is in operation, the high-frequency support mode is in operation, or whether the front door frame 14 is in open state are input. The 10 buffers 122h to 122j are excluded from the measurement target. The distinction between these measurement objects is made based on the correspondence information stored in the correspondence areas 123a to 123o of the correspondence memory 116.

FIG. 77 is a flowchart showing the history setting process executed by the management-side CPU 112 in this embodiment.

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 S2801). Specifically, of the first to fifteenth correspondence areas 123a to 123o in the correspondence memory 116, the number of correspondence areas in which information other than the information indicating blank is stored is specified, and the identification is performed. The information of the number that was set is set in the check target counter. As described above, the pachinko machine 10 stores the information other than the information indicating that it is blank in the first to tenth correspondence areas 123a to 123j, so that "10" is set in the check target counter in step S2801. To do.

After that, it is determined whether or not the buffers 122a to 122o corresponding to the current check target counter are buffers to which the signal of the status information is input (step S2802). Specifically, in the correspondence areas 123a to 123o corresponding to the current value of the check target counter, as correspondence 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 an affirmative decision is made in step S2802, state information setting processing is executed (step S2803). In the setting process, when the output state of the eighth signal indicating whether or not the open/close execution mode is switched from the LOW level to the HI level, the information on the first state indicating that the open/close execution mode is set is displayed on the management side. When the output state of the eighth signal is switched from the HI level to the LOW level, it is stored in the RAM 114, and the information of the first state is erased from the management side RAM 114. Further, when the output state of the ninth signal indicating whether the high frequency support mode is in effect switches from the LOW level to the HI level, the second state information indicating that the high frequency support mode is in effect is provided to 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 of the second state is erased from the management side RAM 114. In addition, when the output state of the tenth signal indicating whether the front door frame 14 is open is switched from the LOW level to the HI level, the third state information indicating that the front door frame 14 is open Is stored in the management RAM 114, and when the output state of the tenth signal is switched from the HI level to the LOW level, the information of the third state is erased from the management RAM 114.

When a negative determination is made in step S2802, the first to fifteenth buffers 122a to 122o are stored in the buffer corresponding to the current value of the check target counter and to which the signal of the information different from the state information is input. Whether the output state of the input signal from the main CPU 63 to the relevant buffer has been switched from the LOW level to the HI level by confirming whether or not the numerical information stored is changed from "0" to "1". It is determined whether or not (step S2804). If an affirmative decision is made in step S2804, the addition processing of the corresponding counter for summation is executed (step S2805). In the addition processing, the value of the counter corresponding to the current value of the check target counter among the first to fifteenth counters for total 641a to 641o in the total area 641 of the history memory 117 is incremented by 1. For example, if the value of the check target counter is "5", the fifth total counter 641e is the addition target, and if the value of the check target counter is "1", the first total counter 641a is the addition target. ..

Thereafter, by referring to the state information of 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 open/close execution mode (step S2806). If it is in the first state (step S2806: YES), the corresponding addition process of the counter for the first state is executed (step S2807). In the addition processing, the value of the counter corresponding to the current value of the check target counter among the first to fifteenth counters 642a to 642o for the first state in the first state area 642 of the history memory 117 is incremented by 1. . For example, if the value of the check target counter is "5", the fifth counter 642e for the first state is the addition target, and if the value of the check target counter is "1", the first counter 642a for the first state is the addition target. It will be added.

After that, by referring to the state information of 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 S2808). If it is in the second state (step S2808: YES), the corresponding counter for the second state is added (step S2809). In the addition processing, the value of the counter corresponding to the value of the current check target counter among the first to fifteenth counters 643a to 643o for the second state in the second state area 643 of the history memory 117 is incremented by 1. .. For example, if the value of the check target counter is “5”, the fifth counter 643e for the second state is the addition target, and if the value of the check target counter is “1”, the first counter 643a for the second state is the addition target. It becomes an addition target.

After that, by referring to the state information of the management side RAM 114, it is determined whether or not it is in the third state, that is, whether or not the front door frame 14 is open (step S2810). If it is in the third state (step S2810: YES), the corresponding counter for the third state is added (step S2811). In the addition processing, the value of the counter corresponding to the value of the current check target counter among the first to fifteenth counters 644a to 644o for the third state in the third state area 644 of the history memory 117 is incremented by 1. . For example, if the value of the check target counter is "5", the fifth counter 644e for the third state is the addition target, and if the value of the check target counter is "1", the first counter 644a for the third state is the It will be added.

When the process of step S2803 is executed, the negative determination is made in step S2804, the negative determination is made in step S2810, or the process of step S2811, the value of the check target counter of the management side RAM 114 is set to 1 Subtract (step S2812). Then, it is determined whether or not the value of the check target counter after the subtraction of 1 is "0" (step S2813). When the value of the check target counter is 1 or more (step S2813: NO), the process from step S2802 is executed for the check target corresponding to the new check target counter value.

By executing the history setting process as described above, the history of game balls entering the outlet 24a, the general winning opening 31, the special electricity winning device 32, the first operating opening 33, and the second operating opening 34 is changed to the above. Instead of being stored as history information as in the first embodiment, it is stored as information on the number of times a game ball is detected by each of the ball detection sensors 42a to 48a. As a result, the storage capacity required in the history memory 117 can be suppressed as compared with the configuration in which each history information is stored individually.

As described above, since the game ball is stored as the information on the number of times the game ball is detected by each of the ball detection sensors 42a to 48a, the external outlet 24a such as step S1602 in the external output process (FIG. 40) in the present embodiment. To calculate the number of game balls entered into the special electric prize winning device 32 such as step S1604, and to calculate the number of game balls entered into the first operating port 33 such as step S1605. The process of calculating and the process of calculating the number of game balls entering the second operation port 34, such as step S1606, are unnecessary. This makes it possible to reduce the processing load for calculating various parameters.

In the process of calculating the number of game balls entering the general winning opening 31 such as step S1603, the first to third counters 641a to 641c, 642a to 642c, 643a to 643c, 644a to 644c are all general winning openings. Since it corresponds to 31, it is necessary to execute a process of summing the values of the first to third counters 641a to 641c, 642a to 642c, 643a to 643c, 644a to 644c. Further, it is impossible to distinguish the number of balls entered in the situation in which the front door frame 14 is open in the opening/closing execution mode from the number of balls entered in other situations. Therefore, the process of step S1612 is not executed in the external output process (FIG. 40) in the present embodiment. Similarly, it is impossible to distinguish the number of balls entered in the situation in which the front door frame 14 is open in the high frequency support mode from the number of balls entered in other situations. Therefore, the process of step S1616 is not executed in the external output process (FIG. 40) in the present embodiment.

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

FIG. 78 is a block diagram for explaining the electrical configuration of the MPU 62 in this embodiment. As in the first embodiment, the MPU 62 is provided with 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 memory 116, and the history memory 117. Instead, the management IC 66 is provided with a calculation result memory 631 as in the twelfth embodiment. Since the management IC 66 is not provided with the RTC 115, the correspondence memory 116, and the history memory 117, history information is not stored in the management IC 66 in this embodiment. In the present embodiment, the entry history into the outlet 24a, the general winning opening 31, the special electric winning device 32, the first operating opening 33, and the second operating opening 34 is stored in the main RAM 65. That is, the main RAM 65, which temporarily stores information necessary for executing the program in the main CPU 63, is also used as a memory for storing the entry history. Then, the management IC 66 can access the main RAM 65 through the management I/F 111. When the calculation trigger of various parameters occurs, the main IC 65 is accessed to read the entry history and read it. Various parameters are calculated using the entry history. The calculated various parameters are stored in the calculation result memory 631. When the reading device is electrically connected to the reading terminal 102, various parameters are provided from the calculation result memory 631 to the reading device, but the entry history stored in the main RAM 65 is not provided to the reading device. ..

FIG. 79 is a flow chart showing a ball entry detection process in the present embodiment executed by the main CPU 63. The incoming ball detection process is executed in step S211 of the timer interrupt process (FIG. 18).

When it is confirmed that the state in which the information of “0” is stored for the 0th bit D0 is switched to the state in which the information of “1” is stored, the first winning hole detection sensor 42a outputs 1 It is determined that the individual game balls have been detected (step S2901: YES). In this case, the value of the general winning counter provided in the main RAM 65 is incremented by 1 (step S2902). The general winning counter is a counter for storing the number of balls entered into the general winning opening 31 as a history of entered balls. 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 631 by the reading device. By the way, 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, even if the pachinko machine 10 is powered off, the value of the general winning counter is It is retained. After that, the value of the counter for 10 prize balls in the main RAM 65 is incremented by 1 (step S2903).

When it is confirmed that the state in which the information of "0" is stored for the first bit D1 is switched to the state in which the information of "1" is stored, the second winning hole detection sensor 43a outputs 1 It is determined that the individual game balls have been detected (step S2904: YES). In this case, the value of the general winning counter of the main RAM 65 is incremented by 1 (step S2905). After that, the value of the counter for 10 prize balls in the main RAM 65 is incremented by 1 (step S2906).

When it is confirmed that the state in which the information of “0” is stored for the second bit D2 is switched to the state in which the information of “1” is stored, it is set to 1 by the third winning hole detection sensor 44a. It is determined that the individual game balls have been detected (step S2907: YES). In this case, the value of the general winning counter of the main RAM 65 is incremented by 1 (step S2908). Then, the value of the counter for 10 prize balls of the main RAM 65 is incremented by 1 (step S2909).

When it is confirmed that the information of "0" is stored in the third bit D3 and the information of "1" is stored in the third bit D3, one game is performed by the special electric detection sensor 45a. It is determined that a sphere has been detected (step S2910: YES). In this case, "1" is set to the special electricity winning flag of the main RAM 65 (step S2911). In addition, the value of the special electric prize winning counter provided in the main RAM 65 is incremented by 1 (step S2912). 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 entering history. The value of the special electric prize 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 631 by the reading device. By the way, 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, even if the pachinko machine 10 is powered off, the value of the special electricity prize counter is Retained. After that, the value of the counter for 15 prize balls in the main RAM 65 is incremented by 1 (step S2913).

When it is confirmed that the state in which the information “0” is stored for the fourth bit D4 is switched to the state in which the information “1” is stored, the first working port detection sensor 46a outputs 1 It is determined that one game ball has been detected (step S2914: YES). In this case, the first operation winning flag of the main RAM 65 is set to "1" (step S2915). Further, the value of the first operation counter provided in the main RAM 65 is incremented by 1 (step S2916). The first operation counter is a counter for storing the number of balls entered into the first operation port 33 as a ball entry history. The value of the first operation counter is cleared to “0” when the reading device is electrically connected to the reading terminal 102 and various parameters are read from the calculation result memory 631 by the reading device. . By the way, 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, even if the pachinko machine 10 is powered off, the value of the first operation counter Is retained. Thereafter, the value of the one prize ball counter of the main RAM 65 is incremented by 1 (step S2917).

When it is confirmed that the state in which the information “0” is stored for the fifth bit D5 is switched to the state in which the information “1” is stored, the second working port detection sensor 47a outputs 1 It is determined that one game ball has been detected (step S2918: YES). In this case, the second operation winning flag of the main RAM 65 is set to "1" (step S2919). Further, the value of the second operation counter provided in the main RAM 65 is incremented by 1 (step S2920). The second operation counter is a counter for storing the number of balls entered into the second operation port 34 as a ball entry history. The value of the second operation counter is cleared to “0” when the reading device is electrically connected to the reading terminal 102 and various parameters are read from the calculation result memory 631 by the reading device. . By the way, since the backup power is supplied to the main side RAM 65 even when the supply of the operating power to the MPU 62 is stopped, even if the pachinko machine 10 is in the power-off state, the value of the second operation counter Is retained. Then, the value of the one prize ball counter of the main RAM 65 is incremented by 1 (step S2921).

When it is confirmed that the state in which the information of “0” is stored for the sixth bit D6 is switched to the state in which the information of “1” is stored, one port is detected by the outlet detection sensor 48a. It is determined that a game ball has been detected (step S2922: YES). In this case, the value of the out counter provided in the main RAM 65 is incremented by 1 (step S2923). The out counter is a counter for storing the number of balls entered into the outlet 24a as a history of entered balls. The value of the out-counter is cleared to “0” when the reading device is electrically connected to the reading terminal 102 and various parameters are read from the calculation result memory 631 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 in the power-off state. Retained.

When it is confirmed that the state in which the information of “0” is stored for the 7th bit D7 is switched to the state in which the information of “1” is stored, one is detected by the first gate detection sensor 49a. It is determined that the game ball is detected (step S2924: YES). In this case, "1" is set to the first gate winning flag of the main RAM 65 (step S2925).

When it is confirmed that the state in which the information of “0” is stored for the eighth bit D8 is switched to the state in which the information of “1” is stored, one is detected by the second gate detection sensor 50a. It is determined that the game ball is detected (step S2926: YES). In this case, "1" is set to the second gate winning flag of the main RAM 65 (step S2927).

By performing the entrance detection process as described above, the entrance history into the outlet 24a, the general winning opening 31, the special electricity winning device 32, the first operating opening 33, and the second operating opening 34 is recorded in each entering portion. It is stored in the main side RAM 65 as the number of balls entered. As a result, a signal is sent from the main CPU 63 to the management CPU 112 each time a ball enters any of the outlet 24a, the general winning opening 31, the special electricity winning device 32, the first operating opening 33, and the second operating opening 34. 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 the calculation trigger occurs, the management-side CPU 112 reads the number of balls entered into the general winning opening 31 from the general winning counter of the main RAM 65, and transfers the special power winning counter of the main RAM 65 to the special power winning device 32. The number of balls entered is read, the number of balls entered into the first operation port 33 is read from the first operation counter of the main RAM 65, the number of balls entered into the second operation port 34 is read from the second operation counter of the main RAM 65, The number of balls entered into the out port 24a is read from the out counter of the main RAM 65. Then, the first to eighth parameters described in the first embodiment are calculated by using the read numbers of respective balls entered. However, the number of incoming balls is not measured in a state where the number of incoming balls when the front door frame 14 is open and the number of incoming balls when the front door frame 14 is closed are distinguished. Therefore, the first parameter to the eighth parameter are calculated in a state in which the number of balls entered when the front door frame 14 is open is also included. In addition, since the number of incoming balls in the open/close execution mode and the number of incoming balls in the high frequency support mode are not individually measured, the first parameter to the eighteenth parameter and the twenty-first 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 631. Then, when the reading device is electrically connected to the reading terminal 102, all the parameters written in the operation result memory 631 at that time are provided to the reading device. At this time, the calculation result memory 631 is cleared to "0".

It should be noted that the management IC 66 does not access the main RAM 65 independently, but the information on the number of each ball stored in the main RAM 65 as a ball entry history is transmitted to the management IC 66 by the transfer control by the main CPU 63. May be configured. In this case, it is possible to reliably prevent the main RAM 65 from being simultaneously accessed by the main CPU 63 and the management CPU 112.

<17th 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 in each entry portion are different from those in the first embodiment. ing. The configuration different from that of the first embodiment will be described below. The description of the same configuration as the first embodiment is basically omitted.

FIG. 80 is a block diagram for explaining the electrical configuration of the main control board 61 in this embodiment. The MPU 62 is mounted on the main control board 61 as in the first embodiment. As in the first embodiment, the MPU 62 is provided with 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, a management side RAM 114, a correspondence relationship memory 116 and a history memory 117, as in the first embodiment.

On the other hand, in this embodiment, unlike the first embodiment, the management IC 66 is not provided with the RTC 115. Also. In addition to the MPU 62, the main control board 61 is provided with a notification light emitting section 651. The notification light emitting unit 651 is directly controlled by the main CPU 63. The main side CPU 63 can access the history memory 117 of the management IC 66, and calculates various parameters by using the information of the history of entering the respective ball portions read from the history memory 117. Then, the light emitting state of the notification light emitting unit 651 is controlled according to the contents of the calculated various parameters. The light emitting unit 651 for notification is housed in the housing space of the board box 60a of the main control device 60. However, the board box 60a is formed transparent, and the light emitting state of the light emitting unit 651 for notification is set outside the board box 60a. The notification light emitting unit 651 is provided so that the user can visually check it. In this way, 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, so that the notification light emitting unit 651 can be performed without the need to open the board box 60a. It is possible to visually check the light emitting state of.

FIG. 81 is an explanatory diagram for explaining the configuration of the input port 121 of the management-side I/F 111 in this embodiment.

The same kind of signal as that of the first embodiment is input to the first to seventh buffers 122a to 122g and the 16th buffer 122p. Specifically, the first signal corresponding to the detection result of the first winning opening detection sensor 42a is input to the first buffer 122a, and the second signal corresponding to the detection result of the second winning opening detection sensor 43a is input to the second buffer 122b. A signal is input, a third signal corresponding to the detection result of the third winning a prize detection sensor 44a is input to the third buffer 122c, and a fourth signal corresponding to the detection result of the special electric power detection sensor 45a is input to the fourth buffer 122d. Is input to the fifth buffer 122e, a fifth signal corresponding to the detection result of the first working opening detection sensor 46a is input, and the sixth buffer 122f corresponds to the detection result of the second working opening detection sensor 47a. Six signals are input, a seventh signal corresponding to the detection result of the outlet detection sensor 48a is input to the seventh buffer 122g, and an output instruction signal is input to the sixteenth buffer 122p.

On the other hand, in the first embodiment, the signal corresponding to the open/close execution mode is input to the eighth buffer 122h as the eighth signal, and the signal corresponding to the high frequency support mode is input to the ninth buffer 122i as the ninth signal. 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 The signal corresponding to the door frame 14 is not input to the input port 121. That is, no signal regarding the entry history is input to the eighth to fifteenth buffers 122h to 122o.

What kind 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 kind of these signals is determined by receiving an instruction from the main CPU 63. It is specified by the management CPU 112. The process for specifying the type of the 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, it is decided at the design stage of the management IC 66 that the output instruction signal is input to the 16th buffer 122p, and the management CPU 112 outputs the 16th buffer 122p to the 16th buffer 122p without receiving an instruction from the main CPU 63. It is possible to specify that the instruction signal is input.

FIG. 82 is an explanatory diagram for explaining the configuration of the history memory 117 in this embodiment. The history memory 117 is provided with first to fifteenth buffer counters 652a to 652o. The first buffer counter 652a stores 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. The second buffer counter 652b stores 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. The third buffer counter 652c stores 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. The fourth buffer counter 652d stores 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. The fifth buffer counter 652e stores 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. The sixth buffer counter 652f stores 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. The seventh buffer counter 652g stores 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. The eighth buffer counter 652h stores 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. The ninth buffer counter 652i stores 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. The tenth buffer counter 652j stores 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. The eleventh buffer counter 652k stores 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. The twelfth buffer counter 652l stores 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. The thirteenth buffer counter 652m stores 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. The 14th buffer counter 652n stores information on the number of times the output state of the 14th signal input to the 14th buffer 122n is changed from the LOW level to the HI level. The fifteenth buffer counter 652o stores information on the number of times the output state of the fifteenth signal input to the fifteenth buffer 122o is changed from the LOW level to the HI level.

However, the measurement target using the first to fifteenth buffer counters 652a to 652o is any of the outlet 24a, the general winning opening 31, the special electricity winning device 32, the first working opening 33, and the second working opening 34. It is the first to seventh buffers 122a to 122g to which signals corresponding to the result of entering the ball are input. Therefore, the eighth to fifteenth buffers 122h to 122o are excluded from the measurement target. The distinction between these measurement objects is made based on the correspondence information stored in the correspondence areas 123a to 123o of the correspondence memory 116.

FIG. 83 is a flowchart showing the history setting process executed by the management CPU 112. The history setting process is executed in step S1207 of the management process (FIG. 34).

First, the number of buffers to be confirmed in the management CPU 112 of the first to fifteenth buffers 122a to 122o is set to the confirmation target counter of the management RAM 114 (step S3001). Specifically, of the first to fifteenth correspondence areas 123a to 123o in the correspondence memory 116, the number of correspondence areas in which information other than the information indicating blank is stored is specified, and the identification is performed. The information of the number that was set is set in the check target counter. As described above, the pachinko machine 10 stores information other than the information indicating that it is blank in the first to seventh correspondence areas 123a to 123j, and therefore, in step S3001, the confirmation target counter is set to "7". To do.

Then, it is confirmed whether 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". Then, 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 S3002). When the value of the check target counter is "n", the nth buffers 122a to 122o are the check targets of the numerical information. For example, if the value of the check target counter is "5", the fifth buffer 122e is the check target of the numerical information, and if the value of the check target counter is "1", the first buffer 122a is the check target of the numerical information. .

When an affirmative determination is made in step S3002, the addition processing of the corresponding buffer counters 652a to 652o is executed (step S3003). In the addition processing, the value of the counter corresponding to the current value of the check target counter among the counters 652a to 652o for the first to fifteenth buffers of the history memory 117 is incremented by one. For example, if the value of the check target counter is “5”, the fifth buffer counter 652e is the addition target, and if the value of the check target counter is “1”, the first buffer counter 652a is the addition target.

When a negative determination is made in step S3002, or when the process of step S3003 is executed, the value of the check target counter of the management RAM 114 is decremented by 1 (step S3004). Then, it is determined whether or not the value of the check target counter after subtracting 1 is "0" (step S3005). When the value of the check target counter is 1 or more (step S3005: NO), the process from step S3002 is executed for the check target corresponding to the new check target counter value.

By executing the history setting process as described above, the history of game balls entering the outlet 24a, the general winning opening 31, the special electricity winning device 32, the first operating opening 33, and the second operating opening 34 is changed to the above. Instead of being stored as history information as in the first embodiment, it is stored as information on the number of times a game ball is detected by each of the ball detection sensors 42a to 48a. As a result, the storage capacity required in the history memory 117 can be suppressed as compared with the configuration in which each history information is stored individually.

FIG. 84 is a flowchart showing the external output processing in this embodiment executed by the management CPU 112. The external output process is executed in step S1208 of the management process (FIG. 34).

When the output state of the output instruction signal received from the main CPU 63 becomes the HI level (step S3101: YES), the output target counters provided in the management RAM 114 include the first to fifteenth buffer counters 652a to 652a. Of the 652o, the management-side CPU 112 sets the number of counters to which the frequency information is output (step S3102). Specifically, of the first to fifteenth correspondence areas 123a to 123o in the correspondence memory 116, the number of correspondence areas in which information other than the information indicating blank is stored is specified, and the identification is performed. The information of the number that was set is set in the check target counter. In the present embodiment, as already described, the first to seventh correspondence areas 123a to 123g store information other than the information indicating that it is blank, and therefore, in step S3102, "7" is set in the output target counter. ..

After that, 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 S3103), and the history information is used. Of the first to fifteenth buffer counters 652a to 652o in the memory 117, the frequency information stored in the counter corresponding to the current output target counter is read (step S3104). In this case, when the value of the output target counter is “n”, the n-th correspondence area 123a to 123o becomes the read target of the correspondence information, and the n-th buffer counters 652a to 652o read the number-of-times information. Be the target. For example, if the value of the output target counter is "5", the fifth correspondence area 123e is the target of reading the correspondence information, the fifth buffer counter 652e is the target of reading the count information, and the value of the output target counter is If the value is "1", the first correspondence area 123a is the target for reading the correspondence information, and the first buffer counter 652a is the target for reading the number-of-times information.

After that, information output processing is executed (step S3105). In the information output process, the combination of the correspondence information read in step S3103 and the number-of-times information read in step S3104 is output to the reading terminal 102. As a result, the reading device electrically connected to the reading terminal 102 reads the number-of-times information about the correspondence information that is the current output target.

Thereafter, the value of the output target counter of the management side RAM 114 is decremented by 1 (step S3106). Then, it is determined whether or not the value of the output target counter after the subtraction of 1 is "0" (step S3107). When the value of the output target counter is 1 or more (step S3107: NO), the process from step S3103 is executed on the output target corresponding to the new output target counter value. In addition, when a positive determination is made in step S3107, the values of the first to fifteenth buffer counters 652a to 652o are cleared to "0".

FIG. 85 is a flowchart showing the parameter management process executed by the main CPU 63. The parameter management process is executed after the management output process of step S221 is executed in the timer interrupt process (FIG. 18).

First, it is determined whether or not there is a trigger for calculation of various parameters (step S3201). The calculation trigger is when the parameter management process is first executed after the supply of the operating power to the main CPU 63 is started, and like the eleventh embodiment, the outlet 24a, the general winning opening 31, and the special prize winning. It occurs every time the total number of game balls entered into the device 32, the first operation port 33, and the second operation port 34 becomes 500 or more, which is the trigger reference number. Since the case where the parameter management process is first executed after the supply of the operating power is started is set as the calculation trigger, the power of the pachinko machine 10 is once turned off and then turned on again to calculate various parameters. The trigger can be easily generated. If an affirmative decision is made in step S3201, notification corresponding to the calculation results of various parameters will be executed, as will be described later, so simply turning the power supply OFF/ON in the game area PA up to that point. It is possible to grasp the entering mode of the game ball. In addition, by having a configuration in which a calculation trigger is generated every time the total number of entered balls of the game balls becomes 500 or more, which is the trigger reference number, it is possible to finely manage the entering mode of the game balls in the game area PA. Becomes

If the calculation trigger has occurred (step S3201: YES), the entry history is read from the counters of the first to fifteenth buffer counters 652a to 652o of the history memory 117, which are the storage targets of the entry history. Specifically, the numerical information of the first to seventh buffer counters 652a to 652g is read. In this case, the main CPU 63 can recognize the buffer counters 652a to 652o from which the entry history is read based on the programs and data stored in the main ROM 64.

After that, various arithmetic processes are executed (step S3203). In the various calculation processes, various parameters are calculated by using the entry history read out in step S3202 and the information on the number of prize balls corresponding to the entry history. Based on the programs and data stored in the main ROM 64, the main CPU 63 determines that each entrance history read in step S3202 is an outlet 24a, a general winning opening 31, a special electricity winning device 32, a first operating opening 33, and a first operating opening 33. It is possible to specify which of the two working ports 34 corresponds, and it is also possible to specify information on the number of prize balls corresponding to each ball entry history read in step S3202.

Regarding the various parameters calculated in step S3203, specifically,
・Seventh parameter: (K3דnumber of prize balls for winning in special electric prize winning device 32”+K5דnumber of prize balls for winning in second operation port 34”)/total payout number of game balls (K2דgeneral”) "Number of prize balls for winning in prize hole 31" + K3 x "Number of prize balls for winning in special electric prize winning device 32" + K4 x "Number of prize balls for prize in first operating port 33" + K5 x "Second operating port 34" 8th parameter: K3 x "number of prize balls for winning in special electric prize winning device 32" / total payout number of gaming balls (K2 x for winning in general winning hole 31) "Number of prize balls" + K3 x "Number of prize balls for winning the special electric prize winning device 32" + K4 x "Number of prize balls for winning the first operating port 33" + K5 x "Number of prize balls for winning the second operating port 34" )) is calculated.

After that, it is determined whether the calculated various parameters are within the first range (step S3204). When the value of the seventh parameter is 0.7 or less and the value of the eighth parameter is 0.6 or less, it is determined in step S3204 that the calculated various parameters are in the first range and a positive determination is made. When an affirmative determination is made in step S3204, the first notification state setting processing is executed (step S3205). In the setting process, the notification light emitting unit 651 is controlled to emit light so as to be in the first notification state. In this case, the notification light emitting unit 651 is in a blue light emitting state.

When a negative determination is made in step S3204, it is determined whether the calculated various parameters are in the second range (step S3206). When the condition that only one of the value of the seventh parameter exceeds 0.7 and the value of the eighth parameter exceeds 0.6 is satisfied, the calculated various parameters are A positive determination is made in step S3206 assuming that the range is two. When an affirmative determination is made in step S3206, the second notification state setting processing is executed (step S3207). In the setting process, the notification light emitting unit 651 is controlled to emit light so as to be in the second notification state. In this case, the notification light emitting unit 651 is in a yellow light emitting state.

A negative determination in step S3206 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 S3208). In the setting process, the notification light emitting unit 651 is controlled to emit light so as to be in the third notification state. In this case, the notification light emitting unit 651 is in a red light emitting state.

The light emission state set in step S3205, step S3207, or step S3208 is stopped until a new notification state is set for the notification light emitting unit 651 or the supply of operating power to the notification light emitting unit 651 is stopped. Continue until. Further, since the notification state of the notification light emitting unit 651 is stored and held in the main RAM 65 and backup power is supplied to the main RAM 65, the supply of operating power to the main CPU 63 is stopped and the notification light emitting unit 651 is stopped. Even if 651 is once turned off, when the supply of operating power to the main CPU 63 is resumed, the light emitting state corresponding to the type of information of the notification state stored in the main RAM 65 is set. The light emission control of the notification light emitting unit 651 is executed.

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

The entry history of the game ball into the outlet 24a, the general winning opening 31, the special electric winning device 32, the first operating opening 33 and the second operating opening 34 is stored as history information as in the first embodiment. Instead, it is stored as information on the number of times the game ball is 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 suppressed as compared with the configuration in which each history information is stored individually.

A notification light emitting unit 651 is provided to notify the contents corresponding to various parameters calculated by the management-side CPU 112. As a result, the contents corresponding to 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 to read the game balls in the game area PA. It is possible to grasp the entering mode.

The main control board 61 housed in the board box 60a is provided with the notification light emitting section 651 together with the MPU 62. This makes it difficult to make unauthorized access to the communication path between the MPU 62 and the notification light emitting unit 651.

The calculation of various parameters and the light emission control of the notification light emitting unit 651 are executed by the main CPU 63 instead of the management CPU 112. This makes it possible to increase the reliability of the notification content in the notification light emitting unit 651.

When the calculation results of various parameters correspond to the first range, the first notification state is set. When the calculation results of various parameters correspond to the second range, the second notification state is set. The third notification state is set when neither the first range nor the second range is supported. That is, not the various parameters are reported as they are, but the content corresponding to the range including the various parameters is reported. Accordingly, it becomes possible to prevent the notification light emitting unit 651 from having too many notification patterns, and it is possible to reduce the load for controlling the notification light emitting unit 651.

Immediately before the supply of the operating power to the main CPU 63 is stopped by continuing the power supply to the notification light emitting unit 651 even when the supply of the operating power to the main CPU 63 is stopped. The light emitting state may be maintained. In this case, even if the supply of the operating power to the main CPU 63 is stopped, by checking the notification light emitting unit 651, it is possible to grasp the entry mode of the game ball in the game area PA. ..

Further, instead of the configuration, when the supply of the operating power to the main CPU 63 is stopped, the notification light emitting unit 651 is turned off, but when the supply of the operating power to the main CPU 63 is started. Alternatively, the notification light emitting unit 651 may be configured to emit light so as to be in a light emitting state corresponding to the result of various parameters calculated before the supply of the operating power is stopped. In this case, for example, by checking the notification light emitting unit 651 before the start of business in the game hall, it becomes possible to grasp the entering mode of the game ball on the last business day.

The notifying means for notifying the calculation results of various parameters is not limited to the notification light emitting unit 651, and may be a display device having a display surface such as the symbol display device 41 or the like, and the speaker unit 54. May be In addition, a signal corresponding to the calculation result of various parameters may be externally 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 general figure display part 38a of the general figure unit 38 may also function as the notification light emitting section 651. For example, various parameters are calculated when the supply of the operating power to the MPU 62 is started, and the calculation result is included in the first range, the second range as in the above embodiment, or other than them. The configuration corresponding to the calculation result may be executed on the special figure display unit 37a or the general figure display unit 38a immediately after the supply of the operating power is started. In this case, the notification may be terminated when the condition for starting the variable display of the pattern on the special figure display unit 37a or the condition for starting the variable display of the pattern on the public figure display unit 38a is satisfied. The configuration may be such that when the variable display start condition is satisfied, it is temporarily interrupted, and when the variable display of the pattern is finished, it is restarted. According to this configuration, it is possible to use the special figure display portion 37a or the general figure display portion 38a as an informing means for informing the entry mode of the game ball in the game area PA.

The notification light emitting unit 651 may be provided at a position visible from the front of the pachinko machine 10 in a state where the gaming machine body 12 and the front door frame 14 are closed. For example, the notification light emitting unit 651 may be provided at a position behind the window panel 52 and visible from the front of the pachinko machine 10 through the window panel 52. In this case, it is possible to confirm the notification content corresponding to the calculation results of various parameters without requiring the opening operation of the gaming machine main body 12 and the front door frame 14.

<Eighteenth embodiment>
The present embodiment is different from the first embodiment in the configuration for providing the information of each entrance result to the management IC 66. The configuration different from that of the first embodiment will be described below. The description of the same configuration as the first embodiment is basically omitted.

FIG. 86 is an explanatory diagram for explaining the configuration of a signal path for allowing the detection results of the respective ball detection sensors 42a to 48a to be input to the main CPU 63 and the management IC 66.

The detection result of the first winning opening detection sensor 42a is input to the main CPU 63 through the first signal path SL11. The detection result of the second winning opening detection sensor 43a is input to the main CPU 63 through the second signal path SL12. The detection result of the third winning opening detection sensor 44a is input to the main CPU 63 through the third signal path SL13. The detection result of the special electric power detection sensor 45a is input to the main CPU 63 through the fourth signal path SL14. Further, 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 via the sixth signal path SL16. The detection result of the outlet 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 an intermediate position of the first signal path SL11, and the first branch path SL21 is electrically connected to the management IC 66. Further, the second branch path SL22 is formed so as to branch from the middle 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 an intermediate 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 an intermediate position of the fourth signal path SL14, and the fourth branch path SL24 is electrically connected to the management IC 66. A fifth branch path SL25 is formed so as to branch from an intermediate 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 an intermediate 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 an intermediate position of the seventh signal path SL17, and the seventh branch path SL27 is electrically connected to the management IC 66.

With the above configuration, the detection results of the respective ball detection sensors 42a to 48a are input to the management IC 66 without intervention of the processing by the main CPU 63. As a result, the main CPU 63 executes a process for causing the management CPU 112 to recognize the result of entering each of the outlet 24a, the general winning opening 31, the special electric winning device 32, the first operating opening 33, and the second operating opening 34. Since it is not necessary to do so, it is possible to reduce the processing load of the main CPU 63.

The branch points of the branch paths SL21 to SL27 from the signal paths SL11 to SL17 are present in the MPU 62. As a result, it is possible to make it difficult to access the branch point and the branch paths SL21 to SL27 from the outside, and it is possible to prevent a fraudulent act of inputting an abnormal entry result only to the management IC 66. ..

<Other Embodiments>
It should be noted that the present invention is not limited to the description of the above-described embodiment, and various modifications and improvements can be made without departing from the spirit of the present invention. For example, you may change as follows. By the way, the configurations of the following different modes may be applied individually or in combination with the configurations of the above-described embodiments.

(1) In each of the above-described embodiments, the discharge adjusting means for periodically discharging the taken game ball B1 is provided above the first through gate 35, but the arrangement of the discharge adjusting means is not limited to this. Here, the discharge adjusting means means the adjusting mechanism 180 in the first and sixth embodiments, the adjusting mechanism 220 in the second embodiment, the adjusting mechanism 330 in the third embodiment, and the fourth embodiment. The adjusting mechanism 430 in FIG. 5, the adjusting mechanism 530 in the fifth embodiment, and the adjusting mechanism 620 in the seventh embodiment are generic names. For example, instead of the second through gate 39 in each of the above-described embodiments, a game ball is an opening into which a game ball can enter, and a first opening that is open upward and switching between an open state and a closed state are possible. In a game board having a second opening which is an opening having a possible opening/closing means, the discharge adjusting means may be arranged above the first opening and the second opening.

Specifically, in the game board, the first opening and the second opening are provided on the right side of the game area. The discharge adjusting means is located above the first opening, and only the game balls discharged from the discharge adjusting means can enter the first opening. The opening/closing means of the second opening prohibits the game ball from entering the second opening in the closed state. When the game ball is taken into the discharge adjusting means, the game ball is discharged from the discharge adjusting means and enters the first opening, the opening/closing means switches from the closed state to the open state, and 2 The ball can enter the opening. The open state of the opening/closing means is continued for a predetermined period, and when the number of balls of the game ball entering the second opening reaches the predetermined number in the predetermined period, advantageous benefits are given to the player.

In order to shift the opening/closing means from the closed state to the open state, it is necessary for the player to shoot the game ball aiming at the discharge adjusting means. Further, in order to make the game ball enter the second opening a predetermined number of times, it is necessary for the player to shoot the game ball aiming at the second opening. In this way, the player performs the shooting operation of the game ball aiming at the aim, and the advantageous privilege is given to the player when the predetermined result is obtained, so that the player's consciousness of participation is increased. It is possible to improve the enjoyment of the game.

In this case, it is possible to avoid a situation where the open state of the opening/closing means frequently occurs by limiting the timing of entering the game ball into the first opening using the discharge adjusting means. That is, by using the discharge adjusting means, it is possible to appropriately manage the interval at which the opening/closing means shifts to the open state.

(2) The discharge adjusting means in each of the above-described embodiments may be provided above the first operating port 33, and the winning/winning lottery means may have only one type of lottery mode. Here, the discharge adjusting means means the adjusting mechanism 180 in the first and sixth embodiments, the adjusting mechanism 220 in the second embodiment, the adjusting mechanism 330 in the third embodiment, and the fourth embodiment. Of the adjustment mechanism 430 in the fifth embodiment, the adjustment mechanism 530 in the fifth embodiment, and the adjustment mechanism 620 in the seventh embodiment. Specifically, the main CPU 63 drives and controls the discharge adjusting means such that the discharge adjusting means generates a dischargeable period in which the captured game ball B1 can be discharged toward the first operating port 33 in a cycle of 1 sec. .. The main ROM 64 stores a win/loss determination table in which a determination value to be a jackpot winning target in the win/loss determination process is set. As described above, the win/no win determination process is a process of determining whether or not the hold information corresponds to the jackpot win, and is executed in the special figure special power control process (step S215) of the timer interrupt process (FIG. 18). Processing. In the win/loss determination table, (1250×n−5) to (1250×n) are set as the determination values targeted for the jackpot winning. Here, the variable n is a natural number of 1 to 52. The probability that the jackpot determination process is executed and the jackpot is won is about 1/210. The jackpot target period in which the hold information obtained by winning the game ball B1 in the first operating opening 33 is a jackpot winning target occurs in a cycle of 5 seconds and continues for 24 msec. If the dischargeable period in the discharge adjusting means does not correspond to the jackpot target period, the jackpot result will not be obtained in the hit determination process. In this case, the initial value of the hit random number counter C1 (FIG. 13) is updated, so that the dischargeable period may correspond to the jackpot target period. When the dischargeable period corresponds to the jackpot target period, there is a high probability that the jackpot is won in the win/loss determination process. Specifically, when the game ball B1 is discharged from the discharge adjusting means toward the first working port 33 without fail in a cycle of 1 sec, the winning in the first working port 33 is performed once every five times. You will be eligible for a big win. In this way, the discharge adjusting means creates a situation in which the jackpot winning is likely to occur and a situation in which the jackpot winning is not likely to occur in the winning/disabling determination process, whereby the behavior of the game ball B1 around the discharge adjusting means is determined by the player. It is possible to gather interest and improve the interest of the game.

(3) The configuration for preventing the rising and stopping of the game ball B1 described in each of the above embodiments may be applied to the member for distributing the game ball B1 to one of the two passages.

Specifically, the game board is provided with a distribution winning device. The winning lottery is executed when a prize is generated in either the first operating opening 33 or the second operating opening 34. Of these, in the case where the small lottery is won in the winning lottery executed when the winning of the second working opening 34 is won, the distribution execution mode is entered. In the distribution execution mode, when the V winning is generated, the special electric winning device 32 is in the open/close execution mode in which the special electric winning device 32 is opened.

The distribution winning apparatus has an upstream passage, and the upstream passage branches into a V winning passage and a discharge passage in a branch space. The upstream passage, the V winning passage, and the discharge passage have a passage cross section that allows one gaming ball B1 to pass therethrough and does not allow a plurality of gaming balls B1 to pass simultaneously. There is. The upstream passage is linearly formed downward in the vicinity of the branch space. In addition, an inlet of the discharge passage is provided immediately below the outlet of the upstream passage in the vicinity of the branch space. For this reason, when the game ball B1 flowing straight down the upstream passage around the branch space goes downward as it is, it enters the discharge passage.

In the branch space, a switching member is provided below the upstream passage and above the discharge passage. The switching member includes a rotation shaft, a plate-shaped switching piece that rotates around the rotation axis from an initial position to a displacement position, and the switching piece is switched from the initial position to the displacement position based on a signal from the main CPU 63. And a switching drive unit for switching the displacement position to the initial position. When the switching piece is in the initial position, the switching piece is in the first state in which the switching piece extends downward. In the first state, the discharge passage is opened upward. Therefore, the game ball B1 flowing down the upstream passage enters the discharge passage.

On the other hand, when the switching piece is in the displaced position, the switching piece is in the second state in which the switching piece extends diagonally forward left. In the second state, since the switching piece exists above the discharge passage, the game ball B1 discharged from the upstream passage comes into contact with the switching piece. In the second state, the contact surface of the switching piece with the game ball B1 is inclined downward toward the front. For this reason, the course of the game ball B1 that comes into contact with the switching piece moves forward. The V winning passage is formed in a mode in which the game ball B1 contacting the switching piece in the second state enters in front of the discharge passage. Therefore, when the switching drive unit switches the switching piece to the displacement position, the game ball B1 discharged from the upstream passage is guided to the V winning passage. The distribution winning apparatus includes a detection sensor for detecting the game ball B1 flowing down the V winning passage, and when the game ball B1 is detected by the detection sensor, the V winning is won.

The V winning passage is separated from the discharging passage by a plate-shaped partition member. The displacement position of the switching piece is set so that the distance from the free end of the switching piece at the displacement position to the upper end of the partition member is smaller than the diameter of the game ball B1. This prevents the game ball B1 from entering the discharge passage through the gap between the switching piece and the partition member in the second state where the switching piece is in the displaced position. In this configuration, an intermediate state occurs in which the distance from the free end of the switching piece to the upper end of the partition member is substantially the same as the diameter of the game ball B1 while the switching piece is switching from the initial position to the displacement position. In the intermediate state, when the game ball B1 discharged from the upstream passage enters the gap between the rotating switching piece and the partition member, the game ball B1 may be sandwiched between the switching piece and the partition member and stay there. There is.

The configuration described in the first embodiment can be applied to this configuration. Specifically, the distribution winning apparatus is provided with an escape passage adjacent to the discharge passage on the left side of the discharge passage. The entrance of the escape passage is provided at a position lower than the upper end of the partition member. The contact surface of the switching piece with the game ball B1 is inclined rearward toward the left, and the wall surface on the discharge passage side near the upper end of the partition member is inclined forward toward the left. That is, the two surfaces that come into contact with the game ball B1 in the intermediate state both have an inclination for pushing the game ball B1 toward the escape passage. Therefore, when the game ball B1 is in contact with the switching piece and the partition member in the intermediate state, the game ball B1 is pushed out to the escape passage as the switching piece moves to the displaced state. As a result, in the distribution winning device, it is possible to prevent the game ball B1 from being pinched without causing the game ball B1 to rise and stop. The escape passage merges with the discharge passage at an intermediate position of the discharge passage. When the game ball B1 is pushed toward the escape passage in the intermediate state in which the switching piece is switched, the game ball B1 flows down the escape passage and is guided to an intermediate position of the discharge passage. The game ball B1 guided to the escape passage is not detected by the detection sensor provided in the V winning passage. Therefore, when the game ball B1 is pushed into the escape passage in the intermediate state, the V winning is not generated, as in the case where the game ball B1 flows down the discharge passage.

The configuration described in the third embodiment can be applied to this configuration. Specifically, when the game ball B1 is in contact with the blade member 343 and the upright wall 352, the blade member 343 rotates around the rotation shaft 344 along with the rotation of the rotating body 340, and the blade It is possible to apply a configuration in which the game ball B1 is prevented from being pinched by the member 343 taking the displaced position. Specifically, the plate-shaped switching piece includes a fixed portion on the fixed end side and a rotatable portion on the free end side. A rotation shaft is provided on the free end side of the plate-shaped fixed portion, and the plate-shaped rotatable portion is connected to the fixed portion in a manner rotatable about the rotation shaft. When no external force is applied, the surface of the fixed portion of the switching piece is flush with the surface of the rotatable portion. The rotatable portion rotates downward when pushed downward from the outside, and returns to the original state by the restoring force of the biasing member when the force from the outside is removed. When the game ball B1 is in contact with the switching piece and the partition member in the intermediate state, the rotatable portion rotates downward as the switching piece moves to the displaced position. The restoring force of the biasing member is not so strong as to prevent the game ball B1 in contact with the partition member and the rotatable portion from dropping downward due to its own weight. Therefore, the game ball B1 that is temporarily in contact with the partition member and the rotatable portion does not get caught and stays, but moves downward by its own weight and enters the discharge passage. In the switching piece in the displaced position, the protruding length of the fixed portion above the discharge passage is such that the fixed portion alone can guide the game ball B1 to the V winning passage. In the state where the switching piece is in the displaced position, when the game ball B1 that has fallen from above collides with the rotatable portion, the rotatable portion rotates downward. However, the distance from the free end of the rotating movable portion to the upper end of the partition member is shorter than the diameter of the game ball B1 in both the state in which the rotating movable portion is not rotating and the state in which the rotating movable portion is rotating. Therefore, in the state where the switching piece is completely moved to the displacement position, the game ball B1 does not enter the gap between the free end of the rotatable portion and the upper end of the partition plate and enter the discharge passage. .. As described above, the switching piece is provided with the fixed portion, the rotating shaft, and the rotatable portion, and the rotatable portion is rotatable around the rotating shaft, whereby the game ball B1 is It is possible to enter the discharge passage without ascending and stopping.

(4) In the gaming machine in which the second operating port 34 is opened when the gaming ball B1 that has entered the trigger generating device is detected, the gaming ball B1 described in each of the above embodiments for the trigger generating device. A configuration for preventing the rising and stopping of the vehicle may be applied.

Specifically, the game area PA is composed of an upper area PA1, a left area PA2, a right area PA3, and a lower area PA4 of the variable display unit 36. The lower area PA4 is provided with the first actuation port 33, and the right area PA3 is provided with a trigger generation device and a special opening device.

In the right side area PA3, the special opening device is arranged below the trigger generation device. The trigger generating device includes a rotating body, a housing portion that stores the rotating body, a trigger generating drive unit that rotates the rotating body based on a signal from the main CPU 63, and a game ball in a trigger generating area of the trigger generating device. A trigger occurrence detection sensor that detects B1. The accommodating part includes a standing wall for partitioning the accommodating space. In the upper part of the accommodation portion, the left standing wall and the right standing wall are separated from each other, and the gap between the left standing wall and the right standing wall serves as the entrance of the trigger generating device. The entrance of the trigger generation device is an opening that is opened upward, and the width of the entrance is set to be slightly larger than the diameter of the game ball B1.

The game ball B1 can enter the opportunity generation device from the entrance. Along with the rotation of the rotating body, a state in which the game ball B1 can enter and a state in which the game ball B1 cannot enter occur at the entrance of the trigger generation device. The special opening device includes a special opening portion that is opened upward, an opening/closing member that can open the special opening portion and can close the special opening portion, and a main CPU 63. By driving the opening/closing member based on a signal, a special drive unit for opening and closing the special opening is provided.

The main CPU 63 executes a big hit lottery when a prize for the first working opening 33 is generated. When the jackpot result is reached in the jackpot lottery, the right is generated. In the right generation state, when the game ball B1 enters the trigger generation device and the game ball B1 is detected by the trigger generation detection sensor, the opening/closing period of the special opening device is started. Then, the game ball B1 is paid out when the ball enters the special opening that has been opened. If the preset reference time has elapsed while the opening/closing operation of the special opening device is being performed, or if the number of times the player has entered the special opening has reached the reference number, the opening/closing of the special opening device is performed. The period ends. Of these, if the preset reference time has elapsed while the opening/closing operation of the special opening device is being executed, the second opening/closing operation is executed by the special opening device.

In this configuration, when a rotating body having one or more recesses capable of accommodating the game ball B1 is used as the rotating body of the trigger generating device, when the game ball B1 enters the trigger generating device, it stands up with the rotating body. There is a possibility of being caught in the wall. On the other hand, the configuration described in the first embodiment can be applied to this configuration.

Specifically, on the surface of the game board, a passage entrance is provided at a position corresponding to the upper portion of the trigger generation device. In addition, the game board is formed with an escape passage for letting the game ball B1 entering from the passage entrance toward the rear and downward. The rotating body has a disk shape, and the peripheral surface of the rotating body excluding the recessed portion is inclined rearward in the axial direction. Therefore, the game ball B1 that has not been taken into the recessed portion in the upper part of the trigger generation device is guided to the passage entrance along the inclination of the peripheral surface of the rotating body. In the upper part of the trigger generation device, the contact surface of the standing wall with the game ball B1 is inclined rightward toward the rear. Also, the rotating body rotates clockwise. Therefore, when the game ball B1 is pressed against the standing wall from the rotating body in the upper part of the trigger generation device, the game ball B1 is guided along the slope of the standing wall and escapes toward the rear passage entrance. Therefore, when the game ball B1 is in contact with the rotating body and the standing wall in the upper part of the trigger generation device, the game ball B1 enters the passage entrance as the rotating body rotates. In this way, by applying the configuration of avoiding the trapping of the game ball B1 in the upper part of the trigger generation device, when the game ball B1 enters the trigger generation device, the game ball B1 rises or stops. Things have been avoided. The trigger occurrence detection sensor is provided inside the trigger generating device, and can detect only the game ball B1 taken into the trigger generating device. Therefore, even if the game ball B1 enters the passage entrance, the entrance does not trigger the opening and closing operation of the special opening device.

The configuration described in the second embodiment can be applied to this configuration. Specifically, when the game ball B1 comes into contact with the rotating body 230 and the upper right standing wall 252, the upper right standing wall 252 rotates around the rotation shaft 254 to take in the game ball B1. The possible configurations can be applied. Specifically, the standing wall includes a rotating shaft and a movable standing wall that is rotatable around the rotating shaft. The movable standing wall is located above the trigger generator, and defines the right end of the entrance of the trigger generator. The rotating body rotates clockwise. On the upper part of the opportunity generation device, the game ball B1 that is about to enter the opportunity generation device may be in contact with the rotating body and the movable standing wall. In this case, the game ball B1 is pushed toward the right side where the movable standing wall is present as the rotating body rotates. The movable standing wall can release the force of the rotating body pressing the game ball B1 against the movable standing wall by rotating about the rotation axis. Further, the contact surface of the movable upright wall with the game ball B1 is inclined rightward downward. For this reason, when the game ball B1 is pushed toward the contact surface by the rotating body, the movable standing wall rotates rightward and the game ball B1 is guided to the slope of the contact surface with the rotating standing wall. Are taken into the trigger generator. By avoiding that the game ball B1 that is in a state of temporarily contacting the rotating body and the movable standing wall is caught, it is possible to prevent the game ball B1 from rising and staying. In addition, when the game ball B1 taken into the trigger generation device after being temporarily in contact with the rotating body and the movable standing wall is detected by the trigger generation detection sensor, the opening/closing operation of the special opening device is performed. It will be an opportunity to start.

(5) The adjusting mechanism (adjusting mechanism 180, 220, 330, 430, 530, 620) in each of the above-described embodiments has a dischargeable period in which the game ball B1 can be discharged toward the first through gate 35 only for a certain period. It is not limited to the configuration that occurs in. For example, the adjustment mechanism has a gaming ball within a range that does not exceed the upper limit number (4) of numerical information that can be held by the normal electric power holding area HA (FIG. 13) at timings other than the dischargeable period that occur in a certain cycle. B1 may be discharged toward the first through gate 35.

In the first embodiment described above, in addition to the four recesses 183b to 183e (FIG. 4) arranged at equal intervals in the circumferential direction, the rotating body 183 may be provided with an additional fifth recess. Good. The said 5th recessed part has the same shape and size as the 1st recessed part 183b, the 2nd recessed part 183c, and the 3rd recessed part 183d, and can take in one game ball B1. In this case, in the first through gate 35, the game ball B1 discharged from any one of the four recesses 183b to 183e wins in a 1 sec cycle, and is taken into the fifth recessed part and is discharged in a 1 sec cycle. The game ball B1 discharged at a timing other than the possible period enters.

In the fifth embodiment described above, the open state of the adjusting unit 546 (FIG. 55) may occur in a cycle of 0.5 sec. When the game ball B1 enters the first through gate 35 in the winning continuation period of the low frequency support mode, the regular electric open lottery occurs in the regular electric open lottery once every two times. be able to. Further, in the fifth embodiment, the open state of the adjusting unit 546 (FIG. 55) that occurs in a cycle of 1 sec may be continued for 0.5 sec, which is longer than that in the fifth embodiment. In this case, a plurality of gaming balls B1 can be configured to be discharged toward the first through gate 35 in the once opened state. Here, the shortest firing interval in the game ball firing mechanism 27 is 0.6 sec. Therefore, in the one-time open state, the upper limit of the numerical information with which the normal electric power holding area HA can hold the number of gaming balls B1 that are discharged at a timing outside the original dischargeable period and win the first through gate 35 It can fit in the range that does not exceed the number.

The game ball B1 is configured to enter the first through gate 35 within a range not exceeding the upper limit number of numerical information that can be reserved by the normal electric power holding area HA even at timings other than the dischargeable period that occur in a 1 sec cycle. As a result, even in the non-winning continuous period of the low frequency support mode, it is possible to generate a single non-consecutive regular electric open winning. Therefore, even when the non-winning continuous period in the low frequency support mode continues for a long time, the player's expectation for the continuous winning period is increased every time the universal electric open win occurs, and the player is not bored. can do.

(6) In each of the above-described embodiments, the outlet 24a, the general winning opening 31, the special electric winning device 32, the first operating opening 33, and the second operating opening 34 are all targets for storing history information (or entry history). However, the present invention is not limited to this, and only a part of the outlet 24a, the general winning opening 31, the special electricity winning device 32, the first working opening 33, and the second working opening 34 is the storage target of the history information. The configuration may be set as follows. For example, the general winning opening 31, the special electric winning device 32, and the second working opening 34 may be the target of storing history information, or the general winning opening 31 may be the target of storing history information. Good. Even in this case, it is possible to grasp the entering mode of the game ball in the predetermined period for the entering part for which the history information is stored.

(7) In each of the above-described embodiments, information corresponding to the result of entering a game ball is transmitted in correspondence with each of the first winning opening detection sensor 42a, the second winning opening detection sensor 43a, and the third winning opening detection sensor 44a. Although the signal paths 118a to 118c for setting are set, the present invention is not limited to this, and the information corresponding to the ball entry result for the same type of ball entering portion is the same type of ball entering portion. There may be a plurality of ball entrance detection sensors and a plurality of ball entrance detection sensors corresponding thereto, or one kind of information may be transmitted. This makes it possible to reduce the number of types of information transmitted from the main CPU 63 to the management IC 66.

(8) In the first embodiment and the like, correspondence information indicating the correspondence between the types of information transmitted from the main CPU 63 to the management IC 66 and 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 advance in the management IC 66. In this case, since it is not necessary to execute the processing for causing the management IC 66 to recognize the correspondence information, it is possible to reduce the processing load of the main CPU 63.

(9) In the first embodiment and the like, the correspondence information indicating the correspondence between the types of information transmitted from the main CPU 63 to the management IC 66 and the buffers 122a to 122o is transmitted from the main CPU 63 to the management IC 66. However, the configuration is performed when the supply of operating power to the main CPU 63 is started, but the present invention is not limited to this. For example, bidirectional communication between the main CPU 63 and the management IC 66 is possible, and the management IC 66 handles it. The correspondence information may be 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 is used for both reading and writing, and the correspondence information provided from the main CPU 63 to the management IC 66 after the pachinko machine 10 is shipped to the main CPU 63. Even if the supply of the operating power is stopped, the correspondence memory 116 stores and holds it. This makes it possible to reduce the frequency with which the correspondence information is transmitted.

(10) In the first embodiment and the like, the correspondence information indicating the correspondence between the types of information transmitted from the main CPU 63 to the management IC 66 and the buffers 122a to 122o is transmitted from the main CPU 63 to the management IC 66. However, the configuration is performed using the signal paths 118a to 118g for transmitting the information of the detection results of the respective ball detection sensors 42a to 48a, but the present invention is not limited to this, and the correspondence information is mainly used. A dedicated signal path for transmitting from the side CPU 63 to the management IC 66 may be provided. As a result, the management IC 66 can grasp which type of information is being received from the main CPU 63 by the type of the buffers 122a to 122o that receives the information.

(11) In the first embodiment and the like, the main CPU 63 transmits information to the management IC 66, but the management IC 66 does not transmit information to the main CPU 63. However, the present invention is not limited to this. Instead, 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 be configured to directly execute the notification control of the notification means in the same manner as the seventeenth embodiment so that the notification corresponding to the contents of the received various parameters is performed. By transmitting a command corresponding to the contents of the various parameters received by the main CPU 63 to the sound emission control device 81, the display light emitting unit 53, the speaker unit 54, and the symbol display device 41 are used to change the contents of the various parameters. The configuration may be such that the corresponding notification is executed.

(12) 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, and the calculated parameters are calculated. The contents of various parameters may be notified by 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 entering mode of the game ball in the game area PA on the last business day is normal at the start of the game hall business.

(13) When various parameters calculated based on the history information stored in the history memory 117 are abnormal results, the pachinko machine 10 cannot start the game until the prohibition canceling operation is performed. May be As a configuration that prevents the game from being started, for example, a configuration in which the game ball is not allowed to be launched, the ball detection sensors 42a to 49a may be invalidated, and the first operation opening It is also possible to adopt a configuration in which the winning/non-winning determination processing is not executed even if a win is generated in 33 or the second operating port 34. Further, the prohibition canceling operation may be an operation of turning on the power of the pachinko machine 10 again while the RAM erasing switch is turned on, and can be operated when the gaming machine main body 12 is opened to the outer frame 11. Alternatively, the operation means may be operated. As a result, it is possible to prevent the game from being played as it is in a situation where the game ball in the game area PA is in an abnormal mode.

(14) Although history information corresponding to the detection results of the ball entrance detection sensors 42a to 48a is stored in the history memory 117, calculation of various parameters using the history information is performed by either the main CPU 63 or the management CPU 112. The configuration may be such that it is not executed. In this case, the history information may be read by the reading device electrically connected to the reading terminal 102, and the operator of the reading operation may calculate various parameters using the read history information. Of course, 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.

(15) The management IC 66 may not be provided, and the main CPU 63 may have the function of executing the storage process of the history information and the function of calculating various parameters in each of the above embodiments. The configuration may be included in the CPU 92, or may be included in the voice emission control device 81. When the payout side CPU 92 or the voice emission control device 81 is provided with these functions, the information of the detection result of each of the ball detection sensors 42a to 48a is transmitted from the main side CPU 63 to the control subject having the function. It will be.

(16) 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, the history information or the information of various parameters may be output. 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.

(17) The reading terminal 102 used to read the program from the main ROM 64 is also used as a terminal used to read the history information or various parameters by the reading device, but is not limited to this. Alternatively, the terminal used for reading the 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, the terminal used to read the 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.

(18) The correspondence memory 116, the history memory 117, and the operation result memory 631 in each of the above embodiments are not limited to the configuration provided as a non-volatile storage unit such as a flash memory. Any one of 116, 117, and 131 is provided as a volatile storage unit that requires power supply to store and hold information, and backup power is supplied to the memory, thereby operating power to the main CPU 63. The information may be stored and held even if the supply of the information is stopped. In this case, a dedicated backup power device may be provided for that memory, or a configuration in which backup power is supplied to the memory from a power supply/launch control device 78 that supplies backup power to the main RAM 65. Good.

(19) The history information is not limited to the configuration in which various parameters are calculated, the history information is not stored and held, and the game ball is detected by any of the ball-entry detection sensors 42a to 48a. Various parameters may be calculated and updated each time they are newly detected. In this case, although the frequency of calculation of various parameters increases, it becomes possible to extract various parameters at arbitrary timing.

(20) The management IC 66 includes the management-side CPU 112 as a general-purpose CPU and is not limited to the configuration in which the history-information storage processing and various parameter calculation processing are executed based on the programs and data stored in the management-side ROM 113. Alternatively, a hard circuit designed to have these functions may be formed in the management IC 66. More specifically, regarding the configuration, in the case of the first embodiment, for example, the hardware circuit receives a signal from the main CPU 63 indicating that one of the detection sensors 42a to 48a has detected a game ball. The correspondence relationship information corresponding to the buffer that received the signal is stored in the history memory 117 from the correspondence relationship memory 116, and the RTC 115 information at that time is stored in the history memory 117. To do. Further, for example, in the case of the fifteenth embodiment, when the hardware circuit receives from the main CPU 63 a signal indicating that one of the detection sensors 42a to 48a has detected a game ball, the hardware circuit receives the signal. The value of the counter corresponding to the buffer is incremented by 1. Further, the hardware circuit calculates various parameters by using the history information at the time when the calculation trigger in the first embodiment or the like occurs. Further, when an external output trigger to the reading terminal 102 is generated, the hardware circuit externally outputs various parameters that are calculation results and history information.

(21) In addition to or instead of the configuration in which the information on the detection results of the ball detection sensors 42a to 48a is stored as history information, the configuration in which the occurrence of the transition to the open/close execution mode is also stored as history information It is also possible to have a configuration in which the transition timing to the open/close execution mode and the end timing are stored as history information, and the configuration in which the occurrence of the transition to the high-frequency support mode is stored as history information, and a predetermined abnormality The occurrence of may be stored as history information. Further, by using the history information as described above, the transition probability to the open/close execution mode may be calculated, or the transition probability to the high-frequency support mode may be calculated. The frequency of occurrence may be calculated. The history information and various parameters may be read by a reading device.

(22) The main CPU 63 and the management IC 66 may be provided as separate chips, may be provided as a separate board, or may be provided as a separate control device.

(23) In the first embodiment and the like, the number of game balls to be entered into the out port 24a is measured, while the general prize hole 31, the special electric prize device 32, the first actuation port 33, and History information including RTC information may be stored for paying out prize balls of game balls such as the second operating port 34 or entering a privilege-triggered ball part that triggers the winning/non-winning determination process. As a result, it is possible to calculate the entry frequency of the game ball into each privilege-triggered ball portion with respect to the total number of discharged game balls, while enabling the entry history of the game ball into the bonus-triggered ball portion to be extracted. Become.

(24) The target to be left as history information may include those other than those in the above embodiments. For example, at least one of the timing when the lower tray 56a is full, the timing when the full tank is started, and the timing when the full tank is released may be stored as history information. At least one of the time when the non-ball state is started, the timing when the no-ball state is started, and the timing when the no-ball state is released may be stored as history information, and the payout device 76 is in an abnormal state. That is, at least one of the timing at which the abnormal state of the dispensing device 76 is started and the timing at which the abnormal state of the dispensing device 76 is released may be stored as history information. In this case, it becomes possible to grasp the occurrence frequency of these events.

(25) In the first embodiment and the like described above, the 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 16th buffer 122p corresponds to the output instruction signal is recognized by the management IC 66 when the type identification command is transmitted from the main CPU 63. It may be configured. In this case, it is not necessary to set the correspondence between the buffers 122a to 122p and the types of signals input to the buffers 122a to 122p in the management IC 66 in advance.

(26) The number of game balls entered into a predetermined ball-entering portion that has occurred when the front door frame 14 is in the open state is stored as history information, and the number of entered balls grasped by 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 the predetermined ball-in portion in the situation where the front door frame 14 is in the 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 entering portion that occurs when the front door frame 14 is in the open state is calculated when a predetermined calculation trigger occurs, and the calculated number of entered balls is an abnormal number. In some cases, the abnormality notification may be executed. As a result, it is possible to deal with an illegal act in which the front door frame 14 is illegally opened and the game ball is inserted into a predetermined ball entrance portion.

(27) The management IC 66 may be configured to send a normal operation signal to the main CPU 63 when operating normally. In this case, the main CPU 63 can monitor whether the management IC 66 is operating normally.

(28) In the first embodiment and 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 reversed from that of the first embodiment and the like. In this case, the order in which the main CPU 63 executes the processing for changing the output state of each signal and the order in which the management CPU 112 executes the confirmation processing for the buffers 122a to 122o match.

(29) When the 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 may be used. Only one of them may be externally output. In this case, the information to be analyzed can be selectively read by the reading device. As a configuration for selectively outputting the information to the outside, the main CPU 63 selects the information to be the external output target from the selection information received from the reading device through the reading terminal 102, and outputs the selected information to the outside. Can be considered.

(30) The 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 the history information and various parameters. For example, when an abnormality occurs, The history information of the abnormality occurrence may be stored and the stored history information may be externally output through the reading terminal 102.

(31) The detection sensors 42a to 48a are individually provided for each of the outlet 24a, the general winning opening 31, the special electric winning device 32, the first operating opening 33, and the second operating opening 34, and the detection sensors 42a to 48a are provided. The total number of game balls discharged from the game area PA is grasped by totaling the number of detected game balls, but the present invention is not limited to this. For example, all the game balls discharged from the game area PA. It is also possible to provide a passage area in which the game balls pass through one by one and to provide a discharge detection sensor for detecting the game balls passing through the passage area. 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, similarly to each of the above-described embodiments, a detection sensor for detecting the number of entered game balls of each of the general winning opening 31, the special electric winning device 32, the first operating opening 33, and the second operating opening 34. By providing 42a to 47a, it is possible to calculate the ratio of the number of game balls entered in each ball entering portion to the total number of game balls discharged from the game area PA.

(32) Display control based on a command transmitted from the main control device 60 instead of the configuration in which the display control device 82 is controlled by the sound emission control device 81 based on the command transmitted from the main control device 60. The device 82 may control the audio 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, both control devices may be provided as one control device, and the function of one of the both control devices may be provided. May be integrated in the main control device 60, and both functions of the both control devices may be integrated in the main control device 60. Further, 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.

(33) Other types of pachinko machines different from the above embodiments, such as a pachinko machine in which the electric accessory opens 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 the special device. The present invention can also be applied to a pachinko machine in which a right is generated and a big hit is generated, a pachinko machine provided with another accessory, an arrangement ball machine, a game machine such as a sparrow ball.

Further, a non-ball-ball type gaming machine, for example, a plurality of reels provided with a plurality of kinds of symbols in the circumferential direction is provided, the reel is started to rotate by inserting a medal and operating a start lever, and a stop switch is operated. After the reels stop after a predetermined time elapses, if a specific symbol or a combination of specific symbols is established on the effective line visible from the display window, a bonus such as payout of medals is given to the player. The present invention can be applied to a slot machine.

In addition, the game machine main body that is openably and closably supported by the outer frame is provided with a storage unit and a loading device, and the start lever is operated after a predetermined number of game balls stored in the storage unit are loaded by the loading device. The present invention can also be applied to a gaming machine in which a pachinko machine and a slot machine are combined, in which the reel starts to rotate.

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, the result of the lottery process of the winning combination executed when one game is started based on the operation of the start lever is history information. The actual winning probability of each winning combination may be calculated by using the history information, and when a transition to a special game state such as a bonus game occurs, it is stored as history information and the history thereof is stored. The information may be used to calculate the actual transition probability to the special game state, or the ratio of the number of stay games in the special game state to the total number of exhausted games may be calculated. Then, the history information and various parameters may be read by a reading device, or a notification corresponding to the calculation result of various parameters may be performed by the gaming machine itself.

(34) The characteristic configurations of the first to eighteenth embodiments may be mutually applied in any combination. For example, the characteristic configuration of the first embodiment, the characteristic configuration of the twelfth embodiment, and the characteristic configuration of the eighteenth embodiment may be combined, and the characteristic configuration of the second embodiment may be combined. The characteristic configuration of the embodiment, the characteristic configuration of the tenth embodiment, and the characteristic configuration of the fourteenth embodiment may be combined. Further, in addition to the configuration in which the characteristic configurations of the first to fifteenth embodiments are applied in a predetermined combination, the configuration in the other mode may be applied in an arbitrary combination.

<Regarding invention groups extracted from the above embodiments>
The features of the invention group extracted from each of the above-described embodiments will be described below, showing effects and the like as necessary. It should be noted that, in the following, for ease of understanding, the configuration corresponding to each of the above-described embodiments is appropriately shown in parentheses or the like, but is not limited to the specific configuration shown in brackets or the like.

<Feature A group>
Features A1. A ball entering portion (first through gate 35) into which a game ball flowing down the game area (game area PA) can enter.
A privilege granting means (a function of executing the processes of steps S705 and S706 in the main CPU 63) for granting a privilege on the condition that at least one of the game balls has entered the ball-in portion,
Equipped with
A first mode (low frequency support mode) and a second mode (high frequency support mode) in which the privilege is more likely to be granted than the first mode are set as the control modes of the privilege application status. ,
Guide means (adjusting mechanism 180, 220, 330, 430, 530, 620) for guiding the game ball toward the ball-in portion,
In the first mode, each guidance timing of the game ball guided by the guide means corresponds to the grant trigger timing at which the game ball guided to the entrance portion becomes the grant of the privilege, or A predetermined situation generating means (a function of executing the processes of steps S312 and S313 in the main CPU 63) that causes a predetermined situation (winning continuous period) that facilitates
A gaming machine characterized by being equipped with.

According to the characteristic A1, the first mode is less likely to be in the privilege granting state than the second mode. Therefore, in the first mode, the player's expectation that the privilege is being granted is low. In the configuration, as a situation that occurs in the first mode, a predetermined situation is provided in which the guide timing of the game ball guided by the guide means corresponds to or easily corresponds to the grant trigger timing. As a result, it is possible to give the player, who is performing the operation of launching the game ball in the first mode, an expectation that a predetermined situation may occur. In the first mode, it is possible to improve the interest of the game by suppressing a decrease in the player's expectation that the privilege will be granted.

Feature A2. A ball entering portion (first through gate 35) into which a game ball flowing down the game area (game area PA) can enter.
A privilege granting means (a function of executing the processes of steps S705 and S706 in the main CPU 63) for granting a privilege on the condition that at least one of the game balls has entered the ball-in portion,
Guide means (adjusting mechanism 180, 220, 330, 430, 530, 620) for guiding the game ball toward the ball-in portion,
Each of the guidance timings of the game balls guided by the guiding means at a predetermined time interval in the ball entrance portion is a grant trigger timing at which the game ball guided to the ball entrance portion triggers the grant of the privilege. A predetermined situation generating means (a function of executing the processing of steps S312 and S313 in the main CPU 63) that causes a predetermined situation (winning continuous period) that corresponds to or easily corresponds to
A gaming machine characterized by being equipped with.

According to the characteristic A2, all or part of the condition for granting the privilege is satisfied because the guidance timing is in a situation corresponding to the grant trigger timing or in a predetermined situation in which the guidance timing is easily supported. The predetermined situation is a situation in which the possibility of granting a privilege occurs each time the guide timing is reached, which is an advantageous situation for the player. With the configuration in which the predetermined situation occurs, it is possible to make the player aware of the occurrence of the predetermined situation even when the situation is not the predetermined situation, and to improve the interest of the game.

Features A3. The gaming machine according to feature A1 or A2, wherein the predetermined situation generating means generates the predetermined situation by changing the grant timing.

According to the characteristic A3, when the grant timing is changed and the guidance timing corresponds to the grant timing, or when the situation becomes easier to deal with, a predetermined situation occurs and the grant timing is changed. When the guidance timing does not correspond to the grant timing, the predetermined situation ends. By allowing the predetermined situation to occur without any sign, the player can be made aware of the predetermined situation at all times. By keeping the player's expectation for occurrence of the predetermined situation high, it is possible to improve the interest of the game.

Features A4. A first updating means for updating and storing numerical information (university electrical accessory release counter C4, a function of the main CPU 63 for executing the processing of step S202);
Second updating means for updating and storing numerical information for updating the initial value of the first updating means (opening initial value counter C5, function of executing step S113 in the main CPU 63, main CPU 63 A function of executing the processing of step S204),
Equipped with
The privilege granting means,
Based on the determination standard information (low frequency winning determination value table T1) in which the numerical information corresponding to the grant timing is set, the predetermined processing is performed using the numerical information stored in the first updating unit Means for executing the open lottery (function of executing the process of step S705 in the main CPU 63, function of executing the process of step S717 in the main CPU 63),
In the predetermined process, when the numerical value information stored in the first updating unit is a predetermined granting result (universal opening win) that is numerical value information corresponding to the grant timing, a unit for granting the privilege ( A function of the main CPU 63 to execute the processing of steps S410 and S411, a function of the main CPU 63 to execute the processing of steps S803 to S807),
Is equipped with
The game according to feature A3, characterized in that the predetermined situation generating means causes the predetermined situation by setting numerical information stored in the second updating means as an initial value of the first updating means. Machine.

According to the characteristic A4, by setting the numerical value information stored in the second updating means as the initial value of the first updating means, the timing of occurrence of the predetermined situation can be made irregular. By not knowing when the predetermined situation will occur, the player can be made aware of the predetermined situation at all times. By keeping the player's expectation for occurrence of the predetermined situation high, it is possible to improve the interest of the game.

Features A5. The predetermined situation generating means,
Means for executing a predetermined change process for changing the temporal front-rear relationship between the guide timing and the grant trigger timing to generate the predetermined situation every time the predetermined change timing is reached (step S312 in the main CPU 63). And a function for executing the process of step S313),
In the predetermined situation, when the change timing comes, an extension means for extending the predetermined situation by suspending the execution of the predetermined change process (a function of executing step S305 in the main CPU 63, a step in the main CPU 63) A function for executing the processing of S712),
The gaming machine according to any one of the features A1 to A4, characterized in that

According to the characteristic A5, the execution of the predetermined change process is postponed, so that the predetermined situation advantageous for the player is continued for a long time, and the predetermined situation can be made attractive. As a result, it is possible to increase the player's expectation of the predetermined situation and improve the interest of the game.

Features A6. A starting ball entering portion (first operating port 33, 581, second operating port 34, 582) into which a game ball flowing down in the game area can enter.
Means (function of executing the process of step S215 in the main CPU 63) for producing a state advantageous to the player on the condition that at least one of the game balls has entered the starting ball entering portion,
Equipped with
From the first predetermined state, the start-up ball input section is a first predetermined state (a closed state of the universal utility product 34a) in which the game ball is difficult or impossible to enter. Is also provided with an acceptance control means (a function of executing the universal figure universal control process in the main CPU 63) that can be switched to a second predetermined state (an open state of the universal electric accessory 34a) in which a game ball can easily enter. ,
As a control mode of the starting ball entering section by the acceptance control means, there are a first mode (low frequency support mode) and a second mode (high frequency support mode) which is more likely to be in the second predetermined state than the first mode. , Is set,
The privilege granting means executes a predetermined determination (universal opening lottery) with at least one condition that a game ball has entered the entrance portion, and a predetermined determination result (universal opening winning) in the predetermined determination. When it becomes, the means for bringing the starting ball entering portion into the second predetermined state (function of executing the processing of steps S407 to S411 in the main CPU 63) is provided as the privilege,
Any one of the characteristics A1 to A5, wherein the predetermined situation generating means causes the predetermined situation under the condition that the control mode of the starting ball entering portion is the first mode. Gaming machine described in.

According to the characteristic A6, in the first mode, the starting ball entering portion is less likely to be in the second predetermined state than in the second mode. Therefore, in the first mode, as compared with the second mode, the player's expectation for the game ball entering the starting ball entering portion is low. On the other hand, by adopting a configuration in which the predetermined situation occurs in the first mode, it is possible to increase the player's expectation that the game ball will enter the starting ball entering section in the first mode. .. Since the predetermined situation occurs on condition that the first mode is the first mode, it is possible to reduce the impression that the first mode is disadvantageous as compared with the second mode.

Features A7. The probability of occurrence of the predetermined situation includes the first mode including both the case where the control mode in the acceptance control unit is the second mode and the case where the control mode is not the predetermined situation. The gaming machine according to characteristic A6 is characterized in that the probability is set to be more advantageous to the player than the case.

According to the characteristic A7, when the second mode is compared with the entire first mode including both the case where the situation is the predetermined situation and the case where the situation is not the predetermined situation, the case where the situation is the second mode is the first mode. It is more advantageous to the player than the case. While maintaining the premise that the case of the second mode is more advantageous to the player than the case of the first mode, a predetermined situation is generated in the first mode, so that the game ball is started in the first mode. It is possible to prevent the player's expectation for entering the ball entering portion from being significantly lowered.

Feature A8. A launching means (playing ball launching mechanism 27) for launching a game ball toward the game area based on a launching operation by the player;
In the game area, as the ball-in portion, a first ball-in portion (first through) existing at a position where a ball can be generated when a player performs a firing operation of the launching means in a first firing mode. The gate 35) and a second ball entering portion (second ball) existing at a position where a ball can enter when the player performs the firing operation of the firing means in the second firing mode different from the first firing mode. Through gate 39) is provided,
The guiding means guides the game ball toward the first ball-in portion,
When the control mode in the acceptance control means is the first mode, it is more advantageous for the player to perform the firing operation in the first firing mode than to perform the firing operation in the second firing mode, Characteristic A7 characterized in that in the second mode, performing a firing operation in the second firing mode is more advantageous to the player than performing a firing operation in the first firing mode Game machine.

According to the characteristic A8, when the number of ball entry portions is one, even when the control mode in the acceptance control means is the second mode, the game ball is guided to the guide means to enter the ball entry portion. Need to occur. Therefore, the game ball not guided by the guiding means cannot enter the ball entering portion. On the other hand, by providing the second ball entering portion different from the first ball entering portion provided with the guiding means, in the second mode, the game ball is moved to the first ball without passing through the guiding means. 2 It is possible to enter the ball into the ball entry section. This can increase the frequency with which the predetermined determination is executed in the second mode.

In addition, by changing the firing mode depending on the situation, it is advantageous for the player so that the player's consciousness of participation can be increased and the interest of the game can be improved as compared with the configuration in which the same firing mode is continued. Can be planned.

Feature A9. The privilege granting means determines the predetermined determination in the first mode when the predetermined determination result is obtained in the predetermined determination when the control mode in the acceptance control means is the second mode. Any of the characteristics A6 to A8, characterized in that the starting ball entering portion is set to the second predetermined state in a mode in which a game ball enters the starting ball entering portion more easily than when the predetermined determination result is obtained. The gaming machine described in 1.

According to the characteristic A9, when the predetermined situation occurs in the first mode, which is originally more disadvantageous to the player than the second mode, a predetermined determination result is obtained in the predetermined determination each time the game ball enters the ball entry section. Become. For this reason, in the case of the first mode and the predetermined situation, the starting ball entering portion may be in the second predetermined state at a higher frequency than in the case of the second mode. On the other hand, when the predetermined determination result of the second mode is the predetermined determination result, the starting ball entering portion is in the second predetermined state when the predetermined determination result of the first mode is the predetermined determination result. In the configuration, the starting ball entering portion is more likely to enter the starting ball entering portion than the aspect in which the starting ball entering portion is in the second predetermined situation. As a result, between the frequency of the game ball entering the starting ball entering section in the second mode and the frequency of the game ball entering the starting ball entering section in the first mode and in the predetermined situation. Balance can be achieved.

Feature A10. The guiding means is
A guide part (near the intake port 185, near the intake port 262, the upper part of the adjustment mechanisms 330 and 430, near the adjustment part 546) where a game ball flowing down the game area can reach.
Means for guiding the game ball that has reached the guide unit toward the ball entrance unit at a guideable timing (timing in a take-in permission state) at which the guide unit can guide the game ball toward the ball entrance unit (Rotating body 183, 230, 340, 440),
Discharging means (peripheral surfaces 188a to 191a of the blade portions 188 to 191) for discharging the game balls reaching the guiding portion at a timing different from the guideable timing to a region different from the ball entering portion,
The gaming machine according to any one of the features A1 to A9, characterized in that the gaming machine is provided.

According to the characteristic A10, since the game ball that has reached the guide portion can be discharged at a timing different from the guideable timing, it is possible to prevent the game ball that has not been taken into the guide means from staying near the guide portion. As a result, the vicinity of the guide portion can be kept in a state where the game ball that has reached the guide portion at the guideable timing is easily guided toward the ball entering portion.

Features A11. The discharge means is provided with means (peripheral surfaces 188a to 191a of the blade portions 188 to 191) for discharging the game balls reaching the guide portion at a timing different from the guideable timing to the outside of the guide means. The gaming machine described in the characteristic A10.

According to the characteristic A11, the game ball that has reached the guide portion at a timing different from the guideable timing is discharged to the outside of the guide means by the guide portion, thereby suppressing the game ball from staying near the guide portion. be able to. Thereby, in the guide unit, it is possible to reduce the possibility that the guide of the game ball that is the guide target to the ball entry unit is blocked by the game ball that is not the guide target.

Feature A12. The discharging means is
A space in which a game ball can flow down, and a flow-down space (a space provided on the left and right of the adjusting mechanism 180, 430, 530, 620) provided around the guiding means in the game area. Space provided on the left side of 220),
It is provided in the game area with an interval that allows the game ball guided to the guide section to flow down into the flow-down space at a timing different from the guideable timing between the guide means. , Ball guide means (nail 24b, left guide nail 291, right guide nail 292, downstream guide nail 371, guide nail 472) for guiding a game ball flowing down in the game area toward the guide portion,
The gaming machine according to the feature A10 or A11, which is characterized by comprising:

According to the characteristic A12, the possibility that the game balls are retained in the vicinity of the guide part is reduced by adopting a configuration in which the game balls that are guided to the guide part and have not been taken in by the guide means flow down the flow-down space toward the downstream side. can do. In addition, since the game ball can be guided to the guide portion by the ball guide means, it is possible to reduce the possibility that the guide means guides the game ball toward the ball entrance portion.

Feature A13. Any one of the characteristics A10 to A12 characterized in that the discharging means is provided with an auxiliary passage (escape passage 172) into which the game ball reaching the guiding portion can enter at a timing different from the guiding possible timing. The gaming machine described in 1.

According to the characteristic A13, by arranging the game ball that has arrived at the guide portion at a timing different from the guideable timing to move to another place through the auxiliary passage, the game ball reaches the guide portion and moves to another place. It is possible to avoid the game ball that has reached the guide part from staying around the guide part while avoiding that the game ball that is in the middle of collision collides with another game ball that is flowing down the game area.

Features A14. The boundary on the rear side of the game area is defined by a plate-shaped area defining means (game board 24, 610),
The gaming machine according to feature A13, wherein the auxiliary passage allows a game ball to pass behind a front surface of the area defining means.

According to the characteristic A14, the auxiliary passage is defined by the configuration in which the game ball that has reached the guide portion at a timing different from the guideable timing is discharged toward the rear of the front surface of the area defining means. Can be prevented from colliding with another game ball flowing down the game area and disturbing the course of the game ball.

Feature A15. The feature A14 is characterized in that the auxiliary passage is provided with a passage outlet (passage outlet 173) for discharging the game ball flowing down the auxiliary passage toward the game area in front of the area defining means. Game machine.

According to the characteristic A15, in a configuration in which the game ball that has entered the auxiliary passage does not return to the game area, there is a possibility that the game ball that flows down the guide means will run short. On the other hand, by adopting a configuration in which the game ball flowing down the auxiliary passage returns from the passage outlet to the game area, it is possible to reduce the possibility that the number of game balls flowing down the downstream of the guiding means decreases.

Feature A16. In the game area, a game ball discharged from the passage outlet toward the game area is prevented from colliding with a game ball flowing down from the passage area upstream from the passage outlet. A game machine according to Feature A15, characterized in that a collision prevention means (exit roof 174) is provided.

According to the characteristic A16, the game ball that is about to return to the game area from the passage exit collides with the game ball that has flowed down from the upstream of the passage exit in the game area and is returned to the auxiliary passage again. Can be blocked.

Feature A17. The game machine according to any one of features A13 to A16, wherein the movement of the game ball passing through the auxiliary passage is visible from the outside.

According to the characteristic A17, by making the movement of the game ball in the auxiliary passage visible from the outside, it is possible to avoid that the movement of the game ball cannot be followed by the eye as soon as the game ball enters the auxiliary passage. In particular, in the structure where the game ball returns to the game area after passing through the auxiliary passage, the player can continuously see the movement of the game ball, so that the player can see the ball once entering the auxiliary passage. The game ball can be configured so as not to cause an uncomfortable feeling that the game ball suddenly returns to the game area.

Features A18. The guiding means is
Entry blocking means (left standing walls 181c, 181h, right standing wall 181d, upper right standing wall 252, left standing wall 261) for preventing the game ball flowing down toward the guiding means from entering the inside of the guiding means. , Standing wall 352),
Rotating means (rotating body) that is rotatable and is provided with taking-in means (concave portions 183b to 183e, step surfaces 241a to 244a, and blade members 343) that can take in and hold the game ball in the guiding means. 183, 230, 340, 440),
By rotating the rotating means, a rotation control means (a function for executing the process of step S206 in the main CPU 63, a drive portion 184 for adjustment) that conveys the game balls taken into the guiding means,
Is equipped with
The entry blocking means includes a take-in opening (a take-in opening 185) as an opening capable of taking the game ball reaching the guiding section into the guiding means.
The discharge means discharges the game ball in a state of being in contact with both the rotation means and the entry blocking means at the intake opening so that the game ball enters the auxiliary passage. Therefore, it is equipped with avoiding means (first front surface 188b, second front surface 189b, third front surface 190b, fourth front surface 191b, right standing wall 181d) for avoiding the game ball being caught. The gaming machine according to any one of the features A13 to A17.

According to the characteristic A18, by ejecting the game ball that is in contact with the rotation means and the entry blocking means at the intake opening so that the game ball enters the auxiliary passage, It is possible to avoid the game ball being caught and stopped. Further, by avoiding the game ball being caught, it is possible to reduce the maintenance burden that the manager of the game hall must perform.

Features A19. The avoidance means, when the rotation means rotates with respect to the game ball in a state of being in contact with both the rotation means and the entry blocking means at the intake opening, the auxiliary passage The gaming machine according to Feature A18, characterized by applying a force toward the entrance.

According to the characteristic A19, by rotating the rotating means, the state in which the game ball is in contact with both the rotating means and the entry blocking means at the intake opening is eliminated. Therefore, there is no need for a dedicated configuration for avoiding trapping of the game ball. As a result, the manufacturing cost can be suppressed while avoiding the complication of the configuration, and the degree of freedom in arranging the guide means can be ensured while avoiding the size increase of the guide means.

Feature A20. The avoiding means is means for applying a force including a downward component to the game ball when the game ball is in contact with both the rotating means and the entry blocking means (front surface 188b). ~ 191b of inclination), the gaming machine according to the characteristic A18 or A19.

According to the characteristic A20, a force having a downward component is applied to the game sphere that is in contact with both the rotation means and the entry blocking means. As a result, it is possible to avoid a situation in which the game ball that is in contact with both the rotating means and the entry blocking means is pushed out upward and the flow of the upstream game ball is disturbed.

Feature A21. The discharge means includes a passage inlet (passage inlet 171) as an opening that allows a game ball to enter the auxiliary passage,
The take-in means includes means (inclination of inner walls of the recessed portions 183b to 183e) for preventing the game ball taken into the guide means by the take-in means from moving toward the entrance for passage. The gaming machine according to any one of features A18 to A20 characterized by being present.

According to the feature A21, it is possible to reduce the possibility that the game ball taken in by the taking-in means will be guided into the auxiliary passage from the passage entrance before it is guided to reach the entering portion. As a result, it is possible to suppress a decrease in the number of game balls guided to the ball entering portion by the guiding means.

Feature A22. The guiding means is
A take-in opening (take-in port 262) that allows the game ball flowing down toward the guide means to enter the inside of the guide means.
Opening partition means (upper right upright wall 252, left upright wall 261) for partitioning the intake opening,
Rotating means (rotating bodies 230, 340) that are rotatable and are provided with a conveying means (step surfaces 241a to 244a, a blade member 343) that conveys the game balls taken inside the guiding means inside the guiding means. )When,
By rotating the rotating means, a rotation control means (a function for executing the process of step S206 in the main CPU 63, a drive portion 184 for adjustment) that conveys the game balls taken into the guiding means,
The game ball is provided around the intake opening, and is deformed when the game ball is in contact with both the rotation means and the opening partition means at the intake opening, and the game ball is deformed. Deformation means (upper right upright wall 252, vane member 343, rotation shafts 254, 344) capable of escaping the force of sandwiching the
The gaming machine according to any one of the features A1 to A21, which is characterized by comprising:

According to the characteristic A22, it is possible to avoid a situation in which the game ball is sandwiched between the rotation means and the opening partition means and stays due to the deformation of the intake permission means around the intake opening.

Feature A23. The deformation means includes means (upper right upright wall 252, rotating shaft 254) that allows the force applied to the opening defining means to be released by temporarily displacing the opening defining means to a predetermined position. The game machine according to feature A22, which is characterized by being.

According to the characteristic A23, the game ball is in contact with both the rotating means and the opening defining means, and the opening is made when the game ball is pushed toward the opening defining means as the rotating means rotates. By temporarily displacing the partition means to a predetermined position, it is possible to avoid a situation where the game ball is caught and stays.

Feature A24. The deforming unit includes a unit (a blade member 343, a rotating shaft 344) that allows the force applied to the rotating unit to escape by temporarily displacing a part of the rotating unit to a specific position. The gaming machine according to feature A22 or A23, which is characterized by being.

According to the characteristic A24, when the game ball is in contact with both the rotating means and the opening defining means, and a situation in which a force is applied to the rotating means and the opening defining means as the rotating means rotates In addition, by partially displacing the rotating means to a specific position and escaping the force of pinching the game ball, it is possible to avoid the situation where the game ball is caught and stays.

Feature A25. The guiding means is
Rotating means (rotating body) that is rotatable and is provided with taking-in means (concave portions 183b to 183e, step surfaces 241a to 244a, and blade members 343) that can take in and hold the game ball in the guiding means. 183, 230, 340, 440),
By rotating the rotating means, a rotation control means (a function for executing the process of step S206 in the main CPU 63, a drive portion 184 for adjustment) that conveys the game balls taken into the guiding means,
At the timing before the timing at which the up and down movement direction of the capturing means is switched from the downward direction to the upward direction, the discharge for discharging the game ball being conveyed by the capturing means toward the ball entering portion. Means (exhaust ports 256, 621),
The gaming machine according to any one of the features A1 to A24, which is characterized by comprising:

According to the characteristic A25, in the case of a configuration in which the game sphere being conveyed by the take-in means is released at the timing when the up and down moving direction of the take-in means is switched from the downward direction to the upward direction, the game ball in the ejecting means When the release timing of the game is delayed, the game ball being conveyed by the take-in means may start rising in the guide means. On the other hand, by adopting a configuration in which the game balls being conveyed by the take-in means are discharged at a timing before the timing when the up-and-down moving direction of the take-in means is switched from the downward direction to the upward direction, the game is played. It is possible to reduce the possibility that the game ball will rise in the guide means when the discharge timing of the ball is delayed.

Feature A26. The guiding means prevents the game ball taken into the guiding means and conveyed by the taking-in means from dropping downward and being thrown out of the guiding means by the rotation of the rotating means. Equipped with fall prevention means (left standing wall 181h, right standing wall 181d),
The discharge means is provided with a discharge opening (discharge port) provided in the fall prevention means so that the game balls conveyed in contact with the fall prevention means are discharged toward the outside of the guiding means. 621) is provided. The gaming machine according to Feature A25.

According to the characteristic A26, the game ball is conveyed while being in contact with the fall prevention means, and is discharged toward the outside of the guiding means when reaching the discharge opening. Since the position of the discharge opening in the fall prevention means is fixed, the position at which the game ball is discharged from the guiding means can be the same every time. Further, since the timing at which the rotating means guides the game ball to the discharge opening is determined according to the rotation mode of the rotating means, the timing at which the game ball is discharged from the guiding means can be the timing set at the design stage.

Feature A27. The gaming machine according to feature A26, wherein the discharge opening has a direction in which a game ball discharged from the discharge opening is directed toward the entrance ball portion at an edge of the discharge opening.

According to the characteristic A27, when the game ball is discharged from the discharge opening, it comes into contact with the edge of the discharge opening and is discharged toward the ball entering portion. By fixing the position at which the game ball is discharged from the guiding means and the direction in which it is discharged, it is possible to increase the probability that the game ball discharged from the guiding means reaches the ball entry portion.

Feature A28. The discharging means, at a discharging position for discharging the game ball in the guiding means, a direction changing means (a discharging projection 181e, for changing the moving direction of the game ball reaching the discharging position to the moving direction for discharging). The gaming machine according to any one of the features A25 to A27, which is provided with a discharge protruding end 263a).

According to the characteristic A28, the direction changing means changes the moving direction of the game ball at the discharge position to the moving direction for discharging the game ball, so that the discharge position is changed without the game ball being discharged from the discharging means. You can suppress passing by. As a result, it is possible to prevent the game balls that have not been released at the release position from rising in the guide means.

Feature A29. The direction changing means protrudes to an intermediate position in the front-rear direction of the game area in a manner capable of contacting the game ball guided by the rotating means,
The gaming machine according to feature A28, wherein the rotating means includes contact avoiding means (collision avoiding groove 192) for avoiding contact with the protruding direction changing means.

According to the feature A29, by contacting the game ball guided by the rotating means without disturbing the rotation of the rotating means, the moving direction of the game ball is changed at the discharge position to promote the discharge of the game ball. be able to.

Feature A30. The direction changing means is provided with means (right side surface 181g for discharge) that guides the game ball that has come into contact with the direction changing means at the discharge position toward the ball entering portion. A game machine described in A29.

According to the characteristic A30, since the discharge direction of the game ball is directed to the ball entrance portion at the discharge position, it is possible to increase the probability that the game ball discharged from the guiding means at the discharge position reaches the ball entrance portion. ..

Feature A31. The guiding means is
Direction defining means (guide passage 545) for defining the discharge direction of the game ball toward the ball entering portion,
In the direction defining means, the game ball is located upstream of the direction of flow of the game ball in the direction defining means, and when the game ball is opened, the game ball can enter the direction defining means and is closed. By means of the opening and closing means (adjustment unit 546) that makes it impossible for the game ball to enter.
The gaming machine according to any one of features A1 to A30, which is characterized by comprising:

According to the feature A31, by simplifying the structure of the guiding means, the volume of the guiding means occupying the game area can be suppressed. As a result, it is possible to increase the choices of places where the guide means is arranged in the game area and increase the degree of freedom in design.

Feature A32. The guiding means discharges the game ball toward the ball-in portion,
There is a case where the game ball discharged from the guiding means is allowed to flow down toward the ball entering portion and a case where the game ball is not allowed to flow toward the ball entering portion. (Electric nail 560) is provided, The gaming machine of any one of the features A1 to A31.

According to the characteristic A32, a part of the game ball released from the guiding means toward the ball entrance part comes off the ball entrance part. By determining whether or not the game ball released from the guide means enters the ball entering portion, the movement of the game ball after being released from the guide means is regarded as one of the player's interests. , It is possible to raise the degree of attention to the movement of the game ball around the guiding means and improve the interest of the game.

Feature A33. The route adjusting means,
Change execution means (electric nail 560) for changing the course of the game ball when it comes into contact with the game ball,
Moving the change execution means so that the game ball released from the guide means comes into contact with the change execution means, and the change so that the game ball released from the guide means does not come into contact with the change execution means. A path adjusting drive means (nail drive part 560a) capable of moving the execution means;
A gaming machine according to feature A32, which is characterized by comprising:

According to the characteristic A33, the volume occupied by the path adjusting means is made by moving the change executing means so as to create a state in which the game ball can flow down toward the ball entering portion and a state in which it cannot flow down. Can be suppressed and the degree of freedom in design can be increased.

Feature A34. The guiding means is
Means (first support surface 241, second support surface 242, third support surface 243) for discharging the game ball so that the discharged game ball comes into contact with the path adjusting means,
A means (fourth support surface 244) for discharging the game ball so that the discharged game ball does not come into contact with the path adjusting means,
The gaming machine according to the feature A32 or A33, which is characterized by comprising:

According to the characteristic A34, the guiding means is configured to discharge the game balls in a plurality of ways, so that the game balls that are discharged from the guiding means and enter the ball-entering portion and the game balls that do not enter are generated. be able to. Further, in the guide means, the game ball released from the guide means enters the ball by making the ratio of the release mode in which the released game ball comes into contact with the path adjusting means and the release mode in which the released game ball does not come into contact, to be constant. It is possible to make the ratio of entering the part and the ratio of not entering the part close to the ratio set in the design stage.

Feature A35. The guiding means discharges the game ball toward the ball-in portion,
Any of the characteristics A1 to A34, wherein the ball-in portion is provided in the game area at a position apart from the position where the discharge of the game ball is started by the guiding means by at least the diameter of the game ball. The gaming machine described in 1.

According to the characteristic A35, the game ball can pass between the position where the discharge of the game ball is started by the guiding means and the ball entering portion. Therefore, there is a possibility that the game ball released from the guiding means will not enter the ball entering portion. By determining whether or not the game ball released from the guide means enters the ball entering portion, the movement of the game ball after being released from the guide means is regarded as one of the player's interests. , It is possible to raise the degree of attention to the movement of the game ball around the guiding means and improve the interest of the game.

Feature A36. The guiding means discharges the game sphere from a predetermined discharge start position in a predetermined discharge direction so that the game sphere reaches the ball-in portion.
The ball-in portion has an opening having an inclination substantially orthogonal to the moving direction of the game ball discharged from the guiding means and flowing down to the height position of the ball-in portion. The gaming machine according to any one of features A1 to A35.

According to the characteristic A36, it is possible to increase the possibility that the game ball discharged from the guiding means and reaching the ball entrance portion will enter the ball entrance portion without contacting the edge of the ball entrance portion. As a result, it is possible to reduce the possibility that the game ball discharged from the guiding means collides with the edge of the ball entering portion and the ball entering timing is shifted or the game ball is separated from the ball entering portion.

In addition, with respect to the configurations of the features A1 to A36, the features A1 to A36, the features B1 to B12, the features C1 to C12, the features D1 to D3, the features E1 to E11, the features F1 to F41, the features G1 to G20, and the features H1 to H1. Any one or a plurality of configurations of H19, features I1 to I7, features J1 to J4, features K1 to K10, and features L1 to L7 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

According to the invention related to the characteristic group A, the following problems can be solved.

As gaming machines, pachinko gaming machines and slot machines are known. It is known that these gaming machines perform a lottery using numerical information when a predetermined lottery condition is satisfied, and give a bonus to the player according to the result of the lottery.

For example, in a pachinko gaming machine, when a game ball enters a ball entering portion provided in the game area, numerical information is acquired from updating means for updating numerical information for lottery, and the acquired numerical information is It is determined whether or not it corresponds to the winning information. In addition, a configuration is known in which numerical information is acquired based on the satisfaction of a predetermined acquisition condition, and specific performance and notification are performed based on the result of a lottery performed using the numerical information.

Here, novel game contents are required in the game machines as illustrated above, and there is still room for improvement in this respect.

<Feature B group>
Feature B1. A predetermined area of the game ball that has reached the guiding part (near the take-in port 185, near the take-in port 262, the upper part of the adjusting mechanism 330, 430, near the adjusting part 546) at the guideable timing (timing in the take-in permitted state). Guiding means (adjusting mechanism 180, 220, 330, 430, 530, 620) capable of guiding toward the first through gate 35, the first operating port 33, 581),
Discharging means (peripheral surfaces 188a to 191a of the blade portions 188 to 191) for discharging the game balls reaching the guiding portion at a timing different from the guideable timing to a region different from the predetermined region,
A gaming machine characterized by being equipped with.

According to the feature B1, by discharging the game ball that has reached the guide portion at a timing different from the guideable timing, it is possible to prevent the game ball that has not been guided from staying near the guide portion. As a result, the vicinity of the guide portion can be kept in a state where the game ball that has reached the guide portion at the guideable timing is easily guided.

Feature B2. The discharge means is provided with means (peripheral surfaces 188a to 191a of the blade portions 188 to 191) for discharging the game balls reaching the guide portion at a timing different from the guideable timing to the outside of the guide means. The gaming machine described in the feature B1.

According to the characteristic B2, by discharging the game ball that has arrived at the guide portion at a timing different from the guideable timing to the outside of the guide means by the guide portion, it is possible to prevent the game ball from staying near the guide portion. be able to. As a result, in the guiding unit, it is possible to reduce the possibility that the guidance of the game ball that is the guidance target to the predetermined area is blocked by the game ball that is not the guidance target.

Feature B3. The discharging means is
It is a space in which a game ball can flow down, and is provided on the left and right sides of a flow-down space (adjustment mechanism 180, 430, 530, 620) provided around the guide means in a game area (game area PA). Space, a space provided on the left side of the adjusting mechanism 220),
It is provided in the game area with an interval that allows the game ball guided to the guide section to flow down into the flow-down space at a timing different from the guideable timing between the guide means. , Ball guide means (nail 24b, left guide nail 291, right guide nail 292, downstream guide nail 371, guide nail 472) for guiding a game ball flowing down in the game area toward the guide portion,
The gaming machine according to the feature B1 or B2, which is provided with.

According to the feature B3, the possibility that the game ball stays in the vicinity of the guide part is reduced by configuring the game ball that is guided by the guide part and is not taken in by the guide means to flow down the flow-down space toward the downstream side. can do. In addition, since the game ball can be guided to the guide portion by the ball guide means, it is possible to reduce the possibility that the game ball that the guide means guides toward the predetermined area is insufficient.

Feature B4. Any of the features B1 to B3 characterized in that the discharge means is provided with an auxiliary passage (escape passage 172) into which the game ball that has reached the guide portion can enter at a timing different from the guideable timing. The gaming machine described in 1.

According to the feature B4, by arranging the game ball that has arrived at the guide section at a different timing from the guideable timing to another location by the auxiliary passage, it reaches the guide section and moves to another location. It is possible to avoid the game ball that has reached the guide part from staying around the guide part while avoiding that the game ball that is in the middle of collision collides with another game ball that is flowing down the game area.

Feature B5. The boundary on the rear side of the game area (game area PA) is defined by plate-shaped area defining means (game boards 24, 610),
The game machine according to feature B4, wherein the auxiliary passage allows the game ball to pass behind the front surface of the area defining means.

According to the feature B5, the auxiliary lane is divided by arranging the game ball that has arrived at the guide portion at a timing different from the guideable timing to be discharged rearward from the front surface of the area defining means. Can be prevented from colliding with another game ball flowing down the game area and disturbing the course of the game ball.

Feature B6. The feature B5 is characterized in that the auxiliary passage is provided with a passage outlet (passage outlet 173) for discharging the game ball flowing down the auxiliary passage toward the game area in front of the area defining means. Game machine.

According to the feature B6, in a configuration in which the game ball that has entered the auxiliary passage does not return to the game area, there is a possibility that the game ball that flows down the guide means will be insufficient. On the other hand, by adopting a configuration in which the game ball flowing down the auxiliary passage returns from the passage outlet to the game area, it is possible to reduce the possibility that the number of game balls flowing down the downstream of the guiding means decreases.

Feature B7. In the game area, a game ball discharged from the passage outlet toward the game area is prevented from colliding with a game ball flowing down from the passage area upstream from the passage outlet. The game machine according to Feature B6, which is provided with a collision prevention unit (exit roof 174) for the use.

According to the feature B7, the game ball that tries to return to the game area from the passage exit collides with the game ball that has flowed down from the upstream of the passage exit in the game area and is returned to the auxiliary passage again. Can be blocked.

Feature B8. The game machine according to any one of features B4 to B7, wherein the movement of the game ball passing through the auxiliary passage is visible from the outside.

According to the feature B8, by making the movement of the game ball in the auxiliary passage visible from the outside, it is possible to avoid that the movement of the game ball cannot be followed by the eye as soon as the game ball enters the auxiliary passage. In particular, in the structure where the game ball returns to the game area after passing through the auxiliary passage, the player can continuously see the movement of the game ball, so that the player can see the ball once entering the auxiliary passage. The game ball can be configured so as not to cause an uncomfortable feeling that the game ball suddenly returns to the game area.

Feature B9. The guiding means is
Entry blocking means (left standing walls 181c, 181h, right standing wall 181d, upper right standing wall 252, left standing wall 261) for preventing the game ball flowing down toward the guiding means from entering the inside of the guiding means. , Standing wall 352),
Rotating means (rotating body) that is rotatable and is provided with taking-in means (concave portions 183b to 183e, step surfaces 241a to 244a, and blade members 343) that can take in and hold the game ball in the guiding means. 183, 230, 340, 440),
By rotating the rotating means, a rotation control means (a function for executing the process of step S206 in the main CPU 63, a drive portion 184 for adjustment) that conveys the game balls taken into the guiding means,
Is equipped with
The entry blocking means includes a take-in opening (a take-in opening 185) as an opening capable of taking the game ball reaching the guiding section into the guiding means.
The discharging means discharges the game sphere, which is in contact with both the rotating means and the entry blocking means, at an area different from the predetermined area at the intake opening. B1 which is provided with avoiding means (first front surface 188b, second front surface 189b, third front surface 190b, fourth front surface 191b, right upright wall 181d) for avoiding being caught. A gaming machine according to any one of to B8.

According to the feature B9, the game ball is brought into contact with the rotating means and the entry blocking means at the take-in opening, and the game ball is sandwiched by discharging the game ball into a region different from the predetermined region. It is possible to avoid stopping. Further, by avoiding the game ball being caught, it is possible to reduce the maintenance burden that the manager of the game hall must perform.

Feature B10. The avoidance means, when the rotation means rotates with respect to the game ball in a state of being in contact with both the rotation means and the entrance blocking means at the intake opening, the predetermined area and The game machine according to Feature B9, wherein forces are applied to different areas.

According to the characteristic B10, by rotating the rotating means, the state in which the game ball is in contact with both the rotating means and the entry blocking means at the intake opening is eliminated. Therefore, there is no need for a dedicated configuration for avoiding trapping of the game ball. As a result, the manufacturing cost can be suppressed while avoiding the complication of the configuration, and the degree of freedom in arranging the guide means can be ensured while avoiding the size increase of the guide means.

Feature B11. The avoiding means is means for applying a force including a downward component to the game ball when the game ball is in contact with both the rotating means and the entry blocking means (front surface 188b). The game machine according to the feature B9 or B10, characterized in that the gaming machine is provided with an inclination of ~191b).

According to the feature B11, a force having a downward component is applied to the game sphere that is in contact with both the rotation means and the entry blocking means. As a result, it is possible to avoid a situation in which the game ball that is in contact with both the rotating means and the entry blocking means is pushed out upward and the flow of the upstream game ball is disturbed.

Feature B12. The discharging means is
An auxiliary passage (escape passage 172) in which the game ball that has reached the guide portion can enter at a timing different from the guideable timing,
A passage entrance (passage entrance 171) that is an opening that allows a game ball to enter the auxiliary passage,
Is equipped with
The take-in means is provided with means (inclination of inner walls of the recessed portions 183b to 183e) for preventing the game ball taken into the guide means by the take-in means from moving toward the entrance for passage. The gaming machine according to any one of features B9 to B11.

According to the feature B12, it is possible to reduce the possibility that the game ball taken into the taking-in means will be guided into the auxiliary passage from the passage entrance before reaching the predetermined area by being guided. As a result, it is possible to suppress a decrease in the number of game balls guided by the guiding means to the predetermined area.

It should be noted that features A1 to A36, features B1 to B12, features C1 to C12, features D1 to D3, features E1 to E11, features F1 to F41, features G1 to G20, and features H1 to the configurations of the features B1 to B12. Any one or a plurality of configurations of H19, features I1 to I7, features J1 to J4, features K1 to K10, and features L1 to L7 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

According to the invention related to the feature B group, it is possible to solve the following problems.

Pachinko gaming machines and slot machines are known as gaming machines. For example, a pachinko game machine includes a game board that defines a game area in which a game ball flows down, and a nail and a windmill are provided on the game board to appropriately disperse the falling direction of the game ball flowing down the game area. Various members are provided. Further, the game board is provided with openings for paying out game balls, such as a general winning opening, a special electric winning device, and an operating opening. The game ball launched from the game ball launching device flows down the game area while contacting various members, and when the game ball enters the general winning opening, the special electricity winning device, the working opening, etc. The game ball is paid out to the player.

Here, in the gaming machine as exemplified above, it is necessary to make the behavior of the gaming ball suitable, and there is still room for improvement in this respect.

<Characteristic C group>
Feature C1. Equipped with a guide means (adjustment mechanism 180, 220, 330, 430, 620) capable of guiding the game ball toward a predetermined area (first through gate 35, first operating port 33, 581),
The guiding means is
Rotating means (rotating body) that is rotatable and is provided with taking-in means (concave portions 183b to 183e, step surfaces 241a to 244a, and blade members 343) that can take in and hold the game ball in the guiding means. 183, 230, 340, 440),
By rotating the rotating means, a rotation control means (a function for executing the process of step S206 in the main CPU 63, a drive portion 184 for adjustment) that conveys the game balls taken into the guiding means,
At a timing before the timing at which the up-and-down moving direction of the capturing means is switched from the downward direction to the upward direction, the discharging means for discharging the game ball being conveyed by the capturing means toward the predetermined area. (Discharge ports 256 and 621),
A gaming machine characterized by being equipped with.

According to the characteristic C1, in the case of a configuration in which the game sphere being conveyed by the take-in means is released at the timing when the up and down moving direction of the take-in means is switched from the downward direction to the upward direction, the game ball in the ejecting means When the release timing of the game is delayed, the game ball being conveyed by the take-in means may start rising in the guide means. On the other hand, by adopting a configuration in which the game balls being conveyed by the take-in means are discharged at a timing before the timing when the up-and-down moving direction of the take-in means is switched from the downward direction to the upward direction, the game is played. It is possible to reduce the possibility that the game ball will rise in the guide means when the discharge timing of the ball is delayed.

Feature C2. The guiding means prevents the game ball taken into the guiding means and conveyed by the taking-in means from dropping downward and being thrown out of the guiding means by the rotation of the rotating means. Equipped with fall prevention means (left standing wall 181h, right standing wall 181d),
The discharge means is provided with a discharge opening (discharge port) provided in the fall prevention means so that the game balls conveyed in contact with the fall prevention means are discharged toward the outside of the guiding means. 621) is provided. The gaming machine according to the feature C1.

According to the characteristic C2, the game sphere is conveyed while being in contact with the fall prevention means, and is discharged toward the outside of the guiding means when reaching the discharge opening. Since the position of the discharge opening in the fall prevention means is fixed, the position at which the game ball is discharged from the guiding means can be the same every time. Further, since the timing at which the rotating means guides the game ball to the discharge opening is determined according to the rotation mode of the rotating means, the timing at which the game ball is discharged from the guiding means can be the timing set at the design stage.

Feature C3. The gaming machine according to Feature C2, wherein the discharge opening has a direction in which a game ball discharged from the discharge opening is directed toward the predetermined area at an edge of the discharge opening.

According to the characteristic C3, when the game ball is discharged from the discharge opening, the game ball is discharged toward the predetermined area by coming into contact with the edge of the discharge opening. By fixing the position at which the game ball is discharged from the guide means and the direction in which the game ball is discharged, it is possible to increase the probability that the game ball discharged from the guide means reaches the predetermined area.

Feature C4. The predetermined area is provided with a ball-in portion (first through gate 35, first operating ports 33, 581) into which a game ball flowing down the game area (game area PA) can enter.
The game player is provided with a privilege granting unit (a function of executing the processes of steps S705 and S706 in the main CPU 63) that grants a privilege on the condition that at least one of the game balls has entered the ball-in part,
In the characteristic C3, the discharge direction is a direction that allows the game ball discharged from the discharge opening to enter the ball entering portion without colliding with the edge of the ball entering portion. The game machine described.

According to the characteristic C4, when the game ball discharged from the discharge opening collides with the edge of the ball entering portion, the timing at which the game ball enters the ball entering portion is deviated, or the game ball comes out of the ball entering portion. The possibility of coming off can be suppressed.

Feature C5. The releasing means changes the direction of movement of the game ball, which has reached the releasing position, to the moving direction for releasing at the releasing position of releasing the game ball in the guiding means (ejecting protrusion 181e, ejecting). Gaming machine according to any one of features C1 to C4, characterized in that the gaming machine has a projecting end 263a).

According to the characteristic C5, the direction changing means changes the moving direction of the game ball at the discharging position to the moving direction for discharging the game ball, so that the discharging position of the game ball is not discharged from the discharging means. You can suppress passing by. As a result, it is possible to prevent the game balls that have not been released at the release position from rising in the guide means.

Feature C6. The direction changing means projects to an intermediate position in the front-rear direction of the game area (game area PA) in a manner that the direction changing means can contact the game ball guided by the rotating means.
The gaming machine according to feature C5, wherein the rotating means includes contact avoidance means (collision avoidance groove 192) for avoiding contact with the protruding direction changing means.

According to the characteristic C6, by contacting the game ball guided by the rotating means without disturbing the rotation of the rotating means, the moving direction of the game ball is changed at the discharge position to promote the discharge of the game ball. be able to.

Feature C7. The direction changing means is provided with means (right side surface 181g for discharging) for guiding the game ball that has come into contact with the direction changing means at the discharge position toward the predetermined area. C5 or C6 Gaming machine described in.

According to the characteristic C7, since the discharge direction of the game ball is directed to the predetermined area at the discharge position, it is possible to increase the probability that the game ball discharged from the guide means at the discharge position reaches the ball entry portion.

Feature C8. At a midway position of the game ball discharged from the guiding means toward the predetermined area, there is a case where the game ball is allowed to flow down toward the predetermined area and a case where it is not allowed. The game machine according to any one of the features C1 to C7, characterized in that a nail 560) is provided.

According to the characteristic C8, a part of the game sphere emitted from the guiding means toward the predetermined area is out of the predetermined area. By making it uncertain whether or not the game ball released from the guide means enters the predetermined area, the movement of the game ball after being released from the guide means is one of the interests of the player. It is possible to improve the interest of the game by increasing the degree of attention to the movement of the game ball around the guide means.

Feature C9. The route adjusting means,
Change execution means (electric nail 560) for changing the course of the game ball when it comes into contact with the game ball,
Moving the change execution means so that the game ball released from the guide means comes into contact with the change execution means, and the change so that the game ball released from the guide means does not come into contact with the change execution means. A path adjusting drive means (nail drive part 560a) capable of moving the execution means;
A gaming machine according to feature C8, which is provided with:

According to the characteristic C9, the volume occupied by the path adjusting means is changed by moving the change executing means so that the gaming ball has a simple structure in which it can flow down toward the predetermined area and in which it cannot flow down. It is possible to suppress and increase the degree of freedom in design.

Feature C10. The guiding means is
Means (first support surface 241, second support surface 242, third support surface 243) for discharging the game ball so that the discharged game ball comes into contact with the path adjusting means,
A means (fourth support surface 244) for discharging the game ball so that the discharged game ball does not come into contact with the path adjusting means,
The gaming machine according to the feature C8 or C9, which is characterized by comprising:

According to the characteristic C10, the guide means is configured to emit the game balls in a plurality of ways, so that the game balls that are emitted from the guide means and enter the predetermined area and the game balls that do not enter are generated. You can Further, in the guide means, the game ball released from the guide means is in a predetermined area by keeping the ratio of the release mode in which the released game ball comes into contact with the path adjusting means and the release mode in which the released game ball does not come into contact with the route adjusting means. It is possible to make the ratio of entering the ball and the ratio of not entering the ball close to the ratio set in the design stage.

Feature C11. The guiding means is for discharging a game ball toward the predetermined area,
The predetermined area is provided in a game area (game area PA) at a position separated by a diameter of the game ball or more from a position where the guiding means starts discharging the game ball. The gaming machine according to any one of C10.

According to the characteristic C11, the game ball can pass between the position where the discharge of the game ball is started by the guiding means and the predetermined area. Therefore, there is a possibility that the game balls released from the guiding means will not enter the predetermined area. By making it uncertain whether or not the game ball released from the guide means enters the predetermined area, the movement of the game ball after being released from the guide means is one of the interests of the player. It is possible to improve the interest of the game by increasing the degree of attention to the movement of the game ball around the guide means.

Feature C12. A game ball flowing down a game area (game area PA) can enter the predetermined area, and when the game ball enters, one of the conditions for granting a privilege is satisfied. (First through gate 35, first operating ports 33, 581) are provided,
The guiding means discharges the game sphere from a predetermined discharge start position in a predetermined discharge direction so that the game sphere reaches the ball-in portion.
The ball-in portion has an inclined opening that is substantially orthogonal to the moving direction of the game ball at the height position of the game ball discharged from the guide means and flowing down to the height position of the ball-in portion. The gaming machine according to any one of features C1 to C11.

According to the feature C12, it is possible to increase the possibility that the game ball discharged from the guiding means and reaching the ball entrance portion will enter the ball entrance portion without contacting the edge of the ball entrance portion. As a result, it is possible to reduce the possibility that the game ball discharged from the guiding means collides with the edge of the ball entering portion and the ball entering timing is shifted or the game ball is separated from the ball entering portion.

In addition, with respect to the configurations of the features C1 to C12, the features A1 to A36, the features B1 to B12, the features C1 to C12, the features D1 to D3, the features E1 to E11, the features F1 to F41, the features G1 to G20, and the features H1 to H1. Any one or a plurality of configurations of H19, features I1 to I7, features J1 to J4, features K1 to K10, and features L1 to L7 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

According to the invention related to the above-mentioned feature C group, the following problems can be solved.

Pachinko gaming machines and slot machines are known as gaming machines. For example, a pachinko game machine includes a game board that defines a game area in which a game ball flows down, and a nail and a windmill are provided on the game board to appropriately disperse the falling direction of the game ball flowing down the game area. Various members are provided. Further, the game board is provided with openings for paying out game balls, such as a general winning opening, a special electric winning device, and an operating opening. The game ball launched from the game ball launching device flows down the game area while contacting various members, and when the game ball enters the general winning opening, the special electricity winning device, the working opening, etc. The game ball is paid out to the player.

Here, in the gaming machine as exemplified above, it is necessary to make the behavior of the gaming ball suitable, and there is still room for improvement in this respect.

<Feature D group>
Feature D1. Equipped with a guide means (adjustment mechanism 180, 220, 330, 430, 620) capable of guiding the game ball toward a predetermined area (first through gate 35, first operation port 33, 581),
The guiding means is
A take-in opening (take-in port 262) that allows the game ball flowing down toward the guide means to enter the inside of the guide means.
Opening partition means (upper right upright wall 252, left upright wall 261) for partitioning the intake opening,
Rotating means (rotating bodies 230, 340) that are rotatable and are provided with a conveying means (step surfaces 241a to 244a, a blade member 343) that conveys the game balls taken inside the guiding means inside the guiding means. )When,
By rotating the rotating means, a rotation control means (a function for executing the process of step S206 in the main CPU 63, a drive portion 184 for adjustment) that conveys the game balls taken into the guiding means,
The game ball is provided around the intake opening, and is deformed when the game ball is in contact with both the rotation means and the opening partition means at the intake opening, and the game ball is deformed. Deformation means (upper right upright wall 252, vane member 343, rotation shafts 254, 344) capable of escaping the force of sandwiching the
A gaming machine characterized by being equipped with.

According to the feature D1, the game ball can be guided to a predetermined area while avoiding a situation in which the game ball is sandwiched between the rotating device and the opening partitioning device and stays due to the deformation of the deforming device around the intake opening. As a result, it is possible to prevent the game ball from being trapped and interrupting the game, and the need to deal with a problem of removing the trapped game ball from occurring.

Feature D2. The deformation means includes means (upper right upright wall 252, rotating shaft 254) that allows the force applied to the opening defining means to be released by temporarily displacing the opening defining means to a predetermined position. The gaming machine described in the feature D1.

According to the characteristic D2, the game ball is in contact with both the rotating means and the opening defining means, and when the game ball is pushed toward the opening defining means with the rotation of the rotating means, the opening occurs. By temporarily displacing the partition means to a predetermined position, it is possible to avoid a situation where the game ball is caught and stays.

Feature D3. The deforming unit includes a unit (a blade member 343, a rotating shaft 344) that allows the force applied to the rotating unit to escape by temporarily displacing a part of the rotating unit to a specific position. The gaming machine described in the feature D1 or D2.

According to the feature D3, when the game ball is in contact with both the rotating means and the opening defining means, and a situation in which a force is applied to the rotating means and the opening defining means as the rotating means rotates In addition, by partially displacing the rotating means to a specific position and escaping the force of pinching the game ball, it is possible to avoid the situation where the game ball is caught and stays.

It should be noted that features A1 to A36, features B1 to B12, features C1 to C12, features D1 to D3, features E1 to E11, features F1 to F41, features G1 to G20, and features H1 to the configurations of the features D1 to D3. Any one or a plurality of configurations of H19, features I1 to I7, features J1 to J4, features K1 to K10, and features L1 to L7 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

According to the invention related to the characteristic group D, it is possible to solve the following problems.

Pachinko gaming machines and slot machines are known as gaming machines. For example, a pachinko game machine includes a game board that defines a game area in which a game ball flows down, and a nail and a windmill are provided on the game board to appropriately disperse the falling direction of the game ball flowing down the game area. Various members are provided. Further, the game board is provided with openings for paying out game balls, such as a general winning opening, a special electric winning device, and an operating opening. The game ball launched from the game ball launching device flows down the game area while contacting various members, and when the game ball enters the general winning opening, the special electricity winning device, the working opening, etc. The game ball is paid out to the player.

Here, in the gaming machine as exemplified above, it is necessary to make the behavior of the gaming ball suitable, and there is still room for improvement in this respect.

<Feature E group>
Feature E1. A ball entering portion (first through gate 35) into which a game ball flowing down the game area (game area PA) can enter.
Guide means (adjusting mechanism 180, 220, 330, 430, 530, 620) for guiding the game ball toward the ball-in portion,
Equipped with
The guiding means includes a discharging means (discharging ports 256, 621) for discharging the game ball toward the ball entering portion,
The game machine, wherein the ball-in portion is provided at a position separated from the discharging means by a diameter of a game ball or more.

According to the characteristic E1, the game ball discharged from the discharging means needs to flow down a distance longer than the diameter of the game ball before entering the ball entering portion. For this reason, both a case where the game ball enters the ball entering portion and a case where the game ball does not enter depending on the release direction and the release speed of the game ball released from the releasing means may occur. When all of the game balls discharged from the discharging means enter the ball entering portion, the player may lose interest in the whereabouts of the game balls after the discharge. On the other hand, by setting whether or not the game ball discharged from the discharging means enters the ball entering portion as an uncertain element, the player's attention is paid to the whereabouts of the game ball after the discharge, and the game is played. The interest in can be improved.

Feature E2. The guiding means is
Rotating means (rotating body) that is rotatable and is provided with taking-in means (concave portions 183b to 183e, step surfaces 241a to 244a, and blade members 343) that can take in and hold the game ball in the guiding means. 183, 230, 340, 440),
By rotating the rotating means, a rotation control means (a function for executing the process of step S206 in the main CPU 63, a drive portion 184 for adjustment) that conveys the game balls taken into the guiding means,
Fall prevention means (left side) that prevents the game balls that are taken into the guide means and are conveyed by the take-in means from falling down and from being thrown out of the guide means by the rotation of the rotating means. Upright wall 181h, right upright wall 181d),
Is equipped with
The discharge means is provided with a discharge opening (discharge port) provided in the fall prevention means so that the game balls conveyed in contact with the fall prevention means are discharged toward the outside of the guiding means. 621) is provided. The gaming machine according to feature E1.

According to the feature E2, the game ball is conveyed while being in contact with the drop prevention means, and is discharged toward the outside of the guiding means when reaching the discharge opening. Since the position of the discharge opening in the fall prevention means is fixed, the position at which the game ball is discharged from the guiding means can be the same every time. Further, since the timing at which the rotating means guides the game ball to the discharge opening is determined according to the rotation mode of the rotating means, the timing at which the game ball is discharged from the guiding means can be the timing set at the design stage.

Feature E3. The game machine according to feature E2, wherein the discharge opening has a discharge ball game ball discharged from the discharge opening in a direction toward the ball entering portion at an edge of the discharge opening.

According to the feature E3, when the game sphere is discharged from the discharge opening, it comes into contact with the edge of the discharge opening and is discharged toward the ball entering portion. By fixing the position at which the game ball is discharged from the guiding means and the direction in which it is discharged, it is possible to increase the probability that the game ball discharged from the guiding means reaches the ball entry portion.

Feature E4. The discharging means, at a discharging position for discharging the game ball in the guiding means, a direction changing means (a discharging projection 181e, for changing the moving direction of the game ball reaching the discharging position to the moving direction for discharging). The gaming machine according to feature E2 or E3, which is provided with a protruding end 263a for discharge.

According to the characteristic E4, the direction changing means changes the moving direction of the game ball at the discharge position to the moving direction for discharging the game ball, so that the discharge position is changed without discharging the game ball from the discharging means. You can suppress passing by.

Feature E5. The direction changing means protrudes to an intermediate position in the front-rear direction of the game area in a manner capable of contacting the game ball guided by the rotating means,
The gaming machine according to feature E4, wherein the rotating means includes a contact avoiding means (collision avoiding groove 192) for avoiding contact with the protruding direction changing means.

According to the feature E5, by contacting the game ball guided by the rotating means without disturbing the rotation of the rotating means, the moving direction of the game ball is changed at the discharge position to promote the discharge of the game ball. be able to.

Feature E6. The direction changing means is provided with means (right side surface 181g for discharge) for guiding the game ball, which comes into contact with the direction changing means at the discharge position, toward the ball-in portion, a feature E4 or The gaming machine described in E5.

According to the feature E6, since the discharge direction of the game ball is directed to the ball entrance portion at the discharge position, it is possible to increase the probability that the game ball discharged from the guide means at the discharge position reaches the ball entrance portion. ..

Feature E7. The discharging means is provided with a direction defining means (guide passage 545) for defining the discharging direction of the game ball toward the ball entering portion,
The guiding means is located upstream in the direction of flow of the game balls in the direction defining means, and when the guiding means is opened, the game balls can enter the direction defining means and is closed. 7. The gaming machine according to any one of the features E1 to E6, which is provided with an opening/closing unit (adjusting unit 546) that makes it impossible for a gaming ball to enter.

According to the feature E7, the volume of the guiding means occupying the game area can be suppressed by using the simple guiding means including the direction defining means and the opening/closing means. As a result, it is possible to increase the choices of places where the guide means is arranged in the game area and increase the degree of freedom in design.

Feature E8. In the game area, a case where the game ball discharged from the discharging means is allowed to flow down toward the ball entering portion at an intermediate position toward the ball entering portion; The gaming machine according to any one of features E1 to E7, characterized in that there is provided a course adjusting means (electric nail 560).

According to the characteristic E8, a part of the game ball discharged from the discharging means toward the ball entrance part comes off the ball entrance part. By providing a path adjusting means that causes both the case where the game ball discharged from the discharging means enters the ball entering portion and the case where the game ball does not enter the ball entering portion, the game ball released from the discharging means enters the ball entering portion. Whether or not to enter the ball can be an uncertain factor.

Feature E9. The route adjusting means,
Change execution means (electric nail 560) for changing the course of the game ball when it comes into contact with the game ball,
Moving the change execution means so that the game ball discharged from the discharge means comes into contact with the change execution means, and the change so that the game ball discharged from the discharge means does not come into contact with the change execution means. A path adjusting drive means (nail drive part 560a) capable of moving the execution means;
A gaming machine according to feature E8, which is provided with.

According to the characteristic E9, the volume occupied by the route adjusting means is made by moving the change executing means so as to create a state in which the game ball can flow down toward the ball entering portion and a state in which it cannot flow down. Can be suppressed and the degree of freedom in design can be increased.

Feature E10. The discharging means is
Means (first support surface 241, second support surface 242, third support surface 243) for discharging the game ball so that the discharged game ball comes into contact with the path adjusting means,
A means (fourth support surface 244) for discharging the game ball so that the discharged game ball does not come into contact with the path adjusting means,
The gaming machine according to the feature E8 or E9, which is characterized by comprising:

According to the feature E10, the discharging means is configured to discharge the game balls in a plurality of ways, so that both the game balls that are discharged from the discharging means and enter the ball entering portion and the game balls that do not enter Can be generated. Further, in the discharging means, the gaming sphere discharged from the discharging means enters the sphere by making the ratio of the discharging manner in which the discharged gaming sphere comes into contact with the route adjusting means and the discharging manner in which the gaming sphere does not come into contact with each other to be constant. It is possible to make the ratio of entering the part and the ratio of not entering the part close to the ratio set in the design stage.

Feature E11. The discharging means is for discharging the game ball from the predetermined discharge start position in a predetermined discharge direction to reach the game ball.
The ball-in portion has an opening having an inclination substantially orthogonal to the moving direction of the game ball discharged from the discharging means and flowing down to the height position of the ball-in portion. The gaming machine according to any one of features E1 to E10.

According to the feature E11, it is possible to increase the possibility that the game ball discharged from the discharging means and reaching the ball entering portion will enter the ball entering portion without contacting the edge of the ball entering portion. As a result, it is possible to reduce the possibility that the game ball discharged from the discharging means collides with the edge of the ball entering portion and the ball entering timing is shifted or the game ball comes off the ball entering portion.

In addition, with respect to the configuration of the features E1 to E11, the features A1 to A36, the features B1 to B12, the features C1 to C12, the features D1 to D3, the features E1 to E11, the features F1 to F41, the features G1 to G20, and the features H1 to H1. Any one or a plurality of configurations of H19, features I1 to I7, features J1 to J4, features K1 to K10, and features L1 to L7 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

According to the invention related to the above feature E group, the following problems can be solved.

Pachinko gaming machines and slot machines are known as gaming machines. For example, a pachinko game machine includes a game board that defines a game area in which a game ball flows down, and a nail and a windmill are provided on the game board to appropriately disperse the falling direction of the game ball flowing down the game area. Various members are provided. Further, the game board is provided with openings for paying out game balls, such as a general winning opening, a special electric winning device, and an operating opening. The game ball launched from the game ball launching device flows down the game area while contacting various members, and when the game ball enters the general winning opening, the special electricity winning device, the working opening, etc. The game ball is paid out to the player.

Here, in the gaming machine as exemplified above, it is necessary to make the behavior of the gaming ball suitable, and there is still room for improvement in this respect.

<Feature F group>
Feature F1. Predetermined ball entering means (out port 24a, general winning hole 31, special electric prize 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 entering means, information corresponding to the game ball is stored in the specific storage means (main side RAM 65) and a specific storage executing means (the main CPU 63 executes the entrance detecting process). Function),
A privilege to execute a process for giving a privilege to the player based on the fact that the information corresponding to the game ball entering the predetermined ball entering device is stored in the specific storage device. Giving means (a function of the main CPU 63 to execute the process of step S219, a payout CPU 92 to execute the process of step S1008),
In a gaming machine equipped with
When a game ball enters the predetermined ball entering means, the corresponding information is stored in the predetermined storage means (the history memory 117 in the first to fifteenth and seventeenth to eighteenth embodiments, the sixteenth embodiment). Then, the main information is executed in the main RAM 65), and the predetermined information (first number) that enables the number of balls entered into the predetermined ball entering means or the frequency of entering the balls to be specified by the game machine or a device external to the game machine. -Predetermined storage execution means (first storage means) for storing history information in the fourteenth and eighteenth embodiments, and numerical information measured by a counter in the fifteenth to seventeenth embodiments) In the fifteenth and seventeenth to eighteenth embodiments, the function of executing the history setting processing in the management side CPU 112, and in the sixteenth embodiment, step S2902, step S2905, step S2908, step S2912, step S2916 in the main CPU63, A game machine having a function of executing the processing of step S2920 and step S2923).

According to the characteristic F1, when the game ball enters the predetermined ball entering means, the corresponding information is stored in the specific storage means, and when the information is stored in the specific storage means, the bonus is given to the player. To be done. As a result, the player will play the game while expecting that the game ball will enter the predetermined ball entering means. In the configuration, when a game ball enters the predetermined ball entering means, the corresponding information is stored in the predetermined storage means, and the number of the game balls entering the predetermined ball entering means or the frequency of entering the ball. Predetermined information that enables the control means of the game machine or a device outside the game machine to specify the information is stored in the predetermined storage means. As a result, it becomes possible for the gaming machine to store and hold information for managing the number of balls or the frequency of entering the game balls into the predetermined ball entering means. By using this managed information, the predetermined information can be stored. It is possible to appropriately manage the entering mode of the game ball into the entering device. Further, by storing and holding the predetermined information in the gaming machine itself, it becomes possible to prevent unauthorized access or unauthorized modification of the predetermined information.

Feature F2. The gaming machine according to Feature F1, wherein the predetermined information does not trigger execution of a process for granting a privilege to the player.

According to the feature F2, the predetermined information does not trigger the execution of the process for granting the privilege to the player, so that it is aimed to appropriately manage the entering mode of the game ball into the predetermined entering means. It becomes possible to store and hold the predetermined information in the information form.

Feature F3. It is provided with a specific ball-in means (outlet port 24a, a general prize hole 31, a special electric prize winning device 32, a first operation port 33, a second operation port 34) into which a game ball flowing down the game area can enter.
When the game ball enters the specific ball entering means, the predetermined memory executing means causes the predetermined memory means to store information corresponding to the game ball, and when the game ball enters the specific ball entering means. Specific information (the history information in the first to fourteenth and eighteenth embodiments, the counter in the fifteenth to seventeenth embodiments, which makes it possible to specify the number of balls by the control means of the gaming machine or a device outside the gaming machine. The game machine according to the feature F1 or F2, characterized in that the measured numerical information) is stored in the predetermined storage means.

According to the characteristic F3, not only the predetermined information corresponding to the predetermined ball entering means but also the specific information corresponding to the specific ball entering means is stored in the predetermined storage means. As a result, it is possible to manage not only the entering mode of the game ball into the predetermined entering device but also the entering form of the game ball into the specific entering device. Also, by using both the predetermined information and the specific information, it becomes possible to manage the ratio of the frequency of entering the ball between the predetermined entering means and the specific entering means.

Feature F4. All the ball entering means for ejecting the entered game ball from the game area, including the predetermined ball entering means, are the storage targets of the information corresponding to the occurrence of the ball entering the game ball in the predetermined storage means. The gaming machine according to any one of the features F1 to F3, which is a ball entering means.

According to the feature F4, all the ball entry means for ejecting the game ball from the game area are subject to management using the information stored in the predetermined storage means, and thus the ball entry frequency for any ball entry means. Can be managed by using the information stored in the predetermined storage means. Further, it is possible to manage the ratio of the number of game balls entering the predetermined ball entering means with respect to the number of game balls discharged from the game area, using the information stored in the predetermined storage means.

Feature F5. The gaming machine according to any one of features F1 to F4, wherein the predetermined information includes information corresponding to a timing at which a game ball enters the predetermined ball entering means.

According to the feature F5, since the predetermined information includes information corresponding to the timing at which the game ball enters the predetermined ball entering means, by using the predetermined information, the game ball entering the predetermined ball entering means It is possible to grasp the entry history in detail.

Feature F6. The gaming machine according to any one of features F1 to F5, characterized in that the predetermined information is counting information of the number of game balls entered in the predetermined entering means.

According to the feature F6, since the predetermined information is the counting information of the number of game balls that have entered the predetermined ball entering means, the amount of information of the predetermined information is suppressed, and the mode in which the game balls enter the predetermined ball entering means. Can be managed.

Feature F7. The predetermined storage execution means is means for causing the predetermined storage means to store information that enables identification of whether or not a game ball has entered the predetermined ball insertion means in a predetermined situation (first In the first to thirteenth embodiments, the function of executing the processing of steps S1404 and S1409 in the management CPU 112, in the fourteenth embodiment, the function of executing the processing of step S2704 in the management CPU112, and in the fifteenth embodiment, management The game machine according to any one of features F1 to F6, which is provided with a function of executing the process of step S2803 in the side CPU 112.

According to the feature F7, it is possible to manage whether or not the game ball enters the predetermined ball entering means by distinguishing whether or not it is in a predetermined situation.

Feature F8. Any one of features F1 to F7 characterized by including an external output unit (a function for executing an external output process in the management-side CPU 112) that outputs the information stored in the predetermined storage unit to a device outside the gaming machine. The gaming machine described in 1.

According to the characteristic F8, it becomes possible to read the information stored in the predetermined storage means from the gaming machine and analyze the entering mode of the game ball into the predetermined entering means by using the read information.

Feature F9. A program output unit (function of executing the process of step S1503 in the main CPU 63) that outputs a control program to a device outside the gaming machine using the information output unit (reading terminal 102) is provided.
The game machine according to Feature F8, wherein the external output unit uses the information output unit to output the information stored in the predetermined storage unit to a device outside the game machine.

According to the feature F9, it is possible to output the information stored in the predetermined storage means to the outside by using the information output unit for outputting the control program to the outside. This makes it possible to output the information stored in the predetermined storage means to the outside while preventing the configuration from becoming complicated.

Feature F10. Means for identifying whether the information to be output from the information output unit is the information stored in the predetermined storage unit or the control program, and outputting the information corresponding to the identification result (mainly The game machine according to Feature F9, which is provided with a function of executing the processing of step S1502 in the side CPU 63.

According to the characteristic F10, in the configuration in which the information output unit for externally outputting the control program is used to externally output the information stored in the predetermined storage unit, 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. This makes it possible to read out only the necessary information even if the information output section is also used.

Feature F11. First control means (main CPU 63) having the specific storage execution means,
Second control means (management side CPU 112) having the predetermined storage execution means,
The gaming machine according to any one of the features F1 to F10, which is characterized by comprising:

According to the feature F11, the second control means provided separately from the first control means having the specific storage execution means has the predetermined storage execution means, so that the processing load of the first control means is extremely increased. It is possible to obtain the excellent effect as already described while preventing the occurrence of the above.

Feature F12. The gaming machine according to Feature F11, wherein the first control unit and the second control unit are provided on the same chip.

According to the feature F12, since the first control means and the second control means are provided in the same chip, unauthorized access to the communication path between the first control means and the second control means can be prevented. It becomes possible to prevent it.

Feature F13. It is provided with a specific ball-in means (outlet port 24a, a general prize hole 31, a special electric prize winning device 32, a first operation port 33, a second operation port 34) into which a game ball flowing down the game area can enter.
When the game ball enters the specific ball entering means, the predetermined memory executing means causes the predetermined memory means to store information corresponding to the game ball, so that the game to the specific ball entering means is executed. Specific information (the history information in the first to fourteenth and eighteenth embodiments, the fifteenth to the fifteenth) that allows the number of balls entered or the frequency of balls entered to be specified by the control means of the game machine or a device outside the game machine. In the seventeenth embodiment, the numerical information measured by the counter is stored in the predetermined storage means,
The first control means is
First transmitting means (first to seventh signals of the main CPU 63 for transmitting the first information to the second control means using the first signal path when the game ball enters the predetermined ball entering means) Function to output either),
Second transmitting means for transmitting second information to the second control means by using a second signal path when a game ball enters the specific ball entering means (first to seventh signals of the main CPU 63) Function to output either),
The gaming machine according to the feature F11 or F12, which is characterized by comprising:

According to the feature F13, not only the predetermined information corresponding to the predetermined ball entering means but also the specific information corresponding to the specific ball entering means is stored in the predetermined storage means. As a result, it is possible to manage not only the entering mode of the game ball into the predetermined entering device but also the entering form of the game ball into the specific entering device. Also, by using both the predetermined information and the specific information, it becomes possible to manage the ratio of the frequency of entering the ball between the predetermined entering means and the specific entering means.

In addition, when the game ball enters the predetermined ball entering means, the first information is transmitted to the second control means using the first signal path, and when the game ball enters the specific ball entering 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 it is possible to simplify the configuration for distinguishing each type of information in the second control means.

Feature F14. The first control means transmits, to the second control means, identification information that enables the second control means to identify whether or not a predetermined situation is present, using the third route. (In the first to seventh, ninth to fifteenth, and eighteenth embodiments, the main CPU 63 outputs any of the eighth to tenth signals, and in the eighth embodiment, the main CPU 63 opens and closes the execution mode. The game machine according to Feature F13, which is provided with a function of outputting any one of a medium signal, a high-frequency support mode signal, and a door opening signal.

According to the feature F14, it is possible to manage whether the game ball enters the predetermined ball entering means and the game ball enters the specific ball entering means by distinguishing whether or not the situation is a predetermined situation. Further, since the identification information that enables identification of whether or not the predetermined situation is present is transmitted to the second control means using the third route, the second control means transmits the identification information to the first information and the first information. It is possible to simplify the configuration for distinguishing it from other information such as 2 information.

Feature F15. The first control means, to the second control means, identification information indicating that the first information corresponds to the predetermined ball entering means and the second information corresponds to the specific ball entering means. The gaming machine described in the characteristic F13 or F14, which is provided with an identification information transmitting unit (a function for executing a recognition process in the main CPU 63) for transmitting.

According to the characteristic F15, the identification information indicating that the first information corresponds to the predetermined entrance means and the second information corresponds to the specific entrance means is transmitted from the first control means to the second control means. Therefore, it is not necessary to store the correspondence relationship of these pieces of information in the second control means in advance. This makes it possible to increase the versatility of the second control means.

Feature F16. The gaming machine according to Feature F15, wherein the identification information transmitting unit transmits the identification information to the second control unit when supply of operating power to the first control unit is started.

According to the feature F16, when the supply of the operating power to the first control means is started, the identification information is transmitted from the first control means to the second control means, so the predetermined ball entry means and the specific ball entry means. In a situation in which a game ball may enter the ball, it is possible for the second controller to specify the correspondence between the information transmitted from the first controller and the ball entered. Become.

Feature F17. The identification information transmission means transmits the identification information to the second control means by using at least one of the first signal path and the second signal path. Amusement machine.

According to the feature F17, the identification information is transmitted to the second control means by using at least one of the first signal path and the second signal path, so that a dedicated signal path for transmitting the identification information is provided. It is possible to simplify the configuration related to communication as compared with.

Feature F18. When the second control means receives the identification information, the second control means can specify that the first information corresponds to the predetermined ball entering means and the second information corresponds to the specific ball entering means. Any of the features F15 to F17 characterized by including a unit (a function of executing the correspondence relation setting process in the management side CPU 112) for storing the correspondence relation information in the correspondence relation storage unit (correspondence relation memory 116). The gaming machine described in 1.

According to the characteristic F18, the correspondence relationship between the information transmitted from the first control means and the ball entry means is stored in the second control means. Thus, the second control means is provided with information that enables the second control means to specify the ball entry means corresponding to the information to be transmitted, every time the first control means transmits the first information or the second information. There is no need to do it. Therefore, the information amount of the first information and the second information can be suppressed.

Feature F19. The first control means transmits third information, which enables the second control means to specify whether or not a predetermined situation is present, to the second control means by using a third route. (In the first to seventh, ninth to fifteenth, and eighteenth embodiments, the function of outputting any of the eighth to tenth signals in the main CPU 63, in the eighth embodiment, the open/close execution mode in the main CPU63. The function to output one of the medium signal, high frequency support mode signal and door open signal),
The feature F15 characterized in that the second control means can recognize the third information as information that can identify whether or not the predetermined condition is present, without receiving the identification information. The gaming machine according to any one of to F18.

According to the feature F19, it is possible to manage whether or not the game ball enters the predetermined ball entering means and the game ball enters the specific ball entering means by distinguishing whether or not the situation is a predetermined situation. Further, the fact that the third information is information that can identify whether or not the predetermined condition is present can be identified by the second control means without receiving the identification information from the first control means. .. This makes it possible to prevent the information form of the identification information from becoming complicated.

Feature F20. The second control means is a receiving unit capable of receiving the information from the first control means, and the number of types of information required to be transmitted from the first control means to the second control means is larger than the number of types of information. The gaming machine according to any one of features F13 to F19, characterized in that a large number of receiving units (buffers 122a to 122p) are provided.

According to the feature F20, since the second control means is provided with the number of receiving units that is larger than the number of types of information that needs 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 deal with the information without changing the configuration of the receiving unit. Therefore, it becomes possible to improve the versatility of the second control means.

Feature F21. First external output means (management Function for executing external output processing in the side CPU 112),
A second external output unit (management Function for executing external output processing in the side CPU 112),
The gaming machine according to any one of the features F13 to F20, characterized by comprising:

According to the characteristic F21, the information stored in the predetermined storage means is read from the gaming machine, and the read information is used to enter the game ball into the predetermined ball entering means and the game ball to the specific ball entering means. It is possible to specify the entering mode. In addition, when the external output is performed, information of a combination of predetermined information and information that makes it possible to recognize that the predetermined information corresponds to the predetermined ball entrance means is externally output, and also corresponds to the specific information and the specific ball entrance means. Information of a combination with the information that makes it possible to recognize that it is being output is output to the outside. Thereby, it is possible to specify each incoming mode by using the information read from the predetermined storage means.

Feature F22. Information computing means (first to seventh, eighth, twelfth, fourteenth, fourteenth, fourteenth, fourteenth, fourteenth, fourteenth, fourteenth, fourteenth In the fifteenth, sixteenth, and eighteenth embodiments, the function of executing the processes of step S1608, step S1613, and step S1617 in the management-side CPU 112, and the processing of steps S2008, step S2013, and step S2017 in the management-side CPU 112 in the ninth embodiment. Function for executing step S2202 in the management-side CPU 112 in the tenth embodiment, function for executing step S2402 in the management-side CPU 112 in the eleventh embodiment, management in the thirteenth embodiment Any one of features F1 to F21 characterized in that it has a function of executing the process of step S2605 in the side CPU 112, and a function of executing the process of step S3203 in the main CPU 63 in the seventeenth embodiment). Game machine.

According to the feature F22, the mode information corresponding to the entering mode of the game ball is calculated by the game machine using the predetermined information stored in the predetermined storage means. As a result, for example, it becomes possible for the gaming machine itself to perform the process corresponding to the entering mode of the game ball, or it is possible to output the mode information which is the result of the calculation using the predetermined information. ..

Feature F23. The predetermined storage execution means is a means for causing the predetermined storage means to have information for specifying whether or not the game ball has entered the predetermined ball insertion means in a predetermined situation (first). ~ A function of executing the processing of steps S1404 and S1409 in the management CPU 112 in the thirteenth embodiment, a function of executing the processing of step S2704 in the management CPU 112 in the fourteenth embodiment, A function of executing the processing of step S2803 in the CPU 112),
The information calculating means calculates the aspect information by extracting or excluding the predetermined information corresponding to the entry of the game ball into the predetermined entry means in the predetermined situation (first to seventh, In the eighth, twelfth, fourteenth, fifteenth, sixteenth, and eighteenth embodiments, the function of executing the processes of step S1608, step S1613, and step S1617 in the management-side CPU 112, and in the management-side CPU112 in the ninth embodiment. A function of executing the processing of steps S2008, S2013 and S2017, a function of executing the processing of step S2202 in the management CPU 112 in the tenth embodiment, and a processing of step S2402 in the management CPU 112 in the eleventh embodiment. A function of executing the process of step S2605 in the management-side CPU 112 in the thirteenth embodiment and a function of executing the process of step S3203 in the main-side CPU 63 in the seventeenth embodiment). The gaming machine described in F22.

According to the feature F23, it becomes possible to calculate the mode information corresponding to the entering mode of the game ball by distinguishing whether or not it is the predetermined situation.

Feature F24. When the aspect information is calculated by the information calculation means, means for deleting the predetermined information stored in the predetermined storage means (first to seventh, eighth, fourteenth, fifteenth, sixteenth, sixteenth In the eighteenth embodiment, the management side CPU 112 has a function of executing the process of step S1619, and the twelfth embodiment has a function of executing the process of step S2205 in the management side CPU 112). Gaming machine described in.

According to the feature F24, when the aspect information is calculated, the predetermined information stored in the predetermined storage means is erased, so that it is difficult for the predetermined information to exceed the storage capacity of the predetermined storage means. It becomes possible.

Feature F25. Even if the aspect information is calculated by the information calculating means, the state in which the predetermined information used when calculating the aspect information is stored in the predetermined storage means is maintained. Or the game machine according to F23.

According to the feature F25, even if the mode information is calculated, the predetermined information used when calculating the mode information is stored and held in the predetermined storage means, so that the mode information is read and the game ball enters the ball. When analyzing the aspect, it is possible to refer not only to the aspect information but also to the predetermined information that is the basis of the calculation of the aspect information.

Feature F26. The information calculation means, 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 F22 to F25, wherein the aspect information is calculated.

According to the feature F26, the aspect information is calculated when the supply of the operating power to the control means is stopped or when the supply of the operating power to the control means is stopped, so the aspect information is calculated for each business day. It becomes possible to manage.

Feature F27. The information calculation unit calculates the aspect information when a calculation trigger that can occur repeatedly occurs in a situation where operating power is being supplied to the control unit having the specific storage execution unit. The gaming machine according to any one of F26.

According to the feature F27, the mode information is calculated every time the calculation trigger repeatedly occurs in the situation where the operating power is supplied to the control means, and therefore the mode information is finely managed within the range of one business day. Is possible.

Feature F28. The information calculation means calculates the aspect information every time the period measured by the period measurement means (measurement counter provided in the main RAM 65) reaches a predetermined period,
The period measuring means stops the measurement of the period when the game is not being executed, and restarts the measurement of the period from the state before the stop when the game is started in the situation where the measurement of the period is stopped. The gaming machine according to any one of features F22 to F27.

According to the feature F28, 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, when the game is not being executed, the measurement for the predetermined period is stopped, and when the game is started, the measurement for the predetermined period is restarted from the state before the stop. This makes it possible to exclude the situation where the game is not being executed from the calculation target of the situation information, and it is possible to appropriately derive the situation information in the situation where the game is being performed.

Feature F29. Features F22 to F28, which are provided with an external output unit (a function for executing an external output process in the management-side CPU 112) that outputs the aspect information calculated by the information calculation unit to a device outside the gaming machine. The gaming machine according to any one of 1.

According to the feature F29, the aspect information is output to the device outside the gaming machine, so that the entering aspect of the game ball can be easily grasped.

Feature F30. The game machine according to feature F29, wherein the external output unit outputs the predetermined information to a device outside the game machine when the aspect information is output to a device outside the game machine.

According to the feature F30, not only the aspect information but also the predetermined information is output to the device outside the gaming machine, so that when the aspect information is read and the entering aspect of the game ball is analyzed, not only the aspect information but also the aspect information It is possible to refer to the predetermined information that is the basis of the calculation of the aspect information.

Feature F31. First control means (main CPU 63) having the specific storage execution means,
Second control means (management side CPU 112) having the external output means,
Equipped with
A feature F29 characterized in that the external output means outputs the aspect information to a device outside the gaming machine when the second control means receives the output instruction information transmitted from the first control means. The gaming machine described in F30.

According to the feature F31, the second control means having the external output means is provided separately from the first control means to reduce the processing load of the first control means, and based on the instruction from the first control means. The information can be output to a device outside the gaming machine.

Feature F32. The information calculation means calculates the aspect information each time a predetermined calculation trigger occurs,
Result storage executing means for sequentially storing the mode information calculated by the information calculating means in the calculation result storage means (calculation result memory 631) (in the ninth embodiment, step S2010, step S2014 and step S2018 in the management CPU 112). The game machine according to any one of the features F22 to F31, which has a function of performing the process of step S2204 in the management-side CPU 112 in the tenth embodiment.

According to the feature F32, it becomes possible to accumulate mode information in the gaming machine. This makes it possible to collectively read a plurality of aspect information when managing the entry aspect of the game ball.

Feature F33. The result storage executing means,
Means for determining whether or not the aspect information is storage target information (a function of the management-side CPU 112 for executing the processing of step S2203);
Means for storing the mode information in the calculation result storage means when the mode information is the storage target information (function of executing the process of step S2204 in the management CPU 112);
A gaming machine according to feature F32, which is characterized by including:

According to the feature F33, when the mode information of the calculated result corresponds to the storage target information, the mode information is stored in the calculation result storage means. As a result, it becomes possible to limit the form information to be stored in the calculation result storage means, and it is possible to suppress the storage capacity required in the calculation result storage means.

Feature F34. The result storage executing means stores information in the operation result storage means along with the information that makes it possible to specify the time when the aspect information is calculated, and stores the result in the operation result storage means. Machine.

According to the feature F34, the information that enables the time when the aspect information is calculated is associated with the aspect information. Thereby, it becomes possible to analyze each aspect information while grasping the time when each aspect information was calculated.

Feature F35. First control means (main CPU 63) having the specific storage execution means,
Second control means (management side CPU 112) having the information calculation means,
Equipped with
The information computing means computes the aspect information when the second control means receives the computation trigger information transmitted from the first control means, according to any one of features F22 to F34. Game machine.

According to the feature F35, the second control means having the information calculation means is provided separately from the first control means to reduce the processing load of the first control means, and the aspect is based on the instruction from the first control means. The information can be calculated by the second control means.

Feature F36. A notification control unit (a function of executing the processes of steps S3205, S3207, and S3208 in the main CPU 63) that controls the notification unit (the notification light emitting unit 651) to notify the content corresponding to the aspect information is provided. The gaming machine according to any one of the features F22 to F35.

According to the feature F36, the content corresponding to the aspect 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 entering mode of the game ball without reading the mode information from the gaming machine.

Feature F37. The control board (main control board 61) provided with the notification control means is housed in a board box,
The gaming machine according to Feature F36, wherein the notification unit is provided on the control board.

According to the feature F37, it becomes possible to make it difficult to illegally access the communication path between the notification control unit and the notification unit.

Feature F38. First control means (main CPU 63) having the specific storage execution means,
Second control means (management side CPU 112) having the predetermined storage execution means,
Equipped with
The game machine according to feature F36 or F37, wherein the first control means includes the information calculation means and the notification control means.

According to Feature F38, the function of calculating the aspect information and the calculation result thereof in the configuration in which the processing load of the first control means is reduced by providing the second control means having the predetermined storage means separately from the first control means. It is possible to integrate the function for executing the notification corresponding to the first control means.

Feature F39. The notification control means controls the notification means so that the first notification is executed when the aspect information is the information of the first range, and when the aspect information is the information of the second range, The gaming machine according to any one of features F36 to F38, characterized in that the notifying means is controlled so that the second notification is executed.

According to the feature F39, the content corresponding to the range including the aspect information is notified instead of notifying the aspect information as it is. As a result, it is possible to prevent the notification means from having too many notification patterns, and it is possible to reduce the load for controlling the notification means.

Feature F40. When a game ball enters the predetermined ball entering means, a means (a function of executing the process of step S220 in the main CPU 63) for externally outputting corresponding information corresponding to the game ball is provided. The gaming machine according to any one of F39.

According to the feature F40, the predetermined information is stored in the predetermined storage means in a configuration in which the corresponding information corresponding to the game ball entering the predetermined ball entering means is output to the outside. With this, by using the correspondence information, the predetermined number of game balls entered into the predetermined ball entering means can be easily grasped, and the predetermined information stored in the predetermined storage means can be used. It is possible to accurately grasp the number of game balls entering the ball means and the frequency of entering the balls.

Feature F41. The gaming machine according to any one of features F1 to F40, wherein the predetermined storage execution means or the second control means is provided as a dedicated circuit.

According to the feature F41, it is possible to obtain the excellent effects as already described in the configuration in which the predetermined storage executing means or the second control means is provided as a dedicated circuit.

In addition, with respect to the configurations of the features F1 to F41, the features A1 to A36, the features B1 to B12, the features C1 to C12, the features D1 to D3, the features E1 to E11, the features F1 to F41, the features G1 to G20, and the features H1 to H1. Any one or a plurality of configurations of H19, features I1 to I7, features J1 to J4, features K1 to K10, and features L1 to L7 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

<Feature G group>
Features G1. When a predetermined event occurs as a result of the game, the storage of the information corresponding to the predetermined event is stored in the predetermined storage means (the history memory 117 in the first to fifteenth and seventeenth to eighteenth embodiments, the main side in the sixteenth embodiment). The predetermined information (history information in the first to fourteenth and eighteenth embodiments, numerical information measured by the counter in the fifteenth to seventeenth embodiments) is executed by the RAM65). Predetermined storage execution means to be stored in the storage means (a function for executing history setting processing in the management side CPU 112 in the first to fifteenth, seventeenth to eighteenth embodiments, a main CPU63 in the sixteenth embodiment). In step S2902, step S2905, step S2908, step S2912, step S2916, step S2920, and step S2923)).
Information calculating means (first to seventh, eighth, twelfth, fourteenth, fifteenth, sixteenth, eighteenth) for calculating aspect information corresponding to a result of a game in a predetermined period by using the predetermined information. In the twelfth embodiment, the function of executing the processes of steps S1608, S1613, and S1617 in the management CPU 112, and in the twelfth embodiment, the function of executing the processes of step S2008, step S2013, and step S2017 in the management CPU 112, the tenth embodiment. Of the management CPU 112 in the eleventh embodiment, the function of executing step S2402 in the management CPU 112 in the eleventh embodiment, and the processing of step S2605 in the management CPU 112 in the thirteenth embodiment. Function for executing step S3203 in the main CPU 63 in the seventeenth embodiment).
A gaming machine characterized by being equipped with.

According to the characteristic G1, when a predetermined event occurs, the information corresponding to the predetermined event is stored in the predetermined storage means, and the predetermined information is stored in the predetermined storage means. This makes it possible for the gaming machine to store and hold information for managing the number of times or frequency of occurrence of a predetermined event, and by using this managed information, it is possible to appropriately manage the occurrence mode of the predetermined event. It becomes possible to do it. Further, by storing and holding the predetermined information in the gaming machine itself, it becomes possible to prevent unauthorized access or unauthorized modification of the predetermined information.

Further, using the predetermined information stored in the predetermined storage means, the mode information corresponding to the result of the game in the predetermined period is calculated in the gaming machine. Thereby, for example, it becomes possible for the gaming machine itself to perform a process corresponding to the result of the game in a predetermined period, or it is possible to externally output the mode information which is the result of the calculation using the predetermined information. Become.

Features G2. The predetermined storage execution means is means for causing the predetermined storage means to store information that enables identification of whether or not the occurrence of the predetermined event is in a predetermined situation (in the first to thirteenth embodiments). The function of executing the processing of steps S1204 and S1209 in the management CPU 112, the function of executing the processing of step S2704 in the management CPU 112 in the fourteenth embodiment, and the processing of step S2803 in the management CPU 112 in the fifteenth embodiment. Function to execute)
The information computing means computes the aspect information by extracting or excluding the predetermined information corresponding to the occurrence of the predetermined event in the predetermined situation (first to seventh, eighth, twelfth, twelfth). In the fourteenth, fifteenth, sixteenth, and eighteenth embodiments, the function of executing the processes of step S1608, step S1613, and step S1617 in the management-side CPU 112, and in the twelfth embodiment, step S2008, step S2013, and step in the management-side CPU 112. A function of executing the process of S2017, a function of executing the process of step S2202 in the management CPU 112 in the tenth embodiment, a function of executing the process of step S2402 in the management CPU 112 in the eleventh embodiment, and a thirteenth embodiment. The gaming machine according to feature G1 having a function of executing the process of step S2605 in the management-side CPU 112 in the embodiment, and a function of executing the process of step S3203 in the main-side CPU 63 in the seventeenth embodiment). ..

According to the feature G2, it is possible to distinguish whether or not the situation is the predetermined situation and calculate the mode information corresponding to the result of the game in the predetermined period.

Features G3. When the aspect information is calculated by the information calculation means, means for deleting the predetermined information stored in the predetermined storage means (first to seventh, eighth, fourteenth, fifteenth, sixteenth, sixteenth In the eighteenth embodiment, the management CPU 112 has a function of executing the process of step S1619, and in the twelfth embodiment, the management CPU 112 has a function of executing the process of step S2205). Gaming machine described in.

According to the characteristic G3, when the mode information is calculated, the predetermined information stored in the predetermined storage means is deleted, so that it is difficult for the predetermined information to exceed the storage capacity of the predetermined storage means. It becomes possible.

Features G4. Even if the aspect information is calculated by the information calculation means, the state in which the predetermined information used when calculating the aspect information is stored in the predetermined storage means is maintained. Alternatively, the gaming machine described in G2.

According to the feature G4, even if the mode information is calculated, the predetermined information used when calculating the mode information is stored and held in the predetermined storage means, so that the mode information is read and the game in the predetermined period is performed. When analyzing the result of (3), it is possible to refer not only to the aspect information but also to the predetermined information that is the basis of the calculation of the aspect information.

Features G5. A feature G1 characterized in that the information computing means computes 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. The gaming machine according to any one of to G4.

According to the characteristic G5, the aspect information is calculated when the supply of the operating power to the control means is stopped or when the supply of the operating power to the control means is started. Therefore, the aspect information is calculated for each business day. It becomes possible to manage.

Features G6. One of the features G1 to G5 characterized in that the information computing unit computes the aspect information when a computation trigger that may occur repeatedly occurs in a situation where operating power is being supplied to the control unit (MPU 62). The gaming machine described in 1.

According to the feature G6, the mode information is calculated every time the calculation trigger repeatedly occurs in the situation where the operating power is being supplied to the control means, and therefore the mode information is finely managed within the range of one business day. Is possible.

Features G7. The information calculation means calculates the aspect information every time the period measured by the period measurement means (measurement counter provided in the main RAM 65) reaches a predetermined period,
The period measuring means stops the measurement of the period when the game is not being executed, and when the game is started in the situation where the measurement of the period is stopped, restarts the measurement of the period from the state before the stop. The gaming machine according to any one of the features G1 to G6.

According to the feature G7, 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, when the game is not being executed, the measurement for the predetermined period is stopped, and when the game is started, the measurement for the predetermined period is restarted from the state before the stop. This makes it possible to exclude the situation where the game is not being executed from the calculation target of the situation information, and it is possible to appropriately derive the situation information in the situation where the game is being performed.

Features G8. Features G1 to G7, which are provided with an external output unit (a function for executing an external output process in the management-side CPU 112) that outputs the aspect information calculated by the information calculation unit to a device outside the gaming machine. The gaming machine according to any one of 1.

According to the feature G8, the aspect information is output to the device outside the gaming machine, so that the entering aspect of the game ball can be easily grasped.

Features G9. The game machine according to feature G8, wherein the external output unit outputs the predetermined information to a device outside the game machine when the aspect information is output to a device outside the game machine.

According to the feature G9, not only the aspect information but also the predetermined information is output to the device outside the gaming machine, so that when the aspect information is read and the entering aspect of the game ball is analyzed, not only the aspect information but also the aspect information It is possible to refer to the predetermined information that is the basis of the calculation of the aspect information.

Feature G10. First control means (main CPU 63) having the specific storage execution means,
Second control means (management side CPU 112) having the external output means,
Equipped with
A feature G8 characterized in that the external output means outputs the aspect 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 described in G9.

According to Characteristic G10, in the configuration in which the processing load of the first control means is reduced by providing the second control means having the external output means separately from the first control means, the aspect based on the instruction from the first control means The information can be output to a device outside the gaming machine.

Feature G11. The information calculation means calculates the aspect information each time a predetermined calculation trigger occurs,
Result storage executing means for sequentially storing the mode information calculated by the information calculating means in the operation result storage means (operation result memory 631) (in the ninth embodiment, step S2010, step S2014 and step S2018 in the management CPU 112). The game machine according to any one of the features G1 to G10, which is provided with a function of performing the process of step S2204 in the management-side CPU 112 in the twelfth embodiment.

According to the feature G11, the aspect information can be accumulated in the gaming machine. This makes it possible to collectively read a plurality of aspect information when managing the aspect of the result of the game in a predetermined period.

Features G12. The result storage execution means is provided with means (a function of executing the process of step S2204 in the management side CPU 112) for storing the mode information in the calculation result storage means when the mode information is storage target information. A gaming machine described in Feature G11.

According to the feature G12, when the mode information of the calculated result corresponds to the storage target information, the mode information is stored in the calculation result storage means. As a result, it becomes possible to limit the form information to be stored in the calculation result storage means, and it is possible to suppress the storage capacity required in the calculation result storage means.

Features G13. The game according to the feature G11 or G12, characterized in that the result storage execution means stores information in the operation result storage means in association with the aspect information, which makes it possible to specify the time when the aspect information was calculated. Machine.

According to the feature G13, the information that allows the time when the aspect information is calculated is associated with the aspect information. Thereby, it becomes possible to analyze each aspect information while grasping the time when each aspect information was calculated.

Features G14. First control means (main CPU 63) having the specific storage execution means,
Second control means (management side CPU 112) having the information calculation means,
Equipped with
The information computing means computes the aspect information when the second control means receives the computation trigger information transmitted from the first control means, according to any one of features G1 to G13. Game machine.

According to the characteristic G14, in the configuration in which the processing load of the first control means is reduced by providing the second control means having the information calculation means separately from the first control means, an aspect based on an instruction from the first control means The information can be calculated by the second control means.

Feature G15. A notification control unit (a function of executing the processes of steps S3205, S3207, and S3208 in the main CPU 63) that controls the notification unit (the notification light emitting unit 651) to notify the content corresponding to the aspect information is provided. The gaming machine according to any one of the features G1 to G14.

According to the feature G15, the content corresponding to the aspect 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 the mode information from the game machine.

Feature G16. The control board (main control board 61) provided with the notification control means is housed in a board box,
The gaming machine according to feature G15, wherein the notification unit is provided on the control board.

According to the feature G16, it becomes possible to make it difficult to illegally access the communication path between the notification control unit and the notification unit.

Feature G17. First control means (main CPU 63) having the information calculation means and the notification control means,
Second control means (management side CPU 112) having the predetermined storage execution means,
The gaming machine described in the feature G15 or G16, which is characterized in that

According to Feature G17, in a configuration in which the processing load of the first control means is reduced by providing the second control means having the predetermined storage means separately from the first control means, the function of calculating the aspect information and the calculation result thereof It is possible to integrate the function for executing the notification corresponding to the first control means.

Features G18. The notification control means controls the notification means so that the first notification is executed when the aspect information is the information of the first range, and when the aspect information is the information of the second range, The gaming machine according to any one of features G15 to G17, characterized in that the notifying means is controlled so that the second notification is executed.

According to the feature G18, not the aspect information is reported 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 notification means from having too many notification patterns, and it is possible to reduce the load for controlling the notification means.

Features G19. Predetermined ball entering means (out port 24a, general winning hole 31, special electric prize 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 entering means, the corresponding information is stored in the predetermined storage means (the history memory 117 in the first to fifteenth and seventeenth to eighteenth embodiments, the sixteenth embodiment). Then, the predetermined information (history information in the first to fourteenth and eighteenth embodiments, numerical information measured by the counter in the fifteenth to seventeenth embodiments) is executed by being executed in the main RAM 65). Is stored in the predetermined storage means (in the first to fifteenth and seventeenth to eighteenth embodiments, a function of executing history setting processing in the management CPU 112, in the sixteenth embodiment A function of executing steps S2902, S2905, S2908, S2912, S2916, S2920 and S2923 in the main CPU 63),
Information calculating means (first to seventh, eighth, twelfth, fourteenth, fourteenth, fourteenth, fourteenth, fourteenth In the fifteenth, sixteenth, and eighteenth embodiments, the management CPU 112 executes the processing of steps S1608, S1613, and S1617. In the twelfth embodiment, the management CPU 112 performs the processing of steps S2008, S2013, and S2017. Function for executing step S2202 in the management-side CPU 112 in the tenth embodiment, function for executing step S2402 in the management-side CPU 112 in the eleventh embodiment, management in the thirteenth embodiment The function of executing the process of step S2605 in the side CPU 112, the function of executing the process of step S3203 in the main CPU 63 in the seventeenth embodiment),
A gaming machine characterized by being equipped with.

According to the feature G19, when a game ball enters the predetermined ball entering means, a storage process of information corresponding to the game ball is executed in the predetermined storage means, and the predetermined information is stored in the predetermined storage means. Become. As a result, it becomes possible for the gaming machine to store and hold information for managing the number of balls or the frequency of entering the game balls into the predetermined ball entering means. By using this managed information, the predetermined information can be stored. It is possible to appropriately manage the entering mode of the game ball into the entering device. Further, by storing and holding the predetermined information in the gaming machine itself, it becomes possible to prevent unauthorized access or unauthorized modification of the predetermined information.

Further, using the predetermined information stored in the predetermined storage means, the mode information corresponding to the entering mode of the game ball is calculated in the game machine. As a result, for example, it becomes possible for the gaming machine itself to perform the process corresponding to the entering mode of the game ball, or it is possible to output the mode information which is the result of the calculation using the predetermined information. ..

Feature G20. The gaming machine according to any one of features G1 to G19, wherein the predetermined storage execution means or the second control means is provided as a dedicated circuit.

According to the characteristic G20, it is possible to obtain the excellent effect as already described in the configuration in which the predetermined storage executing means or the second control means is provided as a dedicated circuit.

It should be noted that features A1 to A36, features B1 to B12, features C1 to C12, features D1 to D3, features E1 to E11, features F1 to F41, features G1 to G20, and features H1 to the configurations of the features G1 to G20. Any one or a plurality of configurations of H19, features I1 to I7, features J1 to J4, features K1 to K10, and features L1 to L7 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

<Feature H group>
Features H1. When a predetermined event occurs as a result of the game, the storage of the information corresponding to the predetermined event is stored in the predetermined storage means (the history memory 117 in the first to fifteenth and seventeenth to eighteenth embodiments, the main side in the sixteenth embodiment). The predetermined information (history information in the first to fourteenth and eighteenth embodiments, numerical information measured by the counter in the fifteenth to seventeenth embodiments) is executed by the RAM65). Predetermined storage execution means to be stored in the storage means (a function for executing history setting processing in the management side CPU 112 in the first to fifteenth, seventeenth to eighteenth embodiments, a main CPU63 in the sixteenth embodiment). In step S2902, step S2905, step S2908, step S2912, step S2916, step S2920, and step S2923)).
Information calculation means (first to seventh, eighth, twelfth) for calculating the mode information corresponding to the result of the game in the predetermined period by using the predetermined information each time a predetermined calculation trigger occurs. In the fourteenth, fifteenth, sixteenth and eighteenth embodiments, the management CPU 112 has a function of executing steps S1608, S1613 and S1617. In the twelfth embodiment, the management CPU 112 has steps S2008 and S2013. And a function to execute the process of step S2017, a function to execute the process of step S2202 in the management CPU 112 in the tenth embodiment, a function to execute the process of step S2402 in the management CPU 112 in the eleventh embodiment, and a thirteenth embodiment. Embodiment, the function of executing the process of step S2605 in the management-side CPU 112, and the function of executing the process of step S3203 in the main-side CPU 63 in the seventeenth embodiment).
Result storage executing means for sequentially storing the mode information calculated by the information calculating means in the calculation result storage means (calculation result memory 631) (in the ninth embodiment, step S2010, step S2014 and step S2018 in the management CPU 112). Function for executing the processing of step S2204 in the management-side CPU 112 in the tenth embodiment),
A gaming machine characterized by being equipped with.

According to the characteristic H1, when a game ball enters the predetermined ball entering means, the corresponding information is stored in the predetermined storing means, and the predetermined information is stored in the predetermined storing means. .. As a result, it becomes possible for the gaming machine to store and hold information for managing the number of balls or the frequency of entering the game balls into the predetermined ball entering means. By using this managed information, the predetermined information can be stored. It is possible to appropriately manage the entering mode of the game ball into the entering device. Further, by storing and holding the predetermined information in the gaming machine itself, it becomes possible to prevent unauthorized access or unauthorized modification of the predetermined information.

Further, using the predetermined information stored in the predetermined storage means, the mode information corresponding to the result of the game in the predetermined period is calculated in the gaming machine. Thereby, for example, it becomes possible for the gaming machine itself to perform a process corresponding to the result of the game in a predetermined period, or it is possible to externally output the mode information which is the result of the 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 collectively read a plurality of aspect information when managing the aspect of the result of the game in a predetermined period.

Features H2. The result storage execution means is provided with means (a function of executing the process of step S2204 in the management side CPU 112) for storing the mode information in the calculation result storage means when the mode information is storage target information. The gaming machine described in the feature H1.

According to the feature H2, when the aspect information of the calculated result corresponds to the storage target information, the aspect information is stored in the arithmetic result storage means. As a result, it becomes possible to limit the form information to be stored in the calculation result storage means, and it is possible to suppress the storage capacity required in the calculation result storage means.

Features H3. The game according to the feature H1 or H2, characterized in that the result storage execution means stores information in the operation result storage means in association with the aspect information, which makes it possible to specify the time when the aspect information is calculated. Machine.

According to the characteristic H3, the information that enables the time when the aspect information is calculated is to be attached to the aspect information. Thereby, it becomes possible to analyze each aspect information while grasping the time when each aspect information was calculated.

Features H4. The predetermined storage execution means is means for causing the predetermined storage means to store information that enables identification of whether or not the occurrence of the predetermined event is in a predetermined situation (in the first to thirteenth embodiments). The function of executing the processing of steps S1204 and S1209 in the management CPU 112, the function of executing the processing of step S2704 in the management CPU 112 in the fourteenth embodiment, and the processing of step S2803 in the management CPU 112 in the fifteenth embodiment. Function to execute)
The information computing means computes the aspect information by extracting or excluding the predetermined information corresponding to the occurrence of the predetermined event in the predetermined situation (first to seventh, eighth, tenth, tenth). In the fourteenth, fifteenth, sixteenth, and eighteenth embodiments, the function of executing the processes of step S1608, step S1613, and step S1617 in the management-side CPU 112, and in the ninth embodiment, step S2008, step S2013, and step in the management-side CPU 112. A function of executing the process of S2017, a function of executing the process of step S2202 in the management CPU 112 in the tenth embodiment, a function of executing the process of step S2402 in the management CPU 112 in the eleventh embodiment, and a thirteenth embodiment. Any one of the features H1 to H3, which has a function of executing the process of step S2605 in the management-side CPU 112 in the embodiment, and a function of executing the process of step S3203 in the main-side CPU 63 in the seventeenth embodiment). The gaming machine described in 1.

According to the characteristic H4, it is possible to calculate whether or not the situation is the predetermined situation, and to calculate the mode information corresponding to the result of the game in the predetermined period.

Features H5. When the aspect information is calculated by the information calculation means, means for deleting the predetermined information stored in the predetermined storage means (first to seventh, eighth, fourteenth, fifteenth, sixteenth, sixteenth 18th embodiment has a function of executing the process of step S1619 in the management-side CPU 112, and has a function of executing the process of step S2205 in the management-side CPU 112 in the 12th embodiment). The gaming machine according to any one of 1.

According to the characteristic H5, when the aspect information is calculated, the predetermined information stored in the predetermined storage means is deleted, so that it is difficult for the predetermined information to exceed the storage capacity of the predetermined storage means. It becomes possible.

Features H6. A feature H1 characterized in that even if the aspect information is calculated by the information calculation means, the state in which the predetermined information used when calculating the aspect information is stored in the predetermined storage means is maintained. The gaming machine according to any one of to H5.

According to the feature H6, even if the mode information is calculated, the predetermined information used when calculating the mode information is stored and held in the predetermined storage means, so that the mode information is read and the game in the predetermined period is played. When analyzing the result of (3), it is possible to refer not only to the aspect information but also to the predetermined information that is the basis of the calculation of the aspect information.

Features H7. A feature H1 characterized in that the information computing means computes the mode information when the supply of the operating power to the control means (MPU 62) is stopped or when the supply of the operating power to the control means is started. The gaming machine according to any one of to H6.

According to Feature H7, the aspect information is calculated when the supply of the operating power to the control means is stopped or when the supply of the operating power to the control means is started, and therefore the aspect information is calculated for each business day. It becomes possible to manage.

Features H8. Any of the features H1 to H7, wherein the information computing unit computes the aspect information when a computation trigger that may occur repeatedly occurs in a situation where operating power is being supplied to the control unit (MPU 62). The gaming machine described in 1.

According to the feature H8, the mode information is calculated every time a calculation trigger repeatedly occurs in the situation where the operating power is being supplied to the control means. Therefore, the mode information should be managed finely within the range of one business day. Is possible.

Features H9. The information calculation means calculates the aspect information every time the period measured by the period measurement means (measurement counter provided in the main RAM 65) reaches a predetermined period,
The period measuring means stops the measurement of the period when the game is not being executed, and restarts the measurement of the period from the state before the stop when the game is started in the situation where the measurement of the period is stopped. The gaming machine according to any one of the features H1 to H8.

According to the characteristic H9, 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, when the game is not being executed, the measurement for the predetermined period is stopped, and when the game is started, the measurement for the predetermined period is restarted from the state before the stop. This makes it possible to exclude the situation where the game is not being executed from the calculation target of the situation information, and it is possible to appropriately derive the situation information in the situation where the game is being performed.

Feature H10. Features H1 to H9, which are provided with an external output unit (a function for executing an external output process in the management side CPU 112) that outputs the aspect information calculated by the information calculation unit to a device outside the gaming machine. The gaming machine according to any one of 1.

According to the feature H10, the aspect information is output to the device outside the gaming machine, so that the entering aspect of the game ball can be easily grasped.

Feature H11. The gaming machine according to feature H10, wherein the external output unit outputs the predetermined information to a device outside the gaming machine when the aspect information is output to a device outside the gaming machine.

According to the feature H11, not only the aspect information but also the predetermined information is output to the device outside the gaming machine, so that when the aspect information is read and the entering aspect of the game ball is analyzed, not only the aspect information but also the aspect information It is possible to refer to the predetermined information that is the basis of the calculation of the aspect information.

Features H12. First control means (main CPU 63) having the specific storage execution means,
Second control means (management side CPU 112) having the external output means,
Equipped with
The external output means outputs the aspect information to a device external to the gaming machine when the second control means receives the output instruction information transmitted from the first control means. The gaming machine described in H11.

According to Feature H12, in the configuration in which the processing load of the first control means is reduced by providing the second control means having the external output means separately from the first control means, an aspect based on an instruction from the first control means The information can be output to a device outside the gaming machine.

Features H13. First control means (main CPU 63) having the specific storage execution means,
Second control means (management side CPU 112) having the information calculation means,
Equipped with
The information calculation means calculates the aspect information when the second control means receives the calculation trigger information transmitted from the first control means. Game machine.

According to Feature H13, in the configuration in which the processing load of the first control means is reduced by providing the second control means having the information calculation means separately from the first control means, an aspect based on an instruction from the first control means The information can be calculated by the second control means.

Features H14. A notification control unit (a function of executing the processes of steps S3205, S3207, and S3208 in the main CPU 63) that controls the notification unit (the notification light emitting unit 651) to notify the content corresponding to the aspect information is provided. The gaming machine according to any one of features H1 to H13.

According to the characteristic H14, the content corresponding to the aspect 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 the mode information from the game machine.

Feature H15. The control board (main control board 61) provided with the notification control means is housed in a board box,
The gaming machine according to Feature H14, wherein the notification unit is provided on the control board.

According to the feature H15, it becomes possible to make it difficult to illegally access the communication path between the notification control unit and the notification unit.

Feature H16. First control means (main CPU 63) having the specific storage execution means,
Second control means (management side CPU 112) having the predetermined storage execution means,
Equipped with
The game machine according to feature H14 or H15, wherein the first control means includes the information calculation means and the notification control means.

According to Feature H16, in a configuration in which the processing load of the first control means is reduced by providing the second control means having the predetermined storage means separately from the first control means, the function of calculating the aspect information and the calculation result thereof It is possible to integrate the function for executing the notification corresponding to the first control means.

Feature H17. The notification control means controls the notification means so that the first notification is executed when the aspect information is the information of the first range, and when the aspect information is the information of the second range, The gaming machine according to any one of features H14 to H16, characterized in that the notifying means is controlled so that the second notification is executed.

According to the feature H17, the contents corresponding to the range including the form information are notified instead of notifying the form information as it is. As a result, it is possible to prevent the notification means from having too many notification patterns, and it is possible to reduce the load for controlling the notification means.

Feature H18. Predetermined ball entering means (out port 24a, general winning hole 31, special electric prize 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 entering means, the corresponding information is stored in the predetermined storage means (the history memory 117 in the first to fifteenth and seventeenth to eighteenth embodiments, the sixteenth embodiment). Then, the predetermined information (history information in the first to fourteenth and eighteenth embodiments, numerical information measured by the counter in the fifteenth to seventeenth embodiments) is executed by being executed in the main RAM 65). Is stored in the predetermined storage means (in the first to fifteenth and seventeenth to eighteenth embodiments, a function of executing history setting processing in the management CPU 112, in the sixteenth embodiment A function of executing steps S2902, S2905, S2908, S2912, S2916, S2920 and S2923 in the main CPU 63),
Every time a predetermined calculation trigger occurs, the predetermined information is used to calculate the mode information corresponding to the entering mode of the game ball in the game area in the predetermined period (first to first). In the seventh, eighth, twelfth, fourteenth, fifteenth, sixteenth, and eighteenth embodiments, the management side CPU 112 executes the processing of steps S1608, S1613, and S1617. In the eleventh embodiment, the management side. A function of the CPU 112 that executes the processing of steps S2008, S2013, and S2017, a function of the management CPU 112 that executes the processing of step S2202 in the tenth embodiment, and a processing of step S2402 of the management CPU 112 that is the eleventh embodiment. A function of executing step S2605 in the management-side CPU 112 in the thirteenth embodiment, a function of executing step S3203 in the main-side CPU 63 in the seventeenth embodiment),
Result storage executing means for sequentially storing the mode information calculated by the information calculating means in the calculation result storing means (calculation result memory 631) (in the twelfth embodiment, step S2010, step S2014 and step S2018 in the management CPU 112). Function for executing the processing of step S2204 in the management side CPU 112 in the thirteenth embodiment),
A gaming machine characterized by being equipped with.

According to the feature H18, when a game ball enters the predetermined ball entering means, a storage process of information corresponding to the game ball is executed in the predetermined storage means, and the predetermined information is stored in the predetermined storage means. Become. As a result, it becomes possible for the gaming machine to store and hold information for managing the number of balls or the frequency of entering the game balls into the predetermined ball entering means. By using this managed information, the predetermined information can be stored. It is possible to appropriately manage the entering mode of the game ball into the entering device. Further, by storing and holding the predetermined information in the gaming machine itself, it becomes possible to prevent unauthorized access or unauthorized modification of the predetermined information.

Further, using the predetermined information stored in the predetermined storage means, the mode information corresponding to the entering mode of the game ball is calculated in the game machine. As a result, for example, it becomes possible for the gaming machine itself to perform the process corresponding to the entering mode of the game ball, or it is possible to output the mode information which is the result of the calculation using the predetermined information. ..

In addition, it becomes possible to accumulate the mode information in the gaming machine. This makes it possible to collectively read a plurality of aspect information when managing the aspect of the result of the game in a predetermined period.

Features H19. The gaming machine according to any one of features H1 to H18, wherein the predetermined storage execution means or the second control means is provided as a dedicated circuit.

According to the feature H19, it is possible to obtain the excellent effects as already described in the configuration in which the predetermined storage executing means or the second control means is provided as a dedicated circuit.

In addition, with respect to the configurations of the features H1 to H19, the features A1 to A36, the features B1 to B12, the features C1 to C12, the features D1 to D3, the features E1 to E11, the features F1 to F41, the features G1 to G20, and the features H1 to H1. Any one or a plurality of configurations of H19, features I1 to I7, features J1 to J4, features K1 to K10, and features L1 to L7 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

<Feature group I>
Feature I1. When a predetermined event occurs as a result of the game, the storage of the information corresponding to the predetermined event is stored in the predetermined storage means (the history memory 117 in the first to fifteenth and seventeenth to eighteenth embodiments, the main side in the sixteenth embodiment). The predetermined information (history information in the first to fourteenth and eighteenth embodiments, numerical information measured by the counter in the fifteenth to seventeenth embodiments) is executed by the RAM65). First storage execution means to be stored in the storage means (a function for executing history setting processing in the management side CPU 112 in the first to fifteenth, seventeenth to eighteenth embodiments, a main side in the sixteenth embodiment) A function of executing steps S2902, S2905, S2908, S2912, S2916, S2920 and S2923 in the CPU 63),
When a specific event occurs as a result of a game, specific information is stored in the predetermined storage means so that the corresponding information is stored in the specific storage (history information in the first to fourteenth and eighteenth embodiments. In the fifteenth to seventeenth embodiments, the second storage execution means (first to fifteenth, seventeenth to eighteenth embodiments) that 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 of steps S2902, S2905, S2908, S2912, S2916, S2920, and S2923 in the main CPU 63 in the sixteenth 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 that the predetermined information can be recognized as corresponding to the predetermined event. Function for executing external output processing in), and
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 that the specific information can be recognized as corresponding to the specific event. Function for executing external output processing in), and
A gaming machine characterized by being equipped with.

According to the characteristic I1, it becomes possible to read the information stored in the predetermined storage means 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 specific information corresponds to the specific event while the specific information corresponds to the specific event, and the specific information corresponds to the specific event. The specific information is output to the outside so as to be recognized. With this, even if the second control unit does not process the information, it is possible to specify the occurrence mode of each event by using the information read from the predetermined storage unit.

Feature I2. The gaming machine according to feature I1, further comprising means (a function of executing the process of step S220 in the main CPU 63) that externally outputs corresponding information when the predetermined event occurs.

According to the characteristic I2, the predetermined information is stored in the predetermined storage means in the configuration in which the corresponding information corresponding to the predetermined event is output to the outside when the predetermined event occurs. This makes it possible to accurately grasp the number of occurrences and the frequency of occurrence of a predetermined event by using the correspondence information, and accurately determine the number of occurrences and the frequency of occurrence of a predetermined event by using the predetermined information stored in the predetermined storage means. It becomes possible to grasp.

Feature I3. The gaming machine according to feature I1 or I2, wherein the predetermined information is information on the number of times the predetermined event has occurred, and the specific information is information on the number of times the specific event has occurred.

According to the characteristic I3, the predetermined information is the count information of the number of times the predetermined event has occurred, and the specific information is the count information of the number of times the specific event has occurred. Therefore, while suppressing the information capacity of the predetermined information and the specific information, It is possible to manage the occurrence mode of a predetermined event and the occurrence mode of a specific event.

Feature I4. A program output unit (function of executing the process of step S1503 in the main CPU 63) that outputs a control program to a device outside the gaming machine using the information output unit (reading terminal 102) is provided.
The first external output means and the second external output means utilize the information output section to output the information stored in the predetermined storage means to a device external to the gaming machine. The gaming machine according to any one of I3.

According to the characteristic I4, it is possible to output the information stored in the predetermined storage means to the outside by using the information output unit for outputting the control program to the outside. This makes it possible to output the information stored in the predetermined storage means to the outside while preventing the configuration from becoming complicated.

Feature I5. A selection unit that specifies whether the information to be output from the information output unit is the information stored in the predetermined storage unit or the control program, and outputs the information corresponding to the identification result ( The game machine according to feature I4, which is provided with a function of executing the process of step S1502 in the main CPU 63.

According to the feature I5, in the configuration in which the information output unit for externally outputting the control program is used to externally output the information stored in the predetermined storage unit, 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. This makes it possible to read out only the necessary information even if the information output section is also used.

Feature I6. The selecting means, based on information received from an external device electrically connected to the information output part, information to be output from the information output part is stored in the predetermined storage part and the control program is stored. The gaming machine according to feature I5, characterized in that it identifies which one of them.

According to the feature I6, which information is to be output from the information output unit is specified based on the information received from the external device electrically connected to the information output unit. As a result, it is possible to prevent the configuration regarding the selection of the information to be output from becoming complicated.

Feature I7. A chip (MPU 62) having a program storage unit (main side ROM 64) that stores the control program in advance has the information output unit, the first external output unit, and the second external output unit. The gaming machine according to any one of features I4 to I6.

According to the feature I7, the signal paths for the information output unit can be integrated in the chip. As a result, it is possible to obtain the excellent effects as already described while making it difficult to illegally access the signal path to the information output unit.

In addition, with respect to the configurations of the features I1 to I7, the features A1 to A36, the features B1 to B12, the features C1 to C12, the features D1 to D3, the features E1 to E11, the features F1 to F41, the features G1 to G20, and the features H1 to H1. Any one or a plurality of configurations of H19, features I1 to I7, features J1 to J4, features K1 to K10, and features L1 to L7 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

<Feature J group>
Features J1. Program output means (a function for executing the process of step S1503 in the main CPU 63) that outputs a control program to a device outside the gaming machine using the information output unit (reading terminal 102),
An information output unit (a function for executing external output processing in the management-side CPU 112) that outputs special information using the information output unit;
A gaming machine characterized by being equipped with.

According to the feature J1, 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 the special information to the outside while preventing the configuration from becoming complicated.

Features J2. Selection means for specifying whether the information to be output from the information output unit is the special information or the control program and outputting the information corresponding to the specified result (step S1502 in the main CPU 63) The game machine according to the feature J1 is provided with a function of executing the process (1).

According to the feature J2, in the configuration in which the special information is externally output by using the information output unit for externally outputting the control program, the information targeted for external 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. This makes it possible to read out only the necessary information even if the information output section is also used.

Features J3. The selection means determines, based on information received from an external device electrically connected to the information output unit, whether the information to be output from the information output unit is the special information or the control program. The game machine according to feature J2, which is characterized by being specified.

According to the feature J3, based on the information received from the external device electrically connected to the information output unit, which information is to be output from the information output unit is specified. As a result, it is possible to prevent the configuration regarding the selection of the information to be output from becoming complicated.

Features J4. Any one of features J1 to J3 characterized in that a chip (MPU 62) having a program storage means (main side ROM 64) for storing the control program in advance has the information output section and the information output means. Gaming machine described in.

According to the feature J4, the signal paths for the information output unit can be integrated in the chip. As a result, it is possible to obtain the excellent effects as already described while making it difficult to illegally access the signal path to the information output unit.

In addition, with respect to the configurations of the features J1 to J4, the features A1 to A36, the features B1 to B12, the features C1 to C12, the features D1 to D3, the features E1 to E11, the features F1 to F41, the features G1 to G20, and the features H1 to H1. Any one or a plurality of configurations of H19, features I1 to I7, features J1 to J4, features K1 to K10, and features L1 to L7 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

<Characteristic K group>
Features K1. A first control means (main CPU 63) and a second control means (management CPU 112),
The first control means is
A privilege giving means (a function for executing the process of step S219 in the main CPU 63, a function for executing the process of step S1008 in the payout CPU 92) for giving a privilege to the player when a predetermined event occurs,
An information transmitting unit (a function for executing management output processing in the main CPU 63) that transmits predetermined event information corresponding to the predetermined event when the predetermined event occurs;
Equipped with
The second control means stores the information corresponding to the predetermined event information when the predetermined event information is received (in the first to fifteenth and seventeenth to eighteenth embodiments, the history memory 117 and the sixteenth history memory). In the embodiment, by being executed in the main RAM 65), the predetermined information (first to fourteenth) that enables the gaming machine or a device outside the gaming machine to specify the number of times or frequency of occurrence of the predetermined event. The predetermined storage execution means (first to fifteenth) for storing history information in the eighteenth embodiment and numerical information measured by a counter in the fifteenth to seventeenth embodiments). In the seventeenth to eighteenth embodiments, a function of executing history setting processing in the management side CPU 112, and in the sixteenth embodiment, steps S2902, S2905, S2908, S2912, S2916, and S2920 in the main CPU63 are executed. A game machine having a function of executing the process of step S2923.

According to the characteristic K1, a privilege is given to the player when a predetermined event occurs. As a result, the player will play the game while expecting that a predetermined event will occur. In the configuration, when a predetermined event occurs, the information corresponding to the predetermined event is stored in the predetermined storage means, and the number of times or the frequency of occurrence 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 for the gaming machine to store and hold information for managing the number of times or frequency of occurrence of a predetermined event, and by using this managed information, it is possible to appropriately manage the occurrence mode of the predetermined event. It becomes possible to do it. Further, by storing and holding the predetermined information in the gaming machine itself, it becomes possible to prevent unauthorized access or unauthorized modification of the predetermined information.

Further, since the second control means provided separately from the first control means having the privilege granting means has the predetermined storage executing means, the processing load of the first control means is prevented from extremely increasing. However, it is possible to obtain the excellent effects as already described.

Features K2. The gaming machine according to feature K1, wherein the first control means and the second control means are provided on the same chip.

According to the characteristic K2, since the first control means and the second control means are provided in 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 prevent it.

Features K3. When the specific event occurs, the predetermined storage execution means executes a storage process of information corresponding to the specific event in the predetermined storage means to determine the number of occurrences or the frequency of occurrence of the specific event in the gaming machine or the outside of the gaming machine. Specific information (historical information in the first to fourteenth and eighteenth embodiments, numerical information measured by a counter in the fifteenth to seventeenth embodiments) that can be specified by the device is stored in the predetermined storage means. So that
The first control means is
First transmitting means for transmitting the first information to the second control means using the first signal path when the predetermined event occurs (function of outputting any one of the first to seventh signals in the main CPU 63) )When,
Second transmitting means for transmitting the second information to the second control means using the second signal path when the specific event occurs (function of outputting any one of the first to seventh signals in the main CPU 63) )When,
The gaming machine according to the feature K1 or K2, which is characterized by comprising:

According to the characteristic K3, 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 means. This makes it 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 becomes 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 a specific event occurs, the second information is utilized by 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 it is possible to simplify the configuration for distinguishing each type of information in the second control means.

Features K4. The first control means transmits, to the second control means, identification information that enables the second control means to identify whether or not a predetermined situation is present, using the third route. (In the first to seventh, ninth to fifteenth, and eighteenth embodiments, the function of outputting any of the eighth to tenth signals in the main CPU 63, and in the sixth embodiment, the opening/closing execution mode in the main CPU63. A game machine according to Feature K3, which is provided with a function of outputting one of a medium signal, a high-frequency support mode medium signal, and a door opening signal.

According to the characteristic K4, 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 the predetermined situation. Further, since the identification information that enables identification of whether or not the predetermined situation is present is transmitted to the second control means using the third route, the second control means transmits the identification information to the first information and the first information. It is possible to simplify the configuration for distinguishing it from other information such as 2 information.

Features K5. 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 described in the characteristic K3 or K4, which is provided with a transmitting unit (a function of executing a recognition process in the main CPU 63).

According to the characteristic K5, 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 means to the second control means. It is not necessary for the second control means to store the correspondence of these pieces of information in advance. This makes it possible to increase the versatility of the second control means.

Features K6. The gaming machine according to Feature K5, wherein the identification information transmission unit transmits the identification information to the second control unit when supply of operating power to the first control unit is started.

According to the characteristic K6, since the identification information is transmitted from the first control means to the second control means when the supply of the operating power to the first control means is started, a predetermined event and a specific event may occur. In the situation, it becomes possible for the second control means to be able to specify the correspondence between the information transmitted from the first control means and the ball entry means.

Features K7. The identification information transmission means transmits the identification information to the second control means by using at least one of the first signal path and the second signal path. Amusement machine.

According to the characteristic K7, since the identification information is transmitted to the second control means by 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. It is possible to simplify the configuration related to communication as compared with.

Features K8. Correspondence relationship information that enables the second control means to specify that the first information corresponds to the predetermined event and the second information corresponds to the specific event when the identification information is received. The correspondence storage means (correspondence memory 116) stores means (function for executing correspondence setting processing in the management-side CPU 112) according to any one of characteristics K5 to K7. Amusement machine.

According to the characteristic K8, the correspondence between the information transmitted from the first control means and the type of event is stored in the second control means. Thereby, the second control means is provided with information that enables the second control means to specify the type of event corresponding to the information to be transmitted, every time the first information or the second information is transmitted from the first control means. There is no need to do it. Therefore, the information amount of the first information and the second information can be suppressed.

Features K9. The first control means transmits third information, which enables the second control means to specify whether or not a predetermined situation is present, to the second control means by using a third route. (In the first to seventh, ninth to fifteenth and eighteenth embodiments, the function of outputting any of the eighth to tenth signals in the main CPU 63, and in the sixth embodiment, the open/close execution mode in the main CPU63. The function to output one of the medium signal, high frequency support mode signal and door open signal),
A feature K5 characterized in that 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. The gaming machine according to any one of to K8.

According to the characteristic K9, 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 the predetermined situation. Further, the fact that the third information is information that can identify whether or not the predetermined condition is present can be identified by the second control means without receiving the identification information from the first control means. .. This makes it possible to prevent the information form of the identification information from becoming complicated.

Features K10. The game machine according to any one of features K1 to K9, wherein the second control means is provided as a dedicated circuit.

According to the characteristic K10, it is possible to obtain the excellent effects as already described in the configuration in which the second control means is provided as a dedicated circuit.

It should be noted that features A1 to A36, features B1 to B12, features C1 to C12, features D1 to D3, features E1 to E11, features F1 to F41, features G1 to G20, and features H1 to the configurations of the features K1 to K10. Any one or a plurality of configurations of H19, features I1 to I7, features J1 to J4, features K1 to K10, and features L1 to L7 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

According to the invention related to the characteristic E group, the characteristic F group, the characteristic G group, the characteristic H group, the characteristic I group, and the characteristic J group, the following problems can be solved.

Pachinko gaming machines and slot machines are known as gaming machines. For example, in a pachinko game machine, the game machine front face section is provided with a dish storage section for storing the game balls given to the player, and the game balls stored in the dish storage section are guided to the game ball launching device. , Is fired toward the game area in accordance with the player's firing operation. Then, for example, when the game ball enters the ball entering portion provided in the game area, for example, the game ball is paid out from the payout device to the dish storage part. In addition, in the pachinko gaming machine, a configuration is also known that includes an upper plate storage part and a lower plate storage part as a plate storage part. In this case, the game balls stored in the upper plate storage part are launched. Guided by the device, the excess game balls in the upper dish storage section are discharged to the lower dish storage section.

Here, in the gaming machine as exemplified above, it is necessary to manage the gaming machine appropriately, and there is still room for improvement in this respect.

<Feature L group>
Feature L1. First control means (main side CPU 63),
Second control means (management side CPU 112) for receiving the information transmitted from the first control means,
Equipped with
The first control means is
First transmission means for transmitting the first information to the second control means using the first signal path when the first event occurs (function of outputting any one of the first to seventh signals in the main CPU 63) )When,
Second transmitting means for transmitting the second information to the second control means using the second signal path when the second event occurs (function of outputting any one of the first to seventh signals in the main CPU 63) )When,
Identification information transmitting means (main side) for transmitting to the second control means identification information indicating that the first information corresponds to the first event and the second information corresponds to the second event. A function of executing recognition processing in the CPU 63),
A gaming machine characterized by being equipped with.

According to the feature L1, the first information is transmitted to the second control means using the first signal path when the first event occurs, and the second signal path is used when the second event occurs. 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 it is possible to simplify the configuration for distinguishing each type of information in the second control means.

Further, since the identification information indicating that the first information corresponds to the first event and the second information corresponds to the second event is transmitted from the first control unit to the second control unit, these information items are transmitted. It is not necessary for the second control means to previously store the correspondence relationship of. This makes it possible to increase the versatility of the second control means.

Feature L2. The gaming machine according to feature L1, wherein the identification information transmission 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 feature L2, when the supply of the operating power to the first control means is started, the identification information is transmitted from the first control means to the second control means, so the predetermined ball entry means and the specific ball entry means. In a situation in which a game ball may enter the ball, it is possible for the second controller to specify the correspondence between the information transmitted from the first controller and the ball entered. Become.

Feature L3. The identification information transmitting means transmits the identification information to the second control means by using at least one of the first signal path and the second signal path. Amusement machine.

According to the feature L3, since the identification information is transmitted to the second control means by 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. It is possible to simplify the configuration related to communication as compared with.

Feature L4. When the identification information is received, 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 features L1 to L3 characterized by including a unit (a function for executing the correspondence setting process in the management side CPU 112) for storing the relation information in the correspondence storage unit (correspondence memory 116). The game machine described.

According to the feature L4, the correspondence between the information transmitted from the first control means and the ball entry means is stored in the second control means. With this, it is necessary to provide the second control means with information that enables the second control means to identify an event corresponding to the information to be transmitted, every time the first control means transmits the first information or the second information. Disappears. Therefore, the information amount of the first information and the second information can be suppressed.

Feature L5. The first control means transmits third information, which enables the second control means to specify whether or not a predetermined situation is present, to the second control means by using a third route. (In the first to seventh, ninth to fifteenth, and eighteenth embodiments, the main CPU 63 outputs any of the eighth to tenth signals, and in the tenth embodiment, the main CPU 63 opens and closes the execution mode. The function to output one of the medium signal, high frequency support mode signal and door open signal),
A feature L1 characterized in that the second control means can recognize the third information as information that can identify whether or not the predetermined condition is present, without receiving the identification information. The gaming machine according to any one of to L4.

According to the feature L5, 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 the predetermined situation. Further, the fact that the third information is information that can identify whether or not the predetermined condition is present can be identified by the second control means without receiving the identification information from the first control means. .. This makes it possible to prevent the information form of the identification information from becoming complicated.

Feature L6. As a signal path capable of transmitting information from the first control unit to the second control unit, the number of types of information that is greater than the number of types of information that needs to be transmitted from the first control unit to the second control unit is used. The gaming machine according to any one of features L1 to L5, characterized in that a signal path is provided.

According to the feature L6, since the number of signal paths that is larger than the number of types of information that needs to be transmitted from the first control means to the second control means is provided, the number of signal paths of the information can be changed according to the model of the gaming machine. Even if the number of types is increased or decreased, it is possible to deal with it without changing the configuration related to the signal path. Therefore, it becomes possible to improve the versatility of the second control means.

Feature L7. The game machine according to any one of features L1 to L6, wherein the second control means is provided as a dedicated circuit.

According to the feature L7, it is possible to obtain the excellent effect as already described in the configuration in which the second control means is provided as a dedicated circuit.

In addition, with respect to the configurations of the features L1 to L7, the features A1 to A36, the features B1 to B12, the features C1 to C12, the features D1 to D3, the features E1 to E11, the features F1 to F41, the features G1 to G20, and the features H1 to H1. Any one or a plurality of configurations of H19, features I1 to I7, features J1 to J4, features K1 to K10, and features L1 to L7 may be applied. As a result, it is possible to exert a synergistic effect due to the combined configuration.

According to the invention related to the characteristic group K, the following problems can be solved.

Pachinko gaming machines and slot machines are known as gaming machines. For example, in a pachinko game machine, the game machine front face section is provided with a dish storage section for storing the game balls given to the player, and the game balls stored in the dish storage section are guided to the game ball launching device. , Is fired toward the game area in accordance with the player's firing operation. Then, for example, when the game ball enters the ball entering portion provided in the game area, for example, the game ball is paid out from the payout device to the dish storage part. In addition, in the pachinko gaming machine, a configuration is also known that includes an upper plate storage part and a lower plate storage part as a plate storage part. In this case, the game balls stored in the upper plate storage part are launched. Guided by the device, the excess game balls in the upper dish storage section are discharged to the lower dish storage section.

Here, in the gaming machine as illustrated above, it is necessary to make the configuration relating to communication suitable, and there is still room for improvement in this respect.

The following is a basic configuration of a gaming machine to which each of the above features can be applied or applied to each feature.

Pachinko gaming machine: operating means operated by a player, game ball launching means for launching a game ball based on the operation of the operating means, a ball passage for guiding the launched game ball to a predetermined game area, and a game A gaming machine that includes each game component arranged in the area, and gives a bonus to the player when a game ball passes through a predetermined passage portion of each of the game components.

Spinning machine such as slot machine: equipped with a pattern display device for variably displaying a plurality of patterns, the variable display of the plurality of patterns is started by the operation of the start operation means, and is caused by the operation of the stop operation means In addition, or after a lapse of a predetermined time, the variable display of the plurality of patterns is stopped, and a gaming machine which gives a privilege to the player according to the stopped patterns.

10... Pachinko machine, 24... Game board, 24a... Out opening, 24b... Nail, 27... Game ball launching mechanism, 31... General winning opening, 32... Special electricity winning device, 33... First operating opening, 34... Second operating Mouth, 34a... General electric utility, 35... First through gate, 39... Second through gate, 61... Main control board, 62... MPU, 63... Main CPU, 65... Main RAM, 92... Dispensing CPU , 102... Read terminal, 112... Management CPU, 116... Correspondence memory, 171... Passage entrance, 172... Escape passage, 173... Passage exit, 174... Exit roof, 180... Adjustment mechanism, 181c... Left standing wall , 181d... Right standing wall, 181e... Discharging protrusion, 181g... Discharging right side surface, 181h... Left standing wall, 183... Rotating body, 183b to 183e... Recessed portion, 184... Adjusting drive section, 185... Retrieval Mouth, 188-191... Blade part, 188a-191a... Circumferential surface, 188b-191b... Front surface, 192... Collision avoidance groove, 220... Adjusting mechanism, 230... Rotating body, 241-244... Support surface, 241a-244a... Step surface, 252... Upper right standing wall, 254... Rotating shaft, 256... Discharge port, 261... Left standing wall, 262... Intake port, 263a... Discharge protruding end, 291... Left guide nail, 292... Right guide nail , 330... Adjusting mechanism, 340... Rotating body, 343... Blade member, 344... Rotating shaft, 352... Standing wall, 371... Downstream guide nail, 430... Adjusting mechanism, 440... Rotating body, 472... Guide nail, 530... Adjusting mechanism, 545... Guide passage, 546... Adjusting part, 560... Electric nail, 560a... Nail driving part, 581... First operating port, 610... Game board, 620... Adjusting mechanism, 621... Discharge port, 631... Calculation Result memory, 651... Notification light emitting part, PA... Game area, C4... General electric utility object opening counter, C5... Opening initial value counter, T1... Low frequency winning determination value table.

Claims (2)

Profit giving means for giving advantageous profit to the player on the condition that at least one of the game balls has entered the ball entering portion ,
And guide means for guiding the game ball toward the ball entrance portion,
The guidance timing of the game ball guided by the guiding means at a predetermined time interval in the ball entrance portion is the grant timing when the game ball guided to the ball entrance portion becomes the trigger for granting the profit. Predetermined situation generating means for producing a predetermined situation to be dealt with,
A gaming machine characterized by being equipped with. The gaming machine according to claim 1, which is a pachinko machine.

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