JP4338033B2 - Bullet ball machine - Google Patents

Description

  The present invention relates to a ball game machine such as a pachinko game machine or an arrangement ball game machine that plays a game by firing a game ball toward a game board surface.

  2. Description of the Related Art Conventionally, a bullet ball game machine that plays a game by firing a game ball on the game board surface is widely known. In such a gaming machine, a plurality of entrances and various kinds of accessories are provided on the game board surface, and any one of the entrances or accessories entered while the game ball that has been launched falls on the game board surface. When a ball is played, a predetermined number of prize balls are paid out to the player according to the place where the ball is entered, and in order to enhance the player's interest, the game is produced by voice output, lighting, and various symbol displays. Is done.

  Further, in addition to such effects by voice, lighting, symbol display, etc., the effect of game effects is often increased by changing the movement of the game ball falling on the game board surface. For example, in Patent Document 1, a rotating body incorporating a magnet is provided on the game board surface, and a game ball that has passed near the rotating body is attracted to the magnet and transported to change the movement of the gaming ball. Giving technology has been proposed.

JP 2000-140250 A

  However, such an effect that changes the movement of the game ball by the transport body such as a rotating body is performed separately from the effect by voice, lighting, symbol display, etc., and thus it is difficult to increase the effect for enhancing the interest of the player. There was a problem. If a sensor for detecting a game ball can be provided on the carrier, an effect in accordance with the movement of the game ball can be performed by displaying the symbol, such as starting the symbol display in accordance with the detection timing of the game ball. Due to structural limitations, it may be difficult to provide such a sensor.

  The present invention has been made to solve the above-described problems, and it is possible to produce an effect in accordance with the movement of the game ball by a symbol display or the like without providing a sensor for directly detecting the game ball. The purpose is to provide a ball game machine.

In order to solve at least a part of the above-described problems, the bullet ball game machine of the present invention employs the following configuration. That is,
A ball game machine in which a central device having a game ball guidance mechanism is provided in a game area of a game board and performs a game by firing a game ball in the game area ,
The game ball guiding mechanism is:
An intake for taking a game ball into the central device;
A warp passage for guiding the game ball taken in from the intake to the first stage;
A second stage formed above the first stage and different from the first stage;
A rotator that has a game ball catcher capable of catching a game ball, and that is capable of transporting the game ball caught at the first stage by the game ball catcher to the second stage;
Consisting of
A drive motor for driving the rotating body ;
A load detector that detects a change in the amount of current supplied to the drive motor, and detects that a load applied to the drive motor has changed based on the detection result ;
And an effect control unit for effecting a game according to the detection result by the load detection unit,
The rotating body is formed in a cylindrical shape, and is arranged so that end portions of the first stage and the second stage are included in a space inside the cylinder of the rotating body,
The game ball capturing unit is provided on an inner peripheral surface of the rotating body,
When the game ball rolls on the first stage and reaches the inside of the rotating body, and the game ball capturing unit captures the game ball, the captured game ball moves along with the rotation of the rotating body. Conveyed to the second stage,
When the load detection unit detects the conveyance of the game ball by the rotating body, the production control unit executes the production in accordance with the movement of the game ball being conveyed .

In the ball game machine having such a configuration, the first stage continuing from the warp passage, the second stage formed in a step difference above the first stage, and the ends of the first stage and the second stage are included. Thus, a cylindrical rotating body is provided. Then, the game ball guided from the warp passage to the first stage is captured by the game ball capturing unit provided on the inner peripheral surface of the rotating body, and is transported to the second stage by the rotation of the rotating body. The rotating body is driven by a drive motor, and detects that the load (torque load) applied to the drive motor that drives the rotating body has changed based on a change in the amount of current supplied to the drive motor . And when conveyance of the game ball by a rotating body is detected based on the change of load, it produces an effect according to the movement of the game ball conveyed .

  Thus, according to the bullet ball game machine of the present invention, it is possible to determine the state of transport of the game ball by the transport body by detecting that the load of the drive motor has changed. As will be described in detail later, since the load of the drive motor can be detected relatively easily, an effect by sound output, an effect by blinking of a lamp, an LED, etc. without providing a sensor for directly detecting a game ball, Or the effect by a symbol display etc. can be performed according to the motion of a game ball, and the interest of a player can be raised further effectively. Further, if the load of the drive motor is detected, unlike the case where the game ball is directly detected, there is no restriction due to the structure of the carrier.

  As a configuration for detecting a load applied to the drive motor, the following modes can be exemplified. For example, since there is a relationship between the load applied to the drive motor and the amount of current supplied to the drive motor that increases when one increases, it is detected that the current supplied to the drive motor has changed. Based on the detection result, it may be detected that the load of the drive motor has changed. This is preferable because a load change of the drive motor can be detected with a simple configuration.

  Examples of the transport body for transporting the game ball include a belt conveyor that moves on a predetermined track, but in addition, a rotating body that can rotate while the game ball is captured by the game ball capturing section. May be adopted. By doing so, the movement of the game ball can be changed with a simpler configuration.

  Further, the game ball catching portion of such a carrier may be provided with a magnet for attracting the game ball in the game ball catching portion. If the game ball is captured using a magnet, the game ball can be reliably captured with a simple structure. As such a magnet, a neodymium magnet is preferably used. This is because the neodymium magnet is small and generates a strong magnetic field, so that the game ball can be reliably adsorbed.

  Further, in such a transport body, the game ball captured by the game ball capturing unit may be transported to a position higher than the capture position. If the transport body is configured in this way, the difference in load applied to the drive motor between the state where the game ball is transported and the state where the game ball is not transported becomes large, so that the load change can be detected more reliably. Can do. In addition, if the captured game ball is transported to a high position in this way, the game ball can be moved again from that position using gravity. As a result, the movement of the game ball can be greatly changed, and the interest of the player can be effectively enhanced.

Hereinafter, in order to clarify the contents of the present invention described above, examples will be described in the following order.
[1] First embodiment:
A. Pachinko machine configuration:
A-1. overall structure:
A-2. Game board surface structure:
A-3. Back side structure:
A-4. Configuration of pachinko machine control circuit:
B. Outline of action of prize ball:
C. Overview of pachinko machine control:
C-1. Operation immediately after power-on:
C-2. Control start preparation operation:
C-3. Game control overview:
C-3-1. Watchdog timer reset processing:
C-3-2. Motor load detection processing:
C-3-3. Normal symbol game start judgment processing:
C-3-4. Normal design game processing:
C-3-5. Normal electric game processing:
C-3-6. Special symbol game start decision processing:
C-3-7. Special design game processing:
C-3-8. Special electric game game processing:
C-4. Processing when power failure occurs:
D. Configuration of the game ball guidance mechanism:
E. Transporting game balls:
F. Drive motor load detection:
G. Processing details of motor load detection processing:
[2] Second embodiment:
A. Game board surface structure:
B. Configuration of variable pitching device and movement of game ball:

  The present invention can be applied to general ball game machines such as so-called pachinko machines, arrange ball game machines, and sparrow ball game machines. Hereinafter, a so-called “digital pachi” type pachinko machine (ball game machine) will be described. For example, a specific description will be given.

[1] First embodiment:
A. Pachinko machine configuration:
A-1. overall structure :
First, a rough structure of the pachinko machine 1 according to the first embodiment will be described with reference to FIGS. 1 and 2. FIG. 1 is a front view of the pachinko machine 1 when viewed from the front side of the pachinko machine 1 (that is, the player's side). FIG. 2 is a perspective view when the pachinko machine 1 is viewed obliquely from above. As shown in the figure, the pachinko machine 1 can be opened and closed mainly on an outer frame (also referred to as a main body frame) 2 in which a wooden plate is assembled and fixed in a substantially rectangular frame shape, and on the front surface of the outer frame 2. A plastic middle frame 3 that is pivotally supported, a plastic front frame 4 that is pivotally supported at the left end of the middle frame 3, and an upper platen 5 and a lower plate provided below the front frame 4 A part 6, a locking device 7 provided on the right side of the middle frame 3 for locking the front frame 4, and a game board (not shown) attached to the front side of the middle frame 3 are configured. The upper plate 5 is pivotally attached to the middle frame 3 so as to be openable and closable at a position just below the front frame 4 when the front frame 4 is locked. Further, the lower plate portion 6 is attached to the middle frame 3 at a position below the upper plate portion 5.

  As shown in FIG. 1, the front frame 4 occupies approximately 2/3 of the front surface of the pachinko machine 1, and a substantially circular opening 4 a is formed at a substantially central portion thereof. A game area to be described later is formed inside the opening 4a. A left LED display 4b having a substantially arc shape is provided on the left side of the opening 4a, and an upper left LED display unit 4d is provided on the outer upper side thereof, while a right LED having a substantially arc shape is provided on the right side of the opening 4a. The display unit 4c is provided with an upper right LED display unit 4e on the outer upper side thereof. In addition, two substantially circular middle and upper LED display portions 4f are arranged side by side above the opening 4a and between the left LED display portion 4b and the right LED display portion 4c. Between these two middle and upper LED display portions 4f, two prize ball LED display portions 4g are provided. These LED display portions 4d to 4g are turned on / off or blinking in accordance with the progress of the game for the purpose of enhancing the game effect. Further, a substantially fan-shaped error LED display portion 4h is provided above the prize ball LED display portion 4g. Furthermore, a glass frame 41s is attached to the back side of the front frame 4, and two glass plates 41r are attached to the glass frame 41s (see FIG. 2). A player of the pachinko machine 1 can visually observe the game area through the glass plate 41r. The game area will be described in detail later.

  In the upper plate part 5 provided below the front frame 4, a first sound output unit 5 c having a plurality of long holes, a dish outer edge part 5 a, and a game ball inside the pachinko machine 1 are placed in the upper plate part 5. A discharge port 5b for discharging is provided. The first sound output unit 5c is connected to a speaker 400a for generating sound effects or sounds according to the gaming state and a volume switch board 12 to be described later. The speaker 400a of the present embodiment is a multi-way system including a medium / high sound unit (tweeter) and a low sound unit (woofer), and the first sound output unit 5c includes a medium / high sound unit (tweeter). ) Are connected via a duct (not shown). The bass unit (woofer) is connected to a second audio output unit 6d described later via a duct (not shown). The dish outer edge 5a is provided with a ball removal button, a game ball rental / return button, and the like. In addition, the operation plate SW1 and SW2 are provided on the upper plate portion 5 of the present embodiment at the front left end portion. Further, the upper plate part 5 is provided with a supply device (not shown) for supplying the stored game balls to the launch device, a launch device unit (not shown) for firing the game balls, and the like.

  The lower pan 6 provided below the upper pan 5 is provided with a discharge port 6a at a substantially central portion, an ashtray 6b at the left end of the lower pan 6 and a launch handle 9 at the right end. It has been. A game ball is discharged from the inside of the pachinko machine 1 to the lower plate portion 6 from the discharge port 6a. Further, a ball punching hole (not shown) is provided on the bottom surface of the lower plate part 6. The ball hole is normally closed, but if the ball hole is opened by operating the discharge knob 6c provided on the substantially central front side of the lower plate part 6, the ball hole is stored in the lower plate part 6. The game ball can be discharged from the pachinko machine 1. The discharge knob 6c is normally in an upright state. When the lower end of the discharge knob 6c is pressed to the back side, the ball release hole is opened in conjunction with the movement of the knob, and the discharge knob 6c is locked in a tilted state. Thereby, the ball removal hole is held in an open state, and the game ball is discharged from the lower dish portion 6. Further, when the player presses the discharge knob 6c in the tilted state to the back side, the lock is released and the discharge knob 6c returns to the upright state, so that the ball hole is returned to the closed state.

  The launch handle 9 is connected to a launch device unit (not shown) that ejects a game ball toward the game area, and the player of the pachinko machine 1 controls the launch operation of the game ball by operating the launch handle 9. Can do. A touch switch 9a for detecting that the player is touching the handle is attached to the launch handle 9, and a launch stop switch 9b for temporarily stopping the launch of the game ball is attached in the vicinity thereof. Has been. A prepaid card unit 13 is provided on the left end side of the pachinko machine 1.

  Next, the configuration of the middle frame 3 will be described with reference to FIG. The middle frame 3 includes a frame body portion 3a and a lower plate portion 3b. Of these, the frame body portion 3a is in a position where the front frame 4 just covers when the front frame 4 is locked, that is, a position that occupies a size of about 2/3 from the upper end of the middle frame 3 downward. Is provided. Further, the lower plate portion 3b is provided at a position corresponding to the upper plate portion 5 and the lower plate portion 6, that is, a position occupying a size of about 1/3 from the lower end of the middle frame 3 upward.

  In the upper part of the frame 3a, a position corresponding to the frame decoration lamp lens 4b of the front frame 4, a position corresponding to a plurality of game effect lamps (not shown) and a frame decoration LED lens 4c of the front frame 4 are provided. A not-shown prize ball display LED and a stop-display LED (not shown) are provided at positions corresponding to the frame decoration LED lens 4e. Furthermore, the frame body portion 3a includes a frame decoration lamp substrate 4g for controlling blinking of the game effect lamp, a prize ball display LED substrate 4d for controlling blinking of the prize ball display LED, and blinking of the stop display LED. Various substrates such as a stop display LED substrate 4f to be controlled are also attached. Details of these substrates will be described later.

  Here, the positional relationship of the various LED substrates that drive the various LED display units 4b to 4h shown in FIG. 1 will be described. FIG. 3 is an explanatory diagram showing the positional relationship between the various LED substrates 4i to 4o. The various LED substrates 4i to 4o shown in the figure are provided at positions corresponding to the above-described various LED display portions 4b to 4h in the frame body portion of the middle frame 3. Specifically, the left LED substrate 4i corresponds to the left LED display portion 4b, the right LED substrate 4j corresponds to the right LED display portion 4c, the upper left LED substrate 4k corresponds to the upper left LED display portion 4d, and the upper right LED substrate. 4l corresponds to the upper right LED display portion 4e. The middle upper LED board 4m corresponds to the middle upper LED display section 4f, the prize ball LED board 4n corresponds to the prize ball LED display section 4g, and the error LED board 4o corresponds to the error LED display section 4h.

A-2. Game board surface structure:
Next, the configuration of the game board 10 will be described. FIG. 4 is an explanatory diagram showing the structure of the surface of the game board 10. As shown in the figure, the game board 10 is a substantially rectangular plate-like body made of wood and is detachably attached to the front surface side of the middle frame 3, and the rear side of the game board 10 is a back mechanism board 102 (FIG. 5) described later. Cover). An outer rail 14 and an inner rail 15 are provided on the surface of the game board 10, and a substantially circular game area 11 is formed in a portion surrounded by these rails.

  A central device 26 is provided in the approximate center of the game area 11, and a variable winning device 18 is provided in the lower part of the area. A starting port (ordinary electric accessory) 17 is provided between the central device 26 and the variable winning device 18. In addition, a normal symbol operation left gate 36 is provided at the left end of the game area 11, and a normal symbol operation right gate 37 is provided at the right end of the game area 11. Furthermore, a left lamp windmill 24 is provided between the normal symbol operating left gate 36 and the central device 26, and a right lamp windmill 25 is provided between the normal symbol operating right gate 37 and the central device 26. It has been. A number of obstacle nails 23 are provided between and around each of these gaming devices.

  The central device 26 is provided with a symbol display device 27 in the center, and below the symbol display device 27, a game ball guiding mechanism 28 described later is provided. The symbol display device 27 is equipped with a liquid crystal screen, the most area at the center of the liquid crystal screen is allocated to the main display area, and the horizontally long area at the bottom of the screen is allocated to the sub display area. The symbol display device 27 according to the present embodiment can display, in the main display area, effect symbols such as a pseudo symbol, a background symbol, and a character symbol constituting the special symbol. When displaying a special symbol (pseudo symbol), the center of the main display area is assigned to the three display units, left display, middle display, and right display. Three special symbols (pseudo symbols) of symbols are variably displayed. In addition, it is possible to display a background symbol or a character symbol on the background portion of the display portion of the special symbol (pseudo symbol). On the other hand, in the secondary display area, the main symbols constituting the special symbol (two symbols of the left symbol and the right symbol in this embodiment), and the symbols for presentation such as a reserved symbol indicating the number of reserved symbols and a normal symbol are displayed. It is possible. The symbol display device 27 displays these various effect symbols in the main display area and the sub display area in accordance with the progress of the game under the control of the symbol control board 360 described later.

  In addition, as will be described in detail later, an inlet for taking a game ball into the device is provided at the upper portion of the central device 26. Then, the game ball taken into the central device 26 is guided by the game ball guiding mechanism 28 and guided to the starting port (ordinary electric accessory) 17 provided below the central device 26. Yes.

  When the game ball fired by the player operating the firing handle 9 passes through the above-described normal symbol operation left gate 36 or normal symbol operation right gate 37, the symbol display device 27 starts to display normal symbol variation display. . The normal symbol of this embodiment is a symbol representing a number from 1 to 9. Ordinary symbols are variably displayed for a predetermined time, and then stopped and displayed at an arbitrary symbol. At this time, if the stopped symbol is a symbol representing an odd number, the starting port (ordinary electric accessory) 17 is opened for a predetermined time (for example, 0.5 seconds).

  The starting port (ordinary electric accessory) 17 is a so-called tulip type starting port configured such that a pair of blade pieces can be opened and closed on the left and right. Inside the start opening 17 are a start opening (ordinary electric accessory) winning detection switch 17s (see FIG. 6) for detecting the passing of a game ball, and a start opening (normal electric accessory) for operating the wing piece. A solenoid 17c (see FIG. 6) is provided. When the pair of wing pieces are opened to the left and right, the game ball is in an open state in which the possibility of entering the game ball is increased, and the pair of wing pieces are erected to enter the normal state in which the game ball is less likely to enter.

  The wing piece is opened and closed as follows. When the game ball passes through one of the normal symbol operation left gate 36 and the normal symbol operation right gate 37 provided on the left and right of the start port 17, it is provided inside the normal symbol operation left gate 36 and the normal symbol operation right gate 37, respectively. The left and right normal symbol operation gate detection switches 36s and 37s (see FIG. 6) detect the symbol display device 27, and the normal symbol variation display is started. When the normal symbol is stopped and displayed with the predetermined symbol after the predetermined time has elapsed, the blade piece of the start port 17 is opened for a predetermined time (for example, 0.5 seconds).

  On the other hand, when a game ball enters the start opening (ordinary electric accessory) 17, the symbol display device 27 starts the variation display of the special symbol, displays the variation for a predetermined time, and then stops the display with an arbitrary symbol. At this time, when the display is stopped with a predetermined symbol, the big winning device 31 provided in the variable winning device 18 is operated.

  The grand prize winning device 31 is provided substantially at the center of the variable prize winning device 18, and includes a big prize winning opening 311 that opens largely in a substantially rectangular shape, an opening / closing plate 312 that opens or closes the big winning prize opening 311, and an opening / closing plate 312. A grand prize opening solenoid 313 for opening and closing (see FIG. 6), a specific area (V prize opening and general prize opening / not shown) through which a game ball passes after winning the big prize opening 311, an unillustrated interlocking rod A winning ball detection switch 318 (see FIG. 6) for detecting a winning ball, a back box (not shown), a large winning opening relay board (not shown), and the like.

  When a predetermined special symbol is stopped and displayed on the symbol display device 27, the special prize winning device 31 is operated and the special prize winning opening 311 is opened. When the big prize opening 311 is opened, the game balls that have been launched enter the big prize opening 311 with a high probability, so that a gaming state (special gaming state) advantageous to the player is achieved.

  An out port 48 is provided below the game board 10, and a back ball preventing member 58 is provided below the out port 48, so that the game ball that has returned without reaching the game area 11 is again at the launch position. Prevents returning. On the other hand, a foul ball prevention member (not shown) is attached to the tip of the inner rail 15, and a return rubber (not shown) is attached to the outer rail 14 on the substantially opposite side of the foul ball prevention member (the right half side of the game board 10). Attached along the fitting.

  The surface structure of the pachinko machine 1 has been described above. Finally, the operation of the two operation switches SW1 and SW2 provided at the left end of the front surface of the upper plate part 5 will be described. The operation switches SW1 and SW2 have a function of selecting an effect form displayed on the liquid crystal screen of the symbol display device 27. That is, when the player operates the operation switches SW1 and SW2, the form of the effect displayed in the main display area or the sub display area on the liquid crystal screen can be changed under a predetermined condition. For this reason, the player can feel as if he / she actually participates in the effect displayed on the symbol display device 27.

  In this pachinko machine 1, two operation switches SW1 and SW2 are provided, and one operation switch (hereinafter referred to as “first operation switch”) SW1 is set as an “effect mode selection switch”, and the other operation is performed. A switch (hereinafter referred to as a “second operation switch”) SW2 is a “effect mode determination switch”. When the player operates the first operation switch SW1, the display for changing the background of the symbol starts blinking, and within a predetermined time (for example, 5 seconds) after the blinking, the second operation switch When SW2 is operated, a desired background can be selected from a plurality of types (for example, 10 types) of background symbols.

A-3. Back side structure:
Next, the back surface structure of the pachinko machine 1 will be described. FIG. 5 is an explanatory view showing the back surface structure of the pachinko machine 1 of the present embodiment. In this embodiment, the back structure of the pachinko machine 1 is a structure in which various devices are mounted on a large back mechanism board 102, and the back mechanism board 102 can be opened and closed to the middle frame 3 by a pair of hinges 103. Is pivotally supported. In FIG. 5, the hinge 103 is shown near the upper end and the lower end on the right side of the middle frame 3.

  As shown in FIG. 5, the back mechanism board 102 is provided with a prize ball tank 105, a tank rail 106, and a prize ball payout device 109 from the vicinity of the upper part of the pachinko machine 1 to the vicinity of the center of the right end. The prize ball tank 105 is for storing game balls. The tank rail 106 is for supplying game balls from the prize ball tank 105 to the prize ball payout device 109. The prize ball payout device 109 is for paying out game balls to the player. The payout operation by the prize ball payout device 109 is controlled by the payout control board. This payout control board is accommodated in the payout control board case 118. As shown in FIG. 5, the payout control board case 118 is provided in the vicinity of the lower right side on the back side of the back mechanism panel 102. The electrical configuration of the payout control board will be described later with reference to another drawing.

  In the vicinity of the center of the back mechanism board 102, an audio / lamp control board case 114, a lamp interface board case 115, a symbol control board case 116, etc. are provided on the back side of the game board 10. The sound / lamp control board case 114 accommodates a sound / lamp control board. The sound / lamp control board mainly controls the speaker 400a, the lamp, and the like. The lamp interface board case 115 accommodates a lamp interface board. The lamp interface board receives a command from the sound / lamp control board and outputs a drive signal to the lamp or the like. The electrical configuration of the sound / lamp control board and the lamp interface board will be described later with reference to the accompanying drawings. The symbol control board case 116 accommodates a symbol control board. The symbol control board controls the central device 26. The electrical configuration of the symbol control board will be described later with reference to another drawing.

  In the vicinity of the lower part of the back mechanism panel 102, a launch board case 130, a power board case 132, a main control board case 112, and the like are provided. The launch board case 130 accommodates a launch board. The launch board is a control board that controls the launch of the game ball, and is configured to control the launch operation in accordance with the operation of the launch handle 9. A power supply board is accommodated in the power supply board case 132. The power supply board is a board that controls power supply to each device in the pachinko machine 1. The main control board case 112 accommodates the main control board. The main control board is a control board that controls the progress of the game. The electrical configuration of the main control board will be described later with reference to another drawing. In addition, a ball passage member 126 for a lower plate portion is provided at a substantially central lower end portion of the back mechanism panel 102.

A-4. Configuration of pachinko machine control circuit:
Next, the configuration of the control circuit of the pachinko machine 1 according to the present embodiment will be described. FIG. 6 is a block diagram illustrating a configuration of a control circuit in the electronic control device mounted on the pachinko machine 1 according to the present embodiment. As shown in the drawing, the electronic control device is composed of a main control unit 140 and a plurality of sub-control units when paying attention to its function. The sub-control unit includes a primary sub-control unit directly connected to the main control unit 140 and a secondary sub-control unit connected to the main control unit 140 via the first sub-control unit. Has been. The main control unit 140 and the primary sub control unit are connected by a signal transmission path 500a. Depending on the model of the pachinko machine, there may be a third sub control unit connected to the main control unit 140 via the first sub control unit and the second sub control unit.

  As shown in the drawing, the electronic control device of this embodiment is provided with a payout control unit 150 and a voice / lamp control unit 170 as a primary sub-control unit, and as a secondary control unit, A launcher control unit 193 connected to the payout control unit 150 and a symbol control unit 160 connected to the sound / lamp control unit 170 are provided.

  Data is transmitted from the main control unit 140 to the payout control unit 150 and the voice / lamp control unit 170 in a one-way format or a bidirectional format. In this embodiment, the data is transmitted from the voice / lamp control unit 170 to the symbol control unit 160 in a one-way format. However, both the voice / lamp control unit 170 and the symbol control unit 160 are both connected. Data may be transmitted in a bidirectional format.

  Also, the broken-line arrows shown in FIG. 6 represent power supply paths to the respective control units 140 to 180. As shown in the figure, the power is first supplied to the power receiving board 410, converted to a predetermined voltage by the power supply unit 420, and then supplied with power from the distribution board 430 to each of the control units 140 to 180. Further, when the power is turned on, a system reset signal is transmitted to all control boards.

  As will be described in detail later, the main control unit 140 receives information from various switches, detectors, etc., performs predetermined calculations, and then outputs various commands to the payout control unit 150 and the voice / lamp control unit 170. At the same time, it outputs drive signals to various substrates and solenoids. Hereinafter, the configuration of the main control unit 140, the payout control unit 150, the voice / lamp control unit 170, the symbol control unit 160, various substrates, and the like will be described in order.

  The main control unit 140 is mainly configured by a main control board 340 stored in the main control board case 112, and the main control board case 112 is formed in a structure that an unauthorized person cannot easily open and close. . FIG. 7 is an explanatory diagram conceptually showing the configuration of the main control board 340. As shown in the figure, the main control board 340 is configured such that a main circuit unit 400 including a CPU 401 and an input / output circuit unit 500 are connected by a bus and can exchange data with each other. The main circuit unit 400 includes a CPU 401, an oscillation unit 1410, a reset circuit unit 1450, a CPU initialization circuit unit 1460, an I / O decode circuit unit 1420, a data bus stabilization unit 1411, and a first external input. A circuit portion 1430 and the like are provided. The configuration of the CPU 401 mounted on the main circuit unit 400 will be described later.

  The CPU initialization circuit unit 1460 is mainly configured by a dedicated circuit called a watchdog timer. The watchdog timer automatically starts operating when power is supplied, and outputs an initialization signal for forcibly initializing the CPU 401 to the CPU 401 at a predetermined period (Twd). As will be described in detail later, while the game is in progress, the CPU 401 outputs a reset signal to the watchdog timer built in the CPU initialization circuit unit 1460, and the cycle in which the CPU 401 outputs the reset signal is A period (Trset) shorter than a period in which the dog timer outputs an initialization signal toward the CPU 401 is set. For this reason, if the CPU 401 is operating normally, the watchdog timer can be reset before it is forcibly initialized, so the CPU 401 is not initialized. However, if an abnormality occurs in the operation of the CPU 401, the watchdog timer cannot be reset before the initialization signal is output. Therefore, an initialization signal is output from the CPU initialization circuit unit 1460 and the CPU 401 is forcibly initialized, so that it is possible to return to a normal operation state.

  The main circuit unit 400 of this embodiment is also provided with a reset circuit unit 1450. The reset circuit unit 1450 sends a reset signal for resetting the watchdog timer built in the CPU initialization circuit unit 1460 to the CPU 401 while the CPU 401 performs a predetermined operation such as security check at the time of startup. Output. Although the detailed configuration will be described later, the reset circuit unit 1450 receives the clock signal from the oscillation unit 1410, converts it into a signal having an appropriate period, and then outputs a reset signal toward the watchdog timer. For this reason, it can be avoided that the CPU 401 is forcibly initialized by the watchdog timer while performing a predetermined operation such as a security check at the time of activation. In addition, after the CPU 401 is activated and starts operating, the reset circuit unit 1450 receives the activation start signal from the CPU 401 and stops generating the reset signal. That is, after the CPU 401 is activated, it is forcibly initialized by the watchdog timer unless the CPU 401 itself outputs a reset signal. For this reason, even if an abnormality occurs in the operation of the CPU 401, it is possible to return to a normal operation state. If the activation start signal is not output, it can be considered that the CPU 401 is preparing for activation. Therefore, if the activation start signal is inverted, a signal indicating that the CPU is preparing. (Preparation operation signal) can be obtained. That is, the CPU activation start signal can be simultaneously interpreted as a signal indicating that the CPU is being prepared. If the start signal is interpreted in this way, the reset circuit unit 1450 outputs a reset signal on behalf of the CPU only during a period in which the CPU outputs a preparation operation signal.

  The input / output circuit unit 500 is connected to an external terminal unit 145, and is connected to a “hall computer” of a pachinko hall by the external terminal unit 145. When executing the RAM clear process, the main control board 340 performs the operation of turning the RAM clear signal ON and then turning it off again after a predetermined time has passed. This RAM clear signal is sent to the pachinko hall via the external terminal 145. It is reported to the system. For this reason, when the RAM clear process is executed by the cheating person, the cheating person can detect the cheating action without the knowledge of the cheating person.

  The input / output circuit unit 500 is connected to a payout control unit 150 and a voice / lamp control unit 170 via a signal transmission path 500a (see FIG. 6). The input / output circuit unit 500 sends command data, which is a command signal instructing the processing contents of the payout control unit 150 and the voice / lamp control unit 170, to the payout control unit 150 or the voice / lamp control unit 170 via the signal transmission path 500a. Output to. The input / output circuit unit 500 also outputs command data for instructing the processing content in the symbol control unit 160. The command data for the symbol control unit 160 is once output to the voice / lamp control unit 170, and then supplied from the voice / lamp control unit 170 to the symbol control unit 160 via the signal transmission path 500b.

  In addition, the input / output circuit unit 500 includes a start opening (ordinary electric accessory) winning detector (winning detection switch) 17s, a normal symbol display device board 32f, various solenoids 17c and 313, a right normal symbol operating gate passage detector. (Right normal symbol operation gate passage detection switch) 37s, left normal symbol operation gate passage detector (left normal symbol operation gate passage detection switch) 36s, motor load detector 40, and the like are connected. The motor load detection unit 40 will be described later with reference to another drawing.

  FIG. 8 is an explanatory diagram showing a detailed structure of the CPU 401 mounted on the main circuit unit 400. As shown in FIG. 8, the CPU 401 includes a CPU core 480, a built-in RAM 481, a built-in ROM 482, a memory control circuit 483, a clock generator 484, an address decoder 485, a counter / timer 487, and a parallel input / output port 488. A reset / interrupt controller 489, an external bus interface 490, an output control circuit 491, and the like. The CPU 401 executes the control program stored in the ROM 482 while using the RAM 481 as a work area, thereby controlling the operation of the entire pachinko machine 1 (that is, the basic progress control of the game) and stored in the ROM 482. By executing the validity determination program, the validity determination control is performed.

  Next, the configuration of the payout control unit 150 will be described. The payout control unit 150 is mainly configured by a payout control board 350 stored in the payout control board case 118. FIG. 9 is an explanatory diagram conceptually showing the configuration of the payout control board 350. Similar to the main control board 340 described above, the payout control board 350 is configured by connecting the main circuit unit 152 and the input / output circuit unit 153 so that they can exchange data with each other via a bus. A signal transmission path 500a is connected to the input / output circuit section 153, and the above-described command data output from the main control board 340 is input to the input / output circuit section 153 via the signal transmission path 500a. The input / output circuit unit 153 is also connected with a prize ball payout device 109, a launching device control unit 193, and the like.

  As with the main circuit unit 400 shown in FIG. 7, the main circuit unit 152 of the payout control unit 150 is also equipped with a CPU, an oscillation unit, a reset circuit unit, a CPU initialization circuit unit, and the like. Yes. When an abnormality occurs in the operation of the CPU, the CPU is forcibly initialized by an initialization signal from a watchdog timer built in the CPU initialization circuit unit, and as a result, returns to normal operation. It is configured as follows. Since this configuration is the same as the configuration shown in FIG. 7, detailed description thereof is omitted here.

  The voice / lamp control unit 170 receives a voice / lamp control board 370 for mainly controlling the speaker 400a, the lamp, and the like, and a command from the voice / lamp control board 370, and outputs a drive signal to the lamp or the like. The drive substrate 380 for the above is mainly composed of two substrates. FIG. 10 is an explanatory diagram conceptually showing the configuration of the sound / lamp control unit 170. The sound / lamp control board 370 is provided with a CPU 171, a RAM 172, a ROM 173, an input / output port 174, a sound generator 176, and a connector CN 1 as arithmetic circuit components, which are mutually connected by a bus 175. It is connected so that data can be exchanged. The sound generator 176 outputs various sounds from the speaker 400a by reproducing previously stored sound data as the game progresses. The volume output from the speaker 400 a can be adjusted by the volume switch board 12.

  A signal transmission path 500a is connected to the input / output port 174. When the above-described main control unit 140 outputs a control command for instructing a game mode such as special symbol change / stop, reach generation, reach display mode, special game mode, probability change or time reduction, etc. The command is input to the input / output port 174 via the signal transmission path 500a. When the voice / lamp control board 370 receives the control command in this way, it performs predetermined processing in accordance with a program stored in advance in the ROM 173 and outputs various commands to the drive board 380. The sound / lamp control board 370 and the drive board 380 are connected to each other by a connector CN1 and a connector CN2.

  The drive board 380 includes a drive circuit unit 382 that generates drive signals for driving various LEDs, lamps, and the like, and the generated drive signals are sent to various LED boards 4d, 4f, 19f to 22f, various lamp boards 216f, 262f, a connector output unit 384 for outputting to the frame decoration board 4g and the like are provided. One or a plurality of lamps, LEDs, or the like are connected to each of these boards, and are turned on / off or blinking in accordance with the progress of the game by a drive signal supplied from the connector output unit 384. The connector output unit 384 may be provided on a separate substrate from the drive circuit unit 382. In this way, even if the number or color of the lamps such as various LEDs is changed, if it is not necessary to change the drive circuit unit 382, only the connector output unit 384 can be changed.

  The drive circuit unit 382 also has a function of driving the drive motor 29. The drive motor 29 is a direct current motor that rotationally drives a rotating body 285 (described later) provided in the game ball guiding mechanism 28, and constitutes one aspect of the drive motor of the present invention. When a drive signal for driving the drive motor 29 is generated by the drive circuit unit 382 and output via the connector output unit 384, a switch (not shown) in the energization path of the drive motor 29 is turned on to drive the drive motor 29. Energization of the motor 29 is performed.

  The voice / lamp control unit 170 also includes a CPU, an oscillation unit (not shown), a reset circuit unit (not shown), a CPU initialization circuit unit (not shown), and the like. When an abnormality occurs in the operation of the CPU, the CPU is forcibly initialized by an initialization signal from a watchdog timer built in the CPU initialization circuit unit, and as a result, it returns to normal operation. It is configured. Since this configuration is the same as the configuration shown in FIG. 7, detailed description thereof is omitted here.

  The symbol control unit 160 is mainly configured by a symbol control board 360. FIG. 11 is an explanatory diagram conceptually showing the configuration of the symbol control unit 160. As illustrated, the symbol control unit 160 includes a CPU 161, a RAM 162, a ROM 163, an input / output port 164, and a drive circuit 166 as arithmetic circuit components, and these arithmetic circuit components are connected via a bus 165. They are connected and can exchange data with each other. The signal transmission path 500b and the symbol display device 27 are connected to the input / output port 164. The CPU 161 controls the central device 26 by executing a control program stored in the ROM 163 while using the RAM 162 as a work area.

  Winning ball detection switches 318, 19s to 22s and the like are connected to the relay board 190, and an output terminal of the relay board 190 is connected to the input / output circuit unit 500 of the main control unit 140.

  The payout terminal board 191 is connected with a touch switch 9a, a firing stop switch 9b, a volume switch 192, a tank ball breakage detection switch 104, a supply ball breakage detection switch 108, and the like. 9 is connected to the input / output circuit unit 153 of the payout control unit 150 shown in FIG.

  In the electronic control device of the present embodiment having the above-described configuration, when a game ball enters the start port 17, the information is detected by the start port winning detection switch 17s and input to the main control unit 140. When the game ball passes through the normal symbol operation left gate 36 or the normal symbol operation right gate 37, the information is detected by the normal symbol operation gate passage detectors 36 s and 37 s and input to the main control unit 140. Further, when a winning ball is detected by the winning ball detection switches 19 s to 22 s and 318, the information is input to the main control unit 140 via the relay board 190. The main control unit 140 receives these pieces of information and transmits a variation command, a stop symbol command, and a variation stop command. These commands are supplied to the symbol control unit 160 via the signal transmission path 500a, the sound / lamp control unit 170, and the signal transmission path 500b. When the symbol control unit 160 receives the variation pattern designation command, the symbol control unit 160 performs lottery with a random number or the like from a plurality of variation modes to determine the variation mode. The main control unit 140 also transmits a predetermined command to the voice / lamp control unit 170 in synchronization with the command output to the symbol control unit 160. In this way, various effects are performed by combining symbol display, sound output, and LED / lamp lighting / flashing.

B. Outline of action of prize ball:
Next, the winning ball operation of the pachinko machine 1 of the present embodiment will be briefly described. When a game ball enters the big prize opening 311, a winning ball detection switch 318 provided inside the big prize opening 311 detects this and sends a signal notifying the entry to the main control unit 140 via the signal cable. Output. When the signal is received, the main control unit 140 performs processing to be described later, and outputs a command for paying out 15 game balls toward the payout control unit 150. When a game ball enters the start opening (ordinary electric accessory) 17, the start opening winning detection switch 17s provided inside the start opening detects this and detects the main control section via the signal cable. A signal is output to 140. The main control unit 140 receives this signal, performs a process described later, and outputs a command for paying out four game balls to the payout control unit 150. When entering the other winning holes such as the left and right lower winning holes, the passage detection switch provided inside detects the ball and sends a signal to the main control unit 140 via the signal cable. Output. The main control unit 140 performs a process to be described later and outputs a command to the payout control unit 150 to pay out 10 game balls. These prize ball commands are transmitted via the signal transmission path 500a in accordance with the order in which the passing of game balls is detected as a command signal for the payout control unit 150 as an operation command target. The payout control unit 150 thus receives the prize ball command from the main control unit 140 and outputs a prize ball payout signal, thereby operating the prize ball payout device 109 to perform the designated number of prize ball payout operations. .

  In addition, the main control unit 140 determines the gaming state based on the outputs of the various detection switches described above, makes a determination of success / failure based on the gaming state, and displays an image in a corresponding symbol display mode according to the determination content. Read data for display control. For example, the main control unit 140 uses the detection results of the start opening (ordinary electric accessory) winning detection switch 17s, the winning ball detection switch 318, etc., the acquired value of the special symbol success / failure determination random number, and the like. A state of waiting for an unaccompanied customer, “a state in which a game is played but no start-up winnings (variable preparation state)”, “a state in which a start-up winnings are present”, and “special game state” are determined. The main control unit 140 determines whether or not to generate a special gaming state advantageous to the player based on the random number value when detecting the start winning (whether or not the special symbol is determined), and based on the determination result. Various commands for performing display mode control such as change of special symbols (including reach display mode) and confirmation. These commands are once output to the voice / lamp control unit 170 via the signal transmission path 500a, and then transmitted from the voice / lamp control section 170 to the symbol control unit 160 via the signal transmission path 500b.

C. Overview of pachinko machine control:
Below, the outline | summary of the control which the electronic control apparatus is performing when playing a game using the pachinko machine 1 which has the structure mentioned above is demonstrated.

C-1. Operation immediately after power-on:
Below, when a power supply is turned on to the pachinko machine 1, it will be described how the CPU in the electronic control unit is activated to start the control of the pachinko machine 1.

  FIG. 12 is an explanatory diagram showing a large flow from when the pachinko machine 1 is powered on until the game control is started by the electronic control unit. Even when the power is turned on to the pachinko machine 1, the CPU of the electronic control unit is not immediately started, but is first initialized by an initialization signal output from the power supply circuit to the CPU. Such an operation is called a system initialization operation (or system reset), and an initialization signal output at the time of system initialization may be called a system initialization signal. After the CPU is initialized, a security check is performed this time. The security check is to check the contents of the memory including the area where the program and various control parameters are stored when the CPU starts to control the pachinko machine 1 and check whether the program and control parameters have been tampered with. It is a work to confirm whether. With pachinko machines, there should be no unauthorized modification after shipment from the manufacturer, so a security check is performed before game control is started. Since the security check checks a large memory area, a certain amount of time is required until the check is completed.

  When the security check is completed, the CPU mounted on the electronic control device is activated. As described above, the electronic control device is equipped with many control boards such as the audio / lamp control board 370 and the symbol control board 360 including the main control board 340, and each of these control boards has a CPU. Is installed. Since it will be complicated to describe all of these control boards and CPUs, the explanation will be given here using the CPU 401 mounted on the main control board 340 as an example. However, the following explanation is for other control boards. Can be applied in substantially the same manner.

  The CPU after activation largely performs an operation for starting the game control and an operation for controlling the game of the pachinko machine 1. If an interrupt occurs during the execution of game control, a timer interrupt process, a power-off process, and the like are also performed. During game control, an interrupt is generated from the CPU 401 of the main control board 340 to the CPU of the sound / lamp control board 370 and the CPU of the symbol control board 360 to go to these sub boards (sub control units). To perform various operations. The preparation for starting control includes a preparatory operation for generating a timer interrupt and an operation for initializing a sub-board such as a sound / lamp control board and a symbol control board. Hereinafter, a control start preparation operation performed after the CPU 401 of the main control board 340 is activated, a game control operation, and the like will be described in detail.

C-2. Control start preparation operation:
FIG. 13 is a flowchart showing the flow of control start preparation processing that is performed immediately after the CPU 401 mounted on the main control board 340 is activated. Hereinafter, it demonstrates according to a flowchart. When the control preparation process is started, first, the CPU 401 sets a state in which no interrupt is accepted (S10). This is because the control preparation processing to be performed below is performed as preparation for appropriate control, and before completion of the preparation operation, even if an interrupt occurs, the control may be appropriately executed. Since it is not possible, it is set so that interrupts are not accepted until the preparation operation is completed.

  Next, a stack pointer is set (S12). In simple terms, the stack pointer is a variable that indicates a memory area for temporarily saving data being processed when the current process is interrupted and another process is performed. When game control is started, an interrupt may occur and the process may be interrupted, so a memory area for saving various data for resuming the interrupted process is set. is there.

  Next, the CPU 401 performs initial setting of peripheral devices (S14). Here, initialization of various devices such as CTC (counter / timer circuit) and PIO (peripheral device interface) is performed. When game control is performed, timer interrupts are generated periodically (typically every 2 msec) using the CTC to detect the state of various switches and update various random values. Accordingly, the setting for generating such a timer interrupt in the CTC is also performed in S14 of the control start preparation process.

  Following the setting of the peripheral devices, the CPU 401 detects whether or not the RAM clear switch is ON (S16). If the RAM clear switch is on when the power is turned on, it is assumed that the store clerk turned on the power while turning on the RAM clear switch when the amusement store opened. However, if the RAM clear switch is not ON (S16: no), there is a possibility that the power has been cut off due to a power failure or the like, so it is detected whether the backup flag is ON (S18). If the backup flag is ON (S18: yes), the game is not terminated normally because the power is cut off due to a power failure or the like, and it is necessary to restore the gaming state before the disconnection. Conceivable. Therefore, the following recovery operation is performed.

  When the recovery operation is started, first a checksum is calculated (S20). The checksum is roughly calculated as follows. Predetermined checksum data is set in advance. Then, for the data stored in the target area on the memory, the data is sequentially read to calculate an exclusive OR with the checksum data, and the obtained value is sequentially written in the checksum data area. When exclusive OR is written for all data stored in the target area in this way, the value of each bit in the written area is inverted, and the obtained data is used as a checksum. In the power-off process performed at the time of power-off such as a power failure, a checksum is calculated and stored for data in the backup RAM area. Therefore, if the data stored in the backup RAM area has not been changed, the checksum calculated during the recovery operation should be the same value as the checksum calculated when the power is turned off.

  Therefore, it is determined whether or not the checksum calculated in S20 matches the checksum stored when the power is turned off (S22). If the two match (S22: yes), it is considered that the data in the backup RAM area is correctly stored. In this case, after reading the stored data and acquiring the gaming state when the power is cut off (S24), the backup flag is set to OFF (S26). Then, in order to restore the gaming state before power-off, the voice / lamp control board 370, the symbol control board 360, the payout control board 350, etc. (hereinafter, these boards may be referred to as sub-boards) A command at the time of power-off restoration is transmitted to these various control boards (S28). A method for transmitting the command will be described later with reference to another drawing. As a result, the game state before the power interruption is restored, and the game is continued thereafter.

  On the other hand, if it is detected in S16 that the RAM clear switch is ON, the normal power-on operation is considered, and the normal initialization operation shown below is performed. If the RAM clear switch is not turned on but the backup flag is not turned on (S18: no), it is considered that there is no backup data. Therefore, in this case, it is considered that the normal power-on operation is not performed, but the normal initialization operation is also performed. Furthermore, even when the backup flag is ON and the backup data exists, if the checksums do not match (S22: no), the backup data can no longer be used. A normal initialization operation is performed.

  In the normal initialization operation, the RAM is first initialized (S30). That is, after “0” is once written in the entire area of the RAM, the initial data is set to a predetermined address on the RAM.

  Next, an initial command is transmitted to the sub-boards such as the voice / lamp control board 370 and the symbol control board 360 (S32). That is, in accordance with the start of new game control on the main control board 340, the control state of the sub board is initialized so that the voice / lamp control board 370, the symbol control board 360, etc. also start new control. The command to be sent is sent.

  As described above, since the interruption is initially set to the prohibited state in the control start preparation process, the series of operations described above can be reliably performed. Then, when all the preparation operations are completed, the interruption is set to the permitted state (S34), the control start preparation process is ended, and the game control is started. As described above, in the control start preparation process of this embodiment, no reset signal is output from the CPU 401 toward the CPU initialization circuit unit 1460 (see FIG. 7), and the reset is performed during the game control process described later. The signal is output. Therefore, in this embodiment, the reset signal is output from the reset circuit unit 1450 to the CPU initialization circuit unit 1460 while the CPU 401 is performing the above-described control start preparation process. However, it is also possible to output a reset signal from the CPU 401 to the CPU initialization circuit unit 1460 once when the control start preparation process is started. In this case, a reset signal is output from the reset circuit unit 1450 toward the CPU initialization circuit unit 1460 only during the period until the control start preparation process is started (that is, during the security check).

  Here, a state in which a command is transmitted from the main control board 340 toward the sub board will be described. FIG. 14 is an explanatory diagram conceptually showing how various commands are output from the main control unit 140 toward the sound / lamp control board 370. The main control board 340 provided in the main control unit 140 outputs a 1-bit strobe signal and 8-bit command data to the sound / lamp control board 370. The voice / lamp control board 370 can reliably read the transmitted command by reading the command data at the rising timing of the strobe signal. The command thus supplied together with the strobe signal is immediately transferred from the voice / lamp control unit 170 to the symbol control unit 160 as necessary. The power-off recovery command output in the power-off recovery operation and the initial command output in the normal initialization operation are transmitted to the voice / lamp control board 370 in this way, and further the voice / lamp control. Transferred from the board 370 to the symbol control board 360. As a result, an appropriate symbol is displayed on the central device 26 provided on the game board surface, and various lamps and speakers are controlled to an appropriate state.

C-3. Overview of game control:
The CPU 401 mounted on the main control unit board 340 starts the game control of the pachinko machine 1 when the control preparation start process shown in FIG. FIG. 15 is a flowchart showing a rough flow of the game control process executed by the CPU 401 mounted on the main control board 340. As shown in the figure, in the game control process, each process such as a normal symbol game process, a normal electric game game process, a special symbol game process, and a special electric game game process is repeatedly executed. The time required for one round of processing is about 4 msec. Therefore, these various types of processing are repeatedly executed about every 4 msec.

  In addition, as described above, the CTC is set to generate an interrupt every about 2 msec. When an interrupt by the CTC occurs, the state of various random number values, various game ball detection switches, etc. is changed. Processing to detect is performed. In the game control shown in FIG. 15, the normal symbol game process, the ordinary electric accessory game process, while generating various interrupts and detecting the game state almost twice during the control cycle, Special symbol game processing and special electric equipment game processing are implemented. During these processes, various commands are transmitted to the sub-board. By doing so, the game of the entire pachinko machine 1 proceeds. Hereinafter, the game control process will be described with reference to the flowchart of FIG.

C-3-1. Watchdog timer reset processing:
When the CPU 401 mounted in the main circuit unit 400 of the main control board 340 starts the game control process, first, it goes to a watch dog timer (see FIG. 7) built in the CPU initialization circuit unit 1460. A reset signal is output (S90). As described above, the watchdog timer built in the CPU initialization circuit unit 1460 automatically starts operating when power is supplied, and sends an initialization signal for forcibly initializing the CPU 401 to a predetermined period. Output in (Twd). When the CPU 401 is initialized, the control start preparation process shown in FIG. 13 must be performed again from the security check again, and the game cannot proceed. Therefore, in step S90, the CPU 401 resets the operation of the watchdog timer 483 by supplying a reset signal before the initialization signal is output from the CPU initialization circuit unit 1460.

C-3-2. Motor load detection processing:
When the CPU 401 completes the watchdog timer reset process, the CPU 401 starts a motor load detection process (S95). The motor load detection process is a process of detecting that the load applied to the drive motor 29 has changed, and starting an effect by symbol display, sound, lamp, or the like based on the detection result. In the pachinko machine 1 according to the present embodiment, the motor load detection process enables an effective presentation according to the movement of the game ball, which will be described in detail later.

C-3-3. Normal symbol game start judgment processing:
When the motor load detection process (S95) ends, the CPU 401 of the main control board 340 determines whether or not to start the normal symbol game process (S100). FIG. 16 is a flowchart showing a process performed by the CPU 401 to determine whether or not to start the normal symbol game process. In determining whether or not to start the normal symbol game process, first, processing related to the number of normal symbols held is performed. Specifically, it is determined whether or not it has passed through either the normal symbol left operating gate 36 or the normal symbol right operating gate 37 (S102).

  When the game ball passes through the normal symbol operation gate on either the left or right side, the passage can be detected by a detection switch incorporated in the gate. If the game ball has passed (S102: yes), it is determined whether or not the number of ordinary symbols held is 4 or more (S104). If the number of reservations has not reached 4 (S104: no), a random number for determining whether or not the normal symbol is appropriate is stored and the number of reservations is incremented by one (S106). As will be described later, whether or not a normal symbol is true or false is determined based on the random number for determining whether or not it is stored. On the other hand, when the number of reservations has reached 4, acquisition of random numbers for determining whether or not normal symbols are appropriate is not performed. That is, it is possible to store up to four random numbers for determining whether or not normal symbols are appropriate. In this way, the processing related to the holding means that it is detected that the game ball has passed through either the normal symbol left operation gate 36 or the normal symbol right operation gate 37, and up to four random numbers for determining whether or not the normal symbol is correct. Is a process of storing up to.

  When the processing related to the holding of the normal symbol is completed as described above, it is determined whether or not the normal electric accessory is operating (S108). The ordinary electric accessory is an accessory that operates as a result of performing a normal symbol game. Therefore, if the normal electric accessory is in operation (S108: yes), it is not necessary to start the normal symbol game again, so it is determined that the normal symbol game does not start (that is, S100: no). On the other hand, when the ordinary electric accessory is not in operation (S108: no), it is determined that the normal symbol game is started (S108: yes).

  In step S100 of the game control process shown in FIG. 15, whether or not to start the normal symbol game is determined as described above. When it is determined that the normal symbol game is started (S100: yes), the normal symbol game process described below is started (S150). On the other hand, when it is determined that the normal symbol game is not started (S100: no), the normal symbol game process is skipped.

C-3-4. Normal design game processing:
FIG. 17 is a flowchart showing the flow of normal symbol game processing. When the normal symbol game process is started, first, it is determined whether or not the normal symbol is changing (S152). As described above with reference to FIG. 4, in the pachinko machine 1 according to the present embodiment, it is possible to display a normal symbol on the liquid crystal screen (the symbol display device 27) incorporated in the central device 26. When the normal symbol game process is started, first, it is determined whether or not this liquid crystal screen displays the normal symbol in a variable manner.

  If the normal symbol is not fluctuating (S152: no), it is considered that either the normal symbol has not yet fluctuated or has been stopped and displayed as a stop symbol after the fluctuating display. Therefore, it is determined whether or not it is during the time when the normal symbol stop symbol is being displayed (S154). As will be described later, the normal symbol variation display start and the variation display stop are controlled by a command output by the CPU 401 mounted on the main control board 340. Therefore, the CPU 401 can easily determine whether or not the current state is the normal stop symbol stop display based on the internal control state.

  And, when it is determined that it is not during the time of displaying the stop symbol of the normal symbol (S154: no), that is, when the normal symbol is not variably displayed and the stop symbol of the normal symbol is not being displayed. Then, it is determined whether or not the number of ordinary symbols held is “0” (S156). If the number of reservations is not “0”, that is, if there is an ordinary symbol hold (S156: no), whether or not the ordinary symbol is appropriate is determined (S158). Whether or not a normal symbol is determined is determined by determining whether or not the random number value for determining whether or not the symbol is stored when the normal symbol is held matches a predetermined winning value. That is, if the random number stored at the time of holding coincides with the winning value, it is determined that the symbol is a normal symbol, and if it does not match, it is determined that the normal symbol is off.

  When the normal symbol determination is made in this way, the CPU 401 of the main control board 340 outputs a normal symbol related command to the sound / lamp control board 370 and the symbol control board 360 according to the determination result (S160). . The normal symbol related commands are various commands output from the main control board 340 toward the sub board in order to perform various effects such as blinking of various lamps and output of sound effects in accordance with the progress of the normal symbol game. .

  FIG. 18 is an explanatory diagram illustrating various commands set as normal symbol-related commands. As shown in the figure, there are multiple types of normal symbol fluctuation patterns, and various normal symbol fluctuation patterns such as command Chp1, command Chp2, command Chp3, command Chp4, etc., are prepared according to these fluctuation patterns. The specified command is set. In addition, after the change display of symbols, it is possible to stop display with various symbols, and multiple normal symbol specification commands Chs1, command Chs2, command Chs3, command Chs4, etc. are set according to the normal symbols to be stopped and displayed. Has been. Furthermore, a command (normal symbol stop command Chstp) for stopping the fluctuation display of the normal symbol is also set. In S160 shown in FIG. 17, the normal symbol variation pattern designation command is transmitted first, and then the normal symbol designation command is transmitted in accordance with the result of the normal symbol success / failure determination performed previously. Thus, when a normal symbol-related command is transmitted from the main control board 340 to the voice / lamp control board 370, the voice / lamp control board 370 transfers the command to the symbol control board 360 as necessary. As a result, in accordance with the normal symbol game being performed on the main control board 340, the sound / lamp control board 370 and the symbol control board 360 are appropriately rendered. When the normal symbol related command is transmitted as described above, the normal symbol game process shown in FIG. 17 is ended and the game control process shown in FIG. 15 is resumed.

  On the other hand, if “yes” is determined in S156 in FIG. 17, that is, the normal symbol is not changing and the normal symbol is not stopped, but the normal symbol hold count is “0”. Without deciding whether or not the normal symbol is determined in S158 and transmitting the normal symbol related command in S160, the normal symbol game process is terminated as it is, and the game control process shown in FIG. 15 is resumed.

  In S152, when it is determined that the normal symbol is changing (S152: yes), it is considered that the symbol is changing in accordance with the normal symbol-related command that has already been transmitted. Therefore, it is determined whether or not the normal symbol variation time has elapsed (S162). That is, as shown in FIG. 18, a plurality of types of patterns are set for the variation pattern of the normal symbol, and the variation time of the symbol is predetermined according to the variation pattern. Therefore, the CPU 401 of the main control board 340 transmits a normal symbol variation pattern designation command, and at the same time, sets a symbol variation time corresponding to the variation pattern in an internal timer. In S162, by referring to the timer set in this way, it is determined whether or not the normal symbol fluctuation time has elapsed.

  If the variation time has not yet elapsed (S162: no), the normal symbol game process is terminated as it is, and the process returns to the game control process shown in FIG. On the other hand, when it is determined that the fluctuation time has elapsed (S162: yes), the normal symbol stop command described above with reference to FIG. 18 is transmitted (S164). Further, the display time of the stop symbol is set so that the player can confirm the normal symbol that is stopped and displayed (S166).

  Next, it is determined whether or not the display time set to stop and display the normal symbol has passed (S168). If the display time has not passed (S168: no), the normal symbol game process is terminated as it is. Returning to the game control process shown in FIG. On the other hand, if it is determined that the display time of the stop symbol has elapsed (S168: yes), it is determined whether or not the normal symbol that is stopped and displayed is a symbol that will activate the normal electric accessory (S170). ).

  If the determination of whether or not the normal symbol is successful is a hit determination, a normal symbol-related command is transmitted so that the symbol for operating the normal electric accessory is stopped and displayed, and the normal symbol is stopped and displayed according to the command. On the other hand, if the determination is not successful, a normal symbol related command is displayed so that a symbol that does not operate the normal electric accessory is stopped and displayed, and the normal symbol is stopped and displayed according to the command. From this, it is already determined at the stage of transmitting the normal symbol related command whether or not to stop at the symbol where the normal electric accessory operates.

  If the symbol indicating that the normal electric accessory is to be operated is not stopped and displayed (S170: no), the normal symbol game process is terminated as it is, and the game control process shown in FIG. 15 is resumed. On the other hand, when the normal electric actor is stopped and displayed (S170: yes), after the operation of the ordinary electric actor is started (S172), the normal symbol game process is terminated and FIG. Return to the game control process shown in FIG. In the pachinko machine 1 of the present embodiment, when the ordinary electric accessory is activated, the start port 17 is opened.

  As shown in FIG. 15, in the game control process, when returning from the normal symbol game process, it is determined whether or not the normal electric accessory is in operation (S190). If the normal electric accessory is operating, the CPU 401 can easily detect this based on the internal control state. If the normal electric combination is not in operation (S190: no), the normal electric combination game process (S200) is skipped, but if the normal electric combination is in operation (S190: yes), the following description will be given. The ordinary electric accessory game process is started (S200).

C-3-5. Normal electric game game processing:
FIG. 19 is a flowchart showing the flow of the ordinary electric accessory game process. Hereinafter, it demonstrates according to a flowchart. In the ordinary electric accessory game process, first, it is determined whether or not the predetermined operating time has elapsed for the ordinary electric accessory (S202). As described above, when the ordinary electric accessory operates, the pair of blade pieces provided in the start port 17 rotate outwardly, and the start port is opened. The pair of blade pieces returns to the normal state where they are upright. Therefore, in S202, it is determined whether or not the normal electric accessory has reached a preset operation time. If it is determined that the operating time has been reached (S202: yes), after stopping the operation of the ordinary electric accessory, the ordinary electric accessory game process is terminated and the process returns to the game control process shown in FIG. To do.

  On the other hand, if a prescribed number of game balls enter the opening 17 during opening, the opening 17 returns to the normal state even if the opening time has not reached the set time. Corresponding to this, when the operation time of the ordinary electric accessory has not reached the predetermined time (S202: no), it is determined whether or not the prescribed number of prizes for the ordinary electric accessory has been won (S204). When it is determined that there are a number of winnings (S204: yes), the operation of the ordinary electric accessory is stopped and the ordinary electric accessory game process shown in FIG. 19 is terminated. Conversely, if it is determined that there is no predetermined number of winnings (S204: no), the ordinary electric game game process shown in FIG. Return to the game control process shown.

C-3-6. Special symbol game start decision processing:
As shown in FIG. 15, in the game control process, when returning from the ordinary electric accessory game process (S200), it is determined whether or not to perform the special symbol game process (S300). FIG. 20 is a flowchart showing a flow of processing for determining whether or not to perform a special symbol game. As in the case of determining whether or not to start the normal symbol game process described above with reference to FIG. 16, even when determining whether or not to start the special symbol game process, first, it relates to the number of special symbols held Process. Specifically, it is determined whether or not a game ball has entered the start port 17 (S302). As described above, a detection switch for detecting the passage of a game ball is incorporated in the start port 17, and it can be detected that a game ball has entered the start port 17 by this switch.

  If a game ball is in the starting port 17 (S302: yes), it is determined whether or not the number of reserved special symbols is 4 or more (S304). If the number of reservations has not reached 4 (S304: no), a special symbol determination random number is stored and the number of reservations is incremented by one (S306). Similarly to the above-described determination of whether or not the normal symbol is determined, whether or not the special symbol is determined is determined based on the stored determination random number. On the other hand, when the number of reserved special symbols has reached 4, a new random number for determination of success or failure is not acquired. That is, it is possible to store up to four random numbers for determining whether a special symbol is appropriate or not, as with random numbers for determining whether a symbol is normal or not.

  When the processing related to the special symbol suspension is completed as described above, it is determined whether or not the condition device is in operation (S308). The condition device is a device that becomes a condition for operating the accessory continuous operation device, and is a device that starts operation when a special symbol is stopped and displayed as a jackpot symbol. The condition device activates the accessory continuous operation device, thereby starting a gaming state (so-called special gaming state) in which the special winning opening 311 is continuously opened. In S308, if it is determined that the condition device is in operation (S308: yes), it is determined that the special symbol game will not be started in order to avoid starting the special game state again (ie, S300: no). On the other hand, when the condition device is not in operation (S308: no), it is determined that the special symbol game is started (S308: yes).

  In step S300 of the game control process shown in FIG. 15, whether or not to start a special symbol game is determined as described above. If it is determined that the special symbol game is to be started (S300: yes), the special symbol game process described below is started (S350).

C-3-7. Special design game processing:
FIG. 21 is a flowchart showing the flow of the special symbol game process. When the special symbol game process is started, first, it is determined whether or not the special symbol is changing (S352). As described above with reference to FIG. 4, in the pachinko machine 1 of this embodiment, the symbol display device 27 is provided in the center of the central device 26, and a predetermined special symbol (this symbol is displayed on the liquid crystal screen of the symbol display device 27. And pseudo-patterns) can be displayed in a variable manner.

  If the special symbol is not fluctuating (S352: no), it is considered that either the special symbol has not yet fluctuated, or has been stopped and displayed as a stop symbol after the fluctuating display. Therefore, it is determined whether or not it is during the display time for displaying the special symbol stop symbol (S354). If the special symbol is not variably displayed and it is not during the display time when the special symbol is stopped (S354: no), it is determined whether or not the number of special symbols held is “0”. (S356). When the number of holds is not “0”, that is, when there is a special symbol hold (S356: no), the special symbol determination is started.

  In the pachinko machine 1 of the present embodiment, the probability determination of a special symbol is provided with a probability variation state in which a hit determination is likely to occur and a non-probability variation state in which a hit determination is generated with a normal probability. Accordingly, when starting the determination of whether or not the special symbol is correct, it is first determined whether or not the probability variation state is set (S358). If there is not, it is determined whether or not the change is uncertain (S362). The determination of whether or not a special symbol is present is performed using a method that is substantially the same as the determination of whether or not a normal symbol is successful. That is, it is determined whether or not the random number value for determination of success / failure stored at the time of holding the special symbol matches a predetermined winning value, and the random number value stored at the time of holding matches the winning value. If it does not match, it is determined that the special symbol is missed. During the probability change, since the types of preset hit values are increasing, it is easy to generate a big hit.

  When the special symbol determination is made in this manner, the CPU 401 of the main control board 340 outputs a special symbol related command to the sound / lamp control board 370 and the symbol control board 360 in accordance with the result of the determination (S364). . The special symbol related commands are various commands output from the main control board 340 toward the sub board in order to perform various effects such as blinking of various lamps and output of sound effects as the special symbol game progresses. .

  FIG. 22 is an explanatory diagram illustrating various commands set as special symbol-related commands. Like the normal pattern variation pattern described above, there are multiple types of special pattern variation patterns. Depending on these variation patterns, various commands such as command Ctp1, command Ctp2, command Ctp3, and command Ctp4 are available. A special symbol variation pattern designation command is set. In addition, in the symbol display device 27 of the present embodiment, these stop symbols correspond to the fact that the special symbol is composed and the main symbol consisting of the left symbol and the right symbol is variably displayed in the sub display area. , That is, a left symbol designating command CtsL and a right symbol designating command CtsR are set. In addition, special symbol-related commands include a command that specifies the sound effect that is output when the jackpot state is reached (a jackpot sound effect designation command CLsF), and a command that designates the number of rounds of the so-called special gaming state (a jackpot round designation command) CLsR) and a command for stopping the change display of special symbols (special symbol stop command Ctstp) are also set.

  In S364 shown in FIG. 21, first, a special symbol variation pattern designation command is transmitted according to the result of the special symbol success / failure determination performed earlier, and then various main symbol designation commands and various commands associated with jackpots. Send. Thus, when a special symbol related command is transmitted from the main control board 340 to the voice / lamp control board 370, the voice / lamp control board 370 transfers the command to the symbol control board 360 as necessary. As a result, in accordance with the special symbol game being performed on the main control board 340, the sound / lamp control board 370 and the symbol control board 360 perform appropriate effects. When the special symbol related command is transmitted as described above, the special symbol game process shown in FIG. 21 is ended and the game control process shown in FIG. 15 is resumed.

  The display control of the pseudo symbols constituting the special symbol is based on the special symbol related command output from the main control board 340 and the command (pseudo symbol related command) output from the voice / lamp control board 370. This is performed by the CPU 161 of the symbol control board 360. Specifically, first, the pseudo-symbol variation start is performed when the symbol control board 360 receives a special symbol variation pattern designation command output from the main control board 340 via the voice / lamp board 370. Done with. Then, the effect display (reach effect, notice effect, etc.) using the pseudo symbol is based on the variation pattern (variation time) indicated by the special symbol variation pattern designation command output from the main control substrate 340. It is determined and executed by the CPU 161. In addition, the voice / lamp control board 370 outputs a command (pseudo-designation designation command) for designating a pseudo-design to be stopped and displayed toward the design control board 360. This pseudo symbol designation command is output for each of the three symbols of the left symbol, the middle symbol, and the right symbol displayed in the main display area of the symbol display device 27, and the symbol designated by this symbol designation command is displayed. The voice / lamp control board 370 selects and outputs so as to show the same contents as the contents to be shown (normal hit, probability change or miss). Further, the pseudo symbol variation display is stopped when the symbol control board 360 receives the special symbol variation pattern designation command output from the main control board 340 via the voice / lamp board 370. In addition, it is desirable to stop the fluctuation of the pseudo symbol at the same time as the present symbol or slightly (approximately 0.5 seconds) earlier than the present symbol.

  On the other hand, if “yes” is determined in S356 of FIG. 21, that is, the special symbol is not changing and the special symbol is not stopped, but the number of reserved special symbols is “0”. The special symbol game process is terminated as it is without determining whether or not the special symbol is successful or transmitting a special symbol related command, and the process returns to the game control process shown in FIG.

  If it is determined in S352 that the special symbol is changing (S352: yes), it is considered that the symbol is changing in accordance with the special symbol-related command already transmitted. Therefore, it is determined whether or not the special symbol variation time has elapsed (S366). That is, since the variation time of the special symbol is predetermined according to the variation pattern, it is determined whether a predetermined variation time has elapsed by setting a timer at the same time as transmitting the variation pattern designation command. If the variation time has not yet elapsed (S366: no), the special symbol game process is terminated as it is, and the process returns to the game control process shown in FIG. On the other hand, when it is determined that the variation time has elapsed (S366: yes), the special symbol stop command described above with reference to FIG. 22 is transmitted (S367). Further, a display time for stopping and displaying the special symbol stop symbol is set so that the player can confirm the special symbol stopped and displayed on the symbol display device 27 (S370).

  Next, it is determined whether or not the display time of the special symbol stop symbol has elapsed (S372). If the display time has not elapsed (S372: no), the special symbol game process is terminated and the processing shown in FIG. Return to the game control process shown. On the other hand, when it is determined that the display time for stopping and displaying the stop symbol of the special symbol has passed (S372: yes), it is determined whether or not the special symbol that has been stopped is a symbol that will activate the condition device. Judgment is made (S374). The special symbols to be stopped are determined by the left special symbol designation command CtsL, the middle special symbol designation command CtsM and the right special symbol designation command CtsR described with reference to FIG. Whether or not the combination of symbols is to be activated has already been determined in step S364 when the special symbol related command is transmitted.

  If the combination of symbols that will cause the condition device to operate is not stopped and displayed (S374: no), the special symbol game process is terminated as it is, and the game control process shown in FIG. 15 is resumed. On the other hand, when the special symbol is stopped and displayed by the combination of symbols that will cause the conditional device to operate (S374: yes), after starting the conditional device (S376), it is determined whether or not the probability change is in progress (S376). S378). If the probability change is not in progress (S378: no), the special symbol game process is terminated, and if it is determined that the probability change is in progress (S378: yes), after the probability change state is stopped (S380), the special symbol is processed. The game is finished and the process returns to the game control process shown in FIG.

  As shown in FIG. 15, in the game control process, when returning from the special symbol game process, it is determined whether or not the condition device is in operation (S390). As described above, the condition device is a device that starts a so-called special game state by operating the accessory continuous operation device. Therefore, if the condition device is in operation, the CPU 401 starts a special electric accessory game process described below (S400). On the other hand, if the condition device is not in operation (S390: no), the special electric accessory game process (S400) is skipped.

C-3-8. Special electric game game processing:
FIG. 23 is a flowchart showing a process flow of the first half part in the special electric accessory game process. FIG. 24 is a flowchart showing the process flow of the latter half of the special electric accessory game process. A so-called special game state is generated by executing the special electric accessory game process. Hereinafter, the special electric accessory game process will be described with reference to the flowcharts of FIG. 23 and FIG. 24. As preparation thereof, the contents of a game called a special game state will be briefly described.

  As described above with reference to FIG. 4, the big prize opening 311 is provided below the game board, and the big prize opening 311 is closed in a normal gaming state. However, when the special gaming state is started, the special winning opening 311 is opened. The special electric accessory referred to in the present specification is a device that opens the special winning opening 311. Since the big winning opening 311 is opened larger than other winning openings, when the big winning opening 311 is opened, a game ball enters with a high probability. The special winning opening 311 is closed after being opened for a certain period of time or when a predetermined number of game balls enter, but during opening, a specific area (so-called V winning opening) provided inside the special winning opening 311. When the game ball passes through, it is again opened. The accessory continuous operation device referred to in this specification is a device that reopens the grand prize winning port 311 again.

  In this way, as long as the game ball passes through the specific area while the special winning opening 311 is opened, the special winning opening 311 is repeatedly opened and closed up to a predetermined number of times. A game from when the big prize opening 311 is opened until it is closed is called “round”. Then, the special winning opening 311 is opened up to a predetermined number of times (for example, 15 times) (that is, whether the predetermined number of rounds are digested), or the special winning opening 311 is closed without the game ball passing through the specific area. Then, the special game state ends. Such a special game state is realized by repeatedly executing the special electric accessory game process shown in FIGS. 23 and 24 in the game control process shown in FIG. Hereinafter, the first half of the special electric game game process will be described with reference to FIG. 23, and the latter half of the special electric game game process will be described with reference to FIG.

  As shown in FIG. 23, when the special electric accessory game process is started, first, it is determined whether or not the special winning opening 311 is open (S402). The big prize opening 311 is closed in the normal gaming state, and therefore, the big prize opening 311 is closed immediately after the start of the special electric accessory game. Therefore, it is determined that the special winning opening is not open (S402: no), and it is determined whether or not the specific area valid time has ended (S416). The specific area valid time is a time for confirming whether or not the game ball has passed through the specific area provided in the special winning opening 311. When the special electric accessory game process is started for the first time, since the specific area valid time has not ended, it is determined “no” in S416, and subsequently, it is determined whether or not the game ball has passed the specific area. (S418). Immediately after the special electric accessory game is started, the special winning opening 311 is closed, so that the game ball does not pass through the specific area. The physical game process is terminated, and the process returns to the game control process shown in FIG.

  As shown in FIG. 15, when returning to the game control process, after resetting the watchdog timer built in the CPU initialization circuit unit (S90), whether or not to start the normal symbol game process (S100). ), The presence / absence of the operation of the ordinary electric accessory (S190), and whether or not to start the special symbol game process (S300) are sequentially judged. As a result, the ordinary symbol game process (S150) S200), the special symbol game process (S350) is skipped, and the process returns to the special electric accessory game process (S400) again.

  As described above, immediately after the special electric accessory game process is started, the big prize opening 311 is closed. Thus, while the game control process of FIG. 15 is repeatedly performed, the big prize opening 311 is eventually opened. It becomes. As a result, since it is determined that the special winning opening is being opened in the special electric accessory game process (S400) (S402: yes), it is subsequently determined whether or not the game ball has passed through the specific area (S404). ). When the game ball passes through the specific area (S404: yes), it is determined whether or not the accessory continuous operation device is operating (S406). As described above, the accessory continuous operation device in the present embodiment is a device that reopens the once closed special winning opening 311. If the accessory continuous operation device is not operating (S406: no), the operation of the accessory continuous operation device is started (S408). When the accessory continuous operation device is already operating (S406: yes), the processing of S408 is skipped so that the accessory continuous operation device is not overlapped.

  Next, it is determined whether or not the opening time of the special winning opening 311 has reached a predetermined time (S410). As described above, in the special game, the big prize opening 311 is opened, but is closed when the predetermined time is opened for a predetermined time or when a predetermined number of game balls enter the big prize opening 311. In response to this, in S410, it is first determined whether or not the opening time of the special winning opening 311 has reached a predetermined time. If the opening time has reached the predetermined time (S410: yes), the special winning opening is closed (S414). On the other hand, if the opening time has not reached the predetermined time (S410: no), it is determined whether or not the number of game balls that have entered the special winning opening 311 has reached a specified number (S412). When the number of game balls reaches the specified number (S412: yes), the special winning opening 311 is closed (S414). However, if the specified number has not been reached, it is considered that the opening time of the big prize opening 311 has not yet reached the predetermined time, and that the game balls that have entered the big prize opening 311 have not reached the prescribed number. The special electric accessory game process shown in FIGS. 23 and 24 is terminated while the special winning opening 311 is opened, and the process returns to the game control process of FIG.

  When returning to the game control process, first, after resetting the watchdog timer of the CPU initialization circuit (S90), a series of subsequent determinations are made, and the special electric accessory game process (S400) is started again. While repeating these processes, the special winning opening 311 is closed and it is determined as “no” in S402. If “no” is determined in S402, it is then determined whether or not the specific area valid time has elapsed (S416). As described above, the pachinko machine 1 according to the present embodiment is configured such that when the game ball passes the specific area during the specific area effective time, the accessory continuous operation device is activated. If the specific area valid time has not elapsed (S416: no), it is determined whether or not the game ball has passed the specific area (S418), and if it has not passed (S418: no), it remains as it is. The special electric accessory game process is terminated and the process returns to the game control process shown in FIG. On the other hand, when the game ball passes the specific area (S418: yes), it is determined whether or not the accessory continuous operation device is operating (S420), and the accessory continuous operation device is already operating. In the case (S420: yes), the special electric accessory game process is finished as it is, and when the accessory continuous operation device is not yet operated (S420: no), after the accessory continuous operation device is operated (S422). ), The special electric accessory game process is terminated, and the process returns to the game control process shown in FIG.

  On the other hand, if it is determined “yes” in S416, that is, if the special winning opening 311 is closed and the specific area valid time has already passed, it is considered that the round in the so-called special game state has ended. It is done. Therefore, it is determined whether or not the game ball has passed the specific area during the opening of the special winning opening 311 and during the specific area effective time (S424). If the game ball has not passed through the specific area (S424: no), the so-called puncture state is established and the accessory continuous action device is stopped (S426).

  On the other hand, when the game ball passes through the specific area (S424: yes), after confirming that the closing time of the big prize opening has ended (S428: yes), whether or not the accessory continuous operation device is operating. Is determined (S430 in FIG. 24). If the accessory continuous operation device is in operation (S430: yes), after the special winning opening 311 is opened (S432), the special electric accessory game process is terminated and the game control process shown in FIG. 15 is performed. Return. On the other hand, if it becomes a so-called puncture state and the accessory continuous operation device is stopped or if a predetermined round (for example, 15 rounds) is digested, the accessory continuous operation device is not operating (S430: no). In this case, it is determined whether or not the operation of the condition device is based on a predetermined probability variation symbol among the jackpot symbols (S434). Here, the condition device is a device that is a condition for operating the accessory continuous operation device. If the operation of the condition device is based on the probability variation symbol (S434: yes), the operation of the probability variation function is started (S436), and then the operation of the condition device is stopped (S438). On the other hand, when the operation of the condition device is not based on the probability variation symbol (when it is based on the normal symbol) (S434: no), immediately after the operation of the condition device is stopped (S446), the operation of the condition device is the probability variation. It is determined whether or not the function is activated (S448). If it is determined that the operation of the condition device is not during the operation of the probability varying function (S48: no), the special electric accessory game process is terminated and the process returns to the game control process shown in FIG.

  After stopping the operation of the condition device as described above (S438), or when it is determined that the operation of the condition device is operating the probability variation function (S448: yes), the special symbol variation time shortening function Is activated (S440), the normal symbol variation time reduction function is activated (S442), and the normal electric accessory release extension function is activated (S444), and then the special electric accessory game process is terminated. Then, the process returns to the game control process shown in FIG. The pachinko machine 1 of the present embodiment can advance the game by repeatedly performing the game control process as described above.

C-4. Processing when power failure occurs:
Next, when a power failure occurs during the game of the pachinko machine 1 and the power is unexpectedly cut off, a process for storing the state of the game as backup data, that is, a process when a power interruption occurs explain.

  FIG. 25 is a flowchart showing the flow of processing when a power interruption occurs. Such processing is started by generating an interrupt toward the CPU 401 of the main control board 340 when it is detected that the voltage supplied from the power source has dropped below a predetermined value. Since this process is an urgent process, it is set to an interrupt that cannot be masked, and is immediately implemented when an interrupt occurs.

  When the power-off generation process is started, first, the contents of all the registers of the CPU 401 are stored in the backup area on the RAM (S900). Next, the set value of the stack pointer is also stored in the backup area (S902). The start address of the program is set in the stack pointer. Therefore, if the contents of all the registers and the contents of the stack pointer are saved, even when the program is started again, it can be started from the same location under the same conditions.

  Next, in order to confirm the prize balls remaining in the prize ball payout device 109, processing for monitoring the output of the prize ball counting switch for a predetermined period is performed (S904). If there is a prize ball remaining in the payout device 109, the number of game balls passed during this period is detected and stored.

  Thereafter, a checksum is calculated for the backup data stored in the backup area, the obtained result is stored (S906), and then the backup flag is set to ON (S908). Finally, the RAM is set to an access prohibited state (S910), and the process at the time of power-off occurrence is terminated. In the control start preparation process described above with reference to FIG. 13, when it is determined that the backup flag is ON (S <b> 18 in FIG. 13: yes), by reading the backup data stored in this way, It becomes possible to restore the gaming state before the power is cut off.

D. Configuration of game ball guidance mechanism:
In the pachinko machine 1 according to this embodiment described above, a game ball guiding mechanism 28 (see FIG. 4) is mounted below the central device 26 in order to enhance the interest of the player. The game ball guiding mechanism 28 is provided with a rotating body that conveys the game ball, and the movement of the game ball can be changed by conveying the game ball guided into the guiding mechanism by the movement of the rotating body. It is possible. In addition, in order to effectively enhance the interest of the player, a method of transporting the game ball on the inner peripheral surface of the rotating body is adopted. Below, the game ball guidance mechanism 28 mounted on the pachinko machine 1 of the present embodiment will be described, and then, by using the game ball guidance mechanism 28, it is possible to effectively enhance the interest of the player. The reason will be explained.

  First, the configuration of the game ball guiding mechanism 28 mounted on the pachinko machine 1 will be described. FIG. 26 is an explanatory diagram showing a configuration of the game ball guiding mechanism 28 mounted on the central device 26. The game ball guiding mechanism 28 according to the present embodiment roughly includes an intake 260 for taking the game ball into the central device 26 and a warp for guiding the taken game ball from the intake 260 to the game ball guiding mechanism 28. A passage 262, three stages (upper stage 280, middle stage 283, lower stage 287), a rotating body (281, 285) for transporting game balls between the stages, a game ball guide port 289, and a game ball discharge port H.264 or the like. As will be described in detail later, the game ball is guided to the lower stage 287 through the warp passage 262 and conveyed to the middle stage 283 and further to the upper stage 280 by the rotating body 285 and the rotating body 281, and then guided to the game ball The game ball is discharged from the game ball discharge port 264 to the outside of the central device 26 through the port 289. As shown in FIG. 4, since the start port 17 is provided directly below the central device 26, the game ball discharged from the game ball discharge port 264 enters the start port 17 as it is.

  Thus, if the game ball guided to the game ball guiding mechanism 28 through the warp passage 262 can be conveyed to the lower stage 287, the middle stage 283, and the upper stage 280 and guided to the game ball guiding port 289, It is possible to enter the starting port 17 almost certainly. For this reason, the player observes the state in which the game ball is conveyed with a great expectation, and can greatly enhance the interest. In addition, as will be described later, the rotating body 285 that transports the game ball from the lower stage 287 to the middle stage 283 employs a method of transporting the game ball in a state of being captured on the inner peripheral surface. The movement of the ball can be effectively produced, and it is possible to effectively enhance the interest of the player.

E. Game ball transport operation:
Hereinafter, the manner in which a game ball is conveyed in the game ball guiding mechanism 28 of the present embodiment will be described in detail. FIG. 27 is an explanatory view showing a state in which a game ball is guided from the outside of the central device 26 to the game ball guiding mechanism 28. As described above with reference to FIG. 26, the intake port 260 is provided on the left side of the central device 26, and the intake port 260 is connected to the warp passage 262 inside the central device 26. When the game ball enters the intake port 260, the game ball passes through the warp passage 262 and is supplied to the lower stage 287 of the game ball guiding mechanism 28. In FIG. 27, a state in which a game ball that has entered the intake port 260 is guided to the lower stage 287 through the warp passage 262 is indicated by a dashed arrow.

  The game ball supplied from the warp passage 262 to the lower stage 287 is guided to the inside of the rotating body 285 provided at the other end of the stage while rolling on the lower stage 287 with the momentum of the ball. FIG. 28 is an explanatory diagram conceptually showing a state in which a game ball rolls on the lower stage 287 and is guided into the rotating body 285. As will be described later, a mechanism for catching a game ball is provided inside the rotator 285, so that the game ball rolling on the lower stage 287 can be captured and transported to the middle stage 283. Yes.

  FIG. 29 is a perspective view showing the shape of the rotating body 285. As shown in the figure, the rotating body 285 is formed in a substantially cylindrical shape. The lower stage 287 and the middle stage 283 are attached in such a positional relationship that the ends of these stages are enclosed in a space inside the cylinder. A magnet 285m is provided on a part of the side surface of the rotating body 285. Further, the rotating body 285 is provided with a gear, and is rotated in a certain direction by being driven by the drive motor 29. In this embodiment, a neodymium magnet is used as the magnet 285m. Since the neodymium magnet is small and forms a strong magnetic field, it can be suitably incorporated in the rotating body 285.

  When the game ball rolls on the lower stage 287 and reaches the inside of the rotating body 285, if the magnet 285m is in the position shown in FIG. 29, the game ball is attracted to the magnet 285m. Then, the game ball moves along with the rotation of the rotating body 285 and is conveyed to the middle stage 283. Thus, the rotating body 285 has a function of transporting a game ball, and constitutes one aspect of the transport body in the present invention. Further, the magnet 285m provided on the rotating body 285 has a function of capturing a game ball, and constitutes one aspect of the game ball capturing unit in the present invention.

  As shown in FIG. 29, on the outer peripheral surface of the rotating body 285, a mark (star shape in this embodiment) is attached at a position where the magnet 285m is provided. Therefore, the player can easily know whether or not the magnet 285m exists near the lower stage 287 when the game ball reaches the rotating body 285. FIG. 30 shows a state in which the game ball rolling on the lower stage 287 is attracted to the magnet 285m built in the rotating body 285 and is conveyed to the middle stage 283.

  On the other hand, if the magnet 285m does not exist in the vicinity of the lower stage 287 when the game ball reaches the inside of the rotating body 285, the game ball is not attracted to the magnet 285m. The stage 287 is now rolled in the opposite direction. FIG. 31 is an explanatory diagram showing a state in which the lower stage 287 rolls in the reverse direction. The game ball that has returned to the lower stage 287 in this way is reflected on the other end side of the stage, and then rolls toward the rotating body 285 again. When the game ball reaches the inside of the rotating body 285, if the magnet 285m rotating together with the rotating body 285 exists near the lower stage 287, the game ball is attracted to the magnet 285m, and FIG. As shown in FIG. However, when the magnet 285m does not exist in the vicinity of the lower stage 287, the game ball rolls on the lower stage 287 in the opposite direction again. If this is repeated several times, the rolling speed of the game ball gradually decreases and eventually falls from the lower stage 287. FIG. 32 is an explanatory diagram showing a state in which the speed of the game ball decreases and falls from the lower stage 287.

  On the other hand, the game ball attracted to the magnet 285m moves along with the rotation of the rotating body 285 as shown in FIG. 30, and is conveyed to the middle stage 283. FIG. 33 is an explanatory diagram showing a state where the game ball is conveyed from the lower stage 287 to the middle stage 283. Even after the game ball reaches the middle stage 283, the rotating body 285 continues to rotate, so that the portion provided with the magnet 285m goes around to the back side of the middle stage 283. As a result, the game ball is pulled away from the magnet 285m, and thereafter rolls on the middle stage 283 toward the center of the stage.

  FIG. 34 is an explanatory view conceptually showing a state in which the game ball conveyed by the rotating body 285 rolls on the middle stage 283. As shown in the drawing, a rotating body 281 is provided at two locations between the middle stage 283 and the upper stage 280, and each rotating body 281 rotates from the middle stage 283 toward the upper stage 280. ing. Further, a magnet is built in a part of the outer peripheral surface of the rotating body 281, and it is possible to suck the game ball at this portion and transport the game ball from the middle stage 283 to the upper stage 280. . Hereinafter, the above-described rotating body 285 (that is, the rotating body 285 that captures the game ball on the inner peripheral surface and transports the game ball from the lower stage 287 to the middle stage 283) is referred to as a first rotating body. In addition, the rotating body 281 (rotating body 281 that captures the game ball on the outer peripheral surface and transports the game ball from the middle stage 283 to the upper stage 280) may be referred to as a second rotating body. And

  FIG. 35 is an explanatory view showing, in an enlarged manner, a portion where the second rotating body 281 is incorporated between the middle stage 283 and the upper stage 280. As described above, the second rotating body 281 contains a magnet, and a part of the outer peripheral surface sucks the game ball. In the present embodiment, a star-shaped mark is displayed on the portion of the second rotating body 281 that attracts the game ball. Moreover, the white arrow shown in the figure has shown the rotation direction of the 2nd rotary body 281. FIG. Furthermore, the dashed arrow indicates the direction in which the game ball rolls.

  When the game ball rolling on the middle stage 283 passes in front of the rotating body 281, the part with the built-in magnet (that is, the part where the star-shaped mark is displayed) is just on the side of the middle stage 283 (in the figure, If it faces the front side, the game ball is attracted to the outer peripheral surface of the rotating body 281. The sucked game ball moves along with the rotation of the rotating body 281 and is conveyed to the upper stage 280. FIG. 36 is an explanatory view showing a state in which a game ball is attracted to the outer peripheral surface of the rotating body 281 and conveyed to the upper stage 280.

  On the other hand, when the game ball passes in front of the rotator 281, if the star-shaped mark does not face the middle stage 283 side (the front side in the drawing), the game sphere is attracted to the rotator 281. Without rolling, it rolls on the middle stage 283 as it is. FIG. 37 is an explanatory diagram showing a state where the game ball rolls on the middle stage 283 without being attracted to the rotating body 281.

  As described above, in the pachinko machine 1 according to the present embodiment, the two rotating bodies 281 are provided in the middle stage 283. Therefore, even if the game ball passes in front of one rotating body 281, the other rotating body is used. 281 is reached. At this time, if the star-shaped mark attached to the other rotating body 281 faces the middle stage 283 side (the front side in the drawing), the game ball is sucked onto the outer peripheral surface of the rotating body 281. Then, as shown in FIG. 36, it is conveyed to the upper stage 280.

  On the other hand, when the game ball is not attracted to the other rotating body 281, it reaches the other end of the middle stage 283 as it is, and is reflected here, and this time the middle stage 283 is moved in the opposite direction. It rolls. Thus, when the game ball reciprocates while rolling on the middle stage 283 and is attracted to the outer peripheral surface of one of the rotating bodies 281, the gaming ball is conveyed to the upper stage 280 by the rotation of the rotating body 281. However, if the middle stage 283 is reciprocated many times without being attracted by the magnet of the rotating body 281, the speed of the game ball gradually decreases, and eventually falls from the middle stage 283. FIG. 38 is an explanatory diagram showing a state in which the speed of the game ball drops and falls from the middle stage 283.

  When the game ball is conveyed to the upper stage 280 as described above, this time, the game ball rolls toward the center of the upper stage 280. As shown in FIG. 26, a game ball guide port 289 is provided at the center of the upper stage 280, and the game ball guide port 289 is connected to a game ball discharge port 264 provided right above the start port 17. Has been. Therefore, the game ball transported to the upper stage 280 passes through the game ball guide port 289 at the center of the upper stage 280, is discharged from the game ball discharge port 264, and enters the start port 17. FIG. 39 conceptually shows a state in which the game ball conveyed to the upper stage 280 is discharged from the game ball discharge port 264 through the game ball guide port 289.

  As described above, the game ball guided to the game ball guiding mechanism 28 is conveyed to the lower stage 287, the middle stage 283, and the upper stage 280 by the first rotating body 285 and the like, and thereafter, the game ball guiding port 289. After that, it is possible to enter the starting port 17. For this reason, the player observes the state in which the game ball is conveyed with a great expectation, and can greatly enhance the interest.

F. Drive motor load detection:
As described above, in the pachinko machine 1 according to the present embodiment, the game balls are effectively conveyed by transporting the game balls by the first rotating body 285 or the like. Thus, if an effect such as sound output from the speaker 400a, blinking of a lamp or LED, or symbol display by the symbol display device 27 can be performed, the player's interest can be enhanced more effectively.

  Therefore, in the pachinko machine 1 of the present embodiment, as described below, it is detected whether or not the game ball is being conveyed by the first rotating body 285, and according to the detection result, output of sound, illumination It is supposed to produce effects by flashing and displaying symbols. Further, in order to easily detect whether or not the game ball is being transported, in this embodiment, a change in the load applied to the drive motor 29 is detected by the motor load detection unit 40, and the rotation is performed based on the detection result. It is assumed that the state of transport of game balls in the body 285 is determined. Due to the structure of the rotator 285, it is not always easy to provide a sensor that directly detects the game ball. However, if the load change of the drive motor 29 is detected, the structure of the rotator 285 is not restricted. It is also possible to determine the state of transport of game balls. Hereinafter, the contents of the motor load detection unit 40 and the motor load detection process (S95) for realizing the configuration of the present embodiment will be described.

  FIG. 40 is an explanatory diagram showing an electrical configuration of the motor load detection unit 40. As will be described below, the motor load detection unit 40 has a function of detecting a change in torque load applied to the drive motor 29, and constitutes one aspect of the load detection unit of the present invention. As shown in the figure, the motor load detector 40 includes a current detection resistor R1 provided on the energization path of the drive motor 29, and a comparator 42 for detecting a change in the current energized to the drive motor 29. And voltage dividing resistors R2 and R3 for supplying the reference voltage Va to the comparator 42. If the motor load detector 40 configured in this way is used, a change in the load applied to the drive motor 29 can be detected. The reason will be described below with reference to FIG.

  FIG. 41 is a graph showing the relationship between the load applied to the drive motor 29 and the energization current. As shown in the figure, there is a relationship between the torque load applied to the drive motor 29 and the energization current that the energization current increases as the torque load increases. Therefore, if a change in the energization current of the drive motor 29 is detected, a change in torque load applied to the drive motor 29 can be detected indirectly. In this embodiment, as shown in FIG. 40, since the current detection resistor R1 is provided on the downstream side of the drive motor 29, the change in voltage applied to the current detection resistor R1 is detected by the comparator 42. By detecting this, it is possible to detect a change in the energization current of the drive motor 29, thereby detecting a change in the load applied to the drive motor 29.

  For example, when the game ball is not captured by the magnet 285m of the first rotating body 285 and the load applied to the drive motor 29 is smaller than the reference load Ta, as shown in FIG. 41, the drive motor The energizing current 29 is smaller than the reference current Ia. In this case, since the voltage input to the non-inverting input terminal (+) of the comparator 42 is smaller than the reference voltage Va, the signal output from the comparator 42 to the main control unit 140 is at a low level. On the contrary, when the game ball is captured by the magnet 285m of the first rotating body 285, the load applied to the drive motor 29 becomes larger than the reference load Ta, and as a result, the energization current of the drive motor 29 is larger than the reference current Ia. Also grows. In this case, since the voltage input to the non-inverting input terminal (+) of the comparator 42 is higher than the reference voltage Va, the signal output from the comparator 42 to the main control unit 140 becomes Hi level. In the present embodiment, since the motor load detector 40 that operates in this way is provided, it is possible to detect a change in the load applied to the drive motor 29.

  As described above, the present embodiment employs a configuration that detects a change in the load applied to the drive motor 29. Therefore, the first rotating body 285 is not provided with a sensor that directly detects a game ball. It is possible to determine the transport status of game balls. In the above description, the energization current of the drive motor 29 and the reference current Ia are compared, and when the energization current exceeds the reference current Ia, it is determined that the load of the drive motor 29 has changed. . Of course, the present invention is not limited to such a method. For example, a current change amount is obtained by periodically measuring an energization current, and if the change amount exceeds a predetermined value, it may be determined that the motor load has changed. . Furthermore, the differential value of the energization current may be detected in a circuit, and if the differential value exceeds a predetermined value, it may be determined that the motor load has changed.

  Here, if it is determined that the game ball is being transported by the first rotating body 285, if an effect can be provided by a symbol display or the like in accordance with the movement of the game ball, as described above, the player's It is possible to enhance the interest more effectively. Below, the control process for implement | achieving such an effect is demonstrated using FIG.

G. Processing details of motor load detection processing:
FIG. 42 is a flowchart showing a motor load detection process performed in the game control process. This motor load detection process is a process of determining whether or not to produce an effect by voice output, lighting flashing, symbol display, etc., based on the signal level input from the motor load detection unit 40 to the main control unit 140. One aspect of the effect control unit of the present invention is configured.

  As shown in the figure, when the motor load detection process is started, it is first determined whether or not the output signal from the motor load detector 40 is at the Hi level (S950). If the signal level is Hi (S950: YES), it can be determined that the game ball is being transported by the first rotating body 285. In this case, a predetermined effect command is sent to the voice / lamp control. Output to the substrate 370 (S960). Then, an effect by voice, illumination, or symbol display is executed in accordance with the movement of the game ball. On the other hand, when the output signal from the motor load detection unit 40 is at the low level (S950: NO), it can be determined that the game ball is not being conveyed by the first rotating body 285, and in this case, S950 This process is skipped, and the motor load detection process is terminated.

  As described above, in the motor load detection process shown in FIG. 42, the change of the load applied to the drive motor 29 is detected (S950), thereby determining the state of transport of the game ball by the first rotating body 285, and the determination result. Accordingly, the setting is made to produce effects by voice, illumination, symbol display, or the like (S960).

  As described above, the pachinko machine 1 according to the present embodiment is configured to determine the conveyance state of the game ball by the first rotating body 285 by detecting a change in the load applied to the drive motor 29. Yes. Therefore, without providing a sensor for directly detecting a game ball, it is possible to simply execute an effect by sound output, an effect by blinking of a lamp or the like, or an effect by symbol display in accordance with the movement of the game ball. In addition, since it is not necessary to provide a sensor for directly detecting the game ball, it is possible to provide an effect that matches the movement of the game ball without being restricted by the structure of the rotating body 285.

  In addition, since the first rotating body 285 has a mechanism for transporting the game ball to a position higher than the capture position of the game ball, in the state where the game ball is transported and the state where it is not transported, The difference in load applied to the drive motor 29 increases. Therefore, it is possible to more reliably detect a change in load applied to the drive motor 29. Also, if the captured game ball is transported to a high position, the game ball can be moved again from that position using gravity. As a result, a great change can be given to the movement of the game ball, so that the interest of the player can be more effectively enhanced.

[2] Second embodiment:
In the first embodiment described above, the aspect in which the game ball before winning a prize is transported by the transport body (rotating body 285) has been described. On the other hand, as in the second embodiment described below, the winning game ball may be transported by the transport body, and the present invention can be applied to such a configuration.

A. Game board surface structure:
FIG. 43 is an explanatory diagram showing a schematic configuration of the game board 2020 in the second embodiment. The gaming machine of the second embodiment is a type of pachinko machine called a feather. As shown in the drawing, a substantially circular game area 2021 surrounded by an outer rail 2022 and an inner rail 2023 is formed in the approximate center of the game board 2020. In the center of the game area 2021, A variable pitching device 2100 is mounted. As will be described in detail later, the variable pitching device 2100 is provided with a variable pitching port 2102, and when a game ball wins from the variable pitching port 2102 to the variable pitching device 2100, 2120 or the non-specific region 2122 is passed. When the game ball passes through the specific area 2120, the gaming machine enters a special game state that is advantageous to the player. An effect display device 2240 having a liquid crystal screen is provided inside the variable pitching device 2100. In the effect display device 2240, display of an effect design (character) according to the progress of the game, round display in a special game state, and the like are performed.

  Note that three start ports 2032a, 2032b, and 2032c are provided below the variable pitching device 2100, and winning ports 2027a and 2027b are provided on the left and right sides of the variable pitching device 2100. In addition, the game area 2021 is provided with a pair of windmills 2026a and 2026b and a number of obstacle nails (not shown).

B. Configuration of variable pitching device and movement of game ball:
FIG. 44 is an explanatory diagram showing a schematic configuration of the variable pitching device 2100. As shown in the drawing, a pair of wing pieces 2102a and 2102b are provided on both sides of the upper part of the variable pitching device 2100 so as to be opened and closed. The blade pieces 2102a and 2102b are connected to a solenoid (not shown) via a link mechanism (not shown), and can be opened and closed by driving the solenoid.

  A game ball passage 2136 is provided below the variable entrance 2102. When the above-described wing pieces 2102a and 2102b are in the open state, the game ball that has won the variable ball entry device 2100 from the variable ball inlet 2102 is detected by the game ball detection switch 2103, and then the game ball passage 2136. Led to.

  FIG. 45 is an explanatory diagram showing a state in which a game ball that has entered the variable ball entry device 2100 is guided to the game ball passage 2136. In FIG. 45, the movement of the game ball is represented by a dashed arrow. As shown in the figure, the game ball guided to the game ball passage 2136 reaches the substantially central portion of the game ball passage 2136 while rolling by the momentum of dropping.

  A cylindrical rotating body 2140 is provided in the vicinity of the central portion of the game ball passage 2136. The rotating body 2140 rotates from the game ball path 2136 toward the specific area 2120 as indicated by the white arrow. In addition, a magnet 2140m is built in the outer peripheral portion of the rotating body 2140, and the game ball can be attracted to a part of the outer peripheral surface by the magnet 2140m. Therefore, when the game ball reaches the substantially central portion of the game ball passage 2136, if there is a magnet 2140m in the vicinity thereof, the game ball is captured by the magnet 2140m and transferred to the specific area 2120.

  FIG. 46 is an explanatory diagram showing a state in which the game ball captured by the magnet 2140m is conveyed to the specific area 2120. As shown in the drawing, the game ball captured by the magnet 2140 m moves along with the rotation of the rotating body 2140 and reaches a specific area 2120 at a position higher than the game ball passage 2136. Since the rotating body 2140 continues to rotate after the game ball reaches the specific area 2120, the game ball is pulled away from the magnet 2140 m and taken into the pachinko machine 1.

  Also in the present embodiment, as in the first embodiment, the rotating body 2140 is rotationally driven by a predetermined drive motor. The load applied to the drive motor is detected by a motor load detection unit, and depending on the detection result, settings such as production of sound output, lighting flashing, symbol display, and the like are performed. Therefore, when the game ball is captured by the magnet 2140m and starts to move along with the rotation of the rotating body 2140, an effect such as symbol display is performed in accordance with the movement of the game ball.

  On the other hand, when the game ball reaches the substantially central portion of the game ball passage 2136, if there is no magnet 2140m in the vicinity thereof, the game ball rolls over the central portion of the game ball passage 2136, and the game ball passage 2136 It bounces off the opposite side and rolls back to the center of the game ball passage 2136. In this way, the game ball rolls so as to reciprocate on the game ball passage 2136, but if it is caught by the magnet 2140m during that time, the game ball is transported to the specific area 2120. However, if it is not captured by the magnet 2140m of the rotating body 2140, the rolling speed of the game ball gradually decreases, and the game ball finally falls from the game ball passage 2136.

  FIG. 47 is an explanatory diagram showing a state in which a game ball falls from the game ball passage 2136 as a result of a decrease in the speed of the game ball. FIG. 48 is an explanatory diagram showing a state in which a game ball dropped from the game ball passage 2136 passes through the non-specific area 2122. As shown in the drawing, when the game ball falls from the game ball passage 2136, the game ball passes through a non-specific area 2122 provided at the lower center of the variable pitching device 2100 and is taken into the pachinko machine 1. Become.

  As described above, a configuration in which a game ball after winning a prize is conveyed by the rotator 2140 may be adopted, and even in such a configuration, the load of the drive motor that drives the rotator 2140 can be detected. . For this reason, even after winning a prize, it is possible to produce an effect in accordance with the movement of the game ball by means of symbol display or the like, thereby effectively enhancing the interest of the player. Further, if the game ball captured by the rotating body 2140 is directly detected by the sensor, the structure becomes complicated, and a part of the game ball passage 2136 may be hidden behind the sensor, which may reduce the appearance. If the load of the motor is detected, such a problem does not occur.

  In the present embodiment, the magnet 2140m constitutes one aspect of the game ball capturing section in the present invention. The rotating body 2140 constitutes one aspect of the transport body in the present invention.

  While various embodiments of the present invention have been described above, the present invention is not limited to this, and is not limited to the wording of each claim unless it departs from the scope described in each claim. It is possible to appropriately add an improvement based on the knowledge that a person skilled in the art normally has, and also to the extent that those skilled in the art can easily replace them.

  For example, in the above-described embodiment, the display control of all effect symbols displayed on the liquid crystal screen of the symbol display device 27 has been described as being performed by the symbol control unit 160. However, the display control of these effect symbols may be shared by the symbol control unit 160 and the main control unit 140. For example, the main control unit 140 controls display of the normal symbol displayed on the liquid crystal screen, the main symbol, and the hold, and the symbol control unit 160 controls display control of the pseudo symbol, the background image, and the character symbol. It is also possible to do in.

  In the above-described embodiment, the game ball is attracted using the magnet. However, the method is not limited to the method of sucking using the magnet as long as the game ball can be captured. For example, a pocket-shaped concave portion is provided on the inner peripheral surface of the first rotating body 285, and a game is moved from the lower stage 287 to the middle stage 283 by rotating the rotating body with the game ball taken into the concave portion. It is good also as what conveys a ball | bowl.

  Moreover, in the said Example, it demonstrated as what conveyed the captured game ball to a position higher than the capture position. However, it is not always necessary to transport to a high position, and the game ball may be transported to a position lower than the captured position, or the game ball may be transported to a position of almost the same height. .

  Moreover, in the said Example, although the structure which detects the change of the load concerning the drive motor 29 based on the change of the energization current of the drive motor 29 is employ | adopted, it is not restricted to this. For example, when a configuration in which the rotational speed of the drive motor is held substantially constant by feedback control is employed, the applied voltage to the drive motor is increased or decreased with respect to increase or decrease in the load applied to the drive motor. Therefore, when such feedback control is employed, a change in the motor load may be detected by detecting the voltage applied to the drive motor.

It is the front view which looked at the pachinko machine by the 1st example from the front side (namely, player side). It is the perspective view which looked at the pachinko machine by 1st Example from diagonally upward in the state where the front frame opened. It is explanatory drawing which shows the positional relationship of the various LED board mounted in the pachinko machine by 1st Example. It is explanatory drawing which shows the structure of the surface of the game board by 1st Example. It is explanatory drawing which shows the structure of the back surface side of the pachinko machine by 1st Example. It is a block diagram which shows the structure of the control circuit in the electronic control apparatus mounted in the pachinko machine by 1st Example. It is explanatory drawing which shows notionally the structure of the main control board by 1st Example. It is explanatory drawing which shows the detailed structure of CPU by 1st Example. It is explanatory drawing which shows notionally the structure of the payout control board by 1st Example. It is explanatory drawing which shows notionally the structure of the audio | voice / lamp control part by 1st Example. It is explanatory drawing which shows notionally the structure of the symbol control part by 1st Example. In the pachinko machine of 1st Example, it is explanatory drawing which showed the big flow until control of a game is started by an electronic controller after power activation. It is a flowchart which shows the flow of the control start preparation process which CPU mounted in the main control board of 1st Example implements immediately after starting. It is explanatory drawing which shows notionally a mode that various commands are output toward the audio | voice / lamp control board from the main control part of 1st Example. It is a flowchart which shows the rough flow of the game control process which CPU mounted in the main control board of 1st Example performs. It is a flowchart which shows the process performed in order to judge whether the normal symbol game process is started in the game control of 1st Example. It is the flowchart which showed the flow of the normal symbol game process in the game control of 1st Example. It is explanatory drawing which illustrated various commands set as a normal symbol related command in the game control of 1st Example. It is a flowchart which shows the flow of the normal electric accessory game process in the game control of 1st Example. It is the flowchart which showed the flow of the process which judges whether special symbol game is performed in the game control of 1st Example. It is the flowchart which showed the flow of the special symbol game process in the game control of 1st Example. It is explanatory drawing which illustrated various commands set as a special symbol related command in the game control of 1st Example. It is a flowchart which shows the flow of the process of the first half part of the special electric accessory game process performed by the game control of 1st Example. It is a flowchart which shows the flow of the process of the second half part of the special electric accessory game process performed by the game control of 1st Example. It is a flowchart which shows the flow of the process at the time of the power failure generation | occurrence | production in the game control of 1st Example. It is explanatory drawing which shows the structure of the game ball guidance mechanism mounted in the central apparatus. It is explanatory drawing which shows a mode that a game ball is guide | induced to the game ball guidance mechanism from the outside of a central apparatus. It is explanatory drawing which shows notionally a mode that a game ball rolls on the lower stage and is guide | induced to the inside of a 1st rotary body. It is a perspective view which shows the shape of the 1st rotary body which captures and conveys a game ball by an internal peripheral surface. It is explanatory drawing which shows a mode that a game ball is attracted | sucked to the magnet of a 1st rotary body, and is conveyed from a lower stage to a middle stage. It is explanatory drawing which shows a mode that a game ball rolls a lower stage in a reverse direction, without being attracted | sucked to a magnet. It is explanatory drawing which shows a mode that the speed of a game ball falls and falls from a lower stage. It is explanatory drawing which shows a mode that a game ball is conveyed from the lower stage to the middle stage, and leaves | separates from the magnet of a 1st rotary body. It is explanatory drawing which shows a mode that the game ball conveyed by the 1st rotary body rolls on the middle stage. It is explanatory drawing which expands and shows the peripheral part of the 2nd rotary body integrated between the middle stage and the upper stage. It is explanatory drawing which shows a mode that a game ball is attracted | sucked to the outer peripheral surface of a 2nd rotary body, and is conveyed to the upper stage. It is explanatory drawing which shows a mode that a game ball rolls a middle stage, without being attracted | sucked by the 2nd rotary body. It is explanatory drawing which shows a mode that the speed of a game ball falls and falls from a middle stage. It is explanatory drawing which shows notionally a mode that the game ball conveyed to the upper stage is discharged | emitted from a game ball discharge port through a game ball guide port. It is explanatory drawing which shows the electrical structure of a motor load detection part. It is explanatory drawing which shows the relationship between the load concerning a drive motor, and an energization current. It is a flowchart which shows the motor load detection process performed in a game control process. It is explanatory drawing which shows schematic structure of the game board which concerns on 2nd Example. It is explanatory drawing which shows schematic structure of the variable pitching apparatus which concerns on 2nd Example. It is explanatory drawing which shows a mode that the game ball which entered into the variable pitching apparatus which concerns on 2nd Example is guide | induced to the game ball path. It is explanatory drawing which shows a mode that the game ball capture | acquired by the magnet is conveyed to a specific area | region in the variable pitching apparatus which concerns on 2nd Example. It is explanatory drawing which showed a mode that a game ball fell from a game ball path | route as a result of the speed of a game ball falling in the variable pitching apparatus which concerns on 2nd Example. It is explanatory drawing which shows a mode that the game ball which fell from the game ball channel | path passes through a non-specific area | region in the variable pitching apparatus which concerns on 2nd Example.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Pachinko machine 10 ... Game board 17 ... Starting port 26 ... Central device 27 ... Symbol display device 28 ... Game ball guidance mechanism 29 ... Drive motor 40 ... Motor load detection part (load detection part)
280 ... Upper stage 281 ... Second rotating body 283 ... Middle stage 285 ... First rotating body (conveyance body)
285m ... Magnet (game ball catcher)
287 ... Lower stage 2020 ... Game board 2100 ... Variable pitching device 2140 ... Rotating body (conveying body)
2140m ... Magnet (game ball catching part)
2120 ... Specific area 2136 ... Game ball passage

Claims (1)

A ball game machine in which a central device having a game ball guidance mechanism is provided in a game area of a game board and performs a game by firing a game ball in the game area ,
The game ball guiding mechanism is:
An intake for taking a game ball into the central device;
A warp passage for guiding the game ball taken in from the intake to the first stage;
A second stage formed above the first stage and different from the first stage;
A rotator that has a game ball catcher capable of catching a game ball, and that is capable of transporting the game ball caught at the first stage by the game ball catcher to the second stage;
Consisting of
A drive motor for driving the rotating body ;
A load detector that detects a change in the amount of current supplied to the drive motor, and detects that a load applied to the drive motor has changed based on the detection result ;
And an effect control unit for effecting a game according to the detection result by the load detection unit,
The rotating body is formed in a cylindrical shape, and is arranged so that end portions of the first stage and the second stage are included in a space inside the cylinder of the rotating body,
The game ball capturing unit is provided on an inner peripheral surface of the rotating body,
When the game ball rolls on the first stage and reaches the inside of the rotating body, and the game ball capturing unit captures the game ball, the captured game ball moves along with the rotation of the rotating body. Conveyed to the second stage,
When the load detection unit detects conveyance of a game ball by the rotating body, the effect control unit executes an effect in accordance with the movement of the game ball being conveyed .

Images