JP6142127B2 - Amusement stand - Google Patents

Description

  The present invention relates to a game machine represented by a pachinko machine or a slot machine.

  2. Description of the Related Art Conventionally, a gaming table including a substrate is known (for example, see Patent Document 1).

JP 2008-200302 A

  However, the conventional game stand has room for improvement with respect to the board.

  An object of the present invention is to provide a game table having a feature on a board.

According to the present invention,
A first substrate;
Cover means;
A game machine equipped with
The first substrate is a substrate having a first light emitting means,
The first substrate is a substrate having first substrate constituting means,
The cover means is means having a transmission part,
The cover means is means having a non-transmissive portion,
The first light emitting means is located between the first substrate and the non-transmissive portion,
The first substrate constituting means is located between the first substrate and the non-transmissive portion,
The position of the first substrate constituting means is a position where light from the first light emitting means reaches,
The posture of the first light emitting means is changed so that the confirmer can visually recognize the first light emitting means from a direction perpendicular to the game table .
With movable movable means,
The movable means is means having the first substrate,
The movable means is means having the cover means,
When the movable means operates, the posture of the first light emitting means changes .
There is provided a game stand characterized by this.

  According to the present invention, it is possible to realize a game machine having a feature on a board.

It is the external appearance perspective view which looked at the pachinko machine from the front side (player side). It is the external view which looked at the pachinko machine from the back side. It is the schematic front view which looked at the game board from the front. The circuit block diagram of a control part is shown. The block diagram of a game machine is shown. (A) An example of the stop symbol form of the special figure is shown. (B) An example of a stop symbol form of a decorative symbol is shown. (C) An example of a usual stop display symbol is shown. It is a flowchart which shows the flow of a main control part main process. It is a flowchart which shows the flow of a main control part timer interruption process. (A) It is a flowchart of the main process which CPU of a 1st sub control part performs. (B) It is a flowchart of the command reception interruption process of a 1st sub control part. (C) It is a flowchart of the timer interruption process of a 1st sub control part. (A) It is a flowchart of the main process which CPU of a 2nd sub control part performs. (B) It is a flowchart of the command reception interruption process of a 2nd sub control part. (C) It is a flowchart of the timer interruption process of a 2nd sub control part. (A) It is a flowchart of the main process which CPU of a liquid-crystal control part performs. (B) It is a flowchart of the command reception interruption process of a liquid-crystal control part. (C) It is a flowchart of a liquid crystal control part timer interruption process. (D) It is a flowchart of a VDP image control process. It is explanatory drawing of the position of an illumination unit provided with an illumination board | substrate. It is aa sectional drawing of FIG. It is explanatory drawing of the example of wiring. It is explanatory drawing of the example of wiring structure. It is explanatory drawing of the example of wiring structure. It is explanatory drawing of the example of wiring structure. It is explanatory drawing of the example of wiring structure. It is explanatory drawing of the example of wiring structure. It is explanatory drawing of the example of wiring structure. It is explanatory drawing of the example of wiring structure. It is explanatory drawing of the example of wiring structure. It is explanatory drawing of the example of wiring structure. It is explanatory drawing of the example of wiring structure. It is explanatory drawing of a liquid crystal control board. It is explanatory drawing of a liquid crystal control board. It is explanatory drawing of the example of confirmation promotion structure. It is explanatory drawing of the example of confirmation promotion structure. It is explanatory drawing of the example of confirmation promotion structure. It is explanatory drawing of the example of confirmation promotion structure. It is explanatory drawing of the example of confirmation promotion structure. It is explanatory drawing of the example of confirmation promotion structure. It is explanatory drawing of the example of confirmation promotion structure. It is explanatory drawing of the example of confirmation promotion structure. It is explanatory drawing of the example of confirmation promotion structure. It is explanatory drawing of the example of confirmation promotion structure. It is explanatory drawing of the example of confirmation promotion structure. It is explanatory drawing of the example of confirmation promotion structure. It is explanatory drawing of the example of confirmation promotion structure. It is explanatory drawing of the example of confirmation promotion structure. It is explanatory drawing of the example of confirmation promotion structure. It is explanatory drawing of the example of confirmation promotion structure. It is explanatory drawing of the example of confirmation promotion structure. It is explanatory drawing of the example of confirmation promotion structure. It is explanatory drawing of the example of confirmation promotion structure. It is explanatory drawing of the example of confirmation promotion structure. It is a perspective view of the slot machine of an embodiment. It is a front view of the state which opened the front door of the slot machine of an embodiment. It is a block diagram of a control unit of the slot machine of the embodiment. (A) is a diagram showing a plane arrangement of symbols arranged on each reel, (b) is a type of winning combination (including an operating combination), a combination of symbols corresponding to each winning combination, It is a figure which shows the action | operation or payout of a winning combination. It is a flowchart which shows the flow of a main control part main process. It is a flowchart which shows the flow of a main control part timer interruption process. (A) is a flowchart of main processing of the first sub-control unit, (b) is a flowchart of command reception interrupt processing of the first sub-control unit, and (c) is a timer interrupt processing of the first sub-control unit. It is a flowchart of. (A) is a flowchart of main processing of the second sub-control unit, (b) is a flowchart of command reception interrupt processing of the second sub-control unit, and (c) is a timer interrupt processing of the second sub-control unit. (D) is a flowchart of the image control processing of the second sub-control unit.

<Embodiment 1>
Hereinafter, the gaming machine (pachinko machine 100) according to Embodiment 1 of the present invention will be described in detail with reference to the drawings.

<Overall configuration>
First, the overall configuration of the pachinko machine 100 according to the first embodiment of the present invention will be described with reference to FIG. In addition, the figure is the external appearance perspective view which looked at the pachinko machine 100 from the front side (player side).

  As an external structure, the pachinko machine 100 includes an outer frame 102, a main body 104, a front frame door 106, a door 108 with a ball storage tray, a launching device 110, and a game board 200 on the front surface.

  The outer frame 102 is a wooden frame member having a vertical rectangular shape for fixing to an installation location (island facilities or the like) provided in a gaming machine installation sales shop. The main body 104 is referred to as an inner frame, and is a member that is provided inside the outer frame 102 and serves as a longitudinal rectangular gaming machine base body that is rotatably attached to the outer frame 102 via a hinge portion 112. The main body 104 is formed in a frame shape and has a space 114 inside. In addition, when the main body 104 is opened, an inner frame opening sensor (not shown) that detects the opening of the main body 104 is provided.

  The front frame door 106 is attached to the front surface of the main body 104 on the front side of the pachinko machine 100 so as to be openable and closable with a lock function, and is configured in a frame shape so that the inner side of the front frame door 106 can be opened and closed. Is a door member having an opening. The front frame door 106 is provided with a transparent plate member 118 made of glass or resin at the opening, and a speaker 120 and a game stand frame lamp 122 are attached to the front side. A game area 124 is defined by the rear surface of the front frame door 106 and the front surface of the game board 200. Further, a front frame door opening sensor (not shown) that detects opening of the front frame door 106 when the front frame door 106 is opened is provided.

  The door 108 with a ball storage tray is a door member attached to the lower side of the main body 104 on the front surface of the pachinko machine 100 so as to have a lock function and be openable and closable. The ball storage tray-equipped door 108 is capable of storing a plurality of game balls (hereinafter simply referred to as “balls”), and an upper plate 126 provided with a passage for guiding the game balls to the launching device 110. A lower plate 128 that stores game balls that cannot be stored in the upper plate 126, a ball removal button 130 that discharges the game balls stored in the upper plate 126 to the lower plate 128 by the player's operation, A ball discharge lever 132 that discharges game balls stored in the lower plate 128 to a game ball collection container (common name, dollar box) by operation, and a game ball guided to the launching device 110 by operation of the player 200 ball launching handles 134 for launching into the game area 124, chance buttons 136 for changing the effects of the various effects devices 206 by the player's operation, and the chance button 136 to emit light. Sub button lamp 138, ball lending operation button 140 for instructing ball lending to a card unit (CR unit) installed in the game store, and return operation button for instructing the card unit to return the player's balance 142, a ball rental display unit 144 that displays the player's balance and the state of the card unit, and a button unit 190. In addition, a lower plate full tank sensor (not shown) that detects that the lower plate 128 is full is provided.

  The launching device 110 is attached to the lower side of the main body 104, and a launching rod 146 that rotates when the ball launching handle 134 is operated by the player, and a launching rod 148 that strikes the game ball at the tip of the launching rod 146. .

  The game board 200 has a game area 124 on the front surface, and is detachably attached to the main body 104 using a predetermined fixing member so as to face the space 114 of the main body 104. The game area 124 can be observed from the opening after the game board 200 is mounted on the main body 104.

  FIG. 2 is an external view of the pachinko machine 100 of FIG. The upper part of the back surface of the pachinko machine 100 has an opening that opens upward, a ball tank 150 for temporarily storing game balls, and a lower part of the ball tank 150 that is positioned below the ball tank 150. A tank rail 154 is provided for guiding a ball passing through the formed communication hole and dropping to the dispensing device 152 located on the right side of the back surface.

  The payout device 152 is formed of a cylindrical member, and includes a payout motor, a sprocket, and a payout sensor (not shown) therein. The sprocket is configured to be rotatable by a payout motor. The sprocket that temporarily passes through the tank rail 154 and flows down into the payout device 152 is temporarily retained, and the payout motor is driven to rotate by a predetermined angle. Thus, the temporarily accumulated game balls are sent one by one downward to the payout device 152.

  The payout sensor is a sensor for detecting the passage of the game ball sent out by the sprocket. When the game ball is passing, either a high signal or a low signal is passed. Either the high signal or the low signal is output to the dispensing control unit 600. The game ball that has passed through the payout sensor passes through a ball rail (not shown) and reaches the upper plate 126 disposed on the front side of the pachinko machine 100. The pachinko machine 100 The ball is paid out to the player according to the configuration.

  On the left side of the payout device 152 in the figure, the main control board case 158 that houses the main control board 156 that constitutes the main control section 300 that performs the control processing of the entire game, and effects based on the processing information generated by the main control section 300 The first sub-control board 160 that constitutes the first sub-control unit 400 that performs control processing related to the first sub-control unit 400, and the second sub-control unit 500 that performs control processing related to effects based on the processing information generated by the first sub-control unit 400 A first sub-control board case 162 that houses a second sub-control board 164, a liquid crystal control board case 682 that houses a liquid crystal control board 680 that constitutes a liquid crystal control unit 700 that performs liquid crystal control processing, and a game ball payout A payout control board 170 that constitutes a payout control unit 600 that performs control processing and includes an error release switch 168 that releases an error by an operation of a game shop clerk A payout control board case 172 to be delivered, a launch board case 176 that houses a launch board 174 that constitutes a launch control section 630 that performs control processing relating to the launch of a game ball, and a power supply management section 660 that supplies power to various electrical gaming machines. A power supply board that houses a power supply board 182 that is configured and includes a power switch 178 that turns the power on and off by the operation of a game clerk and an RWM clear switch 180 that is operated when the power is turned on and outputs an RWM clear signal to the main control unit 300 A case 184 and a CR interface unit 186 for transmitting and receiving signals between the payout control unit 600 and the card unit are provided. The CR interface unit 186 has a CR unit connection unit configured by, for example, a D-sub (D-subminiature) connector, and transmits and receives signals between the payout control unit 600 and the card unit via the CR unit connection unit. Yes.

  Further, the pachinko machine 100 has a relay board 196 on the right side of the ball tank 150 and above the tank rail 154 when viewed from the back side. The relay board 196 is used for electrical connection between the pachinko machine 100 and the hall computer. Since it is not necessary to change the wiring between the pachinko machine 100 and the hall computer when the gaming board 200 is exchanged, the gaming board 200 is exchanged while the main body 104 and the hall computer are connected via the relay board 196. The However, since it is necessary to change the type of signal transmitted from the pachinko machine 100 to the hall computer depending on the model, the pachinko machine 100 is connected to the relay board 196 from the front (front) side of the pachinko machine 100 when the game board 200 is removed. It may be configured so as to be able to grasp the connection status.

  Further, a volume adjustment switch 192 for adjusting the volume of the speaker 120, for example, is provided at the upper left in the drawing of the first sub control board case 162. The volume adjustment switch 192 is constituted by a rotary switch, for example.

  As described above, the main control board 156, the first sub control board 160, the second sub control board 164, and the liquid crystal control board 680 are provided on the back of the game board 200 because they need to be changed for each model. 170, the launch board 174, and the power board 182 are provided in the outer frame 102 because they are commonly used by a plurality of models.

  FIG. 3 is a schematic front view of the game board 200 as viewed from the front. In the game board 200, an outer rail 202 and an inner rail 204 are arranged, and a game area 124 in which a game ball can roll is defined.

  An effect device 206 is disposed in the approximate center of the game area 124. The effect device 206 is provided with a decorative symbol display device 208 and a movable display device 288 at substantially the center, and around the normal symbol display device 210, a first special symbol display device 212, and a second special symbol display device. A symbol display device 214, a normal symbol hold lamp 216, a first special symbol hold lamp 218, a second special symbol hold lamp 220, and a high-probability medium lamp 222 are provided. Hereinafter, the normal symbol may be referred to as “general symbol” and the special symbol may be referred to as “special symbol”.

  The effect device 206 performs the effect by operating the effect movable body 224, and details thereof will be described later. The decorative symbol display device 208 is a display device for performing various displays used for decorative symbols and effects. In this embodiment, the decorative symbol display device 208 is constituted by a liquid crystal display device (Liquid Crystal Display). The decorative symbol display device 208 is divided into four display areas, a left symbol display area 208a, a middle symbol display area 208b, a right symbol display area 208c, and an effect display area 208d, and the left symbol display area 208a and the middle symbol display area 208b. The right symbol display area 208c displays different decorative symbols, and the effect display area 208d displays an image used for the effect. Furthermore, the position and size of each display area 208a, 208b, 208c, 208d can be freely changed within the display screen of the decorative symbol display device 208. In addition, although the liquid crystal display device is employ | adopted as the decoration symbol display apparatus 208, it is not a liquid crystal display device, What is necessary is just the structure which can display various effects and various game information, for example, a dot matrix display device Other display devices including a 7-segment display device, an organic EL (ElectroLuminescence) display device, a reel (drum) display device, a leaf display device, a plasma display, and a projector may be adopted.

  The movable display device 288 is also a display device for performing various displays used for production. In the present embodiment, the movable display device 288 is constituted by a liquid crystal display device, but, for example, similar to the decorative symbol display device 208, for example, a dot matrix display device, 7 Other display devices including a segment display device, an organic EL display device, a reel (drum) display device, a leaf display device, a plasma display, and a projector may be adopted. The movable display device 288 includes a motor (not shown), is configured to be movable in the vertical direction by the motor, and covers at least a part of the front of the decorative symbol display device 208 when lowered.

  The general map display device 210 is a display device for displaying a general map, and is configured by a 7-segment LED in this embodiment. The first special figure display device 212 and the second special figure display device 214 are display devices for displaying a special figure, and are configured by 7 segment LEDs in this embodiment.

  The multi-purpose hold lamp 216 is a lamp for indicating the number of general-purpose variable games (details will be described later) that are on hold. In this embodiment, the general-purpose variable games are reserved up to a predetermined number (for example, two). It is possible to do. The first special figure hold lamp 218 and the second special figure hold lamp 220 are lamps for indicating the number of special figure variable games (details will be described later) that are being held. In this embodiment, the special figure variable games are displayed. It is possible to hold up to a predetermined number (for example, four). The high-probability medium lamp 222 is a lamp for indicating that the gaming state is a high probability state in which a big hit is likely to occur or a high probability state, and the gaming state is changed from a low probability state in which a big hit is unlikely to occur. Turns on when switching to the probability state, and turns off when switching from the high probability state to the low probability state.

  In addition, there are predetermined ball entrances, for example, a general prize opening 226, a general start port 228, a first special view start port 230, a second special view start port 232, around the effect device 206. A variable winning opening 234 is provided.

  In this embodiment, a plurality of general winning holes 226 are arranged on the game board 200. When a predetermined ball detecting sensor (not shown) detects a ball entering the general winning holes 226 (in the general winning holes 226). In the case of winning, the payout device 152 is driven, and a predetermined number (for example, 10 balls) of balls are discharged to the upper plate 126 as prize balls. The player can freely take out the balls discharged to the upper plate 126. With these configurations, the player can pay out the winning balls to the player based on winning. The ball that has entered the general winning opening 226 is guided to the back side of the pachinko machine 100 and then discharged to the amusement island side. In this embodiment, a ball to be paid out to a player as a consideration for winning is sometimes referred to as a “prize ball”, and a ball lent to a player is sometimes referred to as “rental ball”. They are called “balls (game balls)”.

  The normal start port 228 is constituted by a device called a gate or a through chucker for determining whether or not a ball has passed a predetermined area of the game area 124. In this embodiment, the left side of the game board 200 is used. One is arranged. Unlike the ball that has entered the general winning opening 226, the ball that has passed through the usual starting port 228 is not discharged to the amusement island side. When a predetermined ball detection sensor detects that a ball has passed through the general map starting port 228, the pachinko machine 100 starts a general map variable game by the general map display device 210.

  In the present embodiment, only one first special figure starting port 230 is disposed at the center of the game board 200. When a predetermined ball detection sensor detects a ball entering the first special figure starting port 230, a payout device 152, which will be described later, is driven, and a predetermined number (for example, three) of balls is used as a prize ball for the upper plate 126. The special figure changing game by the first special figure display device 212 is started. The ball that has entered the first special figure starting port 230 is guided to the back side of the pachinko machine 100 and then discharged to the amusement island side.

  The second special figure starting port 232 is called an electric tulip (electric Chu). In the present embodiment, only one second special figure starting port 232 is disposed directly below the first special figure starting port 230. The second special figure starting port 232 includes a wing member 232a that can be opened and closed to the left and right. When the wing member 232a is closed, it is impossible to enter a ball. When 210 hits and stops and displays the symbol, the blade member 232a opens and closes at a predetermined time interval and a predetermined number of times. When a predetermined ball detection sensor detects a ball entering the second special figure starting port 232, the payout device 152 is driven and a predetermined number (for example, four) of balls is discharged to the upper plate 126 as prize balls. At the same time, the special figure variation game by the second special figure display device 214 is started. The ball that has entered the second special figure starting port 232 is guided to the back side of the pachinko machine 100 and then discharged to the amusement island side.

  The variable winning opening 234 is called a large winning opening or an attacker, and in the present embodiment, only one variable winning opening 234 is disposed below the center of the game board 200. This variable winning opening 234 includes a door member 234a that can be opened and closed. When the door member 234a is closed, it is impossible to enter a ball, and the special figure display device stops the big hit symbol when the special figure variable game is won. When displayed, the door member 234a opens and closes at a predetermined time interval (for example, an opening time of 29 seconds and a closing time of 1.5 seconds) and at a predetermined number of times (for example, 15 times). When a predetermined ball detection sensor detects a ball entering the variable winning opening 234, the payout device 152 is driven to discharge a predetermined number (for example, 15 balls) of balls to the upper plate 126 as prize balls. The ball that entered the variable winning opening 234 is guided to the back side of the pachinko machine 100 and then discharged to the amusement island side.

  Further, a plurality of disc-shaped hitting direction changing members 236 called a windmill and a plurality of game nails 238 are arranged in the vicinity of these winning openings and start openings, and at the bottom of the inner rail 204, An out port 240 is provided for guiding a ball that has not won a prize or starting port to the back side of the pachinko machine 100 and then discharging it to the game island side.

  This pachinko machine 100 supplies the ball stored in the upper plate 126 by the player to the launch position of the launch rail, drives the launch motor with strength according to the operation amount of the player's operation handle, and launches 146 Further, the outer rail 202 and the inner rail 204 are passed by the launcher 148 and driven into the game area 124. Then, the ball that has reached the upper part of the game area 124 falls downward while changing the advancing direction by the hitting direction changing member 236, the game nail 238, etc., and a winning opening (general winning opening 226, variable winning opening 234) or start opening (Outside the first special figure starting port 230, the second special figure starting port 232), winning out any winning port or starting port, or just passing through the normal start port 228, the out port 240 To reach.

<Directing device 206>
Next, the rendering device 206 of the pachinko machine 100 will be described.

  On the front side of the effect device 206, a warp device 242 and a stage 244 are arranged in an area where the game ball can roll, and an effect movable body 224 is arranged in an area where the game ball cannot roll. . In addition, a decorative symbol display device 208 and a shielding device 246 (hereinafter sometimes referred to as a door) are disposed on the back side of the effect device 206. That is, in the effect device 206, the decorative symbol display device 208 and the shielding means are located behind the warp device 242, the stage 244, the effect movable body 224, and the movable display device 288.

  The warp device 242 discharges the game balls that have entered the warp inlet 242a provided at the upper left of the effect device 206 to the stage 244 below the front surface of the effect device 206 from the warp outlet 242b. The stage 244 can roll a ball discharged from the warp outlet 242b, a ball carried on by a nail of the game board 200, or the like, and the passed ball is a first special figure starting port 230 at the center of the stage 244. A special route 244a is provided to facilitate entry into the golf course.

  In this embodiment, the effect movable body 224 includes an upper arm 224a and a forearm 224b imitating the upper arm and forearm of a human right arm, and an upper arm motor and an elbow (not shown) that rotate the upper arm 224a to the position of the shoulder. A forearm motor (not shown) that rotates the forearm 224b at a position is provided. The effect movable body 224 moves in front of the decorative symbol display device 208 by the upper arm motor and the forearm motor.

  The shielding device 246 includes a lattice-like left door 246a and right door 246b, and is disposed between the decorative symbol display device 208 and the front stage 244. Belts wound around two pulleys (not shown) are fixed to the upper portions of the left door 246a and the right door 246b, respectively. That is, the left door 246a and the right door 246b move to the left and right as the belt driven by the motor through the pulley moves. When the left door 246a and the right door 246b are closed, the shielding means shields the inner end portions thereof so that it is difficult for the player to visually recognize the decorative symbol display device 208. In the state where the left door 246a and the right door 246b are opened, each inner end portion slightly overlaps the outer end portion of the display screen of the decorative symbol display device 208, but the player can visually recognize all of the display of the decorative symbol display device 208. It is. In addition, the left door 246a and the right door 246b can be stopped at arbitrary positions, respectively, for example, only a part of the decorative design so that the player can identify which decorative design the displayed decorative design is. Can be shielded. In addition, the left door 246a and the right door 246b may be configured so that a part of the decorative symbol display device 208 behind the lattice hole can be visually recognized, or the shoji part of the lattice hole is closed with a translucent lens body. The display by the decorative symbol display device 208 may be made vaguely visible to the player, or the shoji part of the holes in the lattice is completely blocked (shielded), and the decorative symbol display device 208 behind is made completely invisible. Also good.

  The movable display device 288 is a device that displays an effect and is movable. Therefore, in the following description, as the display device, the decorative symbol display device 208 may be referred to as a first display device (main liquid crystal display device), and the movable display device 288 may be referred to as a second display device (sub liquid crystal display device). . Further, it may be referred to as a (production) movable body together with the shielding device 246 and the production movable body 224 simulating a human arm.

<Control unit>
Next, the circuit configuration of the control unit of the pachinko machine 100 will be described in detail with reference to FIG. This figure shows a circuit block diagram of the control unit. The control unit of the pachinko machine 100 is roughly divided into a main control unit 300 that controls the central part of the game, and various devices according to command signals (hereinafter simply referred to as “commands”) transmitted by the main control unit 300. In response to the first sub-control unit 400 to be controlled, the second sub-control unit 500 mainly controlling the production based on the command transmitted from the first sub-control unit 400, and the command transmitted by the main control unit 300 A payout control unit 600 that mainly performs control related to payout of game balls, a launch control unit 630 that performs launch control of game balls, a power supply control unit 660 that controls power supplied to the pachinko machine 100, and a liquid crystal control unit 700 And is composed of.

<Main control unit>
First, the main control unit 300 of the pachinko machine 100 will be described. The main control unit 300 includes a basic circuit 302 that controls the entire main control unit 300. The basic circuit 302 includes a CPU 304, a ROM 306 for storing control programs and various data, and temporary data. RAM 308 for storing data, I / O 310 for controlling input / output of various devices, counter timer 312 for measuring time and frequency, and WDT 314 for monitoring abnormalities in program processing are mounted. . Note that another storage device may be used for the ROM 306 and the RAM 308, and this is the same for the first sub-control unit 400 described later. The CPU 304 of the basic circuit 302 operates by inputting a clock signal of a predetermined period output from the crystal oscillator 316b as a system clock.

  The basic circuit 302 also includes a counter circuit (random value generation circuit) 318 (a random number generation circuit) that is used as a hardware random number counter that changes a numerical value in the range of 0 to 65535 every time a clock signal output from the crystal oscillator 316a is received. This circuit includes two counters) and a predetermined ball detection sensor, for example, a sensor for detecting a game ball passing through each start port, winning port, variable winning port, or opening the front frame door A sensor circuit 322 for receiving signals output from various sensors 320 including a sensor, an inner frame opening sensor, and a lower pan full sensor, and outputting a comparison result with an amplification result and a reference voltage to the counter circuit 318 and the basic circuit 302; A driving circuit 324 for performing display control of a predetermined symbol display device, for example, the first special symbol display device 212 or the second special symbol display device 214; A drive circuit 326 for performing display control of the pattern display device, for example, the general map display device 210, and various status display units 328 (for example, the general map hold lamp 216, the first special figure hold lamp 218, the second special figure hold lamp) 220, a high-accuracy medium lamp 222, etc.) and a drive circuit 330 for performing display control and a predetermined movable member, for example, a blade member 232a of the second special figure starting port 232, a door member 234a of the variable winning port 234, etc. A drive circuit 334 for controlling various solenoids 332 to be driven is connected.

  When the ball detection sensor 320 detects that a ball has won the first special figure starting port 230, the sensor circuit 322 outputs a signal indicating that the ball has been detected to the counter circuit 318. Upon receiving this signal, the counter circuit 318 latches the value of the counter corresponding to the first special figure starting port 230 at that timing, and stores the latched value in the built-in counter value corresponding to the first special figure starting port 230. Store in the register. Similarly, when the counter circuit 318 receives a signal indicating that the second special figure starting port 232 has won a ball, the counter circuit 318 latches the value at the timing of the counter corresponding to the second special figure starting port 232. The latched value is stored in a built-in counter value storage register corresponding to the second special figure starting port 232.

  Further, an information output circuit 336 is connected to the basic circuit 302, and the main control unit 300 is connected to an information input circuit 350 provided in an external hall computer (not shown) or the like via this information output circuit 336. The game information (for example, game state) of the machine 100 is output.

  In addition, the main control unit 300 is provided with a voltage monitoring circuit 338 that monitors the voltage value of the power source supplied from the power source control unit 660 to the main control unit 300. The voltage monitoring circuit 338 is a voltage value of the power source. Is less than a predetermined value (9v in this embodiment), a low voltage signal indicating that the voltage has dropped is output to the basic circuit 302.

  In addition, the main control unit 300 is provided with a start signal output circuit (reset signal output circuit) 340 that outputs a start signal (reset signal) when the power is turned on. When the activation signal is input, game control is started (main control unit main processing described later is started).

  The main control unit 300 includes an output interface for transmitting a command to the first sub-control unit 400 and an output interface for transmitting a command to the payout control unit 600. With this configuration, the first control unit 300 Communication with the sub-control unit 400 and the payout control unit 600 is enabled. Information communication between the main control unit 300 and the first sub-control unit 400 and the payout control unit 600 is one-way communication. The main control unit 300 sends commands and the like to the first sub-control unit 400 and the payout control unit 600. The first sub control unit 400 and the payout control unit 600 are configured such that signals such as commands cannot be transmitted to the main control unit 300.

<Sub control unit>
Next, the first sub control unit 400 of the pachinko machine 100 will be described. The first sub-control unit 400 includes a basic circuit 402 that controls the entire first sub-control unit 400 mainly based on commands transmitted from the main control unit 300. The basic circuit 402 includes a CPU 404 and ROM 406 for storing control programs and various effects data, RAM 408 for temporarily storing data, I / O 410 for controlling input / output of various devices, and for measuring time, frequency, etc. The counter timer 412 is mounted. The CPU 404 of the basic circuit 402 operates by inputting a clock signal of a predetermined period output from the crystal oscillator 414 as a system clock. The ROM 406 may store the control program and various effect data in separate ROMs.

  The basic circuit 402 includes a sound source IC 416 for controlling the speaker 120 (and amplifier) and a drive for controlling various lamps 418 (for example, the chance button lamp 138 and the game table frame lamp 122). A circuit 420, a drive circuit 432 for performing drive control of the movable parts of the chance button 136 and the button unit 190, a button detection sensor 426 and various sensors 430 for detecting pressing of the chance button 136 and pressing of the button unit 190, A sensor circuit 428 that outputs detection signals from the various sensors 430 and the button detection sensor 426 to the basic circuit 402 is connected.

  Next, the second sub control unit 500 of the pachinko machine 100 will be described. The second sub-control unit 500 includes a basic circuit 502 that receives the control command transmitted from the first sub-control unit 400 via the input interface and controls the entire second sub-control unit 500 based on the control command. The basic circuit 502 includes a CPU 504, a RAM 508 for temporarily storing data, an I / O 510 for controlling input / output of various devices, and a counter timer for measuring time and frequency 512 is installed. The CPU 504 of the basic circuit 502 operates by inputting a clock signal of a predetermined period output from the crystal oscillator 514 as a system clock, and controls a control program and data for controlling the entire second sub-control unit 500, and an image display A ROM 506 storing data and the like is provided.

  Further, the basic circuit 502 includes the current stage of the effect movable body 224, the shielding device 246, the drive circuit 516 for performing drive control of the movable part of the movable display device 288, the effect movable body 224, and the shielding device 246. An effect movable body sensor 424 for detecting the position, a sensor circuit 518 for outputting a detection signal from the effect movable body sensor 424 to the basic circuit 502, and a game board lamp drive circuit 530 for controlling the game board lamp 532 And a serial communication control circuit 520 that performs lighting control by serial communication between the basic circuit 502 and the game board lamp drive circuit 530.

<Discharge control unit, launch control unit, power supply control unit>
Next, the payout control unit 600, the launch control unit 630, and the power supply control unit 660 of the pachinko machine 100 will be described. The payout control unit 600 controls the payout motor 602 of the payout device 152 mainly based on a command signal or the like transmitted from the main control unit 300, and a prize ball or a rental ball based on a control signal output from the payout sensor 604 It is detected whether or not the payout has been completed, and communication with a card unit 608 provided separately from the pachinko machine 100 is performed via the interface unit 606.

  The launch control unit 630 outputs a control signal output from the payout control unit 600 to permit or stop the launch, or a launch intensity output circuit provided in the ball launch handle 134 to operate the ball launch handle 134 by the player. Control of the launch motor 632 that drives the launcher 146 and launcher 148, and control of the ball feeder 634 that supplies the launcher 110 with a ball from the upper plate 126 based on a control signal that indicates the launch intensity according to the amount. I do.

  The power control unit 660 converts the AC power supplied from the outside to the pachinko machine 100 into a DC voltage, converts it to a predetermined voltage, and controls each control unit such as the main control unit 300 and the first sub control unit 400, the payout device 152, etc. Supply to each device. Further, the power supply control unit 660 supplies a power storage circuit (for example, a power supply circuit) for supplying power to a predetermined part (for example, the RAM 308 of the main control unit 300) for a predetermined period (for example, 10 days) even after the external power supply is cut off. , Capacitor). In the present embodiment, a predetermined voltage is supplied from the power supply control unit 660 to the payout control unit 600 and the second sub control unit 500, and the main control unit 300, the second sub control unit 500, and the launch control unit are supplied from the payout control unit 600. Although a predetermined voltage is supplied to 630, the predetermined voltage may be supplied to each control unit and each device through another power supply path.

<LCD control unit>
Next, the liquid crystal control unit 700 will be described. The liquid crystal control unit 700 receives the control command transmitted from the first sub control unit 400 via the input interface, and temporarily stores data with the CPU 704 that controls the entire liquid crystal control unit 700 based on the control command. A RAM 708, a control program and data for controlling the entire liquid crystal control unit 700, a ROM 506 storing image display data, and the like, and a VDP (Video Display Processor) 710. The CPU 704 operates by inputting a clock signal of a predetermined period output from the crystal oscillator 714A as a system clock.

  The VDP 710 operates by inputting a clock signal of a predetermined period output from the crystal oscillator 714B as a system clock, reads out image data stored in the CGROM 716 based on a signal from the CPU 404, and uses the work area of the VRAM 718. A display image is generated and displayed on the decorative symbol display device 208 and the movable display device 288.

<Block diagram of the game console>
With reference to FIG. 5, the connection relationship of each board (control board) of the pachinko machine 100 will be described. The figure shows (control) substrates, etc., a display device, a movable body, etc. constituting the main control unit 300, the first sub control unit 400, the second sub control unit 500, the payout control unit 600, the liquid crystal control unit 700, and the like. FIG.

  In the pachinko machine 100, on the game board 200 side, a board surface relay board 722, an external terminal board 720, and a first sub-control board 160 are connected to the main control board 156. Various sensors 320, solenoids 332, and symbol display boards 212, 214, 210, and 328 are connected to the panel relay board 722. As a result, the ball detection sensor 320 detects that the game ball has entered the general winning opening (winning opening) 226, the ordinary start opening (gate) 228, the first special figure starting opening 230 and the second starting opening 232. If this happens, the switch signal is transmitted to the main control unit 300. In addition, a solenoid signal for opening and closing the second special figure starting port (ordinary electric accessory) 232 is transmitted from the drive circuit 334 of the main control unit 300 to the solenoid 332. In addition, a solenoid signal for opening and closing the first variable winning port 234 and the second variable winning port 235 (large winning port) is transmitted from the drive circuit 334 of the main control unit 300 to the solenoid 332. In addition, a count signal for counting the number of balls is transmitted from the first variable winning opening 234 and the second variable winning opening 235 (large winning opening) to the main control unit 300.

  In addition, a liquid crystal control board 680 is connected to the first sub control board 160, and a decorative symbol display device (main liquid crystal display device) 208 and a movable display device (sub liquid crystal display device) 288 are connected to the liquid crystal control board 680. . The second sub-control board 164 is connected to the first sub-control board 160, and the second sub-control board 164 is connected to the movable object M (the movable part 2441 of the movable display device 288, the effect movable body 244, And a board surface side lighting board 724 on which the game board lamp 532 is mounted.

  As a result, the first sub control board 160 performs control according to a command from the main control board 156, and the liquid crystal control board 680 and the second sub control board 164 perform control according to a command from the first sub control board 160. Specifically, the processing information (command signal) generated by the main control unit 300 is transmitted to the first sub control unit 400, and the processing information or the processing information generated by the first sub control unit 400 is the liquid crystal control unit. 700 and the second sub-control unit 500. For example, data for driving the effect movable body 224, data for lighting emission of the effect movable body 224, data for driving the movable display device 288, and the like are transmitted from the first sub control board 160 to the second sub control board 164. The In addition, data or a clock signal for causing the game board 200 side to emit light is transmitted from the drive circuit 516 of the second sub-control unit 500 to the board surface side illumination board 724. Also, signals for display control of the first special figure display device 212, the second special figure display device 214, the common figure display device 210, and the various status display units 328 are transmitted from the respective drive circuits 324, 326, and 330. Further, the control data of the first sub control board 160 is transmitted to the liquid crystal control board 680, and the image data is transmitted to the decorative symbol display device 208 and the movable display device 288.

  The pachinko machine 100 is provided with board frame relay boards 726A, 726B, and 726C on the main body 104 side, and relays and connects the board on the game board 200 side and the board on the main body 104 side. The panel frame relay board 726A is connected to the main control board 156 and the payout control board 170. Thereby, for example, a command signal related to payout control (for example, information for payout and information for communicating with the external terminal board 720) is transmitted from the main control unit 300 to the payout control unit 600. The error information of the discharge system is transmitted to The panel frame relay board 726B connects the first sub-control board 160 and the power supply board 182, and the panel frame relay board 726C includes the chance button 136 and the button provided on the first sub-control board 160 and the front frame door 106. The speaker 120 is connected via the unit 190, the various lamps 138 and 418 for buttons, the button movable part 246, the door-side illumination board 734 on which the various lamps 418 are mounted, and the door-side illumination board 734.

  As a result, data and clock signals for causing the various lamps 418 to emit light are transmitted from the drive circuit 420 of the first sub-control unit 400 to the door side illumination board 734. Audio data is transmitted from the sound source IC 416 to the speaker 120. In addition, the detection result of the button detection sensor 426 and the like by the operation of the chance button 136 and the button unit 190 is transmitted to the first sub-control unit 400.

  The payout control board 170 is connected to the payout sensor 604, the payout motor 602, and the game ball lending device connection board 728. The payout control board 170 is also connected to the power supply board 182, the launch board 174, and the tray board 730. The launch board 174 is connected to the power board 182, the launch motor 632, and the ball feeder 634. The saucer substrate 730 is connected to the firing handle substrate 738 and the frequency display substrate 744 provided on the front frame door 106. A handle volume 736, a full switch 740, and a touch sensor 742 are connected to the firing handle substrate 738.

<Type of design>
6A to 6C, the first special symbol display device 212, the second special symbol display device 214, the decorative symbol display device 208, and the normal symbol display device 210 of the pachinko machine 100 are stopped and displayed. The types of special maps and general maps to be described will be described. FIG. 4A shows an example of the stop symbol form of the special figure.

  The special figure 1 variable game is started on the condition that the first start port sensor detects that the ball has entered the first special figure start port 230, and the ball has entered the second special figure start port 232 The special figure 2 variable game is started on the condition that the second start port sensor has detected. When the special figure 1 variable game is started, the first special symbol display device 212 performs “variable display of special figure 1” by repeating all lighting of seven segments and lighting of one central segment. In addition, when the special figure 2 variable game is started, the second special symbol display device 214 displays “fluctuation display of special figure 2” which repeats lighting of all seven segments and lighting of one central segment. Do. These “variation display of special figure 1” and “variation display of special figure 2” correspond to an example of the symbol fluctuation display according to the present invention.

  Then, when the variation time determined before the variation start of the special figure 1 (corresponding to the variation time referred to in the present invention) elapses, the first special symbol display device 212 stops and displays the special symbol form of the special figure 1. When the variation time determined before the start of variation 2 (this also corresponds to the variation time according to the present invention) has elapsed, the second special symbol display device 214 stops and displays the stop symbol form of the special diagram 2. Therefore, from the start of “figure display of special figure 1” until the stop symbol form of special figure 1 is stopped, or after the start of “fluctuation display of special figure 2”, the stop symbol form of special figure 2 is displayed. Until stop display corresponds to an example of the symbol variation stop display referred to in the present invention, hereinafter, after the “variable display of special figure 1 or 2” is started, the stop symbol form of special figure 1 or 2 is stopped and displayed. The series of displays up to is referred to as symbol variation stop display. As will be described later, the symbol variation stop display may be continuously performed a plurality of times. FIG. 10A shows 10 types of special drawings from “Special Figure A” to “Special Figure J” as stop symbol forms in the symbol variation stop display, and the white portions in the figure are turned off. The location of the segment to be displayed is shown, and the black portion indicates the location of the segment to be lit.

  “Special Figure A” is a 15 round (15R) special jackpot symbol, and “Special Figure B” is a 15R jackpot symbol. In the pachinko machine 100 according to the present embodiment, as will be described later, the determination as to whether or not the big hit in the special figure variable game is made by lottery of hardware random numbers, and the decision as to whether or not it is a special big hit is made by lottery of software random numbers. The difference between the jackpot and the special jackpot is the difference in whether the probability of winning the jackpot is high (special jackpot) or low (jackpot) in the next special figure variation game. Hereinafter, a state having a high probability of winning the jackpot is referred to as a special figure high probability state, and a state having a low probability is referred to as a special figure low probability state. Moreover, after the 15R special jackpot game ends and after the 15R jackpot game ends, both shift to the time-saving state. Although the time reduction will be described in detail later, the state that shifts to the time reduction state is referred to as a normal high probability state, and the state that does not shift to the time reduction state is referred to as a normal low probability state. “Special figure A”, which is a 15R special jackpot symbol, is a special figure high probability normal figure high probability state, and “Special figure B”, which is a 15R jackpot symbol, is a special figure low probability ordinary figure high probability state. These “special chart A” and “special chart B” are symbols that give a relatively large profit amount to the player.

  “Special figure C” is a 2R jackpot symbol called sudden probability change, and is a special figure high probability normal figure high probability state. That is, “Special Figure C” is 2R compared to “Special Figure A” which is 15R. "Special figure D" is a 2R jackpot symbol called sudden time reduction, and is a special figure low probability normal figure high probability state. That is, “Special Figure D” is 2R compared to “Special Figure B” which is 15R.

  “Special figure E” is a 2R jackpot symbol called hidden probability change, and is a special figure high probability normal figure low probability state. "Special figure F" is a 2R jackpot symbol suddenly called normal, and is a special figure low probability normal figure low probability state. These “special drawing E” and “special drawing F” are both 2R and are in a state in which they do not shift to the time-saving state.

  "Special figure G" is a first small hit symbol, and "Special figure H" is a second small hit symbol, both of which are in a special figure low probability normal figure low probability state. The small hit here is equivalent to the same short hit big hit with 2R. That is, “Special Figure G” and “Special Figure H” are in the same state as “Special Figure F”, but the effects displayed on the decorative symbol display device 208 are different in both cases. By providing “G”, “Special Figure H”, and “Special Figure F”, the interest of the game is enhanced. In addition, “Special Figure I” is a first off symbol, and “Special Figure J” is a second off symbol, and the profit amount given to the player is a relatively small profit amount.

  In the pachinko machine 100 of the present embodiment, symbols other than “Special Figure A” are prepared as 15R special jackpot symbols, and the same applies to other symbols such as 15R jackpot symbols.

  FIG. 6B shows an example of a decorative design. There are 10 types of decoration patterns of the present embodiment: “Decoration 1” to “Decoration 10”. The first start port sensor detects that a ball has won the first special figure start port 230 or the second special view start port 232, that is, the ball has entered the first special view start port 230; or On the condition that the second start port sensor detects that a ball has entered the second special symbol start port 232, the left symbol display area 208a, the middle symbol display area 208b, and the right symbol display of the decorative symbol display device 208 are displayed. Displayed in the order of “decoration 1” → “decoration 2” → “decoration 3” →... “Decoration 9” → “decoration 10” → “decoration 1” →... “Decoration display of decorative pattern” is performed. When the 15R jackpot of “Special Figure B” is notified, a symbol combination (for example, “decoration 1—decoration 1—decoration”) corresponding to the 15R jackpot corresponding to the 15R jackpot is displayed in the symbol display areas 208a to 208c. 1 ”or“ decoration 2—decoration 2—decoration 2 ”). When the 15R special jackpot of “special drawing A” is notified, a combination of three symbols of the same odd number of decorative symbols (for example, “decoration 3—decoration 3—decoration 3” or “decoration 7—decoration 7—decoration 7”). Etc.) is stopped and displayed.

  In addition, the 2R jackpot called “hidden probability change” of “Special Figure E”, the 2R jackpot called “Special Figure F” suddenly, or the first small hit of “Special Figure G”, “Special Figure H” When notifying the second small hit, “decoration 1-decoration 2—decoration 3” is stopped and displayed. Furthermore, in order to notify the 2R jackpot called “sudden change” of “special drawing C” or the 2R jackpot called “sudden time reduction” of “special drawing D”, “decoration 1-decoration 3—decoration 5” is displayed. Stop display.

  On the other hand, when notifying the first deviation of “Special Figure I” and the second deviation of “Special Figure J”, the symbol combination other than the symbol combination shown in FIG. 5B is stopped in the symbol display areas 208a to 208c. indicate.

  FIG.6 (c) shows an example of the usual stop display symbol. In the present embodiment, there are two types of stoppage display modes for ordinary maps: “general diagram A” which is a winning symbol and “general symbol B” which is a missed symbol. Based on the fact that the above-mentioned gate sensor has detected that a sphere has passed through the general-purpose start opening 228, the normal symbol display device 210 repeats all lighting of the seven segments and lighting of the central one segment. Perform a “normal change display”. Then, when notifying the winning of the common figure variable game, the “normal figure A” is stopped and displayed, and when notifying the usual figure variable game, the “normal figure B” is stopped and displayed. Also in FIG. 6C, the white portions in the figure indicate the locations of the segments that are turned off, and the black portions indicate the locations of the segments that are turned on.

<Main control unit main processing>
Next, main control unit main processing executed by the CPU 304 of the main control unit 300 will be described with reference to FIG. This figure is a flowchart showing the flow of main processing of the main control unit.

  As described above, the main control unit 300 is provided with the start signal output circuit (reset signal output circuit) 340 that outputs the start signal (reset signal) when the power is turned on. The CPU 304 of the basic circuit 302 to which this activation signal has been input starts reset by a reset interrupt and executes the main process of the main control unit shown in FIG. 7 in accordance with a control program stored in advance in the ROM 306.

  In step S101, initial setting 1 is performed. In this initial setting 1, setting of a stack initial value (temporary setting) to the stack pointer (SP) of the CPU 304, setting of an interrupt mask, initial setting of the I / O 310, initial setting of various variables stored in the RAM 308, to the WDT 314 The operation is permitted and the initial value is set. In the present embodiment, a numerical value corresponding to 32.8 ms is set in WDT 314 as an initial value. In step S103, the value of the counter of WDT 314 is cleared and time measurement by WDT 314 is restarted.

  In step S105, whether or not the low voltage signal is on, that is, the voltage value of the power supply that the voltage monitoring circuit 338 supplies from the power supply control unit 660 to the main control unit 300 is a predetermined value (in this embodiment, 9v), it is monitored whether or not a low voltage signal indicating that the voltage has dropped is output. Then, when the low voltage signal is on (when the CPU 304 detects that the power supply is cut off), the process returns to step S103, and when the low voltage signal is off (when the CPU 304 does not detect that the power supply is cut off), The process proceeds to S107. Even when the predetermined value (9 V) is not yet reached immediately after the power is turned on, the process returns to step S103, and step S105 is repeatedly executed until the supply voltage becomes equal to or higher than the predetermined value.

  In step S107, initial setting 2 is performed. In this initial setting 2, a process for setting a numerical value for determining a cycle for executing a main control unit timer interrupt process, which will be described later, in the counter timer 312 and a predetermined port of the I / O 310 (for example, a test output port, A process of outputting a clear signal from the output port to the first sub control unit 400, a setting for permitting writing to the RAM 308, and the like are performed.

  In step S109, it is determined whether or not the state before the power interruption (before power interruption) is restored, and the state before the power interruption is not restored (when the basic circuit 302 of the main control unit 300 is set to the initial state). ) Proceeds to an initialization process (step S113).

  Specifically, first, a RAM clear signal transmitted when a store clerk or the like of an amusement store operates the RWM clear switch 180 provided on the power supply board is turned on (indicates that there has been an operation). That is, it is determined whether or not the RAM clear is necessary. If the RAM clear signal is on (when the RAM clear is necessary), the process proceeds to step S113 to set the basic circuit 302 to the initial state. On the other hand, when the RAM clear signal is OFF (when the RAM clear is not necessary), the power status information stored in the power status storage area provided in the RAM 308 is read, and the power status information is information indicating suspend. It is determined whether or not. If the power status information is not information indicating suspend, the process proceeds to step S113 to set the basic circuit 302 to an initial state. If the power status information is information indicating suspend, a predetermined area of the RAM 308 is set. A checksum is calculated by adding all the 1-byte data stored in (for example, all areas) to a 1-byte register whose initial value is 0, and the calculated checksum results in a specific value (for example, 0) (whether or not the checksum result is normal). When the checksum result is a specific value (eg, 0) (when the checksum result is normal), the process proceeds to step S111 to return to the state before the power interruption, and the checksum result is a specific value. If the value is other than 0 (for example, 0) (if the result of the checksum is abnormal), the process proceeds to step S113 to set the pachinko machine 100 to the initial state. Similarly, when the power status information indicates information other than “suspend”, the process proceeds to step S113.

  In step S111, power recovery processing is performed. In this power recovery process, the value of the stack pointer stored in the stack pointer save area provided in the RAM 308 at the time of power failure is read out and reset to the stack pointer (this setting). In addition, the value of each register stored in the register save area provided in the RAM 308 at the time of power interruption is read out and reset in each register, and then the interrupt permission is set. Thereafter, as a result of the CPU 304 executing the control program based on the reset stack pointer and registers, the pachinko machine 100 returns to the state when the power is turned off. That is, the processing is resumed from the instruction next to the instruction (predetermined in step S115) performed immediately before branching to the timer interrupt process (described later) immediately before the power interruption. A RAM 308 mounted on the basic circuit 302 in the main control unit 300 shown in FIG. 4 is provided with a transmission information storage area. In step S111, a power recovery command is set in the transmission information storage area. This power recovery command is a command indicating that the power has been restored to the state at the time of power-off, and is transmitted to the first sub-control unit 400 in step S233 in the timer interrupt process of the main control unit 300 described later.

  In step S113, initialization processing is performed. In this initialization process, interrupt prohibition setting, stack initial value setting to the stack pointer (this setting), initialization of all storage areas of the RAM 308, and the like are performed. Further, here, a normal return command is set in the transmission information storage area provided in the RAM 308 of the main control unit 300. This normal return command is a command indicating that the initialization process (step S113) of the main control unit 300 has been performed, and in the same way as the power recovery command, in step S233 in the timer interrupt process of the main control unit 300, 1 is transmitted to the sub-control unit 400.

  In step S115, after setting for prohibition of interruption, a basic random number initial value update process is performed. In this basic random number initial value update process, two initial value generation random number counters for generating the initial values of the ordinary figure winning random number counter and the special figure random value counter, the ordinary figure timer random number value, and the special figure timer, respectively. Two random number counters for generating each random value are updated. For example, if the range of values that can be taken as a normal timer random number value is 0 to 100, a value is acquired from a random number counter storage area for generating a normal timer random value provided in the RAM 308, and 1 is added to the acquired value. Then, it is stored in the original random number counter storage area. At this time, if the result of adding 1 to the acquired value is 101, 0 is stored in the original random number counter storage area. Other initial value generation random number counters and random number counters are similarly updated. Note that the initial value generation random number counter is also updated in step S207 described later. The main control unit 300 repeatedly executes the process of step S115 except during a timer interrupt process that starts every predetermined period.

<Main control unit timer interrupt processing>
Next, the main control unit timer interrupt process executed by the CPU 304 of the main control unit 300 will be described with reference to FIG. This figure is a flowchart showing the flow of the main control unit timer interrupt process.

  The main control unit 300 includes a counter timer 312 that generates a timer interrupt signal at a predetermined cycle (in this embodiment, about once every 2 ms), and the main control unit timer interrupt is triggered by this timer interrupt signal. The process is started at a predetermined cycle. In step S201, a timer interrupt start process is performed. In this timer interrupt start process, a process of temporarily saving each register value of the CPU 304 to the stack area is performed.

  In step S203, the WDT is periodically updated (so that the count value of the WDT 314 exceeds the initial setting value (32.8 ms in the present embodiment) and no WDT interruption occurs (so as not to detect a processing abnormality). In the embodiment, the restart is performed once every about 2 ms, which is the period of the main control unit timer interrupt.

  In step S205, input port state update processing is performed. In this input port state update process, the detection signals of various sensors 320 including the above-mentioned front frame door open sensor, inner frame open sensor, lower pan full sensor, and various ball detection sensors are input via the input port of the I / O 310. The input is monitored for the presence or absence of a detection signal, and stored in a signal state storage area provided for each of the various sensors 320 in the RAM 308. If the detection signal of the sphere detection sensor is described as an example, information on the presence / absence of the detection signal of each sphere detection sensor detected in the timer interruption process (about 4 ms before) is stored in the RAM 308 for each sphere detection sensor. This information is read out from the previous detection signal storage area partitioned and stored in the RAM 308 in the previous detection signal storage area partitioned for each sphere detection sensor, and the previous timer interrupt processing (about 2 ms before) ) Is read from the current detection signal storage area provided for each sphere detection sensor in the RAM 308, and this information is read out from the previous detection signal storage area described above. To remember. Further, the detection signal of each sphere detection sensor detected this time is stored in the above-described current detection signal storage area.

  Further, in step S205, the information on the presence or absence of the detection signal of each sphere detection sensor stored in each storage area of the above-mentioned detection signal storage area, the previous detection signal storage area, and the current detection signal storage area is compared. It is determined whether or not the information on the presence or absence of detection signals for the past three times in the ball detection sensor matches the winning determination pattern information. This main control unit timer interrupt process that is repeatedly started at a very short interval of about 2 ms while one game ball passes one ball detection sensor is started several times. For this reason, every time the main control unit timer interrupt process is activated, in step S205 described above, a detection signal indicating that the same game ball has passed the same ball detection sensor is confirmed. As a result, a detection signal indicating that the same game ball has passed through the same ball detection sensor is stored in each of the detection signal storage area, the previous detection signal storage area, and the current detection signal storage area. That is, when the game ball starts to pass through the ball detection sensor, there is no detection signal before, a previous detection signal, and a current detection signal. In the present embodiment, in consideration of erroneous detection of the sphere detection sensor and noise, it is determined that there is a prize when the detection signal is stored twice continuously after no detection signal. The ROM 306 of the main control unit 300 shown in FIG. 4 stores winning determination pattern information (in this embodiment, information indicating that there is no previous detection signal, that there is a previous detection signal, and that there is a current detection signal). In this step S205, information on the presence or absence of detection signals for the past three times in each sphere detection sensor is predetermined winning determination pattern information (in this embodiment, no previous detection signal, previous detection signal, current detection signal present). In the case of the general winning port 226, the variable winning port 234, the first special figure starting port 230, and the second special figure starting port 232, or the ordinary drawing starting port 228. Is determined to have passed. In other words, it is determined that a prize has been awarded to the winning ports 226 and 234 and the starting ports 230, 232, and 228. For example, when the information on the presence / absence of the detection signals for the past three matches with the above-described winning determination pattern information in the general winning opening sensor for detecting the winning at the general winning opening 226, there is a winning at the general winning opening 226. If the information on the presence / absence of detection signals for the past three times does not match the above-described winning determination pattern information, the subsequent general winnings are performed. The process branches to the subsequent process without performing the process associated with winning the prize to the mouth 226. Note that the ROM 306 of the main control unit 300 stores winning determination clear pattern information (in this embodiment, information indicating that there is a detection signal before the previous time, no previous detection signal, and no current detection signal). After it is determined that there has been a single win, it is not determined that there has been a win until the information on the presence or absence of detection signals for the past three times matches the winning determination clear pattern information in each ball detection sensor, and the winning determination is cleared. If it matches the pattern information, it is next determined whether or not it matches the winning determination pattern information.

  In step S207 and step S209, basic random number initial value update processing and basic random number update processing are performed. In these basic random number initial value update processing and basic random number update processing, the value of the initial value generation random number counter performed in step S115 is updated, and then the normal winning random number value used in the main control unit 300, Two random number counters for generating the special figure 1 random value and the special figure 2 random value are updated. For example, if the range of values that can be taken as a random number value for a normal winning number is 0 to 100, a value is acquired from a random number counter storage area for generating a normal winning random number value provided in the RAM 308, and 1 is added to the acquired value. Then, it is stored in the original random number counter storage area. At this time, if the result of adding 1 to the acquired value is 101, 0 is stored in the original random number counter storage area. If it is determined that the random number counter has made one round as a result of adding 1 to the acquired value, the value of the initial value generating random number counter corresponding to each random number counter is acquired and stored in the storage area of the random number counter. set. For example, a value is acquired from a random number counter for generating a regular winning random number that fluctuates in a numerical range of 0 to 100, and a result obtained by adding 1 to the acquired value is stored in a predetermined initial value storage area provided in the RAM 308. If the value is equal to the previously set initial value (for example, 7), the value is acquired as an initial value from the initial value generation random number counter corresponding to the random number counter for generating the random number for winning the normal number, The initial value set this time is stored in the above-described initial value storage area in order to determine that the random number counter for generating the winning random number value has made one round next time, in addition to setting it in the random number counter for generating the winning random value Keep it. Further, apart from the above-described initial value storage area for determining that the random number counter for generating the random number for winning the normal signal has made one round next, it is determined that the random number counter for generating the special figure random number has made one round. An initial value storage area is provided in the RAM 308. In the present embodiment, the counter for acquiring the random number value of FIG. 1 and the counter for acquiring the random value of FIG. 2 are separately provided, but the same counter may be used.

  In step S211, effect random number update processing is performed. In this effect random number update process, a random number counter for generating an effect random number used by the main control unit 300 is updated.

  In step S213, timer update processing is performed. In this timer update process, the normal symbol display symbol update timer for timing the time for the symbol to be changed / stopped on the normal symbol display device 210, and the time for the symbol to be changed / stopped to be displayed on the first special symbol display device 212 are timed. Special symbol 1 display symbol update timer for performing, special symbol 2 display symbol update timer for measuring the time for the symbol to be changed and stopped on the second special symbol display device 214, a predetermined winning effect time, a predetermined opening time Various timers including a timer for measuring a predetermined closing time, a predetermined end effect period, and the like are updated.

  In step S215, winning prize counter update processing is performed. In this winning opening counter updating process, when the winning openings 226, 234, 235 and the starting openings 230, 232, 228 have been won, the number of winning balls stored in the RAM 308 for each winning opening or for each starting opening is stored. The value of the area is read and 1 is added to set the original prize ball number storage area.

  In step S217, a winning acceptance process is performed. In this winning acceptance process, it is determined whether or not there has been a winning at the first special figure starting port 230, the second special figure starting port 232, the ordinary drawing starting port 228, the first variable winning port 234, and the second variable winning port 235. judge. Here, the determination is made using the determination result of whether or not it matches the winning determination pattern information in step S203. When a winning is made at the first special figure starting port 230 and the corresponding reserved number storage area provided in the RAM 308 is not full, the value is stored in the special counter value storage register of the counter circuit 318. And a value from the random number counter for generating the special figure 1 random value as a special figure 1 random value and storing it in the corresponding random value storage area. When a winning is made to the second special figure starting port 232 and the corresponding reserved number storage area provided in the RAM 308 is not full, the value is sent from the winning counter value storage register of the counter circuit 318 to the special figure 2 winning random number value. And a value from the random number counter for generating the special figure 2 random value as a special figure 2 random value and storing it in the corresponding random value storage area. If there is a win at the general figure starting port 228 and the corresponding reserved number storage area provided in the RAM 308 is not full, the value is obtained as a normal figure winning random value from the random number counter for generating the normal figure winning random number value. Store in the corresponding random value storage area. When there is a winning at the variable winning opening 234, information indicating that a ball has entered the variable winning opening 234 is stored in the winning storage area for the variable winning opening.

  In step S219, a payout request number transmission process is performed. Note that the output schedule information and the payout request information output to the payout control unit 600 are composed of, for example, 1 byte, strobe information (indicating that data is set when ON), bit 6 Power-on information (if turned on, indicates that this is the first command transmission after power-on), bits 4-5 indicate the current processing type for encryption (0-3), and bits 0-3 indicate encryption The number of payout requests after processing is shown.

  In step S221, a normal state update process is performed. This normal state update process performs one of a plurality of processes corresponding to the normal state. For example, in the normal state update process in the middle of the normal symbol display (the above-described general symbol display symbol update timer value is 1 or more), the 7-segment LED constituting the normal symbol display device 210 is repeatedly turned on and off. Turns off drive control. By performing this control, the normal symbol display device 210 performs a usual fluctuation display (ordinary figure fluctuation game).

  Also, in the normal state update process at the timing when the normal symbol change display time has elapsed (the timing when the value of the general symbol display symbol update timer has changed from 1 to 0), if the hit flag is on, the win symbol is displayed. The normal symbol display device 210 is controlled so that the 7-segment LED constituting the normal symbol display device 210 is turned on / off, and when the hit flag is off, the normal symbol display device 210 is configured to be in the off symbol display mode. 7 segment LED on / off drive control is performed. Further, the RAM 308 of the main control unit 300 is provided with a setting area for performing various settings in various processes, not limited to the normal state update process. Here, the above-described lighting / extinguishing drive control is performed, and the setting area is set to indicate that the normal stop display is being performed. By performing this control, the normal symbol display device 210 determines the symbol of either the winning symbol (the general symbol A shown in FIG. 6C) or the off symbol (the universal symbol B shown in FIG. 6C). Display. Thereafter, information indicating the stop period is set in a storage area of a normal stop time management timer provided in the RAM 308 in order to maintain the display for a predetermined stop display period (for example, 500 msec). With this setting, the symbol that has been confirmed and displayed is stopped and displayed for a predetermined period, and the player is notified of the result of the normal game.

  Further, if the result of the usual figure variable game is a hit, the usual figure hit flag is turned on as will be described later. When the usual figure hit flag is on, in the usual figure state update process at the timing when the predetermined stop display period ends (when the usual figure stop time management timer value changes from 1 to 0), The normal operation is set in the setting area, and the blade member 232a is opened to the solenoid (332) for opening and closing the blade member 232a of the second special figure starting port 232 for a predetermined opening period (for example, 2 seconds). And a signal indicating the open period is set in the storage area of the blade open time management timer provided in the RAM 308.

  In the usual state update process that starts at the timing when the predetermined opening period ends (the timing when the value of the blade opening time management timer is changed from 1 to 0), the blade member has a predetermined closing period (for example, 500 milliseconds). A signal for holding the blade member in the closed state is output to the opening / closing drive solenoid 332, and information indicating the closing period is set in the storage area of the blade closing time management timer provided in the RAM 308.

  Further, in the normal state update process that starts at the timing when the predetermined closing period ends (when the value of the blade closing time management timer is changed from 1 to 0), the non-operating state is set in the setting area of the RAM 308. To do. Furthermore, if the result of the usual figure fluctuation game is out, the usual figure out flag is turned on as will be described later. When the off-normal flag is on, the normal state update process at the timing when the predetermined stop display period described above ends (the timing at which the normal stop time management timer value changes from 1 to 0) In the setting area of the RAM 308, normal operation inactive is set. In the general state update process in the case where the general map is not operating, nothing is done and the process proceeds to the next step S223.

  In step S223, a general drawing related lottery process is performed. In this general map-related lottery process, the open / close control of the general map variable game and the second special map start port 232 is not performed (the state of the general map is not in operation), and the pending general map variable game is not held. When the number is 1 or more, it is decided whether to win or not to win the result of the variable figure game by random lottery based on the random number value stored in the random number value storage area. When the winning judgment is made and the winning is made, the winning flag provided in the RAM 308 is set to ON. If unsuccessful, turn off the winning flag. Regardless of the result of the hit determination, next, the value of the random number counter for generating the normal figure timer random value is acquired as the normal figure timer random number value, and a plurality of fluctuation times are obtained based on the acquired general figure timer random number value. One time is selected for variably displaying the normal map on the general map display device 210, and this variable display time is stored as a normal map variable display time in a general map variable time storage area provided in the RAM 308. In addition, the number of pending general figure variable games is stored in the usual figure pending number storage area provided in the RAM 308, and from the number of pending custom figure variable games each time a hit determination is made. The value obtained by subtracting 1 is re-stored in the usual figure number-of-holds storage area. Also, the random number value used for the hit determination is deleted.

  Next, the special figure state update process for each of the special figure 1 and the special figure 2 is performed. First, the special figure state update process (the special figure 2 state update process) for the special figure 2 is performed (step S225). In the special figure 2 state update process, one of the following eight processes is performed in accordance with the state of the special figure 2. For example, in the special figure 2 state update process in the middle of the special figure 2 fluctuation display (the value of the above-mentioned special figure 2 display symbol update timer is 1 or more), the 7-segment LED constituting the second special symbol display device 214 is turned on. Performs lighting / extinguishing drive control that repeatedly turns off. By performing this control, the second special symbol display device 214 performs the variable display of the special figure 2 (special figure 2 variable game). In addition, predetermined transmission information indicating that the rotation start setting transmission process is to be executed in the command setting transmission process (step S233) is additionally stored in the above-described transmission information storage area, and the process ends.

  Further, the RAM 308 of the main control unit 300 includes a 15R big hit flag, a 2R big hit flag, a first small hit flag, a second small hit flag, a first off flag, a second off flag, a special figure probability variation flag, and a normal figure. A flag for each probability variation flag is prepared. In the special figure 2 state update process starting at the timing when the special figure 2 fluctuation display time has elapsed (the timing when the special figure 2 display symbol update timer value has changed from 1 to 0), the 15R big hit flag is on, and the special figure probability fluctuation When the flag is also on and the normal figure probability fluctuation flag is on, the special figure A, 15R jackpot flag shown in FIG. 6A is on, the special figure probability fluctuation flag is off, and the common figure probability fluctuation flag is on. When the special figure B, 2R big hit flag is on, the special figure probability fluctuation flag is on, and the general figure probability fluctuation flag is also on, the special figure C, 2R big hit flag is on, the special figure probability fluctuation flag is off, When the probability fluctuation flag is on, the special figure D, 2R jackpot flag is on, the special figure probability fluctuation flag is on, and when the common figure probability fluctuation flag is on, the special figure E, 2R jackpot flag is on, special chart Probability flag is off, normal When the rate fluctuation flag is also off, the special figure F, when the first small hit flag is on, the special figure G, when the second small hit flag is on, the special figure H, and the first off flag are on. In such a case, the 7-segment LED constituting the second special symbol display device 214 is controlled to be turned on / off so that the special figure I and the second off flag are turned on, respectively, so that the special figure I is in the respective mode. A setting indicating that the special figure 2 stop display is in progress is made in the setting area of the RAM 308. By performing this control, the second special symbol display device 214 has a 15R special jackpot symbol (special symbol A), a 15R jackpot symbol (special symbol B), a sudden probability variation symbol (special symbol C), and a sudden time-short symbol symbol (special symbol). D), hidden probability variation (special E), suddenly normal (special F), first small hit (special G), second small hit (special H), first off symbol (special) Any one of the symbols I) and the second off-set symbol (special symbol J) is confirmed and displayed. After that, information indicating the stop period is set in the storage area of the special figure 2 stop time management timer provided in the RAM 308 in order to maintain the display for a predetermined stop display period (for example, 500 milliseconds). With this setting, the specially displayed special figure 2 is stopped and displayed for a predetermined period, and the result of the special figure 2 variable game is notified to the player. In addition, if the time reduction number stored in the time reduction number storage unit provided in the RAM 308 is 1 or more, 1 is subtracted from the time reduction number, and if the subtraction result becomes 1 to 0, the special figure probability is changing. If not (details will be described later), the time reduction flag is turned off. Further, the hourly flag is also turned off during the big hit game (in the special game state).

  Further, the special transmission information indicating that the rotation stop setting transmission process is executed in the command setting transmission process (step S233) is additionally stored in the above-described transmission information storage area, and the design for stopping the variable display is shown in FIG. The special figure 2 identification information indicating the presence is additionally stored in the RAM 308 as information to be included in command data, which will be described later, and the processing is terminated.

  If the result of the special figure 2 variable game is a big hit, the big hit flag is turned on as will be described later. When the jackpot flag is on, in the special figure 2 state update process at the timing when the predetermined stop display period ends (the timing when the special figure 2 stop time management timer value changes from 1 to 0), the RAM 308 In the setting area, the special figure 2 is in operation and waits for a predetermined winning effect period (for example, 3 seconds), that is, a period during which an image for notifying the player that the big win by the decorative symbol display device 208 is started is displayed. Therefore, information indicating the winning effect period is set in the storage area of the special figure 2 standby time management timer provided in the RAM 308. Further, predetermined transmission information indicating that the winning effect setting transmission process is executed in the command setting transmission process (step S233) is additionally stored in the transmission information storage area.

  Further, in the special figure 2 state update process that starts at the timing when the predetermined winning effect period ends (the timing when the value of the special figure 2 standby time management timer changes from 1 to 0), a predetermined release period (for example, 29 seconds) Alternatively, the second variable prize opening 235 (until the first variable prize opening 234 in the case of FIG. 1) detects a winning of a predetermined number of game balls (for example, 10 balls). The door member 235a (the door member 234a in the case of the special figure 1) is connected to the solenoid (332) for opening and closing the door member 235a (the door member 234a of the first variable winning opening 234 in the case of the special figure 1). A signal for maintaining the open state is output, and information indicating the open period is set in the storage area of the door open time management timer provided in the RAM 308. In addition, predetermined transmission information indicating that the special winning opening release setting transmission process is executed in the command setting transmission process (step S233) is additionally stored in the transmission information storage area.

  In the special figure 2 state update process that starts at the timing when the predetermined opening period ends (the timing when the door opening time management timer value changes from 1 to 0), the predetermined closing period (for example, 1.5 seconds) The door member 235a (in the case of FIG. 1) is connected to the solenoid (332) for opening and closing the door member 235a of the second variable prize opening 235 (in the case of FIG. 1, the door member 234a of the first variable prize opening 234). In addition, a signal for holding the door member 234a) in the closed state is output, and information indicating the closing period is set in the storage area of the door closing time management timer provided in the RAM 308. In addition, predetermined transmission information indicating that the special winning opening closing setting transmission process is executed in the command setting transmission process (step S233) is additionally stored in the transmission information storage area.

  In addition, in the special figure 2 state update process that starts at the timing when the door member opening / closing control is repeated a predetermined number of times (15 rounds or 2 rounds in this embodiment) and finished, a predetermined end effect period (for example, 3 seconds) In other words, the effect standby period is stored in the storage area of the effect standby time management timer provided in the RAM 308 in order to set to wait for a period during which an image for informing the player that the big hit by the decorative symbol display device 208 is to be ended is displayed. Set the information indicating. Also, if the normal probability fluctuation flag is set to ON, at the same time as the end of the jackpot game, the time reduction number 100 is set in the time reduction number storage unit provided in the RAM 308, and the time reduction flag provided in the RAM 308 is set. Turn on. If the usual time probability variation flag is set to OFF, the time reduction number is not set in the time reduction number storage unit, and the time reduction flag is not turned ON. The short time here means that the pachinko machine is in an advantageous state for the player in order to shorten the time from the end of the big hit in the special figure variable game to the start of the next big hit. If the short time flag is set to ON at this time, it is a normal high probability state. There is a higher probability of hitting a general-purpose variable game in the high-probability state than in the low-probability state. In addition, the fluctuation time of the normal figure variable game and the fluctuation time of the special figure variable game are shorter in the normal figure high probability state than in the normal figure low probability state. Further, in the normal high probability state, the opening time in one opening of the pair of blade members 232a of the second special start port 232 tends to be longer than in the normal low probability state. In addition, the pair of blade members 232a are more likely to open in the normal high probability state than in the normal low probability state. In addition, as described above, the hourly flag is set to off during the big hit game (in the special game state). Therefore, the normal low probability state is maintained during the jackpot game. This is because, if the game is in a high probability state during a jackpot game, a large number of games will be placed in the second special figure start port 232 until a predetermined number of game balls are entered during the jackpot game. There is a problem that a ball enters and the number of game balls that can be acquired during the jackpot increases, resulting in an increase in euphoria. This is to solve this problem.

  Further, predetermined transmission information indicating that the end effect setting transmission process is executed in the command setting transmission process (step S233) is additionally stored in the transmission information storage area.

  Also, in the special figure 2 state update process that starts at the timing when the predetermined end production period ends (when the production standby time management timer value changes from 1 to 0), the special figure 2 is not activated in the setting area of the RAM 308. Set medium. Further, if the result of the special figure 2 variable game is out of the way, the off flag is turned on as will be described later. In the case where the miss flag is on, even in the special figure 2 state update process at the timing when the predetermined stop display period described above ends (the timing when the special figure 2 stop time management timer value changes from 1 to 0), In the setting area of the RAM 308, special figure 2 inactive is set. In the special figure 2 state update process when the special figure 2 is not in operation, nothing is done and the process proceeds to the next step S227.

  Subsequently, special figure state update processing (special figure 1 state update process) for special figure 1 is performed (step S227). In the special figure 1 state update process, each process described in the special figure 2 state update process is performed according to the state of the special figure 1. Each process performed in the special figure 1 state update process is the same as the process in which “special figure 2” in the contents described in the special figure 2 state update process is replaced with “special figure 1”. Omitted. The order of the special figure 2 state update process and the special figure 1 state update process may be reversed.

  When the special figure state update process in step S225 and step S227 is completed, a special figure related lottery process for each of special figure 1 and special figure 2 is performed. Also here, first, a special drawing related lottery process for special figure 2 (a special drawing 2 related lottery process) is performed (step S229), and then a special drawing related lottery process for special figure 1 (a special drawing 1 related lottery process). ) Is performed (step S231). Also for these special drawing related lottery processes, the main control unit 300 performs the special figure 2 related lottery processing before the special figure 1 related lottery processing, so that the special figure 2 variable game start condition and the special figure 1 fluctuation Even if the game start conditions are satisfied at the same time, since the special figure 2 variable game is changing first, the special figure 1 variable game does not start changing. Further, the notification of the result of the jackpot determination of the special figure variable game by the decorative symbol display device 208 is performed by the first sub-control unit 400, and the lottery result of the lottery based on the winning at the second special figure starting port 232 is notified. However, it is performed in preference to the notification of the lottery result of the lottery based on the winning at the first special figure starting port 230.

  In step S233, command setting transmission processing is performed, and various commands are transmitted to the first sub-control unit 400. The output schedule information to be transmitted to the first sub-control unit 400 is composed of 16 bits, for example, bit 15 is strobe information (indicating that data is set when ON), bits 11 to 14 are Command type (In this embodiment, command types such as basic command, symbol variation start command, symbol variation stop command, winning effect start command, end effect start command, jackpot round number designation command, power recovery command, RAM clear command are specified. Possible information), bits 0 to 10 are composed of command data (predetermined information corresponding to the command type).

  Specifically, the strobe information is turned on and off in the command transmission process described above. If the command type is a symbol variation start command, information indicating the value of the 15R jackpot flag or 2R jackpot flag, the value of the special figure probability variation flag, the timer number selected in the special figure related lottery process, etc. is included in the command data. In the case of the symbol variation stop command, the value of the 15R jackpot flag, 2R jackpot flag, the value of the special figure probability variation flag, etc. are included. In the case of a jackpot round number designation command, the value of the special variation probability flag, the number of jackpot rounds, and the like are included. When the command type indicates a basic command, device information in the command data, presence / absence of winning at the first special figure starting port 230, presence / absence of winning at the second special figure starting port 232, winning of the variable winning port 234 Includes presence or absence.

  In the rotation start setting transmission process described above, the 15R jackpot flag or 2R jackpot flag value, the special figure probability variation flag value, the special figure 1 related lottery process, and the special figure 2 relation stored in the RAM 308 as command data. Information indicating the timer number selected in the lottery process, the number of the first special figure variable game or the second special figure variable game held, etc. is set. In the rotation stop setting transmission process described above, information indicating the value of the 15R jackpot flag, the 2R jackpot flag, the value of the special figure probability variation flag, etc. stored in the RAM 308 is set in the command data. In the winning effect setting transmission process described above, the command control data stored in the RAM 308, the effect control information output to the decorative symbol display device 208, various lamps 418, and the speaker 120 during the winning effect period, the special figure probability variation flag Information indicating the value, the number of the first special figure variable game or the second special figure variable game being held, etc. is set. In the above-described end effect setting transmission process, the command control data stored in the RAM 308, the effect control information output to the decorative symbol display device 208, various lamps 418, and the speaker 120 during the effect standby period, the special figure probability variation flag Information indicating the value, the number of the first special figure variable game or the second special figure variable game being held, etc. is set. In the above-described large winning opening release setting transmission process, the number of big hits stored in the RAM 308 in the command data, the value of the special figure probability variation flag, the pending first special figure variation game or the second special figure variation game is stored. Set information such as number. In the above-mentioned big winning opening closing setting transmission process, the number of big hits stored in the RAM 308 in the command data, the value of the special figure probability variation flag, the pending first special figure variation game or the second special figure variation game is stored. Set information such as number. In step S233, general command special figure hold increase processing is also performed. In this general command special figure pending increase process, special figure identification information (information showing special figure 1 or special figure 2) stored in the transmission information storage area of the RAM 308, command notice information (preliminary notice information, false) Set either advance notice information or no advance notice information).

  In the first sub-control unit 400, it is possible to determine the production control according to the change of the game control in the main control unit 300 by the command type included in the received output schedule information, and it is included in the output schedule information. Based on the information of the command data, the contents of effect control can be determined.

  In step S235, an external output signal setting process is performed. In this external output signal setting process, the game information stored in the RAM 308 is output to the information input circuit 350 separate from the pachinko machine 100 via the information output circuit 336.

  In step S237, device monitoring processing is performed. In this device monitoring process, the signal states of the various sensors stored in the signal state storage area in step S205 are read, and the presence or absence of a predetermined error, for example, the presence or absence of a front frame door opening error or the presence or absence of a full tray error is monitored. When the front frame door opening error or the lower pan full error is detected, the transmission information to be transmitted to the first sub-control unit 400 includes device information indicating the presence or absence of the front frame door opening error or the lower pan full error. Set. Further, various solenoids 332 are driven to control the opening and closing of the second special figure starting port 232 and the first variable winning port 234 (or the second variable winning port 235), and via the display circuits 324, 326, 330. Display data to be output to the normal symbol display device 210, the first special symbol display device 212, the second special symbol display device 214, the various status display units 328, and the like is set in the output port of the I / O 310. Further, the output schedule information set in the payout request number transmission process (step S219) is output to the first sub-control unit 400 via the output port (I / O 310).

  In step S239, it is monitored whether or not the low voltage signal is on. Then, when the low voltage signal is on (when power supply cutoff is detected), the process proceeds to step S243, and when the low voltage signal is off (when power supply cutoff is not detected), the process proceeds to step S241.

  In step S241, timer interrupt end processing is performed. In this timer interrupt end process, the value of each register temporarily saved in step S201 is set in each original register, interrupt permission is set, etc., and then the main control unit main process shown in FIG. Return to.

  On the other hand, in step S243, a specific variable or stack pointer for returning to the power-off state at the time of power recovery is saved as a return data in a predetermined area of the RAM 308, and power-off processing such as initialization of input / output ports is performed. Then, the process returns to the main process of the main control unit described above.

<Processing of First Sub-Control Unit 400>
Next, processing of the first sub control unit 400 will be described with reference to FIG. FIG. 5A is a flowchart of main processing executed by the CPU 404 of the first sub control unit 400. FIG. 5B is a flowchart of command reception interrupt processing of the first sub control unit 400. FIG. 5C is a flowchart of the timer interrupt process of the first sub control unit 400.

  First, in step S301 in FIG. 9A, various initial settings are performed. When the power is turned on, an initialization process is first executed in step S301. In this initialization processing, initialization of input / output ports, initialization processing of a storage area in the RAM 408, and the like are performed. In step S303, it is determined whether or not the value of the timer variable CNT in the timer variable storage area is 33 (33 ms) or more. This process is repeated until the value of the timer variable CNT becomes 33, and the value of the timer variable CNT is 33 or more. When it becomes, it transfers to the process of step S305. In step S305, 0 is substituted into the timer variable CNT. Note that the value of the timer variable CNT in the timer variable storage area may be changed as indicated by 33, 33, and 34 every time the process proceeds from step S303 to step S305.

  In step S307, command processing is performed. The CPU 404 of the first sub control unit 400 determines whether or not a command from the main control unit 300, a command from the second sub control unit 500, and a return command from the liquid crystal control unit 700 have been received and processes them.

  In step S309, effect control processing is performed. For example, when there is a new command in step S307, processing such as reading effect data corresponding to the command from the ROM 406 is performed, and when update of the effect data is necessary, effect data update processing is performed. Further, an effect lottery process is performed based on a command from the main control unit 300, and a liquid crystal command and a box data setting process (described later) for setting parts data at a predetermined position are performed. If there is part data in the position after receiving the return command (described later), the part data to be transmitted to the speaker 120, various lamps 418, game board lamp 532, effect movable body 246, 224, etc. is set.

  If it is detected in step S311 that the chance button has been pressed, the effect data updated in step S309 is changed to effect data corresponding to the press of the chance button.

  In step S315, if there is a command to the sound source IC 416 in the effect data read in step S309, this command is output to the sound source IC 416. For example, a command is output so that notification (for example, production) by the speaker 120 is executed when the notification condition is satisfied. In addition, a command is output so that notification by the speaker 120 (for example, notification for reporting the occurrence of an abnormality) is executed when an abnormality notification condition related to detection of fraud or failure is established. In step S317, if there is a command to the various lamps 418 in the effect data read in step S309, this command is output to the drive circuit 420. For example, when the light emission conditions of the various lamps 418 are satisfied, a command for the light emission is output.

  In step S 319, if there is a command to the shielding device 246 or the movable body (rotary body) in the chance button 136 in the effect data read in step S 309, this command is output to the drive circuit 432. In step S321, if the effect data read out in step S309 includes a control command to be transmitted to the second sub-control unit 500 or a liquid crystal command to be transmitted to the liquid crystal control unit 700, a setting for outputting this control command is performed. Return to step S303.

  Next, the command reception interrupt process of the first sub-control unit 400 will be described using FIG. This command reception interrupt process is a process executed when the first sub-control unit 400 detects a strobe signal output from the main control unit 300. In step S401 of the command reception interrupt process, the command output from the main control unit 300 is stored as an unprocessed command in a command storage area provided in the RAM 408.

  Next, the first sub control unit timer interrupt process executed by the CPU 404 of the first sub control unit 400 will be described with reference to FIG. The first sub-control unit 400 includes a hardware timer that generates a timer interrupt at a predetermined cycle (in this embodiment, once every 1 ms). Execute in the cycle.

  In step S501 of the first sub-control unit timer interrupt process, 1 is added to the value of the timer variable CNT in the timer variable storage area of the RAM 408 described in step S303 in the first sub-control unit main process to obtain the original timer variable. Store in the storage area. Therefore, in step S303, the value of the timer variable is determined to be 33 or more every 33 ms.

  In step S503 of the first sub-control unit timer interrupt process, transmission of a control command to the second sub-control unit 500 set in step S319, an effect random number update process, and the like are performed.

<Processing of Second Sub-Control Unit 500>
Next, the process of the second sub control unit 500 will be described with reference to FIG. FIG. 6A is a flowchart of main processing executed by the CPU 504 of the second sub-control unit 500. FIG. 7B is a flowchart of command reception interrupt processing of the second sub control unit 500. FIG. 8C is a flowchart of the timer interrupt process of the second sub control unit 500.

  First, in step S701 in FIG. 9A, various initial settings are performed. When the power is turned on, an initialization process is first executed in step S701. In this initialization processing, initial setting of input / output ports, initialization processing of a storage area in the RAM 508, and the like are performed. In step S703, it is determined whether or not the timer variable CNT is 33 or more. This process is repeated until the timer variable CNT becomes 33. When the timer variable CNT becomes 33 or more, the process proceeds to step S705. Note that the value of the timer variable CNT in the timer variable storage area may be changed as indicated by 33, 33, and 34 each time the process proceeds from step S703 to step S707.

  In step S705, 0 is assigned to the timer variable CNT.

  In step S707, command processing is performed. The CPU 504 of the second sub control unit 500 determines whether a command has been received from the CPU 404 of the first sub control unit 400.

  In step S709, an effect control process is performed. For example, if there is a new command in step S707, the effect data corresponding to this command is read from the ROM 506, and if the effect data needs to be updated, the effect data is updated.

  In step S 711, if there is a command from the first sub-control unit 400 to the game board lamp 532 or the game table frame lamp 122, this command is output to the serial communication control circuit 520. In step S713, if there is a command from the first sub-control unit 400 to the movable object M on the board side (the movable part 2441 of the movable display device 288, the effect movable body 224, the shielding device 246, etc.), this command is issued. The data is output to the drive circuit 516, and the process returns to step S703.

  Next, the command reception interrupt process of the second sub control unit 500 will be described with reference to FIG. This command reception interrupt process is a process executed when the second sub control unit 500 detects the strobe signal output from the first sub control unit 400. In step S801 of the command reception interrupt process, the command output from the first sub control unit 400 is stored as an unprocessed command in a command storage area provided in the RAM 508.

  Next, the second sub control unit timer interrupt process executed by the CPU 504 of the second sub control unit 500 will be described with reference to FIG. The second sub-control unit 500 includes a hardware timer that generates a timer interrupt at a predetermined cycle (in this embodiment, once every 1 ms). Execute in the cycle.

  In step S901 of the second sub-control unit timer interrupt process, 1 is set to the value of the timer variable CNT in the timer variable storage area of the RAM 508 described in step S703 in the second sub-control unit main process shown in FIG. Add and store in the original timer variable storage area. Therefore, in step S703, the value of the timer variable is determined to be 33 or more every 33 ms.

  In step S903 of the second sub-control unit timer interrupt process, an effect random number update process is performed.

<Processing of Liquid Crystal Control Unit 700>
Next, processing of the liquid crystal control unit 700 will be described with reference to FIG. FIG. 6A is a flowchart of main processing executed by the CPU 704 of the liquid crystal control unit 700. FIG. 7B is a flowchart of command reception interrupt processing of the liquid crystal control unit 700. FIG. 6C is a flowchart of the timer interrupt process of the liquid crystal control unit 700. FIG. 4D is a flowchart of VDP image processing.

  First, in step S1001 of FIG. When the power is turned on, an initialization process is first executed in step S1001. In this initialization process, initialization of the input / output ports, initialization of the storage area in the RAM 708, and the like are performed. In step S1003, it is determined whether or not the timer variable CNT is 33 or more, and this process is repeated until the timer variable CNT becomes 33. When the timer variable CNT becomes 33 or more, the process proceeds to step S1005. Note that the value of the timer variable CNT in the timer variable storage area may be changed as 33, 33, and 34 each time the process proceeds from step S1003 to step S1005.

  In step S1005, 0 is assigned to the timer variable CNT.

  In step S1007, command processing is performed. The CPU 704 of the liquid crystal control unit 700 determines whether a command is received from the CPU 404 of the first sub control unit 400.

  In step S1009, a VDP command transmission process is performed. For example, when there is an image display instruction from the first sub-control unit 400, a command is transmitted to the VDP 710 to cause the VDP 710 to perform image control processing.

  In step S1011, return command transmission processing is performed. When the liquid crystal control unit 700 controls the decorative symbol display device 208 or the movable display device 288 to display the requested image, the liquid crystal control unit 700 transmits a return command to the first sub-control unit 400 and returns to step S1003.

  Next, the command reception interrupt process of the liquid crystal control unit 700 will be described with reference to FIG. This command reception interrupt process is a process executed when the liquid crystal control unit 700 detects a strobe signal output from the first sub control unit 400. In step S1101 of the command reception interrupt process, the command output from the first sub-control unit 400 is stored as an unprocessed command in a command storage area provided in the RAM 708.

  Next, a second sub control unit timer interrupt process executed by the CPU 704 of the liquid crystal control unit 700 will be described with reference to FIG. The liquid crystal control unit 700 includes a hardware timer that generates a timer interrupt at a predetermined cycle (in this embodiment, once every 1 ms). The timer interrupt processing is triggered by the timer interrupt at a predetermined cycle. Run with.

  In step S1201 of the liquid crystal control unit timer interrupt process, 1 is added to the value of the timer variable CNT in the timer variable storage area of the RAM 708 described in step S1003 in the second sub control unit main process shown in FIG. Stored in the original timer variable storage area. Accordingly, in step S1003, the value of the timer variable is determined to be 33 or more every 33 ms.

  In step S1203 of the liquid crystal controller timer interrupt process, an effect random number update process is performed.

  Next, the image control process of the VDP 710 that has received a command in the VDP command transmission process of step S1009 in the liquid crystal controller main process will be described with reference to FIG. FIG. 5 is a flowchart showing the flow of image control processing.

  In step S1301, an instruction to transfer image data is issued. Here, the CPU 704 first swaps the designation of the drawing areas of the display area A and the display area B of the VRAM 718. As a result, an image of one frame stored in the display area not designated as the drawing area is displayed on the decorative symbol display device 208 and / or the movable display device 288. Next, the CPU 704 sets ROM coordinates (transfer address of the CGROM 716), VRAM coordinates (transfer destination address of the VRAM 718), etc., in the attribute register of the VDP 710 based on the position information table and the like, and then the image from the CGROM 716 to the VRAM 7186. Set an instruction to start data transfer. The VDP 710 transfers image data from the CGROM 716 to the VRAM 718 based on the command set in the attribute register. Thereafter, the VDP 710 outputs a transfer end interrupt signal to the CPU 704.

  In step S1303, it is determined whether or not a transfer end interrupt signal is input from the VDP 710. If a transfer end interrupt signal is input, the process proceeds to step S1305; otherwise, a transfer end interrupt signal is input. Wait for it. In step S1305, parameters are set based on the production scenario configuration table and attribute data. Here, in order to form a display image in the display area A or B of the VRAM 718 based on the image data transferred to the VRAM 710 in step S1301, the CPU 704 displays information on the image data constituting the display image (the coordinate axis and image size of the VRAM 718). , VRAM coordinates (arrangement coordinates, etc.) are instructed to the VDP 718. The VDP 718 performs parameter setting according to the attribute based on the instruction stored in the attribute register.

  In step S1307, a drawing instruction is performed. In this drawing instruction, the CPU 704 instructs the VDP 710 to start drawing an image. The VDP 710 starts drawing an image in the frame buffer in accordance with an instruction from the CPU 704.

  In step S1309, it is determined whether or not the generation end interrupt signal from the VDP 710 based on the image drawing end is input. If the generation end interrupt signal is input, the process proceeds to step S1311. Wait for input. In step S1311, a scene display counter that is set in a predetermined area of the RAM 708 and counts how many scene images have been generated is incremented (+1), and the process ends.

<Wiring structure>
The wiring structure of the electronic components and the like of the pachinko machine 100 will be described. Here, the wiring structure of the speaker 120 will be described. As already described, in the present embodiment, the speaker 120 is connected to the board frame relay board 726 </ b> C via the door side lighting board 734. In the case of the present embodiment, it is assumed that the board frame relay board 726 </ b> C is disposed on the lower side of the pachinko machine 100. In the case of this configuration, if the board frame relay board 726C and the speaker 120 are directly connected by a harness or the like, the required wiring length becomes relatively long and the wiring needs to be passed around the game area 124. In many cases, it is often desirable to secure the game area 124 as wide as possible in terms of game play and fun. In the present embodiment, by using the door-side lighting board 734, the wiring for the speaker 120 can be provided even when it is difficult to secure a space for installing the harness.

  FIG. 12 is a view showing the arrangement of the lighting unit A including the door-side lighting board 734, and is a schematic view seen through the front panel of the front frame door 106. The speakers 120 are arranged at two corners at the top of the front frame door 106. The lighting unit A is disposed on both the left and right sides of the gaming area 124 adjacent to the gaming area 124 and is located in a narrow area between the gaming area 124 and the side surface of the front frame door 106. Although not shown, the board frame relay board 726C is located in the vicinity of the door 108 with a ball storage tray.

  FIG. 13 is a cross-sectional view of the illumination unit A along the line aa in FIG. The lighting unit A includes a door side lighting board 734, a mounting member 1 that fixes the door side lighting board 734 to the front frame door 106, and a covering cover 2 that covers the door side lighting board 734.

  The covering cover 2 is made of a transparent material (for example, acrylic or glass) such as a transparent member or a translucent member, and the door side illumination board 734 can be visually recognized from the outside. In the case of this embodiment, the covering cover 2 is configured to cover the entire door-side lighting board 734, but may be configured to partially cover. Further, all or a part of the covering cover 2 may be formed in a lens shape.

  A lamp 418 is mounted as a light emitting element on the door side illumination board 734. In this embodiment, the lamp 418 is an LED. As already described, the lighting units A are arranged on the left and right sides of the game area 124. For this reason, when the game area 124 is viewed from the front, the player can visually recognize the light emission of the lamp 418, and the light emission aspect may be able to excite the fun of the game. Note that the location of the lighting unit A (that is, the door-side lighting board 734) is not limited to this. Can also be arranged.

  FIG. 14A shows an example of wiring between the panel frame relay board 726 </ b> C and the speaker 120 via the door side illumination board 734. In the example of the figure, the relay substrate 3 is interposed between the door side illumination board 734 and the speaker 120, but a configuration in which the door side illumination board 734 and the speaker 120 are directly connected can also be employed.

  The door-side lighting board 734 has a band shape as a whole (for example, a range of 1:10 to 1:50 in aspect ratio, etc.), and a connector CN1 is provided at one end thereof, and a connector CN2 is provided at the other end. It has been. The door side illumination board 734 is a rigid board, but may be a flexible board. Six lamps 418 are mounted (LEDs 1 to 6). Symbols CN1 and CN2 indicating connectors and symbols LED1 to LED6 indicating lamps 418 are also indications of board components formed on the door side illumination board 734 by printing or the like, and are displayed on the installation surface of the board components. This display may be formed on the back surface of the installation surface.

  The harness H1 has one end connected to the connector CN1 and the other end connected to the panel frame relay board 726C. The harness H2 has one end connected to the connector CN2 and the other end connected to the relay board 3. The harness H3 has one end connected to the relay substrate 3 and the other end connected to the speaker 120.

  The door side illumination board 734 has wiring (conductor pattern) that connects a part of the terminals of the connector CN1 and a part of the terminals of the connector CN2. Therefore, an audio signal can be transmitted from the board frame relay board 726C to the speaker 120 via the door side lighting board 734 and the relay board 3.

  In the present embodiment, the relay board 3 includes a connector and wiring for performing signal transmission between the door side lighting board 734 and the speaker 120, but the relay board 3 is connected to the door side lighting board 734. It is good also as a thing provided with a light emitting element as a structure similar to.

  In the present embodiment, the wiring to the speaker 120 is exemplified, but the application target is not limited to the speaker 120, and may be a light emitting element, an actuator (for example, a motor or a solenoid), or the like. FIG. 14B shows an example. In the example shown in the figure, the board 4 on which the LEDs 1 and 2 are mounted as the game stand frame lamp 122 instead of the speaker 120 is connected to the door side lighting board 734. A lighting / extinguishing signal can be transmitted from the board frame relay board 726C to the game stand frame lamp 122 via the door side lighting board 734. The game stand frame lamp 122 can be used for production, as well as the speaker 120, for abnormality notification.

  It is also possible to combine the configurations shown in FIGS. 14 (a) and 14 (b). That is, a plurality of electronic components such as the speaker 120 and the gaming table frame lamp 122 or a plurality of substrates such as the relay substrate 3 and the substrate 4 are connected to the door side lighting substrate 734, and a control signal is transmitted from the panel frame relay substrate 726C. It can also be used as a relay board for transmission to these.

  Next, the internal structure of the door side illumination board 734 will be described. 15A is a plan view of the door-side illumination board 734 (a view of the mounting surface of the lamp 418), and FIG. 15B is a cross-sectional view taken along the line bb of FIG. 15A.

  In the case of this embodiment, the door side illumination board 734 is a multilayer board provided with three layers of plate-like insulators 5a to 5c, four layers of wiring layers LY1 to LY4, and holes Ha to Hh. FIG. 15C shows each wiring pattern of the wiring layers LY2 to LY4. There are no wirings in each wiring layer other than those shown in the figure, but they may be present (the same applies to other examples described later).

  The wiring layer LY1 is formed on the surface of the insulator 5a. The surface of the insulator 5a constitutes a mounting surface for substrate components (connectors, LEDs) and is covered with a resist film R. The wiring layer LY2 is formed between the insulator 5a and the insulator 5b. The wiring layer LY3 is formed between the insulator 5b and the insulator 5c. The wiring layer LY4 is formed on the back surface of the insulator 5c and is covered with the resist film R. The wiring layers LY1 and LY4 may be referred to as outer layers, and the wiring layers LY2 and LY3 may be referred to as inner layers. The inner layer is a layer located inside the door side lighting board 734 than the outer layer. The holes Ha to Hh are through holes penetrating all the three layers of the insulators 5a to 5c.

  The connector CN1 is a connector having a plurality of pins (here, 6 pins), and the connector CN2 is a connector having a plurality of pins (here, 2 pins). Wirings W1 to W6 are connected to each pin of the connector CN1 in the order of the pins. A wiring W6 is connected to the first pin of the connector CN2, and a wiring W1 is connected to the second pin. The wirings W1 to W6 are patterns formed of a conductor film.

  The wirings W2 to W4 are signal lines and are formed in the wiring layer LY1. The wiring W2 connects LED1 and LED2 in series. These light emission controls can be performed simultaneously by transmitting a signal to the wiring W2. The wiring W3 connects the LED 3 and the LED 4 in series. These light emission controls can be performed simultaneously by transmitting a signal to the wiring W3. The wiring W4 connects the LED 5 and the LED 6 in series. These light emission controls can be performed simultaneously by transmitting a signal to the wiring W4.

  The wiring W5 is a power supply line and is connected to one end side (anode side) of the LED2, LED4, and LED6. The wiring W5 has a wiring layer LY1 portion, a wiring layer LY4 portion, and holes Ha to Hc and He. The wiring W5 has different specifications for the wiring layer LY1 and the wiring layer LY4. Specifically, the width, the area, the distance (for example, the length in the longitudinal direction of the substrate), and the like are different. Most of the wiring W5 is formed in the wiring layer LY4, and is formed in a line shape on the wiring layer LY1 and in a band shape (solid paint) on the wiring layer LY4. By forming the wiring layer LY4 in a strip shape, the electric resistance may be reduced when power is supplied to each part.

  The wirings W1 and W6 are signal lines for the speaker 120. The wiring W1 has a wiring layer LY1, a wiring layer LY3, and holes Hf and Hg. The wiring W1 has different specifications for the wiring layer LY1 and the wiring layer LY3. Specifically, the width, area, distance (for example, length in the longitudinal direction of the substrate), and the like are different. Most of the wiring W1 is formed in the wiring layer LY3. The wiring W1 is formed in a line shape on the wiring layer LY1 and in a band shape (solid coating) on the wiring layer LY3. By forming the wiring layer LY3 in a strip shape, the electrical resistance may be reduced when a signal is transmitted to the speaker 120 in some cases.

  The wiring W6 includes a wiring layer LY1, a wiring layer LY2, and holes Hd and Hh. The wiring W6 has different specifications for the wiring layer LY1 and the wiring layer LY2. Specifically, the width, the area, the distance (for example, the length in the longitudinal direction of the substrate), and the like are different. Most of the wiring W6 is formed in the wiring layer LY2, and is formed in a line shape on the wiring layer LY1 and in a strip shape (solid paint) on the wiring layer LY2. By forming the wiring layer LY2 in a strip shape, the electrical resistance may be reduced when a signal is transmitted to the speaker 120 in some cases.

  Thus, in the present embodiment, the wirings W1 and W6 for the speaker 120 are passed through the inner layer of the door-side lighting board 734. For this reason, the wirings W1 and W6 may not be easily affected by external factors. In addition, since there is a solid coating portion like the wiring W5, there are cases where it is possible to reduce the influence of noise generated from the game ball even when it is located adjacent to the game area 124. In addition, there has been a risk of the harness being disconnected in the past so that an alarm sound is not emitted from the speaker 120 when an unauthorized person performs an illegal act. In the present embodiment, the wiring is relayed by the door side lighting board 734. Therefore, there is a case where the harness portion is shortened, it is difficult to cut the wiring, and the occurrence of the illegal act can be surely notified.

  The wiring structure is not limited to the example of FIG. 15, and various configurations can be adopted. Hereinafter, description will be made sequentially.

<Example 1>
FIG. 16 shows a wiring pattern of the wiring layers LY1 to LY4 of another example 1. In this example, the inner layer through which the wirings W1 and W6 for the speaker 120 are passed is the same inner layer. That is, the wiring layer LY2 is divided in half in the width direction, and the wiring W1 is divided on one side and the wiring W6 is partitioned on the other side, and each is formed in a strip shape. Although the wiring layer LY3 has no wiring, it can also be used to pass other wiring.

<Example 2>
FIG. 17 is a diagram in which a ground (GND) line GP is formed in the wiring layer LY3 of the first example. In this example, a screwing hole GH is formed. The hole GH is a through hole that penetrates all the three layers of the insulators 5a to 5c. For example, a screw for fixing the lighting unit A is inserted into the screw hole GH, and the ground wiring of the pachinko machine 100 is fastened together. The ground line GP is also formed in the hole GH and is electrically connected to the ground wiring.

  The ground line GP is formed in a strip shape (solid coating) in the wiring layer LY3. By forming the wiring layer LY3 in a strip shape, it may be possible to suppress the mixing of noise into the signal line.

<Another example 3>
For wiring having an outer layer portion and an inner layer portion, the specification of part or all of the wiring may be the same for the outer layer portion and the inner layer portion. FIG. 18 shows an example. In the example of FIG. 15, the wiring width is the same in the wiring layer LY1 portion and the wiring layer LY3 portion of the wiring W1 in the example shown in FIG. Similarly, the wiring width is the same in the wiring layer LY1 portion and the wiring layer LY2 portion of the wiring W6. It is also possible to form ground lines and other signal lines in the empty space of the wiring layers LY2 and LY3.

<Another example 4>
The wiring of the inner layer can be used not only for the wiring for relaying the external board, but also for the wiring between board components in the board. 19 (a) and 19 (b) show an example thereof, FIG. 19 (a) is a plan view of the substrate 6 of this example, and FIG. 19 (b) is a substrate 6 along the line cc of FIG. 19 (a). FIG. Among the components of the substrate 6, the same components as those of the door-side illumination substrate 734 are denoted by the same reference numerals, and the description thereof is omitted.

  Substrate components P1 and P2 are mounted on the insulator 5a of the substrate 6. The board components P1 and P2 are assumed to be other than connectors, but may of course be connectors (the same applies to the following other examples). The board components P1 and P2 are circuit components, for example. Specific examples include resistors, capacitors, LEDs, ICs, LSIs, CPUs, ROMs, RAMs, switches, and the like that can be mounted on a printed circuit board.

  In the example of FIGS. 19A and 19B, the holes Ha and Hb are formed as through holes. The wiring W connects the component P1 and the component P2. The wiring W includes a wiring layer LY1, a wiring layer LY2, and holes Ha and Hb.

<Example 5>
The hole may not be a through hole but may be a hole that penetrates only some of the insulators (referred to as a via hole to be distinguished from a through hole). FIGS. 19C and 19D show an example thereof, which is a modified example of the substrate 6 shown in FIGS. 19A and 19B. FIG. 19C is a plan view of the substrate 6 of this example, and FIG. 19D is a cross-sectional view of the substrate 6 taken along the line dd in FIG. 19C. The holes Ha and Hb penetrate only the insulator 5a. The wiring W includes a wiring layer LY1, a wiring layer LY2, and holes Ha and Hb.

<Example 6>
The wiring may be arranged on the outer layer only at the connection portion with the board component. 20 (a) and 20 (b) show an example thereof, which is a modification of the substrate 6 in FIGS. 19 (c) and 19 (d). 20A is a plan view of the substrate 6 of this example, and FIG. 20B is a cross-sectional view of the substrate 6 taken along the line ee of FIG. 20A. In the example of the figure, the holes Ha and Hb are formed in the mounting region of the component P1 and the component P2. In the wiring layer LY1, the wiring W is only the end portions of the holes Ha and Hb (that is, the connection portion with the component), and there is no portion extending in a line shape or a belt shape.

<Example 7>
The wiring may be formed across a plurality of inner layers. 20 (c) and 20 (d) show an example thereof, which is a modification of the substrate 6 in FIGS. 20 (a) and 20 (b). FIG. 20C is a plan view of the substrate 6 of this example, and FIG. 20D is a cross-sectional view of the substrate 6 taken along the line ff of FIG. In the example of the figure, holes Hc and Hd penetrating the insulator 5b are formed as via holes. The wiring W includes a wiring layer LY1, a wiring layer LY2, a wiring layer LY3, and holes Ha to Hd. The portion of the wiring layer LY1 is only the connection portion.

<Example 8>
All of the wiring may be arranged in the inner layer. FIGS. 21A and 21B show an example thereof, which is a modified example of the substrate 6 shown in FIGS. 19A and 19B. FIG. 21A is a plan view of the substrate 6 of this example, and FIG. 21B is a cross-sectional view of the substrate 6 taken along the line gg of FIG. In the example of the figure, the parts P1 and P2 are embedded in the insulator 5a and are not exposed to the outside. The wiring W is formed only in the wiring layer LY2, and connects the component P1 and the component P2.

<Example 9>
A part of the component may be embedded in the insulator. FIGS. 21C and 21D show an example thereof, which is a modification of the substrate 6 in FIGS. 21A and 21B. FIG. 21C is a plan view of the substrate 6 of this example, and FIG. 21D is a cross-sectional view of the substrate 6 taken along the line hh of FIG. 21C. In the example of the figure, the component P1 is mounted on the insulator 5a and exposed to the outside, while the component P2 is embedded in the insulator 5a. The hole H is formed as a via hole penetrating the insulator 5b. The wiring W includes a wiring layer LY1, a wiring layer LY2, and a hole H.

<Example 10>
There may be parts mounted on different outer layers. FIG. 22A is a cross-sectional view showing an example thereof, which is a modified example of the substrate 6 in FIGS. 19A and 19B. In the example of the figure, the component P1 is mounted on the insulator 5a, and the component P2 is mounted on the insulator 5c (lower surface side). The hole Ha is formed as a via hole that penetrates the insulator 5a, and the hole Hb is formed as a via hole that penetrates the insulator 5c. The wiring W includes a wiring layer LY1, a wiring layer LY2, a wiring layer LY4, and holes Ha and Hb. The part of the wiring layer LY2 can be provided in the wiring layer LY3, or can be provided in both the wiring layers LY2 and LY3.

<Example 11>
Wiring that is entirely arranged in the outer layer and wiring that is at least partially arranged in the inner layer may be mixed. The degree of freedom of wiring may be improved. FIGS. 22B and 22C show an example thereof, which is a modification of the substrate 6 shown in FIGS. 19A and 19B. FIG. 22B is a plan view of the substrate 6 of this example, and FIG. 22C is a cross-sectional view of the substrate 6 taken along line ii of FIG. 22B.

  In the example of the figure, the wirings W1 and W2 connect the component P1 and the component P2. The holes Ha and Hb are formed as via holes penetrating the insulator 5a. The wiring W1 is entirely formed in the wiring layer LY1. The wiring W2 has a wiring layer LY1 portion, a wiring layer LY2 portion, and holes Ha and Hb.

  The wirings W1 and W2 may connect different terminals of the components P1 and P2, or may connect the same terminals. When the same terminals are connected, for example, even when the wiring W1 is connected, the signal can be transmitted through the wiring W2. In addition, the wiring W1 may be a dummy wiring that does not actually connect the terminals. In either case, even if the wiring W1 is disconnected due to fraudulent activity, signal transmission may be possible.

<Example 12>
The wiring layer in which the signal line is formed may be disposed between the plurality of wiring layers in which the ground line is formed. The durability against noise may be improved. FIGS. 23A and 23B show an example thereof, which is a modification of the substrate 6 shown in FIGS. 20A and 20B. FIG. 23A is a plan view of the substrate 6 of this example, and FIG. 23B is a cross-sectional view of the substrate 6 taken along the line j-j in FIG. In the example of the figure, a multilayer substrate having a five-layer structure of insulators 5a to 5e and a six-layer structure of wiring layers LY1 to LY6 is used.

  In the example of the figure, holes Ha and Hb penetrating the insulators 5a and 5b are formed as via holes. The wiring W has a wiring layer LY1 part, a wiring layer LY3 part, and holes Ha and Hb. The portion of the wiring layer LY1 is only the connection portion. A ground line is formed in the wiring layer LY2 and the wiring layer LY4. The ground line can be formed in a strip shape (solid paint shape).

  FIGS. 23C and 23D also show an example of this example, which is a modification of the substrate 6 of FIGS. 23A and 23B. FIG.23 (c) is a top view of the board | substrate 6 of this example, FIG.23 (d) is sectional drawing of the board | substrate 6 which follows the kk line | wire of FIG.23 (c).

  In the example of the figure, holes Hb and Hc penetrating the insulators 5a and 5b are formed as via holes. Further, holes Ha and Hd penetrating the insulators 5a to 5c are formed as via holes.

  The wirings W1 and W2 connect the component P1 and the component P2. The wiring W1 has a wiring layer LY1 portion, a wiring layer LY5 portion, and holes Ha and Hd. The portion of the wiring layer LY1 is only the connection portion. The wiring W2 has a wiring layer LY1 portion, a wiring layer LY3 portion, and holes Hb and Hc. The portion of the wiring layer LY1 is only the connection portion.

  A ground line is formed in the wiring layer LY1, the wiring layer LY4, and the wiring layer LY6. The ground line can be formed in a strip shape (solid paint shape).

<Example 13>
A plurality of parts may be connected to one part. In other words, parts having different numbers of wires may be connected. FIG. 24 shows an example thereof, and is a plan view of the substrate 6 of this example. Although a cross-sectional view is omitted, a configuration similar to that of each substrate 6 described above can be employed. In the example of the figure, components P1 to P3 are mounted on the insulator 5a. Note that at least some of the components may be embedded inside.

  The wiring W1 connects the component P1 and the component P2, the wiring W2 branches to the wiring W2a and the wiring W2b, connects the component P1, the component P2, and the component P3, and the wiring W3 connects the component P1 and the component P3. To do. The part P1 has three wires, and the parts P2 and P3 have two.

  The wiring W1 has an outer layer portion, an inner layer portion (broken line portion), and holes Ha and Hd. The holes Ha and Hd are through holes or via holes. The wirings W2, W2a, and W2b have an outer layer portion, an inner layer portion (broken line portion), and holes Hb, He, and Hf. The holes Hb, He and Hf are through holes or via holes. The wiring W3 has an outer layer portion, an inner layer portion (broken line portion), and holes Hc and Hg. The holes Hc and Hg are through holes or via holes.

  The portions existing in the inner layer of each wiring may be in the same wiring layer or in different wiring layers. Like the wiring W2, there may be no wiring that connects one component P1 and a plurality of components P2 and P3, and there may be wiring that connects one component and three or more components.

<Example 14>
Each example mentioned above can be combined suitably.

<Summary of wiring structure>
A1. The gaming table (e.g., 100) in the above embodiment is
A plurality of substrates (e.g. 3,4,726C, 734),
A plurality of harnesses (e.g., H1-H3),
A game machine equipped with
At least one of the plurality of substrates is a first substrate (for example, 726C),
At least one of the plurality of substrates is a second substrate (e.g., 3, 4),
At least one of the plurality of substrates is a third substrate (e.g., 734);
At least one of the plurality of harnesses is a first harness (for example, H1),
At least one of the plurality of harnesses is a second harness (for example, H2),
The third substrate is provided with a plurality of connectors (for example, CN1, CN2),
At least one of the plurality of connectors is a first connector (e.g. CN1),
At least one of the plurality of connectors is a second connector (e.g. CN2),
One end of the first harness is connected to the first connector,
The other end of the first harness is connected to the first substrate,
One end of the second harness is connected to the second connector,
The other end of the second harness is connected to the second substrate,
The third substrate is composed of a plurality of layers (for example, LY1 to LY4),
At least one of the plurality of layers is a first layer (for example, LY1),
At least one of the plurality of layers is a second layer (for example, LY3),
The second layer is located inside the third substrate than the first layer,
The third substrate is provided with a plurality of wirings (for example, W1 to W6),
At least one of the plurality of wirings is a first wiring (for example, W1),
The first wiring is connected to the first connector,
The first wiring is connected to the second connector,
The second layer is provided with at least a part of the first wiring.
It is characterized by that.

  According to this configuration, the influence on the first wiring due to external factors such as noise, unauthorized radio waves, and unauthorized electromagnetic waves may be reduced. Further, there are cases where it is possible to make it difficult for an unauthorized person to cut the wiring than when the wiring is a harness. In addition, since the first board and the second board are relayed and connected by the third board, the space of the game table may be used more effectively than when the harness is connected.

  The substrate may be a flexible substrate. Further, the substrate may be a substrate having at least part of transparency. In addition, the substrate may have a display (for example, LED1, LED2, CN1, etc.) relating to the substrate constituting means displayed on the back surface of the installation surface of the substrate constituting means.

A2. The gaming table (e.g., 100) in the above embodiment is
The third substrate is provided with light emitting means (for example, LED1 to LED6),
At least one of the plurality of wirings is a second wiring (for example, W2 to W5),
The first layer is provided with at least a part of the second wiring,
The second wiring is connected to the light emitting means,
The second wiring is connected to the first connector,
The light emitting means is capable of emitting light when a light emission condition is satisfied.
It is characterized by that.

  According to this configuration, since the third board capable of emitting light relays between the first board and the second board, the space of the game table can be used more effectively than the case of connecting with a harness. There is a case. In addition, since the second wiring is provided in the first layer, external noise may not easily affect the first wiring.

  The light emitting means may be, for example, an LED (single color, two colors, three colors, four colors or more), may be a lamp other than the LED, may be only one, may be two, or may be three. That's all. The lighting conditions are as follows: when the game starts, when the symbol changes, when the symbol stops, when the reach effect starts, when the jackpot starts, when the operation means is operated, when the game media is inserted, when the game media is paid out, and when the demonstration effect starts In addition, at least one of at the time of turning on the power, at the time of setting the game setting, and at the time of setting the volume may be included as at least one of the establishment requirements.

A3. The gaming table (e.g., 100) in the above embodiment is
At least a part of the third substrate is covered by a covering means (for example, 2),
The covering means is made of a material having permeability.
It is characterized by that.

  According to this configuration, it may be possible to confirm whether an illegal act has been performed on the third substrate.

A4. The gaming table (e.g., 100) in the above embodiment is
The third substrate is disposed at a position where the player can visually recognize the light emission of the light emitting means (for example, 106).
A game stand characterized by that.

  According to this configuration, the interest of the game may be improved.

A5. The gaming table (e.g., 100) in the above embodiment is
A game board (e.g., 200) that forms a game area (e.g., 124) in which a game ball can roll,
The third board is disposed adjacent to the game area.
It is characterized by that.

  According to this configuration, it may be possible to reduce the influence of noise generated by rolling of the game ball on the first wiring. As an aspect in which the third board is adjacent to the game area, for example, another member may or may not be interposed between the third board and the game area. Another member may be one or two or more. Further, the third board may have the same position in the depth direction of the game table with respect to the game area, or may be on the front side (front side) or on the rear side (back side).

A6. The gaming table (e.g., 100) in the above embodiment is
The second substrate is connected to a notification means (for example, 120),
The notification means is capable of executing a first notification when a notification condition is established,
The notification means is capable of executing a second notification when an abnormality notification condition is established,
The second notification is a notification that reports the occurrence of an abnormality.
It is characterized by that.

  According to this configuration, since the wiring of the notification means for reporting an abnormality is relayed, it is possible to make it difficult for an unauthorized person to cut the wiring than when the wiring is a harness, and the abnormality notification based on the detection of the unauthorized action is performed. Sometimes it can be done. In addition, since the influence on the first wiring due to external factors is reduced, there are cases where the first notification and the second notification by the notification means can be performed stably.

  The notification means includes, for example, sound output means (speaker), light emitting means (LED (single color, two colors, three colors, four colors or more), lamp), display means (liquid crystal, CRT, dot matrix display) , A segment indicator), a movable object, or a vibration device, or any one or more of them. Further, the number of notification means may be only one, two, or three or more.

  Notification conditions include, for example, when a game starts, when a symbol fluctuates, when a symbol stops, when a reach effect occurs, when a big hit starts, when there is an operation on the operating means, when a game medium is inserted, when a game medium is paid out, and when a demonstration effect starts In addition, at least one of at the time of turning on the power, at the time of setting the game setting, and at the time of setting the volume may be included as at least one of the establishment requirements. The abnormality notification condition is, for example, at least one of abnormality detection means (door open detection sensor, vibration detection sensor, magnetic force detection sensor, radio wave detection sensor, electromagnetic wave detection sensor, ball dish full detection sensor, abnormality detection sensor). The detection of the occurrence of abnormality may be included as at least one of the establishment requirements.

A7. The gaming table (e.g., 100) in the above embodiment is
Provided with a substrate (for example, 5, 6) composed of a plurality of substrate constituting means (for example, CN1, CN2, P1 to P3),
The substrate is composed of a plurality of layers (for example, LY1 to LY4, LY5, LY6),
At least one of the plurality of substrate constituting means is first substrate constituting means (for example, CN1, P1),
At least one of the plurality of substrate constituting means is second substrate constituting means (for example, CN2, P2),
Arranging at least part of the first wiring (for example, W1, W6, W) connecting the first substrate constituting means and the second substrate constituting means on the inner layer,
Disposing at least a part of the first wiring connecting the first substrate constituting means and the second substrate constituting means on the outer layer;
It is characterized by that.

  According to this configuration, the influence on the first wiring due to external factors such as noise, unauthorized radio waves, and unauthorized electromagnetic waves may be reduced. Further, there are cases where it is possible to make it difficult for an unauthorized person to cut the wiring than when the wiring is a harness.

A8. The gaming table (e.g., 100) in the above embodiment is
The first wiring (for example, W) is arranged in the outer layer only at the connection portion with the substrate constituting means (for example, FIG. 20).
It is characterized by that.

  According to this configuration, the protection function against the influence on the first wiring and the disconnection due to external factors may be further enhanced. In addition, repairs and repairs are not possible if they break due to internal breakage, etc., so that the clerk, carrier, etc. handle it roughly and prevent the game from being provided to the player by emergency measures. In some cases, the occurrence of malfunctions due to first aid measures can be prevented, and the reliability of the gaming machine with respect to the player can be improved.

A9. The gaming table (e.g., 100) in the above embodiment is
The first wiring (e.g., W1, W6, W) has different specifications for the inner layer portion and the outer layer portion.
It is characterized by that.

  According to this configuration, the wiring can be partially improved, the wiring design freedom can be partially improved, the protection function can be partially increased, and the conductivity can be partially increased. There is a case.

  For example, the first wiring may have a longer inner layer distance than an outer layer distance. Alternatively, the first wiring may have a shorter inner layer distance than an outer layer distance. Alternatively, the first wiring may be thicker in the inner layer than in the outer layer. Alternatively, the first wiring may have a narrower inner layer width than an outer layer width. Alternatively, the first wiring may have an inner layer area larger than an outer layer area. Alternatively, the first wiring may have an inner layer area smaller than an outer layer area.

A10. The gaming table (e.g., 100) in the above embodiment is
The first wiring (for example, W1, W6, W) has the same specifications for the inner layer portion and the outer layer portion.
It is characterized by that.

  According to this configuration, design may be facilitated.

  For example, the first wiring may have the same distance between the outer layer and the inner layer. Alternatively, the first wiring may have the same outer layer width and inner layer width. Alternatively, the first wiring may have the same outer layer area and inner layer area.

A11. The gaming table (e.g., 100) in the above embodiment is
The first wiring (for example, W1, W6, W) is an inner layer portion and an outer layer portion connected via a hole,
It is characterized by that.

  According to this configuration, the inner layer portion and the outer layer portion may be relatively easily connected. For example, the first wiring may be one in which the outer layer and the inner layer are connected through a through hole. Alternatively, the first wiring may be one in which the outer layer and the inner layer are connected by a via hole.

A12. The gaming table (e.g., 100) in the above embodiment is
At least one of the plurality of board constituting means is a circuit component.
It is characterized by that.

  According to this configuration, it may be possible to improve the protection performance of circuit component wiring.

  For example, the first substrate constituting unit may be at least one of a connector, a resistor, a capacitor, an LED, an IC, an LSI, a CPU, a ROM, a RAM, and a switch. Further, the second substrate constituting unit may be at least one of a connector, a resistor, a capacitor, an LED, an IC, an LSI, a CPU, a ROM, a RAM, and a switch.

A13. The gaming table (e.g., 100) in the above embodiment is
The covering means is partially lens-shaped,
It is characterized by that.

  According to this configuration, it may be possible to further improve the interest of the game or facilitate confirmation of fraud.

A14. The gaming table (e.g., 100) in the above embodiment is
At least one of the plurality of substrate constituting means is third substrate constituting means (for example, P3),
A second wiring connected to the first substrate constituting means is connected to the third substrate constituting means;
It is characterized by that.

  According to this configuration, it may be possible to provide a plurality of wirings on one substrate.

A15. The gaming table (e.g., 100) in the above embodiment is
One of the plurality of layers is a first layer;
One of the plurality of layers is a second layer;
The first layer is provided with at least a part of the second wiring,
The second layer is provided with at least a part of the second wiring.
It is characterized by that.

  According to this configuration, the protection function for a plurality of wirings may be improved.

A16. The gaming table (e.g., 100) in the above embodiment is
The first substrate constituting means (for example, P1) is different from the second substrate constituting means (for example, P2) in the number of wires.
It is characterized by that.

  According to this configuration, it may be possible to provide substrate configuration means having different numbers of wires on one substrate.

A17. The gaming table (e.g., 100) in the above embodiment is
In the second layer, only the first wiring is arranged.
It is characterized by that.

  According to this configuration, there are cases where the design of the wiring can be facilitated and the protection function of the first wiring can be improved.

A18. The gaming table (e.g., 100) in the above embodiment is
At least one of the plurality of wirings is a third wiring (for example, W6),
The third wiring is connected to the first connector,
The third wiring is connected to the second connector,
The first layer is provided with at least a part of the third wiring.
It is characterized by that.

  According to this configuration, it may be easy to secure a space for arranging the third wiring.

A19. The gaming table (e.g., 100) in the above embodiment is
In the second layer, the first wiring and the third wiring are arranged.
It is characterized by that.

  According to this configuration, there are cases where the design of wiring can be facilitated and the degree of freedom of other wiring can be increased.

A20. The gaming table (e.g., 100) in the above embodiment is
In the second layer, only the first wiring and the third wiring are arranged.
It is characterized by that.

  According to this configuration, there are cases where the design of wiring can be facilitated and the degree of freedom of other wiring can be increased.

A21. The gaming table (e.g., 100) in the above embodiment is
At least one of the plurality of layers is a third layer (e.g., LY2),
The third layer is located inside the third substrate than the first layer,
The third layer is provided with at least a part of the third wiring.
It is characterized by that.

  According to this configuration, the short-circuit prevention performance between the first wiring and the third wiring may be improved.

A22. The gaming table (e.g., 100) in the above embodiment is
The third layer is arranged only for the third wiring,
It is characterized by that.

  According to this configuration, there are cases where the design of wiring can be facilitated and the degree of freedom of other wiring can be increased.

A23. The gaming table (e.g., 100) in the above embodiment is
At least one of the plurality of layers includes one or more of a signal line, a power line, and a ground line.
It is characterized by that.

  According to this configuration, the protection performance of various wirings may be improved.

  For example, one or more of a signal line, a power supply line, and a ground line is disposed on the first layer. Alternatively, in the second layer, any one or more of a signal line, a power supply line, and a ground line are arranged. Alternatively, in the third layer, one or more of a signal line, a power supply line, and a ground line are arranged. Alternatively, one or more of a signal line, a power supply line, and a ground line are arranged in one or two layers adjacent to the second layer. Note that the number of inner layers may be one, two, or three or more. The first wiring may be arranged in a plurality of inner layers.

<Confirmation promotion structure>
A structure that facilitates confirmation of a site requiring confirmation for a clerk of an amusement store will be described. In the case of the present embodiment, the substrate component on the liquid crystal control substrate 680 is set as the confirmation required portion, but is not limited thereto.

  As described with reference to FIG. 2, the liquid crystal control board 680 is accommodated in the liquid crystal control board case 682 and disposed on the back surface of the pachinko machine 100. The liquid crystal control board case 682 is surrounded on its four sides by other structures (tank rail 154, dispensing device 152, main control board case 158, first sub control board case 162). Therefore, although the inside of the liquid crystal control board case 682 is relatively easy to visually recognize from the back side to the front side of the pachinko machine 100, the inside visibility of the liquid crystal control board case 682 from the top, bottom, left and right sides is not always good. Therefore, in the present embodiment, in the back-to-front direction of the pachinko machine 100, the visibility inside the liquid crystal control board case 682 is at least partially deteriorated so that the confirmer can perform visual confirmation from a plurality of angles. Is. Hereinafter, in each figure, arrows X, Y, and Z indicate the left-right direction, depth direction (front-rear direction), and vertical direction of the pachinko machine 100, respectively.

  FIG. 25 is an explanatory diagram of the liquid crystal control board 680. The liquid crystal control substrate 680 is composed of a plurality of substrates. Specifically, the liquid crystal control board 680 is roughly divided into a main board 10 and a ROM board 11, which are connected to each other. FIG. 26A is a plan view showing the surface of the main substrate 10, and FIG. 26B is a plan view showing the surface of the ROM substrate 11. FIG. 27 is a cross-sectional view taken along the line l-l in FIG. 26A, and is a cross-sectional view in a state where the main substrate 10 and the ROM substrate 11 are combined and accommodated in the liquid crystal control substrate case 682.

  The CPU 704, ROM 706, VDP 710, and crystal oscillators 714A and 714B described above are mounted on the main board 10. The RAM 708 and VRAM 718 are mounted on the back surface. Further, a connector 21 to which a harness from an external device is connected and a connector 22 to which the ROM substrate 11 is connected are mounted on the main substrate 10. The connector 22 is fixed to the main board 10 and has a function of supporting the ROM board 11. Resistors 25 and 26, capacitors 23 and 24, and light emitting elements 31 to 34 are also mounted on the main substrate 10. Here, the light emitting elements 31 to 34 are LEDs.

  On the main board 10, an identification display PI indicating the mounting position of each component is formed. The identification display PI is formed by printing, for example. The identification display PI of the connector 21 is displayed as CN1, and the identification display PI of the CPU 704 is displayed as IC1. In some cases, the matching between the identification display PI and the mounted component can be confirmed. In addition, the main board 10 and the ROM board 11 may be provided with a display relating to the management number of the board, thereby confirming the consistency between the two.

  The light emitting elements 31 to 34 emit light when a predetermined light emitting condition is satisfied. Here, the following issuance conditions are assumed. The light emitting element 31 emits light every time the timer interrupt process is performed. Apparently, it appears to be always lit after the power is turned on. In the present embodiment, the light emitting element 31 is mainly assumed as a confirmation required part.

  The light emitting element 32 is lit when the software is reset. The light emitting element 33 is lit when the hardware is reset. It is lit when a store clerk of the amusement store performs a reset operation. The light emitting element 34 is turned on during debugging. Therefore, it is not lit when the store is open. Although the number of light emitting elements is four here, the number is not limited. Further, the number of light emitting elements (here 31 to 33) that can be turned on during normal business may be more, less, or the same as the number of light emitting elements that are not turned on (here 34).

  The CGROM 716 already described is mounted on the ROM substrate 11. A connector or pin that can be attached to and detached from the connector 22 is provided on the rear surface of the ROM substrate 11, and the ROM substrate 11 can be separated from the main substrate 10.

  As shown in FIG. 27, the main board 10 and the ROM board 11 are fastened with bolts, nuts and the like in parallel to each other via a plurality of spacers 12. The main board 10 and the ROM board 11 are separated from each other in the normal direction, and the normal direction coincides with the back-to-front direction of the pachinko machine 100.

  When viewed in the normal direction of the main board 10 and the ROM board 11, the main board 10 partially overlaps the ROM board 11. In the present embodiment, a part of the main board 10 overlaps with the ROM board 11, but the whole may overlap. Further, when viewed from the ROM substrate 11, the entire ROM substrate 11 overlaps the main substrate 10, but may be a part.

  Between the main board 10 and the ROM board 11, the capacitor 24, the crystal oscillator 714A, the resistor 26, the connector 22, the light emitting elements 31 to 34, and the identification display PI thereof are located. In the case of this embodiment, the ROM substrate 11 is a structure that entirely constitutes a non-transmissive portion. For this reason, when viewed from the back side to the front side of the pachinko machine 100, the ROM substrate 11 is obstructed and the visibility of these components is reduced. That is, the ROM substrate 11 functions as a visibility lowering unit.

  The visibility will be described with reference to FIG. 27, focusing on the light-emitting element 31 that is a site to be confirmed. Here, the liquid crystal control board 680 is fixed to the mounting portion 682a (for example, the back of the game board) of the pachinko machine 100 while being housed in the liquid crystal control board case 682. The liquid crystal control board case 682 accommodates both the main board 10 and the ROM board 11. The liquid crystal control board case 682 is configured by fixing an upper case 6821 and a lower case 6822 to each other, and the lower part of the main board 10 is attached to the case 6822 as a board attachment portion. The liquid crystal control board case 682 is made of a light-transmitting material (for example, acrylic or glass) such as a transparent member or a translucent member, and the inside is visible from the outside.

  Referring to FIG. 27, when the light emitting element 31 is viewed from the normal direction (D1) of the main substrate 10 and the ROM substrate 11, the ROM substrate 11 becomes an obstacle and the light emitting element 31 (particularly, the light emitting portion) is visually recognized. It can be difficult. Therefore, the confirmer views the light emitting element 31 by changing the viewing angle to, for example, the oblique direction D2 or D3. The light emitting element 31 is still difficult to see in the D2 direction, but at least part of the light from the light emitting element 31 is visible due to light leakage. If the direction is D3, the light emitting element 31 itself (particularly, the light emitting portion) can be seen. As already described, the liquid crystal control board case 682 is surrounded on its four sides by other configurations (tank rail 154, dispensing device 152, main control board case 158, first sub control board case 162). It is structurally difficult to view the light-emitting element 31 from the side, directly above, or directly below. However, it is also possible to adopt a configuration in which the light emitting element 31 can be seen from any one of right side, right above, and right below.

  Now, since the visibility of the light emitting element 31 is poor from the D1 direction, which is a general confirmation direction, the confirmer will naturally visually check the light emitting element 31 from multiple directions. May be more cautious. In addition, there are cases where security can be improved by performing visual confirmation from a plurality of angles, for example, it may be possible to discover that an unauthorized device is installed.

  Although the light emitting element 31 is difficult to see from the D1 direction, for example, the CPU 704 and the like and parts that are not positioned between the main board 10 and the ROM board 11 and the identification display PI are in the D4 direction (parallel to the D1 direction but the viewpoint is different). May be easy to see. Moreover, when the light emitting element 31 emits light, the surroundings may become bright. When the periphery of the light emitting element 31 of the pachinko machine 100 installed in a relatively dark place is confirmed, the visibility may be improved by including the CPU 704, the VDP 710, and the like in the range where this light reaches. In addition, the space between the main board 10 and the ROM board 11 tends to be dark, but depending on the light of the light emitting element 31, other components (for example, a crystal oscillator 714A) between the main board 10 and the ROM board 11 and The identification display PI may also be easier to see when viewed from the D3 direction.

  The confirmation promoting structure is not limited to the examples of FIGS. 25 to 27, and various configurations can be adopted. Hereinafter, description will be made sequentially.

<Example 1>
Although there is no direction in which the light emitting element 31 itself (at least the light emitting portion) can be seen, the leaking light that is at least part of the light from the light emitting element 31 may be visible. 28 and 29 show an example thereof. FIG. 28 is a plan view of the main board 10 of this example, and FIG. 29 is a cross-sectional view taken along the line m-m in FIG. In this example, the positions of the light emitting elements 31 to 34 are moved relative to the examples of FIGS. 25 to 27, moved slightly upward, and are located behind the central portion in the vertical direction of the ROM substrate 11. For this reason, as shown in FIG. 29, it may be difficult to see the light emitting element 31 not only in the D2 direction but also in the D3 direction.

  However, the light emission confirmation itself of the light emitting element 31 may be possible from the leaked light. Further, the CPU 704 and the like may be visible from the D4 direction. Further, as described above, the light from the light emitting element 31 may brighten the surroundings and improve the visibility.

<Another example 2>
The visibility of a plurality of different types of parts may be reduced. 30 and 31 show an example thereof. 30 is a plan view of the main board 10 of this example, and FIG. 31 is a cross-sectional view taken along the line nn of FIG. In this example, the CPU 704 is also located between the main board 10 and the ROM board 11. The visibility of the light emitting element 31 is the same as in the examples of FIGS.

  The visibility of the CPU 704 may be difficult to see in the directions D1 and D3, and the CPU 704 may be visible in the direction D2. The light of the light emitting element 31 may be reflected around (for example, the back surface of the ROM substrate 11) to brighten the periphery of the CPU 704, and the CPU 704 and its identification display PI may be easy to see.

<Another example 3>
It suffices that at least a part of the confirmation required portion is located between the main board 10 and the ROM board 11. FIG. 32 shows an example. FIG. 32 is a plan view of the main board 10 of this example. When viewed in the normal direction of the main substrate 10 and the ROM substrate 11, only half of the light emitting element 31 is located between the main substrate 10 and the ROM substrate 11. Also in this configuration, the entire light emitting part of the light emitting element 31 is difficult to see from the front, and the entire light emitting part of the light emitting element 31 is easy to see obliquely. There are cases where you can.

  It is also possible to adopt a configuration in which a part of the plurality of light emitting elements 31 to 34 is located between the main board 10 and the ROM board 11 and the rest is not located between the main board 10 and the ROM board 11. is there. The number of light emitting elements positioned between the main substrate 10 and the ROM substrate 11 may be the same as or different from the number of light emitting elements that are not positioned.

  FIG. 33 is a plan view of the main board 10 according to another embodiment. When viewed in the normal direction of the main board 10 and the ROM board 11, in addition to the light emitting element 31, only half of the CPU 704 is located between the main board 10 and the ROM board 11.

<Another example 4>
In each of the above examples, the liquid crystal control substrate 680 is composed of two substrates, but may be composed of three or more substrates. FIG. 34 shows an example. FIG. 34 is a plan view of the main board 10 of this example. A substrate 13 indicated by a broken line is added. Similar to the ROM substrate 11, the substrate 13 is a structure that is arranged in parallel with the main substrate 10 and is spaced apart from the main substrate 10 in the normal direction thereof, and is entirely a non-transmissive portion. The separation distance in the normal direction between the main substrate 10 and the ROM substrate 11 and the separation distance in the normal direction between the main substrate 10 and the substrate 13 may be the same or different.

  In this example, a part of the CPU 704 is located between the main board 10 and the ROM board 11, and another part of the CPU 704 is located between the main board 10 and the board 13. That is, the substrate 13 also functions as a visibility lowering unit. In this way, a plurality of substrates may be used as the visibility lowering means. Here, an example in which the visibility of the CPU 704 is lowered by the ROM substrate 11 and the substrate 13 has been described, but the light emitting element 31 may be targeted. That is, a part of the light emitting element 31 (for example, a part of the light emitting part) is located between the main substrate 10 and the ROM substrate 11, and another part of the light emitting element 31 (for example, another part of the light emitting part). It may be located between the main board 10 and the board 13.

<Example 5>
It is good also considering a structure other than a board | substrate as a visibility fall means. FIG. 35 is a sectional view showing an example. In the example of the figure, the main board 10 is reversed and attached to the lower case 6822 of the liquid crystal control board case 682. Therefore, the attachment portion 682a functions as a structure as a visibility lowering unit. In the example of the figure, the light emitting unit of the light emitting element 31 and the CPU 704 may be difficult to visually recognize itself, but the light of the light emitting element 31 may be visible from the leaking light. In the case of this example, the liquid crystal control substrate 680 can also be configured from a single substrate.

  FIG. 36 is a cross-sectional view of this example of another aspect. As a visibility lowering means, a seal 14 is provided on a liquid crystal control board case 682.

  The seal 14 is provided at a position facing the site requiring confirmation. In the example of the figure, it is arranged at a portion facing the CPU 704 and the light emitting element 31. The seal 14 may be any one as long as it reduces the translucency of the liquid crystal control board case 682 or makes it difficult to visually recognize the confirmation required portion, and may be any of a transparent seal, a translucent seal, and an opaque seal. .

  Further, instead of sticking the seal 14, at least a part of the liquid crystal control substrate case 682 itself is a non-transmissive portion (for example, opaque) at a position facing a confirmation required site, or unevenness is formed. Thus, it is possible to make it difficult to visually recognize the confirmation site.

<Example 6>
The main board 10 and the ROM board 11 may be housed in different board cases. FIG. 37 is a sectional view showing an example. In the example shown in the figure, the main substrate 10 is accommodated in the liquid crystal control substrate case 682, and the ROM substrate 11 is accommodated in the liquid crystal control substrate case 15. The CPU 704 and the light emitting element 31 are located between the main board 10 and the ROM board 11, and the ROM board 11 functions as a visibility lowering unit.

  The liquid crystal control board case 15 is formed by fixing an upper case 15a and a lower case 15b to each other. The liquid crystal control board case 15 is fixed on the liquid crystal control board case 682, but a configuration in which the liquid crystal control board case 15 is fixed to the attachment portion 682a can also be adopted. The liquid crystal control substrate case 15 may be made of a light-transmitting material or a material not having a light-transmitting property, like the liquid crystal control substrate case 682. Further, the liquid crystal control board case 15 may have a non-transmissive portion at least in part.

  Also in this example, it may be possible to prompt the confirmer to visually confirm from a plurality of angles. However, the liquid crystal control board case 15 may have a low light reflectance of the light emitting element 31, and in terms of the function of illuminating the periphery of the light emitting element 31, the liquid crystal control board case 682 shown in FIG. 11 may also be better accommodated. Further, when the liquid crystal control board case 15 together with the ROM board 11 is removed from the liquid crystal control board case 682, visual confirmation from a plurality of angles may not be performed.

<Example 7>
Another example of the confirmation promoting structure will be described with reference to FIG. FIG. 38A is a cross-sectional view showing another example of the confirmation promoting structure. FIG. 38A illustrates the substrate 40, the member 41, the light emitting elements 43A and 43B, and the substrate components 44A and 44B. The light emitting elements 43A and 43B may be collectively referred to as the light emitting element 43 when referring to one light emitting element. Similarly, when the substrate components 44A and 44B are collectively referred to, or when referring to one substrate component, it may be referred to as a substrate component 44.

  The substrate 40 is a substrate on which the light emitting element 43 and the substrate component 44 are mounted, and corresponds to the substrate 10 in the example of FIGS. 25 to 37 described above. The substrate 40 may be accommodated in a substrate case and attached to an attachment portion such as the back surface of the pachinko machine 100.

  Both the light emitting element 43 and the board | substrate component 44 are board | substrate components of the board | substrate 40, and the light emitting element 43 is LED here. The board component 44 is, for example, a connector, resistor, capacitor, LED, IC, LSI, CPU, ROM, RAM, switch, or identification display. The identification display is, for example, a display related to any of the board components of the board 40, a display made of continuous lines or broken lines indicating the arrangement positions of the board components, and a display made of continuous lines or broken lines surrounding the board components. And a display related to the management number of the substrate 40.

  In the case of the example in FIG. 38A, the two light emitting elements 43A and 43B are main confirmation sites. However, the number of light emitting elements to be confirmed may be one, or three or more. In this example, the substrate component 44 is not an indispensable part to be confirmed, but may be a part to be confirmed.

  The member 41 is configured to function as a visibility lowering unit. In the example of FIGS. 25 to 37 described above, the member 41 is attached to the ROM substrate 11, the substrate 13, the mounting portion 682 a, the seal 14, or the liquid crystal control substrate case 682. Equivalent to. In the case of the example in FIG. 38A, the member 41 is a plate-like structure whose whole is a non-transmissive portion, and is, for example, a circuit board different from the board 40. Part of the member 41 may be a non-transmissive portion. When the member 41 is a circuit board, it is possible to mount a board component, and the board component is, for example, a connector, resistor, capacitor, LED, IC, LSI, CPU, ROM, RAM, switch, identification display, etc. is there. The identification display is, for example, a display related to any of the board components, a display related to the management number of the board 40, or the like.

  The member 41 is arranged in parallel with the substrate 40 by a support member (not shown). The support member (not shown) may be a member that connects the substrate 40 and the member 41, or may be a member that connects the member 41 with a configuration (for example, a substrate case) other than the substrate 40. The normal direction of the substrate 40 and the member 41 (the direction perpendicular to the substrate surface) coincides with the Y direction.

  The member 41 has a size that overlaps the entire substrate 40 when viewed from the normal direction of the substrate 40 (D11 direction). The member 41 may have a shape that includes the outer shape of the substrate 40 or the same shape as the outer shape of the substrate 40.

  The light emitting element 43 and the substrate component 44 are disposed between the substrate 40 and the member 41. The light emitting element 43 and the substrate component 44 are arranged side by side in the Z direction, and the substrate component 44A is located on the outermost side of the light emitting element 43A. The substrate component 44B is disposed between the light emitting element 43A and the light emitting element 43B. The light emitting element 43B is disposed at the bottom.

  Now, when the board 40 is viewed from the back side to the front side of the pachinko machine 100, the member 41 may be obstructed and the visibility of the components on the board 40 may decrease.

  When attention is paid to the visibility of the light emitting element 43 that is a confirmation required part, when viewed from the normal direction (D11 direction) of the substrate 40, the member 41 becomes an obstacle and the light emitting elements 43A and 43B (particularly, the light emitting portion) are visually recognized. It can be difficult to do. Therefore, the confirmer changes the viewing angle to, for example, the oblique direction D12 or D13, and sees the light emitting elements 43A and 43B. In the D12 direction, the light emitting element 43A is visible, but the light emitting element 43B may be difficult to visually recognize. Conversely, in the direction D13, the light emitting element 43B is visible, but the light emitting element 43A may be difficult to visually recognize. Therefore, confirmation in both directions of the D12 direction and the D13 direction can be promoted. Thus, the light emitting element 43 is visually confirmed from multiple directions. For example, the lighting of the light emitting element 43 may be confirmed more carefully. In addition, there are cases where security can be improved by performing visual confirmation from a plurality of angles, for example, it may be possible to discover that an unauthorized device is installed. In addition, the substrate component 44 may be visible and may be confirmed.

  In FIG. 38A, a broken line arrow indicates light emitted from the light emitting element 43. When viewed from the normal direction (D11 direction) of the substrate 40, as described above, the light emitting element 43 itself may be difficult to visually recognize, but part of the light from the light emitting element 43 may be visible. For example, the light from the light emitting element 43 </ b> A may be visible as it leaks upward from the gap between the substrate 40 and the member 41. Further, for example, the light from the light emitting element 43 </ b> B may be visible by leaking downward from the gap between the substrate 40 and the member 41. Such leaked light brightens the surroundings of the substrate 40 and the member 41, and the surrounding configuration may be confirmed.

  A part of the light of the light emitting element 43A reaches the substrate component 44A, and the substrate component 44A and its surroundings may become bright. Part of the light from the light emitting element 43A and part of the light from the light emitting element 43B reach the substrate component 44B, and the substrate component 44B and its surroundings may become bright. For this reason, the board component 44A and the board component 44B may be easy to see, and the confirmation thereof may be easy. Further, if one of the light emitting element 43A and the light emitting element 43B emits light, the substrate component 44B and its surroundings may become bright, and the substrate component 44B may be easily confirmed.

  When viewed from the D12 direction due to the arrangement of the light emitting element 43 and the substrate component 44 in the Z direction, the confirmer, for example, the substrate component 44A → the light emitting element 43A. . . When viewed from the direction D13, for example, the light emitting element 43B → the substrate component 44B. . . It may be visually recognized in the order. Depending on the visual confirmation direction, the order of the parts to be confirmed or the type of the parts positioned on the front side may be different, so it may be easy to confirm whether the arrangement of the parts is correct (whether tampered).

  In this example, the light emitting element 43 and the substrate component 44 are configured to be visible from both the upward oblique direction (D12 direction) and the downward oblique direction (D13 direction). You may comprise so that other structures may be arrange | positioned and it can visually recognize only from the other side. Further, the light emitting element 43 and the substrate component 44 may be configured to be visible from both the right oblique direction and the left oblique direction, and another structure is arranged on either side. You may comprise so that it can visually recognize only from the other side. Moreover, you may comprise so that visual recognition is possible only from the direction of 1 or several of up-down, right-and-left.

<Example 8>
In the example of FIG. 38A, the member 41 has a size that overlaps the entire substrate 40 when viewed from the normal direction of the substrate 40 (D11 direction). You may have. FIG. 38B shows an example.

  In the example of FIG. 38B, an example is shown in which the member 41 does not overlap with the upper portion of the substrate 40 but has a size that overlaps with the middle portion and the lower portion. The light emitting element 43 and the substrate component 44 are disposed between the substrate 40 and the member 41 at the portion where the substrate 40 and the member 41 overlap, and the other example 8 exhibits the same effect as the seventh example. There is.

<Example 9>
In the example of FIGS. 38A and 38B, the light emitting element 34 is difficult to visually recognize when viewed from the normal direction of the substrate 40 (D11 direction), but a part of the light emitting element 34 is visually recognized. It may be possible. FIG. 38 (c) shows an example.

  In FIG. 38C, a space R <b> 1 indicates a space that is the shadow of the member 41 when the member 41 is projected onto the substrate 40 in the normal direction of the substrate 40. On the other hand, the space R <b> 2 indicates a space that is a shadow of the member 41 when the member 41 is projected onto the substrate 40 in a direction inclined with respect to the normal direction of the substrate 40.

  In the case of the configuration of FIG. 38C, when viewed from the normal direction (D11 direction) of the substrate 40, a part of the light emitting portion of the light emitting element 43 is visible. However, since the entire light emitting unit may be difficult to visually recognize, it is possible to prompt the confirmer to view the light emitting element 43 from another direction. Note that the substrate component 44 may also be visible and may be confirmed. Further, since the substrate component 44 is located within the range where the light from the light emitting element 43 can reach, the substrate component 44 and its surroundings may become bright and the substrate component 44 may be easily seen.

  In the case of the configuration of FIG. 38C, when viewed from the D12 direction, the light emitting element 43 may be difficult to visually recognize because it is located in the space R2. Therefore, it may be possible to prompt the confirmer to see the light emitting element 43 from another direction.

  As shown in the space R1 or the space R2, when at least a part of the light-emitting element 43 is located between the substrate 40 and the member 41 when viewed from a specific direction, the light-emitting element is viewed from multiple directions to the confirmer. 43 may be visually confirmed. That is, the example of FIG. 38C is also an example in which at least a part of the light emitting element 43 is located between the substrate 40 and the member 41, and at least a part of the substrate component 44 is the substrate. It is also an example located between 40 and the member 41. In the case where a part of the member 41 is a non-transmissive part, the confirmer visually confirms the light-emitting element 43 from multiple directions when at least a part of the light-emitting element 43 is located between the substrate 40 and the non-transmissive part. There are cases where it is possible. When the light emitting element 43 is located between the virtual surface VS1 including the surface of the substrate 40 and the virtual surface VS2 including the surface of the member 41, at least the light emitting element 43 when viewed from a specific direction. It is possible to configure a part to be located between the substrate 40 and the member 41. The same applies to the position of the substrate component 44.

<Example 10>
In the example of FIG. 38C, when viewed from the normal direction of the substrate 10 and the member 41 (D11 direction), a part of the light emitting element 34 is visible. It may be visible. FIG. 38 (d) shows an example. In FIG. 38D, a space R <b> 1 indicates a space that is the shadow of the member 41 when the member 41 is projected onto the substrate 40 in the normal direction of the substrate 40. On the other hand, the space R <b> 2 indicates a space that is a shadow of the member 41 when the member 41 is projected onto the substrate 40 in a direction inclined with respect to the normal direction of the substrate 40.

  The example of FIG. 38D is also an example in which the light emitting element 43 is located between the virtual surface VS1 and the virtual surface VS2. The light emitting element 43 and the substrate component 44 are located in the space R2. Therefore, also in the example of FIG. 38D, at least a part of the light emitting element 43 is located between the substrate 40 and the member 41. In particular, the entire light emitting portion of the light emitting element 43 and the substrate component 44 are located between the substrate 40 and the member 41.

  In the case of the configuration in FIG. 38D, when viewed from the D12 direction, since the light emitting element 43 is positioned in the space R2, it may be difficult to visually recognize the light emitting element 43. Therefore, it may be possible to prompt the confirmer to see the light emitting element 43 from another direction.

  In the case of the configuration of FIG. 38D, when viewed from the normal direction (D11 direction) of the substrate 40, the entire light emitting portion of the light emitting element 43 may be visible. In addition, the substrate component 44 may be visible and may be confirmed. However, it may be difficult to view from the D11 direction due to other configurations or the structure of the island where the pachinko machine 100 is installed.

  In addition, since the board | substrate component 44 is located in the range which the light of the light emitting element 43 reaches | attains, the board | substrate component 44 and its periphery become bright and the board | substrate component 44 may be easy to see.

<Example 11>
In the example of FIGS. 38A to 38D, the substrate 40 and the member 41 overlap each other when viewed from the normal direction of the substrate 40 (D11 direction). However, the substrate 40 may not overlap. FIG. 38 (e) shows an example.

  In FIG. 38E, a space R <b> 2 indicates a space that is the shadow of the member 41 when the member 41 is projected onto the substrate 40 in a direction inclined with respect to the normal direction of the substrate 40.

  The example of FIG. 38E is also an example in which the light emitting element 43 is located between the virtual surface VS1 and the virtual surface VS2. The light emitting element 43 and the substrate component 44 are located in the space R2. Therefore, also in the example of FIG. 38D, at least a part of the light emitting element 43 is located between the substrate 40 and the member 41. In particular, the entire light emitting portion of the light emitting element 43 and the substrate component 44 are located between the substrate 40 and the member 41.

  In the case of the configuration in FIG. 38D, when viewed from the D12 direction, since the light emitting element 43 is positioned in the space R2, it may be difficult to visually recognize the light emitting element 43. Therefore, it may be possible to prompt the confirmer to see the light emitting element 43 from another direction. Depending on the viewing direction, the substrate component 44 may also be visible, and the confirmation may be possible.

  In addition, since the board | substrate component 44 is located in the range which the light of the light emitting element 43 reaches | attains, the board | substrate component 44 and its periphery become bright and the board | substrate component 44 may be easy to see.

<Example 12>
In the example of FIG. 38, the case where the substrate 40 and the member 41 are parallel is illustrated, but they may be non-parallel. FIG. 39A shows an example. In the example shown in the figure, the member 41 is inclined with respect to the substrate 40. In the case of the example in the figure, the inclination angle of the member 41 with respect to the substrate 40 is 45 degrees.

  In FIG. 38D, a space R <b> 1 indicates a space that is the shadow of the member 41 when the member 41 is projected onto the substrate 40 in the normal direction of the substrate 40. The light emitting element 43 and the substrate component 44 are located in the space R1, and therefore, also in the example of FIG. 39A, at least a part of the light emitting element 43 is located between the substrate 40 and the member 41. In this example, the entire light emitting portion of the light emitting element 43 and the substrate component 44 are located between the substrate 40 and the member 41.

  In the case of the configuration of FIG. 39A, since the light emitting element 43 is located in the space R1 when viewed from the D11 direction, it may be difficult to visually recognize the light emitting element 43. Therefore, it may be possible to prompt the confirmer to see the light emitting element 43 from another direction. Depending on the viewing direction, the substrate component 44 may also be visible, and the confirmation may be possible.

  In addition, since the board | substrate component 44 is located in the range which the light of the light emitting element 43 reaches | attains, the board | substrate component 44 and its periphery become bright and the board | substrate component 44 may be easy to see.

  Next, also in the example of FIG. 39B, the member 41 is inclined with respect to the substrate 40. In the case of the example in the figure, the inclination angle of the member 41 with respect to the substrate 40 is 90 degrees.

  In FIG. 39B, a space R <b> 2 indicates a space that is the shadow of the member 41 when the member 41 is projected onto the substrate 40 in a direction inclined with respect to the normal direction of the substrate 40. The light emitting element 43 and the substrate component 44 are located in the space R2. Therefore, also in the example of FIG. 39B, at least a part of the light emitting element 43 is located between the substrate 40 and the member 41. In this example, the entire light emitting portion of the light emitting element 43 and the substrate component 44 are located between the substrate 40 and the member 41.

  In the case of the configuration of FIG. 39B, since the light emitting element 43 is located in the space R2 when viewed from the D13 direction, it may be difficult to visually recognize the light emitting element 43. Therefore, it may be possible to prompt the confirmer to see the light emitting element 43 from another direction. Depending on the viewing direction, the substrate component 44 may also be visible, and the confirmation may be possible. Note that the light of the light emitting element 43 may leak from the gap between the substrate 40 and the member 41 as shown by the broken line arrow in the figure, and a part of the light of the light emitting element 43 when viewed from the D13 direction. May be visible.

  In the case of the configuration shown in FIG. 39B, when viewed from the normal direction (D11 direction) of the substrate 40, the entire light emitting portion of the light emitting element 43 may be visible. In addition, the substrate component 44 may be visible and may be confirmed. However, it may be difficult to view from the D11 direction due to other configurations or the structure of the island where the pachinko machine 100 is installed.

  In addition, since the board | substrate component 44 is located in the range which the light of the light emitting element 43 reaches | attains, the board | substrate component 44 and its periphery become bright and the board | substrate component 44 may be easy to see.

  Next, also in the example of FIG. 39C, the member 41 is inclined with respect to the substrate 40. In the case of the example in the figure, the inclination angle of the member 41 with respect to the substrate 40 is 90 degrees.

  In FIG. 39C, a space R <b> 2 indicates a space that is a shadow of the member 41 when the member 41 is projected onto the substrate 40 in a direction inclined with respect to the normal direction of the substrate 40. The light emitting element 43 and the substrate component 44 are located in the space R2, and therefore, in the example of FIG. 39C, at least a part of the light emitting element 43 is located between the substrate 40 and the member 41. In this example, the entire light emitting portion of the light emitting element 43 and the substrate component 44 are located between the substrate 40 and the member 41.

  In the case of the configuration in FIG. 39C, when viewed from the D13 direction, the light emitting element 43 may be difficult to visually recognize because it is located in the space R2. Therefore, it may be possible to prompt the confirmer to see the light emitting element 43 from another direction. Depending on the viewing direction, the substrate component 44 may also be visible, and the confirmation may be possible.

  The example of FIG. 39C differs from the example of FIG. 39B in that the end portion of the member 41 is in contact with the substrate 40. Therefore, the light from the light emitting element 43 may not leak as in the example of FIG. 39B, and the light from the light emitting element 43 may be difficult to see when viewed from the D13 direction.

  In the case of the configuration of FIG. 39C, when viewed from the normal direction (D11 direction) of the substrate 40, the entire light emitting portion of the light emitting element 43 may be visible. In addition, the substrate component 44 may be visible and may be confirmed. However, it may be difficult to view from the D11 direction due to other configurations or the structure of the island where the pachinko machine 100 is installed.

  In addition, since the board | substrate component 44 is located in the range which the light of the light emitting element 43 reaches | attains, the board | substrate component 44 and its periphery become bright and the board | substrate component 44 may be easy to see.

<Example 13>
Although LED was illustrated as the light emitting elements 31-34, 43, other than LED may be sufficient if it is an element which can light-emit. When the light emitting elements 31 to 34 and 43 are LEDs, they may be surface mounted type or through hole mounted type, and may be full color or single color. Moreover, 7 segment LED may be sufficient. Hereinafter, a specific example is illustrated.

  40A is a plan view in the case where a surface-mount type full color LED is used as the light emitting element 43, and FIG. 40B is a cross-sectional view of the state mounted on the substrate 40. FIG. The full color LED includes a light emitting element 43B, a light emitting element 43G, and a light emitting element 43R whose emission colors are blue, green, and red, respectively. As a light emitting element as a confirmation required part, the entire full color LED may be regarded as one light emitting element, or each of the light emitting element 43B, the light emitting element 43G, and the light emitting element 43R may be regarded as one light emitting element.

  FIG. 40C is a plan view when a surface-mount type monochromatic LED is used as the light emitting element 43, and FIG. 40D is a cross-sectional view of the state mounted on the substrate 40. In the case of a single-color LED, there is one light-emitting element, and the entire single-color LED is regarded as one light-emitting element as a light-emitting element as a confirmation required part.

  In the case of a surface mount type LED, as shown in FIG. 40B and FIG. 40D, the whole is located on one side of the substrate 40. Therefore, it is possible to position the entire light emitting element between the substrate 40 and the member 41.

  FIG. 40 (e) shows a cross-sectional view of a state where the light emitting element 43 is mounted on the substrate 40 when a through-hole mounting type (bullet type) full color LED is used. FIG. 40 (f) shows a cross-sectional view of a state where the light emitting element 43 is mounted on the substrate 40 when a through-hole mounting type (bullet type) single color LED is used.

  In the case of a through-hole mounting type LED, the configuration can be broadly divided into a light emitting portion 43a and a lead wire 43b. Unlike the surface-mount type LED, the LED 40 may not be entirely located on one side of the substrate 40, the light emitting portion 43 a passes on one side, and the lead wire 43 b passes through the substrate 40 on the other side. There may be a protruding configuration. In the case of a through-hole mounting type LED, at least a part of the light emitting portion 43 a may be positioned between the substrate 40 and the member 41, and the lead wire 43 b is positioned between the substrate 40 and the member 41. There is no need.

  Similar to the surface-mounting full-color LED, the through-hole mounting type full-color LED has three light-emitting elements (not shown in FIG. 40E) whose emission colors are blue, green, and red, respectively. As a light emitting element as a confirmation site, the entire full color LED may be regarded as one light emitting element, or each color light emitting element may be regarded as one light emitting element.

  FIG. 40G is a plan view when a surface-mounted 7-segment LED is used as the light emitting element 43, and FIG. 40H shows a cross-sectional view of the state mounted on the substrate 40. The 7-segment LED includes seven light-emitting elements. As a light-emitting element as a confirmation required part, the entire 7-segment LED may be regarded as one light-emitting element, or each segment is regarded as one light-emitting element. Also good.

  FIG. 40J is a plan view when a through-hole mounting type 7-segment LED is used as the light-emitting element 43, and FIG. In the case of a through-hole mounted 7 segment LED, the configuration can be roughly divided into a light emitting portion 43a and a lead wire 43b, and light emission between the substrate 40 and the member 41 is similar to the through hole mounted LED. It suffices that at least a part of the portion 43 a is positioned, and the lead wire 43 b does not have to be positioned between the substrate 40 and the member 41.

<Example 14>
A case where the member 41 is a seal will be described. 41 (a) and 41 (b) show an example, and FIG. 41 (a) is a view of the member 41 and the substrate 40 as viewed from the member 41 side in the normal direction of the substrate 40. FIG. ) Is a cross-sectional view taken along line oo of FIG.

  A light emitting element 43 and substrate components 45 and 46 are mounted on the substrate 40. Each of the board components 45 and 46 is an identification display such as silk printing, the board component 45 is a display (LED1) indicating the type of the light emitting element 43, and the board component 46 indicates a mounting portion of the light emitting element 43. It is a display (rectangular border).

  The member 41 is a sheet-like seal and is attached to a member to be attached (not shown). The member to be adhered is, for example, a substrate case that houses the substrate 40, and the member 41 can be adhered to the inner surface or the outer surface of the substrate case.

  The entire sheet base material of the member 41 is a non-transmissive portion, and the character string 41a (substrate management number D-A310000) is printed on the surface of the sheet base material by silk printing or the like. There is no need. In the case of this example, the character string 41a illustratively indicates the management number of the board 40 ("board management number D-A 310000"). The character string 41a can be composed of kanji, hiragana, katakana, alphabetic characters, numbers, symbols, and the like.

  The member 41 is arranged in parallel with the substrate 40, but may be non-parallel. The light emitting element 43 and the substrate components 45 and 46 are located between the substrate 40 and the member 41.

  Now, when the board 40 is viewed from the back side to the front side of the pachinko machine 100, the member 41 may be obstructed and the visibility of the components on the board 40 may decrease.

  When attention is paid to the visibility of the light emitting element 43 that is a confirmation required site, the member 41 is obstructive when viewed from the normal direction (D11 direction) of the substrate 40, and the light emitting element 43 (particularly, the light emitting portion) is visually recognized. Can be difficult. In FIG. 41A, in order to make it easy to understand the positions of the light emitting element 43 and the substrate components 45 and 46, these are indicated by broken lines, but they are not visible at all or almost invisible.

  Therefore, the confirmer changes the viewing angle to, for example, the D12 direction which is an oblique direction and views the light emitting element 43. Thus, it may be possible to promote visual confirmation of the light emitting element 43 from multiple directions. Depending on the viewing direction, the substrate components 45 and 46 may be visible, and the confirmation may be possible.

  Since the substrate components 45 and 46 are located within a range where the light from the light emitting element 43 can reach, the substrate components 45 and 46 and the surroundings thereof become bright and the substrate components 45 and 46 may be easily seen. .

  Next, FIG. 41C and FIG. 41D also illustrate the case where the member 41 is a seal. FIG. 41C shows the member 41 and the substrate 40 from the member 41 side in the normal direction of the substrate 40. 41 (d) is a cross-sectional view taken along the line pp of FIG. 41 (a).

  The example of FIGS. 41C and 41D is the same as the example of FIGS. 41A and 41B except for the configuration of the member 41. In the case of this example, the sheet base material of the member 41 is a transmission part. The sheet substrate is composed of a transparent or translucent substrate, for example. On the other hand, the character string 41a constitutes a non-transparent portion. Therefore, the back of the character string 41a may be difficult to visually recognize.

  Now, when the board 40 is viewed from the back side to the front side of the pachinko machine 100, the board 40 may be partially disturbed by the character string 41a of the member 41 and the visibility may be partially reduced.

  Focusing on the visibility of the light-emitting element 43 that is a confirmation required site, the light-emitting element 43 is located behind the character string 41a when viewed from the normal direction (D11 direction) of the substrate 40. It may be partially difficult to visually recognize the light emitting element 43 (particularly the light emitting portion). The substrate component 45 may be visible and may be confirmed.

  The confirmer changes the viewing angle to, for example, the D12 direction which is an oblique direction, and views the light emitting element 43. Thus, it may be possible to promote visual confirmation of the light emitting element 43 from multiple directions. Depending on the viewing direction, the substrate component 46 may be visible, and the confirmation may be possible.

  Since the substrate components 45 and 46 are located within a range where the light from the light emitting element 43 can reach, the substrate components 45 and 46 and the surroundings thereof become bright and the substrate components 45 and 46 may be easily seen. .

<Example 15>
A case where the member 41 is a sheet metal will be described. 42 (a) and 42 (b) show an example, and FIG. 42 (a) is a view of the member 41 and the substrate 40 as viewed from the member 41 side in the normal direction of the substrate 40. FIG. ) Is a cross-sectional view taken along the line q-q in FIG.

  A light emitting element 43 and substrate components 45 and 46 are mounted on the substrate 40. The substrate components 45 and 46 are the same as in the different example 14.

  The member 41 is a sheet metal having a non-transmission portion as a whole, and is a structure supported by a support member (not shown). The support member is, for example, a substrate case that accommodates the substrate 40, and the member 41 can be fixed to the inner surface or the outer surface of the substrate case.

  The member 41 is arranged in parallel with the substrate 40, but may be non-parallel. The light emitting element 43 and the substrate components 45 and 46 are located between the substrate 40 and the member 41.

  Now, when the board 40 is viewed from the back side to the front side of the pachinko machine 100, the member 41 may be obstructed and the visibility of the components on the board 40 may decrease.

  When attention is paid to the visibility of the light emitting element 43 that is a confirmation required site, the member 41 is obstructive when viewed from the normal direction (D11 direction) of the substrate 40, and the light emitting element 43 (particularly, the light emitting portion) is visually recognized. Can be difficult. In FIG. 42A, in order to make it easy to understand the positions of the light emitting element 43 and the substrate components 45 and 46, these are indicated by broken lines, but they are not actually visible at all.

  Therefore, the confirmer changes the viewing angle to, for example, the D12 direction which is an oblique direction and views the light emitting element 43. Thus, it may be possible to promote visual confirmation of the light emitting element 43 from multiple directions. Depending on the viewing direction, the substrate components 45 and 46 may be visible, and the confirmation may be possible.

  Since the substrate components 45 and 46 are located within a range where the light from the light emitting element 43 can reach, the substrate components 45 and 46 and the surroundings thereof become bright and the substrate components 45 and 46 may be easily seen. .

  Moreover, the member 41 does not need to be a flat sheet metal, and may be curved or bent. Furthermore, a hole serving as a transmission part may be formed in a part of the member 41 so that part of the light emitting element 43 and part of the substrate components 45 and 46 may be visible from the D11 direction. As a form of the hole, the member 41 may be a mesh shape or may be a sheet metal having a punched hole.

<Example 16>
A case where the member 41 is a cable will be described. 42 (c) and 42 (d) show an example thereof, and FIG. 42 (c) is a view of the member 41 and the substrate 40 viewed from the member 41 side in the normal direction of the substrate 40. FIG. ) Is a cross-sectional view taken along line rr of FIG.

  A light emitting element 43 and substrate components 45 and 46 are mounted on the substrate 40. The substrate components 45 and 46 are the same as in the different example 14.

  The member 41 is a cable having a non-transmissive portion as a whole. The cable of this example is a wide cable such as a flexible cable or a flat cable, but may be a thin cable such as a single-wire cable or a cable having a circular or elliptical cross section. The cable may pass through the outside of the board case that houses the board 40, or may pass through the inside.

  The member 41 is arranged in parallel with the substrate 40 on the light emitting element 43, but may be non-parallel. The light emitting element 43 and the substrate components 45 and 46 are located between the substrate 40 and the member 41.

  Now, when the board 40 is viewed from the back side to the front side of the pachinko machine 100, the member 41 may be obstructed and the visibility of the components on the board 40 may decrease.

  When attention is paid to the visibility of the light emitting element 43 that is a confirmation required site, the member 41 is obstructive when viewed from the normal direction (D11 direction) of the substrate 40, and the light emitting element 43 (particularly, the light emitting portion) is visually recognized. Can be difficult. In FIG. 42C, in order to make it easy to understand the positions of the light emitting element 43 and the substrate components 45 and 46, these are indicated by broken lines, but they are not actually seen at all.

  Therefore, the confirmer changes the viewing angle to, for example, the D12 direction which is an oblique direction and views the light emitting element 43. Thus, it may be possible to promote visual confirmation of the light emitting element 43 from multiple directions. Depending on the viewing direction, the substrate components 45 and 46 may be visible, and the confirmation may be possible.

  Since the substrate components 45 and 46 are located within a range where the light from the light emitting element 43 can reach, the substrate components 45 and 46 and the surroundings thereof become bright and the substrate components 45 and 46 may be easily seen. .

<Example 17>
The case where the member 41 is a member that forms a substrate case that accommodates the substrate 40 will be described. 43 (a) and 43 (b) show an example, and FIG. 43 (a) is a view of the member 41 and the substrate 40 as viewed from the member 41 side in the normal direction of the substrate 40. FIG. ) Is a cross-sectional view taken along the line ss of FIG.

  A light emitting element 43 and substrate components 45 and 46 are mounted on the substrate 40. The substrate components 45 and 46 are the same as in the different example 14.

  The member 41 is a member that forms at least a part of a substrate case that accommodates the substrate 40. In this example, the member 41 is a member that forms a lid of the substrate case. The member 41 is made of a transparent or translucent material and is basically a transmissive part, but a display part 41b is formed in part. The display part 41 b can also be formed on the entire member 41.

  In the case of this example, the display unit 41b is a character string integrally formed in the molding process (for example, injection molding) of the member 41, and is expressed as “> PC <”. The character string can be composed of kanji, hiragana, katakana, letters, numbers, symbols, and the like. The character string is formed by forming a convex portion on the surface of the member 41 and expressing each character by the shape of the convex portion, but may be expressed by a concave portion or a combination of the convex portion and the concave portion. Also good. The formation surface of the character string may be on the outside or the inside of the member 41, but in this example, it is the outside.

  The display part 41b is located on the light emitting element 43. Of the member 41, the formation part of the display part 41b is arranged in parallel with the substrate 40, but may be non-parallel. The light emitting element 43 and the substrate components 45 and 46 are located between the substrate 40 and the member 41 (particularly the display unit 41b).

  The display part 41b may be less permeable than the other parts of the member 41 due to turbidity and thickness due to molding, and therefore the back of the display part 41b may be difficult to see.

  Now, when the substrate 40 is viewed from the back side to the front direction of the pachinko machine 100, the visibility of the substrate 40 may be partially degraded by the display unit 41b of the member 41.

  Focusing on the visibility of the light-emitting element 43 that is a confirmation required part, the light-emitting element 43 is located behind the display unit 41b when viewed from the normal direction (D11 direction) of the substrate 40. It may be partially difficult to visually recognize the light emitting element 43 (particularly the light emitting portion).

  Therefore, the confirmer changes the viewing angle to, for example, the oblique direction D13, and views the light emitting element 43. Thus, it may be possible to promote visual confirmation of the light emitting element 43 from multiple directions. Depending on the viewing direction, the substrate components 45 and 46 may be visible, and the confirmation may be possible.

  Since the substrate components 45 and 46 are located within a range where the light from the light emitting element 43 can reach, the substrate components 45 and 46 and the surroundings thereof become bright and the substrate components 45 and 46 may be easily seen. .

  Next, another example in which the member 41 is a member that forms a substrate case will be described with reference to FIGS. 43 (c) and 43 (d). FIG. 43C is a view of the member 41 and the substrate 40 viewed from the member 41 side in the normal direction of the substrate 40, and FIG. 43D is a cross-sectional view taken along the line tt of FIG.

  A light emitting element 43 and substrate components 45 and 46 are mounted on the substrate 40. The substrate components 45 and 46 are the same as in the different example 14.

  The member 41 is a member that forms at least a part of a substrate case that accommodates the substrate 40. In this example, the member 41 is a member that forms a lid of the substrate case. The member 41 is made of a transparent or semi-transparent material, and is basically a transmissive portion as a whole, but has a textured portion 41c in part. The embossed portion 41 c can also be formed on the entire member 41.

  In the case of this example, the embossed portion 41 c is an unevenness formed integrally in the molding process of the member 41 (for example, injection molding), but a part of the member 41 may be roughened by post-processing. The formation surface of the embossed portion 41c may be the outside or the inside of the member 41, but in this example, it is the outside.

  The embossed portion 41 c is located on the light emitting element 43, and the formation portion of the embossed portion 41 c in the member 41 is arranged in parallel with the substrate 40, but may be non-parallel. The light emitting element 43 and the substrate components 45 and 46 are located between the substrate 40 and the member 41 (particularly the embossed portion 41c).

  The embossed portion 41c may be less transparent than other portions of the member 41 due to the unevenness, and therefore the back of the embossed portion 41c may be difficult to visually recognize.

  Now, when the substrate 40 is viewed from the back side to the front direction of the pachinko machine 100, the substrate 40 may be partially disturbed by the embossed portion 41c of the member 41 and the visibility may be partially reduced.

  Focusing on the visibility of the light-emitting element 43 that is a confirmation required part, the light-emitting element 43 is located behind the embossed portion 41c when viewed from the normal direction (D11 direction) of the substrate 40. It may be partially difficult to visually recognize the light emitting element 43 (particularly the light emitting portion). In FIG. 43 (c), in order to make it easy to understand the positions of the light emitting element 43 and the substrate components 45 and 46, these are shown by broken lines. It is harder to see than other parts.

  Therefore, the confirmer changes the viewing angle to, for example, the oblique direction D13, and views the light emitting element 43. Thus, it may be possible to promote visual confirmation of the light emitting element 43 from multiple directions. Depending on the viewing direction, the substrate components 45 and 46 may be visible, and the confirmation may be possible.

  Since the substrate components 45 and 46 are located within a range where the light from the light emitting element 43 can reach, the substrate components 45 and 46 and the surroundings thereof become bright and the substrate components 45 and 46 may be easily seen. .

  Next, another example in which the member 41 is a member that forms a substrate case will be described with reference to FIGS. 44 (a) and 44 (b). 44A is a view of the member 41 and the substrate 40 viewed from the member 41 side in the normal direction of the substrate 40, and FIG. 44B is a cross-sectional view taken along the line uu of FIG. 44A.

  A light emitting element 43 and substrate components 45 and 46 are mounted on the substrate 40. The substrate components 45 and 46 are the same as in the different example 14.

  The member 41 is a member that forms at least a part of a substrate case that accommodates the substrate 40. In this example, the member 41 is a member that forms a lid of the substrate case. The member 41 is made of a transparent or translucent material, and is basically a transmissive part, but a molding mark 41d is formed in part.

  The molding mark 41d is a part formed by molding in the molding process of the member 41 (for example, injection molding). In this example, the molding mark 41d is assumed to be a recess that can be formed at a portion that is pushed by the ejector pin when the molded product is discharged. However, it is not limited to this. The formation surface of the molding mark 41d may be the outside or the inside of the member 41, but in this example, it is the outside.

  The molding mark 41d is located on the light emitting element 43, and the portion of the member 41 where the molding mark 41d is formed is arranged in parallel with the substrate 40, but may be non-parallel. The light emitting element 43 and the substrate components 45 and 46 are located between the substrate 40 and the member 41 (particularly the molding mark 41d).

  The molding mark 41d may be less permeable than the other parts of the member 41 due to turbidity or the like, and therefore, the back of the molding mark 41d may be difficult to see.

  Now, when the substrate 40 is viewed from the back side to the front direction of the pachinko machine 100, the visibility of the substrate 40 may be partially degraded by being obstructed by the molding marks 41d of the member 41.

  Focusing on the visibility of the light-emitting element 43 that is a confirmation required site, the light-emitting element 43 is located behind the molding mark 41d when viewed from the normal direction (D11 direction) of the substrate 40. It may be partially difficult to visually recognize the light emitting element 43 (particularly the light emitting portion).

  Therefore, the confirmer changes the viewing angle to, for example, the oblique direction D13, and views the light emitting element 43. Thus, it may be possible to promote visual confirmation of the light emitting element 43 from multiple directions. Depending on the viewing direction, the substrate components 45 and 46 may be visible, and the confirmation may be possible.

  Since the substrate components 45 and 46 are located within a range where the light from the light emitting element 43 can reach, the substrate components 45 and 46 and the surroundings thereof become bright and the substrate components 45 and 46 may be easily seen. .

  Next, another example in which the member 41 is a member that forms a substrate case will be described with reference to FIGS. 44 (c) and 44 (d). 44C is a view of the member 41 and the substrate 40 viewed from the member 41 side in the normal direction of the substrate 40, and FIG. 44D is a cross-sectional view taken along the line vv of FIG. 44C.

  A light emitting element 43 and substrate components 45 and 46 are mounted on the substrate 40. The substrate components 45 and 46 are the same as in the different example 14.

  The member 41 is a member that forms at least a part of a substrate case that accommodates the substrate 40. In this example, the member 41 is a member that forms a lid of the substrate case. The member 41 is made of a transparent or translucent material, and is basically a transmissive part, but a light refracting part 41e is formed in part. The light refraction part 41e may be formed over the entire area of the member 41.

  The light refracting portion 41e can be integrally formed in the molding process (for example, injection molding) of the member 41. For example, the light refracting portion 41e can have a shape that changes the emitting direction with respect to the incident direction of light. In the case of this embodiment, the light refraction part 41e is a tapered hole. This hole can also be used as a hole for radiating heat generated in the substrate 40, but the light refracting portion 41e may have a bottomed tapered shape, or may have an oblique shape other than the tapered shape, It may be a shape other than an oblique shape (for example, a curved shape).

  The light refracting portion 41e is located on the light emitting element 43, and the portion of the member 41 where the light refracting portion 41e is formed is arranged in parallel to the substrate 40, but may be non-parallel. The light emitting element 43 and the substrate components 45 and 46 are located between the substrate 40 and the member 41 (particularly the light refraction part 41e).

  Since the light refraction part 41e refracts light, the back of the light refraction part 41e may be difficult to visually recognize.

  Now, when the substrate 40 is viewed from the back side to the front side of the pachinko machine 100, the substrate 40 may be partially disturbed by the light refracting portion 41e of the member 41 and the visibility may be partially reduced.

  Focusing on the visibility of the light-emitting element 43 that is a confirmation required site, the light-emitting element 43 is located behind the light refraction part 41e when viewed from the normal direction (D11 direction) of the substrate 40. In some cases, it is partially difficult to visually recognize the light emitting element 43 (particularly, the light emitting portion) due to the hindrance 41e.

  Therefore, the confirmer changes the viewing angle to, for example, the oblique direction D13, and views the light emitting element 43. Thus, it may be possible to promote visual confirmation of the light emitting element 43 from multiple directions. Depending on the viewing direction, the substrate components 45 and 46 may be visible, and the confirmation may be possible.

  Since the substrate components 45 and 46 are located within a range where the light from the light emitting element 43 can reach, the substrate components 45 and 46 and the surroundings thereof become bright and the substrate components 45 and 46 may be easily seen. .

  Next, another example in which the member 41 is a member that forms a substrate case will be described with reference to FIGS. 45 (a) and 45 (b). 45A is a view of the member 41 and the substrate 40 viewed from the member 41 side in the normal direction of the substrate 40, and FIG. 45B is a cross-sectional view taken along the line ww of FIG.

  A light emitting element 43 and substrate components 45 and 46 are mounted on the substrate 40. The substrate components 45 and 46 are the same as in the different example 14.

  The member 41 is a member that forms at least a part of a substrate case that accommodates the substrate 40. In this example, the member 41 is a member that forms a lid of the substrate case. The member 41 is made of a transparent or translucent material and basically is a transmission part, but a bent part 41f and an inclined part 41g are formed in part.

  The bent portion 41 f and the inclined portion 41 g are portions that change the outer shape of the member 41. In this example, the bent portion 41f is an L-shaped corner. The inclined portion 41g is a portion inclined with respect to the substrate 10. The relationship of the thickness of the member 41 in the normal direction of the substrate 40 will be described. When the thickness of the bent portion 41f is B, the thickness of the inclined portion 41g is C, and the thickness of the portion parallel to the substrate 40 is A, B> A, C> A. The relationship between the thickness B and the thickness C may be B> C, B <C, or B = C.

  In the bent portion 41f and the inclined portion 41g, the thickness of the member 41 in the normal direction of the substrate 40 is locally increased, so that the back of the bent portion 41f and the inclined portion 41g may be difficult to visually recognize. As for the bent portion 41f, when the corner portion is rounded, the emission direction may change with respect to the light incident direction, and the back side may be difficult to visually recognize. Since the inclined portion 41g is inclined, the emission direction may change with respect to the incident direction of light, and the back of the inclined portion 41g may be difficult to visually recognize.

  The bent portion 41 f is located on the substrate component 45, and the inclined portion 41 g is located on the light emitting element 43 and the substrate component 46. The light emitting element 43 and the substrate components 45 and 46 are located between the substrate 40 and the member 41 (particularly the bent portion 41f and the inclined portion 41g).

  Now, when the substrate 40 is viewed from the back side to the front side of the pachinko machine 100, the visibility of the substrate 40 may be partially reduced by being disturbed by the bent portion 41f and the inclined portion 41g of the member 41.

  Focusing on the visibility of the light-emitting element 43 that is a confirmation required part, the light-emitting element 43 is located behind the inclined part 41g when viewed from the normal direction (D11 direction) of the substrate 40. It may be partially difficult to visually recognize the light emitting element 43 (particularly the light emitting portion).

  Therefore, the confirmer changes the viewing angle to, for example, the D12 direction which is an oblique direction, and sees the light emitting element 43. However, the bent portion 41f gets in the way and visually recognizes the light emitting element 43 (particularly the light emitting part). Can be partly difficult.

  Therefore, the confirmer changes the viewing angle to, for example, the oblique direction D13, and views the light emitting element 43. In the D13 direction, the bent portion 41f and the inclined portion 41g are not interposed, and thus the visibility of the light emitting element 43 may be improved at least slightly. Thus, it may be possible to promote visual confirmation of the light emitting element 43 from multiple directions. Depending on the viewing direction, the substrate components 45 and 46 may be visible, and the confirmation may be possible.

  Since the substrate components 45 and 46 are located within a range where the light from the light emitting element 43 can reach, the substrate components 45 and 46 and the surroundings thereof become bright and the substrate components 45 and 46 may be easily seen. . Moreover, in this example, although both the bending part 41f and the inclination part 41g were provided, either one may be sufficient.

<Example 18>
The confirmation promoting structure can be applied not only to the control board but also to a production body, for example. 46A and 46B show an example in which the confirmation promoting structure is applied to the effect body MV. 46A shows a front view of the effector MV, and FIG. 46B is a sectional view taken along line xx of FIG. 46A.

  For example, the effect body MV can be arranged at a position where the player can visually recognize it, and can be arranged specifically in the game area 124, but can also be arranged at a position other than the game area 124. . When the player views the pachinko machine 100 in front, the effect body MV may be arranged so that the effect body MV is viewed in front as shown in FIG.

  The director MV includes a substrate 40, a member 41, a plurality of light emitting elements 43, and a substrate component 46. These configurations correspond to the substrate 40, the member 41, the light emitting element 43, and the substrate component 46 described in the different examples 7 to 17, and are partially arranged for the effect body MV.

  The member 41 is a plate-like member, for example, a resin material. The member 41 is arranged in parallel with the substrate 40 but may be non-parallel. The member 41 is made of a transparent or translucent material, and is basically a transmission part as a whole. The member 41 may have a lens shape.

  A display portion 41 h is formed on a part of the member 41. In the case of this example, the display portion 41h is composed of characters “Yoshi”, and is formed on the base material of the member 41 by painting or plating. The display part 41h is a non-transmissive part. When the light emitting element 43 emits light, the light of the light emitting element 43 is emitted from the member 41 and becomes brighter as a whole. However, no light is emitted from the display part 41h or the amount of light is inferior. In some cases, an effect that makes the display unit 41h stand out may be possible.

  Now, when the board 40 is viewed from the front side to the back side of the pachinko machine 100, the visibility of the board 40 may be partially degraded by the display unit 41h of the member 41.

  Focusing on the visibility of the light-emitting element 43 that is a confirmation required site, the light-emitting element 43 is located behind the display unit 41h when viewed from the normal direction (D11 direction) of the substrate 40. It may be partially difficult to visually recognize the light emitting element 43 (particularly the light emitting portion).

  Therefore, the confirmer changes the viewing angle to, for example, the oblique direction D12, and views the light emitting element 43. Thus, it may be possible to promote visual confirmation of the light emitting element 43 from multiple directions. Depending on the viewing direction, the substrate component 46 may be visible, and the confirmation may be possible.

  In addition, since the board | substrate component 46 is located in the range which the light of the light emitting element 43 reaches | attains, the board | substrate component 46 and its periphery become bright, and the board | substrate component 46 may be easy to see.

  The member 41 may be a movable body. FIG. 46 (c) shows an example. The example of the figure shows an example in which the member 41 is translated downward from the state shown in FIG. The substrate 40 remains stationary. When the member 41 moves downward, the light emitting element 43 and the board component 46 are exposed, and the visibility of these elements may be improved, and confirmation may be surely performed. The member 41 may rotate.

  For example, the member 41 can move when the confirmer performs a predetermined operation on the pachinko machine 100, and can return to the original position when the predetermined operation is performed. Further, when the power of the pachinko machine 100 is turned on, the member 41 moves, and when a predetermined operation is performed, the member 41 can be returned to the original position. In addition, the member 41 may move during the game, which can not only be confirmed by the confirmer during the game but also improve the effect.

  The director MV may be a movable body. FIG. 46 (d) shows an example. The example of the figure shows an example in which the entire effector MV is translated downward from the state shown in FIG. When the director MV moves, the angle at which the confirmer sees may be different. For example, when the confirmer is confirming in the D11 direction shown in FIG. 46B, if the effector MV is moved downward, the confirmer only moves the line of sight, and the viewing angle changes in the D12 direction. Will do. Thus, it may be possible to promote visual confirmation of the light emitting element 43 and the like from multiple directions.

  The moving form of the effect body MV may be rotation other than parallel movement. FIG. 46 (e) shows an example. The example of the figure shows an example in which the effector MV is tilted forward from the state shown in FIG. When the director MV is rotated, the viewing angle of the confirmer may be different, and it may be possible to promote visual confirmation of the light emitting element 43 and the like from multiple directions.

  The director MV can move, for example, when the confirmer performs a predetermined operation on the pachinko machine 100, and can return to the original position when the predetermined operation is performed. Further, when the power of the pachinko machine 100 is turned on, the effector MV moves, and can be returned to the original position when a predetermined operation is performed. In addition, the effector MV may move during the game, which may not only be confirmed by the confirmer during the game, but may also improve the effect.

<Other examples>
The above-described other examples 1 to 18 can be appropriately combined. Further, the following configuration can also be adopted.

  The substrate 40 and the member 41 may be parallel, non-parallel, vertical, or non-vertical. Parallel may be substantially parallel, and vertical may be substantially vertical.

  The substrate 40 may be entirely overlapped with the member 41 or may be partially overlapped. The substrate 40 and the member 41 are parallel, and the substrate 40 may overlap the member 41 entirely in the vertical direction, or may partially overlap in the vertical direction, or may not overlap in the vertical direction. Good.

  All of the light emitting elements 43 may be located between the substrate 40 and the member 41 or only a part thereof may be located. The light emitting element 43A may be located between the substrate 40 and the member 41, or may be located only partially. The light emitting element 43B may be located between the substrate 40 and the member 41, or may be located only partially. Each of the substrate components 44 to 46 may be located between the substrate 40 and the member 41, may be located only partially, or may not be located.

  All of the light emitting elements 43 may be located between a part of the substrate 40 (for example, one or more of a plurality of regions obtained by dividing the substrate in a lattice shape) and the member 41, or only a part of the light emitting element 43 is located. May be. The light emitting element 43 </ b> A may be entirely located between a part of the substrate 40 and the member 41, or may be located only partially. The light emitting element 43B may be entirely located between a part of the substrate 40 and the member 41, or may be located only partially.

  Each of the substrate components 44 to 46 may be located between a part of the substrate 40 and the member 41, may be located only partially, or may not be located.

  The portion between the substrate 40 and the member 41 may be between the outermost end portion of the substrate 40 and the outermost end portion of the member 41.

  All of the light emitting elements 43 may be positioned between a part of the substrate 40 and the plurality of members 41, or only a part thereof may be positioned. The light emitting element 43 </ b> A may be located entirely or partially between a part of the substrate 40 and the plurality of members 41. The light emitting element 43 </ b> B may be located entirely between a part of the substrate 40 and the plurality of members 41, or may be located only partially.

  Each of the substrate components 44 to 46 may be located between a part of the substrate 40 and the plurality of members 41, may be located only partially, or may not be located.

  All of the light emitting elements 43 may not be visible from a direction perpendicular to the substrate 40, and may be visible from a direction non-perpendicular to the substrate 40. All of the light emitting elements 43 may be visible from a direction perpendicular to the substrate 40, and may not be visible from a direction non-perpendicular to the substrate 40.

  A part of the light emitting elements 43 may not be visible from a direction perpendicular to the substrate 40, and all may be visible from a direction non-perpendicular to the substrate 40. All of the light emitting elements 43 may be visible from a direction perpendicular to the substrate 40, and some of the light emitting elements 43 may not be visible from a direction non-perpendicular to the substrate 40.

  Each of the substrate components 44 to 46 may not be visible from a direction perpendicular to the substrate 40, and may be visible from a direction non-perpendicular to the substrate 40. Each of the substrate components 44 to 46 may be visible from the direction perpendicular to the substrate 40 and may not be visible from the direction perpendicular to the substrate 40.

  Each of the substrate components 44 to 46 may not be visible from a direction perpendicular to the substrate 40, and all of the substrate components 44 to 46 may be visible from a direction non-perpendicular to the substrate 40. Each of the substrate components 44 to 46 may be visible from a direction perpendicular to the substrate 40, and a part of the substrate components 44 to 46 may not be visible from a direction non-perpendicular to the substrate 40.

  The light emitting element 43 may be at least one of a single color LED, a multicolor LED, a full color LED, a 7-segment LED, a surface-mounted LED, and a through-hole mounted LED.

  The member 41 includes a substrate, a seal having an impermeable portion, a seal having a transmissive portion, a seal having a transmissive portion and an impermeable portion, a seal having a display portion, a seal having a character portion, a sheet metal, and a substrate case having a transmissive portion, It may be at least one of a cable, a board constituting unit mounted on the board, painting, a lens, resin, metal, wood, glass, and a structure. In addition, for example, at least one of a concave shape or a convex shape, a display portion such as a character, a symbol, or a pattern molded on at least one of an inner wall or an outer wall, a textured portion of a substrate case, The substrate case may include an extruded portion, a light refracting portion, a corner portion, an inclined portion, a thickness portion (a second thickness portion thicker than the first thickness)) and the like.

  The member 41 may be configured to be movable. The member 41 may be configured to be movable together with the substrate 40. The member 41 may be configured such that the angle can be changed.

  The board 40 is, for example, one of a main control board, a first sub control board, a second sub control board, a liquid crystal control board, a ROM board, a power supply board, a payout board, a launch board, an LED board, a relay board, and an external terminal board. At least one of them may be used.

  The board component includes, for example, a connector, a resistor, a capacitor, an LED, an IC, an LSI, a CPU, a ROM, a RAM, a switch, a display relating to any of a plurality of board constituting means, a display relating to a management number of the board, an electronic circuit configuration It may be at least one of the means.

  The member 41 includes, for example, a main control board, a first sub control board, a second sub control board, a liquid crystal control board, a ROM board, a power supply board, a payout board, a launch board, an LED board, a relay board, and an external terminal board. At least one of them may be used.

  The member 41 may be smaller than the substrate 40, larger than the substrate 40, or the same size as the substrate 40.

  The light emitting element 43 may be capable of emitting light when the light emission condition is satisfied. The light emission condition may include, as at least one of the requirements for establishment, for example, at least one of interrupt occurrence, Vsync interrupt occurrence, soft reset occurrence, hard reset occurrence, error occurrence, and always after power-on. .

  The substrate case 682 may be made of a light-transmitting material.

  The light emitting element 43 may not be visible from the first direction, or may be partially visible from the first direction. The first direction is, for example, the normal direction of the substrate 40. In other words, for example, the direction is perpendicular to the arrangement surface of the light emitting elements 43. In addition, the first direction may be a direction that does not include as a component a direction from one of the left and right directions of the gaming table toward the other. Further, the first direction may be a direction that does not include a direction from one of the up and down directions of the game table to the other as a component. In addition, the light of the light emitting element 43 may not be visible from the first direction, or may be visible from the first direction.

  The light emitting element 43 may be at least partially visible from the second direction. Specifically, for example, all of the light emitting elements 43 may be visible from the second direction, or only part of them may be visible. The second direction is, for example, a direction different from the first direction. For example, the surface direction of the substrate 40. In addition, the second direction may be a direction that is not perpendicular to the arrangement surface of the light emitting elements 43. In addition, the second direction may be a direction including at least a direction from one of the left and right directions of the game table toward the other as a component. Further, the second direction may be a direction including at least a direction from one of the vertical directions of the game table to the other as a component. The light of the light emitting element 43 may be invisible from the second direction or may be visible from the second direction.

  At least a part of the light emitting element 43 may not be visible from the third direction. Specifically, for example, the light emitting element 43 may not be visible from the third direction, or may be partially visible from the third direction. The third direction is, for example, a direction different from the first direction and the second direction. For example, the third direction may be a direction that is not perpendicular to the surface on which the light emitting element 43 is installed. In addition, the third direction may be a direction including at least a direction from one to the other of the left and right directions of the game table as a component. Further, the third direction may be a direction including at least a direction from one of the vertical directions of the game table toward the other as a component. Note that the light of the light emitting element 43 may not be visible from the third direction, or may be visible from the third direction.

  The substrate components 44 to 46 may be at least partially invisible from the first direction. Specifically, for example, it may not be visible from the first direction, or may be partially visible from the first direction. The substrate components 44 to 46 may be light emitting means or may not emit light. In the case of the light emitting means, it may be used for debugging.

  When the board | substrate 40 is accommodated in a board | substrate case, a board | substrate case may be comprised from several case structure means. At least one of the plurality of case configuration means is a first case configuration means (for example, an upper case), and at least one of the plurality of case configuration means is a second case configuration means (for example, the upper case). Lower case), and the substrate 40 may be installed in at least one of the plurality of case constituting means by fastening means. Removal of the substrate 40 may be difficult. The fastening means may be at least one of a screw, a screw, a nut, and a caulking. Moreover, you may provide the opening prevention means which blocks | releases opening of a 1st case structure means and a 2nd case structure means. The opening prevention means may be a seal member. The seal member may be affixed across the first case constituting means and the second case constituting means. Further, the substrate case may be installed in the substrate case installation part. The substrate case installation unit may include an operation unit, and may be changed to one of a substrate case installation state and a substrate case installation release state by operation of the operation unit. The substrate case installation release state of the substrate case may require a part of the operation unit or the substrate case to be destroyed. The operation unit may be operated by a tool. The operation unit may be fastening means. The fastening means may be at least one of a screw, a screw, a nut, and a caulking.

  The operation unit may be operated without the need for a tool. The fastening means may be capable of changing to either a fastening state or a fastening release state by a tool. Further, the fastening means may be capable of changing to either a fastening state or a fastening release state without the need for a tool.

  The substrate 40 may have a substantially rectangular shape, and a plurality of portions of the plurality of corners may be fastened to the substrate case by fastening means. The substrate 40 may be positioned on the substrate case at one or a plurality of positions of the plurality of corners by positioning means. The substrate 40 may be positioned and installed on the substrate case only by the positioning means without being fastened by the fastening means.

<Summary of confirmation promotion structure>
B1. The gaming table (e.g., 100) in the above embodiment is
A first substrate (e.g. 10,40);
First means (e.g. 11, 14, 682, 682a, 41, 41a-41h);
A game machine equipped with
The first substrate is a substrate having light emitting means (e.g., 31-34, 43),
At least a part of the light emitting means is located between at least a part of the first substrate and the first means (for example, FIG. 26 to FIG. 39, FIG. 41 to FIG. 46),
At least a part of the light emitting means is configured to be visible to a confirmer from a direction perpendicular to the first substrate (for example, FIGS. 32-33, 38 (c) -38 (e)). 39 (b) -39 (c), FIG. 41, FIG. 43-45),
It is characterized by that.

  According to this configuration, the confirmer may be able to perform visual confirmation from a plurality of angles. Further, it may be possible to facilitate visual confirmation of the light emitting means and the periphery of the light emitting means. Further, there is a case where no light projecting means such as a flashlight is required for visual confirmation by a confirmer. Since the checker's hand is not buried with a flashlight, the efficiency of the check operation may be improved. In some cases, the light emitting means can be confirmed from a direction perpendicular to the first substrate.

B2. The gaming table (e.g., 100) in the above embodiment is
The first means is a seal (e.g. 14,41);
It is characterized by that.

  According to this configuration, the first means may be provided relatively easily.

B3. The gaming table (e.g., 100) in the above embodiment is
The first means is a structure (for example, 11,682,682a, 41),
It is characterized by that.

  According to this configuration, the first means may be configured to be robust, and the confirmer may be able to perform visual confirmation from a plurality of angles over a long period of time.

B4. The gaming table (e.g., 100) in the above embodiment is
The first means is a means having a non-transmissive portion (for example, 11, 14, 682, 682a, 41),
It is characterized by that.

  According to this configuration, the confirmer may be able to perform visual confirmation from a plurality of angles.

B5. The gaming table (e.g., 100) in the above embodiment is
The first substrate is a substrate having first substrate constituting means (for example, 704, PI, 44-46),
It is characterized by that.

  According to this configuration, it may be possible to make the confirmer perform visual confirmation of the first substrate constituting unit.

B6. The gaming table (e.g., 100) in the above embodiment is
The light emitting part in the light emitting means is a light emitting part located between the first substrate and the first means (for example, FIGS. 26-39, 41-46),
It is characterized by that.

  According to this configuration, it may be possible to make a confirmer visually check the light emitting unit from a plurality of angles.

B7. The gaming table (e.g., 100) in the above embodiment is
The light emitting means is means that is not visible from the first direction,
The first direction is a direction different from the direction perpendicular to the first substrate (for example, FIG. 27, FIG. 29, FIG. 35, FIG. 38 (c) -FIG. 38 (e), FIG. -Fig. 39 (c), Fig. 45),
It is characterized by that.

  According to this configuration, it may be possible to make a confirmer visually check the light emitting unit from a plurality of angles.

B8. The gaming table (e.g., 100) in the above embodiment is
Comprising a second substrate (e.g. 11, 41),
The first means is means constituted by the second substrate.
It is characterized by that.

  According to this configuration, there is a case where the first means can be configured also by using the substrate.

B9. The gaming table (e.g., 100) in the above embodiment is
The first substrate constituting means is an electronic circuit constituting means (for example, 704, 44).
It is characterized by that.

  According to this configuration, it may be possible to make it easier for the confirmer to visually check the electronic circuit configuration means.

B10. The gaming table (e.g., 100) in the above embodiment is
The first substrate constituting means is an identification display (for example, PI, 44-46),
It is characterized by that.

  According to this configuration, it may be possible to facilitate visual confirmation of the identification display to the confirmer.

B11. The gaming table (e.g., 100) in the above embodiment is
The first substrate is a substrate having second substrate constituting means (for example, 21,710),
The second substrate constituting unit is a unit not positioned between the first substrate and the first unit in a direction perpendicular to the first substrate.
It is characterized by that.

  According to this configuration, the second substrate constituting unit may be visually confirmed from a direction perpendicular to the first substrate.

B12. The gaming table (e.g., 100) in the above embodiment is
The position of the second substrate constituting means is a position where light from the light emitting means reaches.
It is characterized by that.

  According to this configuration, it may be possible to facilitate visual confirmation of the second substrate configuring unit.

B13. The gaming table (e.g., 100) in the above embodiment is
A board case (e.g. 682),
The substrate case is a substrate case that houses the first substrate,
The substrate case is a substrate case that houses the second substrate.
It is characterized by that.

  According to this configuration, since the relative position of the first substrate and the second substrate does not change, it may be possible for the confirmer to reliably perform visual confirmation from a plurality of angles. That is, when the second substrate is outside the substrate case, there is a case where it is possible to eliminate the possibility that the confirmer changes the position of the second substrate and neglects visual confirmation from a plurality of angles.

B14. The gaming table (e.g., 100) in the above embodiment is a pachinko machine,
It is characterized by that.

  According to this configuration, it may be possible to facilitate visual confirmation of the configuration of the pachinko machine.

B15. The gaming table of the above embodiment is a slot machine (for example, 1100 described later),
It is characterized by that.

  According to this configuration, it may be possible to facilitate visual confirmation of the configuration of the slot machine.

C1. The gaming table (e.g., 100) in the above embodiment is
A first substrate (e.g. 10,40);
First means (e.g. 11, 14, 682, 682a, 41, 41a-41h);
A game machine equipped with
The first substrate is a substrate having light emitting means (e.g., 31-34, 43),
At least a part of the light emitting means is located between at least a part of the first substrate and the first means (for example, FIG. 26 to FIG. 39, FIG. 41 to FIG. 46),
The light emitting means is configured such that at least a part of the light of the light emitting means is visible to a confirmer (for example, FIGS. 26 to 39, FIG. 41 to FIG. 46),
It is characterized by that.

  According to this configuration, the confirmer may be able to perform visual confirmation from a plurality of angles. Further, it may be possible to facilitate visual confirmation of the light emitting means and the periphery of the light emitting means. Further, there is a case where no light projecting means such as a flashlight is required for visual confirmation by a confirmer. Since the checker's hand is not buried with a flashlight, the efficiency of the check operation may be improved.

C2. The gaming table (e.g., 100) in the above embodiment is
The first means is a seal (e.g. 14,41);
It is characterized by that.

  According to this configuration, the first means may be provided relatively easily.

C3. The gaming table (e.g., 100) in the above embodiment is
The first means is a structure (for example, 11,682,682a, 41),
It is characterized by that.

  According to this configuration, the first means may be configured to be robust, and the confirmer may be able to perform visual confirmation from a plurality of angles over a long period of time.

C4. The gaming table (e.g., 100) in the above embodiment is
The first means is a means having a non-transmissive portion (for example, 11, 14, 682, 682a, 41),
It is characterized by that.

  According to this configuration, the confirmer may be able to perform visual confirmation from a plurality of angles.

C5. The gaming table (e.g., 100) in the above embodiment is
The first substrate is a substrate having first substrate constituting means (for example, 704, PI, 44-46),
It is characterized by that.

  According to this configuration, it may be possible to make the confirmer perform visual confirmation of the first substrate constituting unit.

C6. The gaming table (e.g., 100) in the above embodiment is
The light emitting part in the light emitting means is a light emitting part located between the first substrate and the first means (for example, FIGS. 26-39, 41-46),
It is characterized by that.

  According to this configuration, it may be possible to make a confirmer visually check the light emitting unit from a plurality of angles.

C7. The gaming table (e.g., 100) in the above embodiment is
The light emitting means is means that is not visible from the first direction,
The light from the light emitting means is visible from the first direction (for example, FIG. 27, FIG. 29, FIG. 35, FIG. 38 (c) -FIG. 38 (e), FIG. 39 (b) -FIG. (c), Fig. 45),
It is characterized by that.

  According to this configuration, it may be possible to make a confirmer visually check the light emitting unit from a plurality of angles.

C8. The gaming table (e.g., 100) in the above embodiment is
Comprising a second substrate (e.g. 11, 41),
The first means is means constituted by the second substrate.
It is characterized by that.

  According to this configuration, there is a case where the first means can be configured also by using the substrate.

C9. The gaming table (e.g., 100) in the above embodiment is
The first substrate constituting means is an electronic circuit constituting means (for example, 704, 44).
It is characterized by that.

  According to this configuration, it may be possible to make it easier for the confirmer to visually check the electronic circuit configuration means.

C10. The gaming table (e.g., 100) in the above embodiment is
The first substrate constituting means is an identification display (for example, PI, 44-46),
It is characterized by that.

  According to this configuration, it may be possible to facilitate visual confirmation of the identification display to the confirmer.

C11. The gaming table (e.g., 100) in the above embodiment is
The first substrate is a substrate having second substrate constituting means (for example, 21,710),
The second substrate constituting unit is a unit not positioned between the first substrate and the first unit in a direction perpendicular to the first substrate.
It is characterized by that.

  According to this configuration, the second substrate constituting unit may be visually confirmed from a direction perpendicular to the first substrate.

C12. The gaming table (e.g., 100) in the above embodiment is
The position of the second substrate constituting means is a position where light from the light emitting means reaches.
It is characterized by that.

  According to this configuration, it may be possible to facilitate visual confirmation of the second substrate configuring unit.

C13. The gaming table (e.g., 100) in the above embodiment is
A board case (e.g. 682),
The substrate case is a substrate case that houses the first substrate,
The substrate case is a substrate case that houses the second substrate.
It is characterized by that.

  According to this configuration, since the relative position of the first substrate and the second substrate does not change, it may be possible for the confirmer to reliably perform visual confirmation from a plurality of angles. That is, when the second substrate is outside the substrate case, there is a case where it is possible to eliminate the possibility that the confirmer changes the position of the second substrate and neglects visual confirmation from a plurality of angles.

C14. The gaming table (e.g., 100) in the above embodiment is a pachinko machine,
It is characterized by that.

  According to this configuration, it may be possible to facilitate visual confirmation of the configuration of the pachinko machine.

C15. The gaming table of the above embodiment is a slot machine (for example, 1100 described later),
It is characterized by that.

  According to this configuration, it may be possible to facilitate visual confirmation of the configuration of the slot machine.

C16. The gaming table (e.g., 100) in the above embodiment is
The light emitting means is configured so that a player can visually recognize at least a part of the light of the light emitting means (for example, FIG. 46),
It is characterized by that.

According to this configuration, the confirmer may be able to confirm the light emitting means from a position where the player can visually recognize.
C21. The gaming table (e.g., 100) in the above embodiment is
A first substrate (e.g. 40);
Cover means (e.g. 41);
A game machine equipped with
The first substrate is a substrate having a first light emitting means (for example, 43),
The first substrate is a substrate having first substrate constituting means (for example, 746),
The cover means is means having a transmission part,
The cover means is means having a non-transmissive portion,
The first light emitting means is located between the first substrate and the non-transmissive portion (for example, FIG. 46),
The first substrate constituting means is located between the first substrate and the non-transmissive portion,
The position of the first substrate constituting means is a position where light from the first light emitting means reaches,
By changing the posture of the first light emitting means, it is configured so that a confirmer can visually recognize the first light emitting means from a direction perpendicular to the game table ( for example, FIG. 46),
Equipped with operable movable means (e.g. MV),
The movable means is means having the first substrate,
The movable means is means having the cover means,
When the movable means operates, the posture of the first light emitting means changes .
It is characterized by that.
C22. The gaming table (e.g., 100) in the above embodiment is
Before SL first substrate configuration means is an electronic circuitry means (e.g. 46),
It is characterized by that.
C2 3 . The gaming table (e.g., 100) in the above embodiment is
The first substrate constituting means is an identification display (for example, 46).
It is characterized by that.
C2 4 . The gaming table (e.g., 100) in the above embodiment is a pachinko machine,
It is characterized by that.
C2 5 . The gaming table of the above embodiment is a slot machine (for example, 1100 described later),
It is characterized by that.

D1. The gaming table (e.g., 100) in the above embodiment is
A first substrate (e.g. 10,40);
First means (e.g. 11, 14, 682, 682a, 41, 41a-41h);
A game machine equipped with
The first substrate is a substrate having light emitting means (e.g., 31-34, 43),
The first substrate is a substrate having first substrate constituting means (for example, 704, PI, 44-46),
At least a part of the light emitting means is located between at least a part of the first substrate and the first means (for example, FIG. 26 to FIG. 39, FIG. 41 to FIG. 46),
At least a part of the first substrate constituting means is located between at least a part of the first substrate and the first means (for example, FIGS. 26-39, 41-46),
The first substrate constituting means is configured to be visible to a confirmer (for example, FIGS. 26 to 39, FIG. 41 to FIG. 46),
It is characterized by that.

  According to this configuration, the confirmer may be able to perform visual confirmation from a plurality of angles. Further, it may be possible to facilitate visual confirmation of the light emitting means and the periphery of the light emitting means. Further, there is a case where no light projecting means such as a flashlight is required for visual confirmation by a confirmer. Since the checker's hand is not buried with a flashlight, the efficiency of the check operation may be improved. In addition, the confirmer may be able to confirm the first substrate constituting unit.

D2. The gaming table (e.g., 100) in the above embodiment is
The first means is a seal (e.g. 14,41);
It is characterized by that.

  According to this configuration, the first means may be provided relatively easily.

D3. The gaming table (e.g., 100) in the above embodiment is
The first means is a structure (for example, 11,682,682a, 41),
It is characterized by that.

  According to this configuration, the first means may be configured to be robust, and the confirmer may be able to perform visual confirmation from a plurality of angles over a long period of time.

D4. The gaming table (e.g., 100) in the above embodiment is
The first means is a means having a non-transmissive portion (for example, 11, 14, 682, 682a, 41),
It is characterized by that.

  According to this configuration, the confirmer may be able to perform visual confirmation from a plurality of angles.

D5. The gaming table (e.g., 100) in the above embodiment is
The light emitting part in the light emitting means is a light emitting part located between the first substrate and the first means (for example, FIGS. 26-39, 41-46),
It is characterized by that.

  According to this configuration, it may be possible to make a confirmer visually check the light emitting unit from a plurality of angles.

D6. The gaming table (e.g., 100) in the above embodiment is
The light emitting means is means that is not visible from the first direction,
The light from the light emitting means is visible from the first direction (for example, FIGS. 26-39, 41-46),
It is characterized by that.

  According to this configuration, there is a case where the confirmer can at least confirm the operation of the light emitting means.

D7. The gaming table (e.g., 100) in the above embodiment is
Comprising a second substrate (e.g. 11, 41),
The first means is means constituted by the second substrate.
It is characterized by that.

  According to this configuration, there is a case where the first means can be configured also by using the substrate.

D8. The gaming table (e.g., 100) in the above embodiment is
The first substrate constituting means is an electronic circuit constituting means (for example, 704, 44).
It is characterized by that.

  According to this configuration, it may be possible to make it easier for the confirmer to visually check the electronic circuit configuration means.

D9. The gaming table (e.g., 100) in the above embodiment is
The first substrate constituting means is an identification display (for example, PI, 44-46),
It is characterized by that.

  According to this configuration, it may be possible to facilitate visual confirmation of the identification display to the confirmer.

D10. The gaming table (e.g., 100) in the above embodiment is
The first substrate is a substrate having second substrate constituting means (for example, 21,710),
The second substrate constituting unit is a unit not positioned between the first substrate and the first unit in a direction perpendicular to the first substrate.
It is characterized by that.

  According to this configuration, the second substrate constituting unit may be visually confirmed from a direction perpendicular to the first substrate.

D11. The gaming table (e.g., 100) in the above embodiment is
The position of the second substrate constituting means is a position where light from the light emitting means reaches.
It is characterized by that.

  According to this configuration, it may be possible to facilitate visual confirmation of the second substrate configuring unit.

D12. The gaming table (e.g., 100) in the above embodiment is
A board case (e.g. 682),
The substrate case is a substrate case that houses the first substrate,
The substrate case is a substrate case that houses the second substrate.
It is characterized by that.

  According to this configuration, since the relative position of the first substrate and the second substrate does not change, it may be possible for the confirmer to reliably perform visual confirmation from a plurality of angles. That is, when the second substrate is outside the substrate case, there is a case where it is possible to eliminate the possibility that the confirmer changes the position of the second substrate and neglects visual confirmation from a plurality of angles.

D13. The gaming table (e.g., 100) in the above embodiment is a pachinko machine,
It is characterized by that.

  According to this configuration, it may be possible to facilitate visual confirmation of the configuration of the pachinko machine.

D14. The gaming table of the above embodiment is a slot machine (for example, 1100 described later),
It is characterized by that.

  According to this configuration, it may be possible to facilitate visual confirmation of the configuration of the slot machine.

E1. The gaming table (e.g., 100) in the above embodiment is
A first substrate (e.g. 10,40);
First means (e.g. 11, 14, 682, 682a, 41, 41a-41h);
A game machine equipped with
The first substrate is a substrate having a first light emitting means (for example, 43A),
The first substrate is a substrate having a second light emitting means (for example, 43B),
The first substrate is a substrate having first substrate constituting means (for example, 44B),
At least a part of the first light emitting means is located between at least a part of the first substrate and the first means (for example, FIG. 38 (a)),
At least a part of the second light emitting means is located between at least a part of the first substrate and the first means (for example, FIG. 38 (a)),
It is characterized by that.

  According to this configuration, the confirmer may be able to perform visual confirmation from a plurality of angles. Further, it may be possible to facilitate visual confirmation of the light emitting means and the periphery of the light emitting means. Further, there is a case where no light projecting means such as a flashlight is required for visual confirmation by a confirmer. Since the checker's hand is not buried with a flashlight, the efficiency of the check operation may be improved.

E2. The gaming table (e.g., 100) in the above embodiment is
The first means is a seal (e.g. 14,41);
It is characterized by that.

  According to this configuration, the first means may be provided relatively easily.

E3. The gaming table (e.g., 100) in the above embodiment is
The first means is a structure (for example, 11,682,682a, 41),
It is characterized by that.

  According to this configuration, the first means may be configured to be robust, and the confirmer may be able to perform visual confirmation from a plurality of angles over a long period of time.

E4. The gaming table (e.g., 100) in the above embodiment is
The first means is a means having a non-transmissive portion (for example, 11, 14, 682, 682a, 41),
It is characterized by that.

  According to this configuration, the confirmer may be able to perform visual confirmation from a plurality of angles.

E5. The gaming table (e.g., 100) in the above embodiment is
At least a part of the first substrate constituting means is located between at least a part of the first substrate and the first means (for example, FIG. 38 (a)),
The position of the first substrate constituting means is a position where the light from the first light emitting means reaches (for example, FIG. 38 (a)),
The position of the first substrate constituting means is a position where light from the second light emitting means reaches (for example, FIG. 38 (a)),
It is characterized by that.

  According to this configuration, there is a case where it is easy for the confirmer to confirm the first substrate constituting unit when one of the first and second light emitting units emits light.

E6. The gaming table (e.g., 100) in the above embodiment is
The light emitting part in the first light emitting means is a light emitting part located between the first substrate and the first means,
The light emitting part in the second light emitting means is a light emitting part located between the first substrate and the first means.
It is characterized by that.

  According to this configuration, it may be possible to make a confirmer visually check the light emitting unit from a plurality of angles.

E7. The gaming table (e.g., 100) in the above embodiment is
The first light emitting means is a means that is not visible from the first direction,
The light from the first light emitting means is visible from the first direction,
The second light emitting means is a means that is not visible from the second direction,
The light from the second light emitting means is visible from the second direction.
It is characterized by that.

  According to this configuration, there is a case where the confirmer can at least confirm the operation of each light emitting means.

E8. The gaming table (e.g., 100) in the above embodiment is
Comprising a second substrate (e.g. 11, 41),
The first means is means constituted by the second substrate.
It is characterized by that.

  According to this configuration, there is a case where the first means can be configured also by using the substrate.

E9. The gaming table (e.g., 100) in the above embodiment is
The first substrate constituting means is an electronic circuit constituting means (for example, 704, 44).
It is characterized by that.

  According to this configuration, it may be possible to make it easier for the confirmer to visually check the electronic circuit configuration means.

E10. The gaming table (e.g., 100) in the above embodiment is
The first substrate constituting means is an identification display (for example, PI, 44-46),
It is characterized by that.

  According to this configuration, it may be possible to facilitate visual confirmation of the identification display to the confirmer.

E11. The gaming table (e.g., 100) in the above embodiment is
A board case (e.g. 682),
The substrate case is a substrate case that houses the first substrate,
The substrate case is a substrate case that houses the second substrate.
It is characterized by that.

  According to this configuration, since the relative position of the first substrate and the second substrate does not change, it may be possible for the confirmer to reliably perform visual confirmation from a plurality of angles. That is, when the second substrate is outside the substrate case, there is a case where it is possible to eliminate the possibility that the confirmer changes the position of the second substrate and neglects visual confirmation from a plurality of angles.

E12. The gaming table (e.g., 100) in the above embodiment is a pachinko machine,
It is characterized by that.

  According to this configuration, it may be possible to facilitate visual confirmation of the configuration of the pachinko machine.

E13. The gaming table of the above embodiment is a slot machine (for example, 1100 described later),
It is characterized by that.

  According to this configuration, it may be possible to facilitate visual confirmation of the configuration of the slot machine.

  Further, the following configuration can be adopted.

  The first substrate and the first means may be parallel, non-parallel, vertical, or non-vertical. Parallel may be substantially parallel. Non-parallel may be substantially non-parallel. The vertical may be substantially vertical. Non-vertical may be substantially non-vertical.

  The first substrate may overlap with the first means or may partially overlap.

  The first substrate and the first means are parallel, and the first substrate may overlap the first means entirely in the vertical direction, or only partially overlap in the vertical direction. It does not have to overlap in the vertical direction.

  The light emitting means may be located entirely or only partially between the first substrate and the first means. The first light emitting means may be located entirely or only partially between the first substrate and the first means. The second light emitting means may be located entirely or only partially between the first substrate and the first means.

  The first substrate constituting means may be located entirely, partially, or not located between the first substrate and the first means. All of the second substrate constituting means may be located between the first substrate and the first means, or only a part may be located, or may not be located.

  The light emitting means may be entirely located between a part of the first substrate (for example, one or more of a plurality of regions obtained by dividing the substrate in a lattice shape) and the first means. However, only a part may be located. The first light emitting means is entirely located between a part of the first substrate (for example, one or more of a plurality of regions obtained by dividing the substrate in a lattice shape) and the first means. Alternatively, only a part may be located. The second light emitting means is entirely located between a part of the first substrate (for example, one or more of a plurality of regions obtained by dividing the substrate in a lattice shape) and the first means. Alternatively, only a part may be located.

  The first substrate constituting means may be located between a part of the first substrate and the first means, or may be located only partially or not. Also good. The second substrate constituting means may be located between the part of the first substrate and the first means, or may be located only partially or not. Also good.

  Between the part of the first substrate and the first means is between the outermost end part of the part of the first substrate and the outermost end part of the first means. Also good.

  The light emitting means may be located entirely or only partially between a part of the first substrate and the plurality of first means. The first light emitting means may be located entirely or partially between a part of the first substrate and the plurality of first means. The second light emitting means may be located entirely or partially between a part of the first substrate and the plurality of first means.

  The first substrate constituting means may be located between all or a part of the first substrate and the plurality of first means. It does not have to be. The second substrate constituting means may be located between all of the first substrate and the plurality of first means, or may be located only partially, or located. It does not have to be.

  All of the light emitting means may not be visible from a direction perpendicular to the substrate, and may be visible from a direction non-perpendicular to the substrate. All of the light emitting means may be visible from a direction perpendicular to the substrate, and may not be visible from a direction non-perpendicular to the substrate. A part of the light emitting means may not be visible from a direction perpendicular to the substrate, and all may be visible from a direction non-perpendicular to the substrate. All of the light emitting means may be visible from a direction perpendicular to the substrate, and a part of the light emitting means may not be visible from a direction non-perpendicular to the substrate.

  All of the first substrate constituting means may be invisible from an orientation perpendicular to the substrate, and may be visible from an orientation non-perpendicular to the substrate. All of the first substrate constituting means may be visible from a direction perpendicular to the substrate, and may not be visible from a direction non-perpendicular to the substrate. The first substrate constituting unit may be partially invisible from a direction perpendicular to the substrate, and all may be visible from a direction non-perpendicular to the substrate. All of the first substrate constituting means may be visible from a direction perpendicular to the substrate, and a part thereof may not be visible from a direction non-perpendicular to the substrate.

  The light emitting means may be at least one of a single color LED, a multicolor LED, a full color LED, a 7-segment LED, a surface-mounted LED, and a through-hole mounted LED.

  The first means includes another substrate, a seal having an impermeable portion, a seal having a transmissive portion, a seal having a transmissive portion and an impermeable portion, a seal display portion, a seal character portion, a sheet metal, and a transmissive portion. Substrate case, a part of the substrate case (for example, a display part such as a character, a symbol, or a pattern formed on at least one of the inner wall and the outer wall in a concave or convex shape on the substrate case, a textured part of the substrate case , Extruded part at the time of molding the substrate case, light refracting part of the substrate case, corner part of the substrate case, thickness part of the substrate case (second thickness part thicker than the first thickness), cable, substrate mounted on the board It may be at least one of constituent means, painting, lens, resin, metal, wood, glass, and structure.

  The first means may be configured to be movable. The first means may be configured to be movable together with the first substrate. The first means may be configured such that the angle can be changed.

<Embodiment 2>
In addition to the pachinko machine 100 of the first embodiment, the present invention can be applied to various game machines such as a slot machine. Hereinafter, a slot machine to which the present invention can be applied will be described as an example.

  A slot machine 1100 shown in FIG. 47 includes a main body 1101 and a front door 1102 that is attached to the front surface of the main body 1101 and can be opened and closed with respect to the main body 1101. Inside the center of the main body 1101 (not shown), three reels (left reel 1110, middle reel 1111 and right reel 1112) having a plurality of types of symbols arranged on the outer peripheral surface are stored and rotated inside the slot machine 1100. It is configured to be able to. These reels 1110 to 1112 are rotationally driven by a driving device such as a stepping motor.

  In the present embodiment, an appropriate number of symbols are printed on the belt-like member at equal intervals, and the reels 1110 to 1112 are configured by attaching the belt-like member to a predetermined circular cylindrical frame member. When viewed from the player, the symbols on the reels 1110 to 1112 are generally displayed in the vertical direction from the symbol display window 1113 so that a total of nine symbols can be seen. Then, by rotating the reels 1110 to 1112, the combination of symbols that can be seen by the player varies. That is, each of the reels 1110 to 1112 functions as a display device that displays a plurality of combinations of symbols in a variable manner. In addition to the reel, an electronic image display device such as a liquid crystal display device can also be used as such a display device. In this embodiment, three reels are provided in the center of the slot machine 1100. However, the number of reels and the installation position of the reels are not limited to this.

  Backlights (not shown) for illuminating individual symbols displayed on the symbol display window 1113 are arranged on the rear surfaces of the reels 1110 to 1112. It is desirable that the backlight is shielded for each symbol so that the individual symbols can be illuminated evenly. In the slot machine 1100, an optical sensor (not shown) including a light projecting unit and a light receiving unit is provided in the vicinity of each reel 1110 to 1112. The light projecting unit and the light receiving unit of this optical sensor are provided. A light shielding piece of a certain length provided on the reel passes between the two. Based on the detection result of this sensor, the position of the symbol on the reel in the rotation direction is determined, and the reels 1110 to 1112 are stopped so that the target symbol is displayed on the winning line.

  The winning line display lamp 1120 is a lamp indicating a winning line 1114 that is valid. The effective pay line is determined in advance by the number of medals bet as a game medium. There are 5 winning lines 1114. For example, when one medal is bet, the middle horizontal winning line is valid, and when two medals are betted, the upper horizontal winning line and the lower horizontal winning line are added. If three are valid and three medals are bet, five lines including a right-down winning line and an upper-right winning line are valid as winning lines. Note that the number of winning lines 1114 is not limited to five. For example, when one medal is bet, the middle horizontal winning line, the upper horizontal winning line, the lower horizontal winning line, the right The down line and the upper right line may be set as valid pay lines, and the same number of pay lines may be set as valid pay lines regardless of the number of bets.

  The notification lamp 1123 is, for example, a lamp that informs the player that a specific winning combination (specifically, a bonus) has been won internally in an internal lottery to be described later, or that a bonus game is in progress. The game medal insertable lamp 1124 is a lamp for notifying that the player can insert a game medal. The replay lamp 1122 informs the player that the current game can be replayed (the medal insertion is unnecessary) when winning a replay that is one of the winning combinations in the previous game. It is a lamp. The reel panel lamp 1128 is an effect lamp.

  The bet buttons 1130 to 1132 are buttons for inserting a predetermined number of medals (referred to as credits) stored electronically in the slot machine 1100. In this embodiment, every time the bet button 1130 is pressed, a maximum of three cards are inserted, two are inserted when the bet button 1131 is pressed, and three are inserted when the bet button 1132 is pressed. It has become so. Hereinafter, the bet button 1132 is also referred to as a MAX bet button. The game medal insertion lamp 1129 lights up a number of lamps corresponding to the number of inserted medals, and when a specified number of medals are inserted, a game start is informed that a game start operation is possible. The lamp 1121 is turned on.

  The medal slot 1141 is an slot for a player to insert a medal when starting a game. In other words, the insertion of medals can be performed electronically by using the bet buttons 1130 to 1132, or an actual medal can be inserted (insertion operation) from the medal insertion slot 1141, and the insertion includes both. is there. The stored number display 1125 is a display for displaying the number of medals stored electronically in the slot machine 1100. The game information display 1126 is a display for displaying various types of internal information (for example, the number of medals paid out during a bonus game) as numerical values. The payout number display 1127 is a display for displaying the number of medals to be paid out to the player as a result of winning a winning combination. The stored number display 1125, the game information display 1126, and the payout number display 1127 are 7-segment (SEG) displays.

  The start lever 1135 is a lever type switch for starting the rotation of the reels 1110 to 1112. That is, when a desired medal number is inserted into the medal insertion slot 1141 or when the bet buttons 1130 to 1132 are operated and the start lever 1135 is operated, the reels 1110 to 1112 start to rotate. The operation on the start lever 1135 is referred to as a game start operation.

  The stop button unit 1136 is provided with stop buttons 1137 to 1139. The stop buttons 1137 to 1139 are button-type switches for individually stopping the reels 1110 to 1112 that have started rotating by the operation of the start lever 1135, and are associated with the reels 1110 to 1112. Hereinafter, the operation on the stop buttons 1137 to 1139 is referred to as a stop operation, the first stop operation is referred to as a first stop operation, the next stop operation is referred to as a second stop operation, and the last stop operation is referred to as a third stop operation. Note that a light emitter may be provided inside each stop button 1137 to 1139, and when the stop button 1137 to 1139 can be operated, the light emitter may be turned on to notify the player.

  The medal return button 1133 is a button for pressing and removing a medal when the inserted medal is clogged. The payment button 1134 is a button for adjusting the medals stored electronically in the slot machine 1100 and the bet medals and discharging them from the medal payout exit 1155. Door key hole 1140 is a hole into which a key for unlocking front door 1102 of slot machine 1100 is inserted.

  Below the stop button unit 1136, a title panel 1162 for displaying a model name and pasting various types of certificate stamps is provided. At the bottom of the title panel 1162, a medal payout opening 1155 and a medal tray 1161 are provided.

  The sound hole 1180 is a hole for outputting the sound of a speaker provided inside the slot machine 1100 to the outside. Side lamps 1144 provided at the left and right portions of the front door 1102 are decorative lamps for exciting games. An effect device 1160 is disposed above the front door 1102, and a sound hole 1143 is provided above the effect device 1160. This effect device 1160 includes a shutter (shielding device) 1163 including two right shutters 1163a and 1163b that can be opened and closed in a horizontal direction, and a liquid crystal display device 1157 (effect image) disposed on the back side of the shutter 1163. And a display screen of the liquid crystal display device 1157 appears on the front side (player side) of the slot machine 1100 when the right shutter 1163a and the left shutter 1163b are opened horizontally in front of the liquid crystal display device 1157. It has become. It should be noted that the display device is not limited to a liquid crystal display device, and any display device capable of displaying various effect images and various game information may be used. , A reel (drum), or a display device including a projector and a screen. Further, the display screen has a rectangular shape and is configured so that the player can visually recognize the entire display screen. In the case of this embodiment, the display screen is rectangular, but may be square. In addition, a decorative object (not shown) may be provided on the periphery of the display screen, and a part of the peripheral edge of the display screen may be hidden by the decorative object, so that the display screen looks irregular. In the present embodiment, the display screen is a flat surface, but may be a curved surface.

  FIG. 48 is a front view showing the slot machine 1100 with the front door 102 opened. The main body 1101 is a box that is surrounded by an upper surface plate 1261, a left side plate 1260, a right side plate 1260, a lower surface plate 1264, and a back plate 1242 and opens to the front. Inside the main body 1101, a main control board storage case 1210 in which a main control board is stored is disposed at a position that does not overlap with the ventilation opening 1249 provided in the upper part of the back plate 1242. Below the three reels 1110 to 1112 are arranged. On the side plate 1260 on the left side of the main control board storage case 1210 and the reels 1110 to 1112, a sub control board storage case 1220 storing the sub control board is disposed. The right side plate 1260 is attached with an external concentration terminal plate 1248 that is connected to the main control board and outputs information of the slot machine 1100 to an external device.

  The bottom plate 1264 is provided with a medal payout device 1180 (device for paying out medals accumulated in a bucket), and has a power supply board above the medal payout device 1180, that is, below the reels 1110 to 1112. A power supply device 1252 is provided, and a power switch 1244 is provided on the front surface of the power supply device 1252. The power supply device 1252 converts the AC power supplied from the outside to the slot machine 1100 into a direct current, converts it into a predetermined voltage, and supplies it to each control unit and each device such as a main control unit 1300 and sub-control units 1400 and 1500 described later. To do. Furthermore, a power storage circuit (for example, a capacitor) for supplying power to a predetermined part (for example, the RAM 1308 of the main control unit 1300) for a predetermined period (for example, 10 days) even after the power supply from the outside is cut off is provided. Yes.

  A medal auxiliary storage 1240 is arranged on the right side of the medal payout device 1180, and an overflow terminal is arranged behind this (not shown). The power supply device 1252 is provided with a power cord connecting portion for connecting a power cord 1265, and the power cord 1265 connected thereto extends to the outside through a power cord hole 1262 provided in the back plate 1242 of the main body 1101. Yes.

  The front door 1102 is hinged to the left side plate 1260 of the main body 1101 via a hinge device 1276, and an effect device 1160 and an effect control board (which controls the effect device 1160) are provided above the symbol display window 1113. An upper speaker 1272 is provided. At the bottom of the symbol display window 1113, a medal selector 1170 for selecting inserted medals, a passage 1266 through which medals pass when the medal selector 1170 drops illegal medals etc. on the medal tray 1161, etc. are provided. Yes. Further, a bass speaker 1277 is provided at a position corresponding to the sound hole 1180.

  The circuit configuration of the control unit of the slot machine 1100 will be described in detail with reference to FIG. This figure shows a circuit block diagram of the control unit. Note that the above-described wiring structure and confirmation promoting structure can be employed for a substrate constituting the control unit.

  The control unit of the slot machine 1100 can be broadly divided into main effects according to a main control unit 1300 that controls the progress of the game and a command signal (hereinafter simply referred to as “command”) transmitted by the main control unit 1300. The first sub-control unit 1400 that performs the above control, and the second sub-control unit 1500 that controls various devices based on the command transmitted from the first sub-control unit 1400.

<Main control unit>
First, the main control unit 1300 of the slot machine 1100 will be described. The main control unit 1300 includes a basic circuit 1302 that controls the entire main control unit 1300. The basic circuit 1302 includes a CPU 1304, control program data, lottery data used during an internal lottery for a winning combination, and reel stop. ROM 1306 for storing position, RAM 1308 for temporarily storing data, I / O 1310 for controlling input / output of various devices, counter timer 1312 for measuring time, frequency, etc. WDT (watchdog timer) 1314 is mounted. Note that another storage device may be used for the ROM 1306 and the RAM 1308, and this is the same for the first sub-control unit 1400 and the second sub-control unit 500 described later. The CPU 1304 of the basic circuit 1302 operates by inputting a clock signal of a predetermined period output from the crystal oscillator 1314 as a system clock. Further, when the power is turned on, the CPU 1304 transmits the frequency division data stored in the predetermined area of the ROM 1306 to the counter timer 1312. The counter timer 1312 sets the interrupt time based on the received frequency division data. An interrupt request is transmitted to the CPU 1304 at every interrupt time. In response to this interrupt request, the CPU 1304 executes monitoring of each sensor and transmission of drive pulses. For example, when the clock signal output from the crystal oscillator 1314 is set to 8 MHz, the frequency division value of the counter timer 1312 is set to 1/256, and the data for frequency division in the ROM 1306 is set to 47, the interrupt reference time is 256 × 47 ÷ 8 MHz. = 1.504 ms.

  The main control unit 1300 includes a random number generation circuit 1316 that is used as a hardware random number counter that fluctuates a numerical value in the range of 0 to 65535, and an activation signal output circuit that outputs an activation signal (reset signal) when the power is turned on. The CPU 1304 starts game control when a start signal is input from the start signal output circuit 1338 (starts main processing main processing described later).

  Further, the main control unit 1300 includes a sensor circuit 1320, and the CPU 1304 is inserted from various sensors 1318 (a bet button 1130 sensor, a bet button 1131 sensor, a bet button 1132 sensor, and a medal slot 1141 at every interruption time. Medal reception sensor, start lever 1135 sensor, stop button 1137 sensor, stop button 1138 sensor, stop button 1139 sensor, checkout button 1134 sensor, medal payout sensor for medals paid out from the medal payout device 1180, index sensor for reel 1110 , The index sensor of the reel 1111, the index sensor of the reel 1112, etc.).

  When the sensor circuit 1320 detects the H level of the start lever sensor, a signal indicating this detection is output to the random number generation circuit 1316. The random number generation circuit 1316 that has received this signal latches the value at that timing and stores it in a register that stores the random number value used for the lottery.

  Two medal acceptance sensors are installed in the internal passage of the medal insertion slot 1141 and detect whether or not a medal has passed. Two start lever 1135 sensors are installed inside the start lever 1135 and detect a start operation by the player. A stop button 1137 sensor, a stop button 1138 sensor, and a stop button 1139 are installed in each of the stop buttons 1137 to 1139, and detect the operation of the stop button by the player.

  The bet button 1130 sensor, the bet button 1131 sensor, and the bet button 1132 sensor are installed in each of the medal insertion buttons 1130 to 1132, and the medal electronically stored in the RAM 1308 is inserted as an inserted medal into the game. Detecting the input operation when The settlement button 1134 sensor is provided on the settlement button 1134. When the settlement button 1134 is pressed once, medals stored electronically are settled. The medal payout sensor is a sensor for detecting a medal paid out by the medal payout device 1180. Each of the above sensors may be a non-contact type sensor or a contact type sensor.

  The index sensor of the reel 1110, the index sensor of the reel 1111, and the index sensor of the reel 1112 are installed at predetermined positions on the mounting bases of the reels 1110 to 1112. Becomes L level. When detecting this signal, the CPU 1304 determines that the reel has made one rotation, and resets the reel rotation position information to zero.

  The main control unit 1300 is provided in a drive circuit 1322 for driving a stepping motor provided in the reel devices 1110 to 1112, a drive circuit 1324 for driving a solenoid provided in a medal selector 1170 for selecting inserted medals, and a medal payout device 1180. A drive circuit 1326 for driving the motor, various lamps 1338 (a winning line display lamp 1120, a notification lamp 1123, a game medal insertion enable lamp 1124, a re-game lamp 1122, a game medal insertion lamp 1129, a game start lamp 1121, and a stored number display. A driving circuit 1328 for driving a device 1125, a game information display 1126, and a payout amount display 1127).

  In addition, an information output circuit 1334 (external concentration terminal board 1248) is connected to the basic circuit 1302, and the main control unit 1300 is connected to an external hall computer (not shown) or the like via the information output circuit 1334. The gaming information (for example, gaming state) of the slot machine 1100 is output to the information input circuit 1652 provided.

  The main control unit 1300 includes a voltage monitoring circuit 1330 that monitors the voltage value of the power supplied from the power management unit (not shown) to the main control unit 1300, and the voltage monitoring circuit 1330 includes the voltage of the power supply. When the value is less than a predetermined value (9 v in this embodiment), a low voltage signal indicating that the voltage has decreased is output to the basic circuit 1302.

  The main control unit 1300 includes an output interface for transmitting a command to the first sub control unit 1400 and enables communication with the first sub control unit 1400. Information communication between the main control unit 1300 and the first sub control unit 1400 is one-way communication, and the main control unit 1300 is configured to transmit a signal such as a command to the first sub control unit 1400. However, the first sub-control unit 1400 is configured not to transmit a signal such as a command to the main control unit 1300.

<Sub control unit>
Next, the first sub control unit 1400 of the slot machine 1100 will be described. The first sub control unit 1400 includes a basic circuit 1402 that receives a control command transmitted from the main control unit 1300 via an input interface and controls the entire first sub control unit 1400 based on the control command. The basic circuit 1402 includes a CPU 1404, a RAM 1408 for temporarily storing data, an I / O 1410 for controlling input / output of various devices, and a counter timer 1412 for measuring time and frequency. It is installed. The CPU 1404 of the basic circuit 1402 operates by inputting a clock signal of a predetermined period output from the crystal oscillator 1414 as a system clock. The ROM 406 stores a control program and data for controlling the entire first sub-control unit 1400, a backlight lighting pattern, data for controlling various displays, and the like.

  The CPU 1404 transmits the frequency dividing data stored in the predetermined area of the ROM 1406 to the counter timer 1412 via the data bus at a predetermined timing. The counter timer 1412 determines an interrupt time based on the received frequency division data, and transmits an interrupt request to the CPU 1404 at each interrupt time. The CPU 1404 controls each IC and each circuit based on the interrupt request timing.

  The first sub-control unit 1400 is provided with a sound source IC 1418, and the sound source IC 1418 is provided with speakers 1272 and 1277 via an output interface. The sound source IC 1418 controls sound output from the amplifiers and speakers 1272 and 1277 in accordance with a command from the CPU 1404. The sound source IC 1418 is connected to an S-ROM (sound ROM) in which audio data is stored. The audio data acquired from the ROM is amplified by an amplifier and output from the speakers 1272 and 1277.

  The first sub-control unit 1400 is provided with a drive circuit 1422, and various lamps 1420 (upper lamp, lower lamp, side lamp 1144, title panel 1162 lamp, etc.) are connected to the drive circuit 1422 through an input / output interface. It is connected.

  The first sub-control unit 1400 is provided with a drive circuit 1424 for driving the motor of the shutter 1163. This drive circuit 1424 is a stepping motor (not shown) provided on the shutter 1163 in response to a command from the CPU 1404. A drive signal is output to.

  The first sub-control unit 1400 is provided with a sensor circuit 1426, and a shutter sensor 1428 is connected to the sensor circuit 1426 via an input interface. The CPU 404 monitors the state of the shutter sensor 1428 every interruption time.

  The CPU 1404 transmits and receives signals to the second sub control unit 1500 via the output interface. Second sub-control unit 1500 performs various controls of effect device 1160 including display control of effect image display device 1157. Note that the second sub-control unit 1500 is, for example, a control unit that controls display of the liquid crystal display device 1157 and a control unit that controls various driving devices for effects (for example, a control unit that controls the motor drive of the shutter 1163). For example, it may be configured by a plurality of control units.

  The second sub control unit 1500 includes a basic circuit 1502 that receives the control command transmitted from the first sub control unit 1400 via the input interface and controls the entire second sub control unit 1500 based on the control command. The basic circuit 1502 includes a CPU 1504, a RAM 1508 for temporarily storing data, an I / O 1510 for controlling input / output of various devices, and a counter timer for measuring time and frequency 1512. The CPU 1504 of the basic circuit 1502 operates by inputting a clock signal of a predetermined period output from the crystal oscillator 1514 as a system clock. The ROM 506 stores a control program and data for controlling the entire second sub control unit 1500, data for image display, and the like.

  The CPU 1504 transmits the frequency dividing data stored in the predetermined area of the ROM 1506 to the counter timer 1512 via the data bus at a predetermined timing. The counter timer 1512 determines an interrupt time based on the received frequency division data, and transmits an interrupt request to the CPU 1404 at each interrupt time. The CPU 1504 controls each IC and each circuit based on the interrupt request timing.

  The second sub control unit 1500 is provided with a VDP 1534 (video display processor), and a ROM 1506 and a VRAM 1536 are connected to the VDP 1534 through a bus. The VDP 1534 reads out image data and the like stored in the ROM 1506 based on a signal from the CPU 1504, generates a display image using the work area of the VRAM 1536, and displays the image on the effect image display device 1157.

  The symbol arrangement applied to each of the reels 1110 to 1112 will be described with reference to FIG. This figure is a diagram in which the arrangement of symbols applied to each reel (left reel 1110, middle reel 1111, right reel 1112) is developed in a plane.

<Pattern arrangement>
In each reel 1110 to 1112, a plurality of types (eight types in the present embodiment) of symbols shown on the right side of the same figure are arranged by a predetermined number of frames (21 frames of numbers 0 to 20 in the present embodiment). Also, numbers 0 to 20 shown at the left end of the figure are numbers indicating the arrangement positions of symbols on the reels 1110 to 1112. For example, in the present embodiment, the “Replay” symbol is assigned to the number 1 frame on the left reel 1110, the “Bell” symbol is assigned to the number 0 frame on the middle reel 1111, and the “No. 2” symbol is assigned to the number 2 frame on the right reel 1112. "Watermelon" design is arranged respectively.

<Type of winning prize>
Next, the types of winning combinations of the slot machine 1100 will be described with reference to FIG. This figure shows the types of winning combinations (including actuating combinations), symbol combinations corresponding to each winning combination, and the operation or payout of each winning combination. Of the winning combinations in the present embodiment, the big bonuses (BB1, BB2) and the regular bonus (RB) are used as a combination for shifting to the bonus game, and the replay (replay) is a replay without newly inserting a medal. Each winning combination is sometimes distinguished from a winning combination and sometimes called an “acting combination”. However, in the “winning combination” in this embodiment, a big bonus, a regular bonus, and a replay that are operating combinations are included. included. In addition, “winning” in the present embodiment includes a case where a symbol combination of an actuator not accompanied by a medal payout (without medal payout) is displayed on an active line, for example, a big bonus, regular Includes bonuses and replay wins.

  The winning combination of the slot machine 1100 includes a big bonus (BB1, BB2), a regular bonus (RB), a small combination (cherry, watermelon, bell), and replay (replay). Needless to say, the type of winning combination is not limited to this and can be arbitrarily adopted.

  “Big Bonus (BB1, BB2)” (hereinafter sometimes simply referred to as “BB”) is a special combination (operating combination) in which a big bonus game (BB game), which is a special game, is started by winning a prize. . Corresponding symbol combinations are “white 7-white 7-white 7” for BB1, and “blue 7-blue 7-blue 7” for BB2. Further, flag carryover is performed for BB1 and BB2. That is, when BB1 and BB2 are won internally, a flag indicating this is raised (stored in a predetermined area of the RAM 1308 of the main control unit 1300), but even if the game does not win BB1 and BB2, Until then, the flag indicating the internal winning is maintained, and even after the next game, BB1 and BB2 are being internally selected, and the symbol combination corresponding to BB1 “white 7-white 7-white 7”, the symbol corresponding to BB2 The combination “blue 7-blue 7-blue 7” is in a state of winning a prize.

  The “regular bonus (RB)” is a special combination (operating combination) in which a regular bonus game (RB game) is started by winning. The corresponding symbol combination is “bonus-bonus-bonus”. Note that the RB carries over the flag as well as the above-mentioned BB. However, in the big bonus game (BB game) (details will be described later), the regular bonus game (RB game) is won internally and the combination of symbols is displayed on the winning line. In addition, the regular bonus game is started after the start of the big bonus game, and when the regular bonus game is finished once, the regular bonus game is automatically started so that the next regular bonus game is immediately started. It is good. “Short (cherry, watermelon, bell)” (hereinafter, simply referred to as “cherry”, “watermelon”, “bell”) is a winning combination in which a predetermined number of medals are paid out by winning. The symbol combinations are “cherry-ANY-ANY” for cherry, “watermelon-watermelon-watermelon” for watermelon, and “bell-bell-bell” for bell. The corresponding payout number is as shown in FIG. In the case of “cherry-ANY-ANY”, the symbol of the left reel 1110 may be “cherry”, and the symbol of the middle reel 1111 and the right reel 1112 may be any symbol.

“Replay” is a winning combination (operating combination) in which a game can be performed without inserting a medal (game medium) in the next game by winning, and no medal is paid out. The corresponding symbol combination is “replay-replay-replay” for replay.
<Type of gaming state>
Next, the types of gaming state of the slot machine 1100 will be described. The gaming state is information for identifying the type of lottery data selected in a lottery or the like. In the present embodiment, the gaming state of the slot machine 1100 is roughly divided into a normal game, a BB game, an RB game, and an internal winning game of a big bonus (BB) and a regular bonus (RB). However, the internal winning game may be a division included in the normal game.
<Normal game>
The winning combinations that are internally won for normal games include a big bonus (BB), regular bonus (RB), replay (replay), and small roles (cherry, watermelon, bell).

  “Big Bonus (BB)” is a special combination (operating combination) in which a big bonus game (BB game), which is a special game, is started by winning. “Regular Bonus (RB)” is a special combination (operating combination) that starts a regular bonus game (RB game) upon winning. The “replay” (replay) is a winning combination (operating combination) in which a game can be performed without a medal being inserted in the next game by winning, and no medal is paid out. The “small role” is a winning combination in which a predetermined number of medals are paid out by winning. In addition, the internal winning probability of each combination is a range of random values obtained at the time of internal lottery from numerical data corresponding to the range of lottery data associated with each combination from lottery data prepared for normal games. It is calculated by the value divided by the numerical data (for example, 65535). The lottery data prepared for the normal game is divided into several numerical ranges in advance, and each combination and lose is associated with each numerical range. It is determined whether the random number value obtained as a result of executing the internal lottery is a value corresponding to the lottery data corresponding to which combination, and the internal lottery combination is determined. The lottery data includes settings 1 to 6 in which the winning probabilities of at least one combination are different, and a game shop clerk can arbitrarily select and set one of the set values.

In the normal game, the internal lottery result is almost lost (big bonus (BB), regular bonus (RB), replay (replay) and small role won), or any stop display result A setting is made so that the stop display result of the losing that does not correspond to the symbol combination of the combination is generally derived, and the total number of medals to be acquired is less than the total number of inserted medals. Therefore, it is a gaming state that is disadvantageous for the player. However, when a predetermined condition is satisfied (for example, when a specific symbol combination is displayed), it is a gaming state that may be changed to increase the probability of internal winning of replaying. In this case, Consumption of medals used for games is suppressed, and a predetermined number of medals are paid out by winning a small role, resulting in a gaming state where the total number of medals exceeds the total number of medals inserted, which is beneficial to the player. May become a gaming state.
<BB game>
The BB game is set to be in a gaming state that is beneficial to the player. That is, the BB game is in a gaming state in which the total number of medals to be acquired exceeds the total number of medals inserted. In this embodiment, the BB game is started by winning a big bonus (BB), and an RB game (described later) can be continuously executed repeatedly, and a predetermined number (for example, during the game) The process ends when more than 465 medals are obtained. However, the BB game only needs to be able to execute the RB game a plurality of times. For example, when a combination (for example, replay-replay-replay) is set for starting the RB game, and this combination is won internally, or The RB game may be set to start when winning. Furthermore, in the BB game, when the BB general game excluding the RB game during the BB game is executed a predetermined number of times (for example, 30 times), or the number of RB games executed during the BB game is a predetermined number of times. It may be made to end when it reaches (for example, three times).
<RB game>
The RB game is set so as to be in a gaming state that is beneficial to the player. That is, the RB game is in a gaming state in which the total number of medals to be acquired exceeds the total number of medals inserted. In this embodiment, the RB game is started by winning a regular bonus (RB), and a predetermined role is set to a variation that increases the probability of internal winning (for example, “setting 1” or “normal game”). The internal winning probability 1/15 of “small role 1” is increased to an internal winning probability 1 / 1.2, which is a predetermined value), and a predetermined number (for example, 8 times) It ends when there is a prize. In the RB game, when a predetermined number of times (at least 2 times) is won (for example, 8 times), or when the number of RB games executed during the RB game reaches a predetermined number of times (for example, (8 times). Since the BB game described above can execute the RB game a plurality of times, when a single RB game is performed, the number of medals less than the total number of medals obtained in the BB game is acquired and terminated. Become.
<Big winning (BB) and regular bonus (RB) internal winning games>
The winning combination that is internally won for the internal winning game of the big bonus (BB) and the regular bonus (RB) includes a replay and a small role. The big bonus (BB) and the regular bonus (RB) are not won internally, and are game states in which a symbol combination corresponding to the big bonus (BB) or the regular bonus (RB) can be won.

  However, the probability of the internal winning of the replay may be changed from the next game internally won in the big bonus (BB) and the regular bonus (RB). Until the symbol combination corresponding to the big bonus (BB) and regular bonus (RB) wins, the total number of medals to be acquired is almost the same as the total number of inserted medals, and is compared with the normal game. The gaming state may be beneficial to the player. It should be noted that BB game and RB game are both game states that are beneficial to the player, and may be generally referred to as bonus games or special games.

<Main control unit main processing>
The main control unit main process executed by the CPU 1304 of the main control unit 1300 will be described with reference to FIG. This figure is a flowchart showing the flow of main processing of the main control unit.

  As described above, the main control unit 1300 is provided with the start signal output circuit (reset signal output circuit) 1338 that outputs the start signal (reset signal) when the power is turned on. The CPU 1304 of the basic circuit 1302 to which the activation signal is input executes reset processing by a reset interrupt, and executes main control unit main processing shown in FIG. 51 in accordance with a control program stored in advance in the ROM 1306.

  When power is turned on, first, various initial settings are made in step SA101. In this initial setting, setting of the stack initial value to the stack pointer (SP) of the CPU 1304, setting of interrupt prohibition, initial setting of the I / O 1310, initial setting of various variables stored in the RAM 1308, operation permission to the WDT 1314, and initial setting Set the value. In step SA103, medal insertion / start operation acceptance processing is executed. Here, it is checked whether or not a medal has been inserted, and the winning line display lamp 1120 is turned on in response to the insertion of the medal. Note that when a re-win is won in the previous game, a process of inserting the same number of medals as the number of medals inserted in the previous game is performed, so that it is not necessary for the player to insert medals. Further, it is checked whether or not the start lever 1135 has been operated. If there is an operation of the start lever 1135, the process proceeds to step SA104.

  In step SA105, the number of inserted medals is determined and an effective winning line is determined. In step SA107, the random number generated by the random number generation circuit 1316 is acquired. In step SA109, the winning combination lottery table stored in the ROM 1306 is read according to the current gaming state, and an internal lottery is performed using this and the random value acquired in step SA107. As a result of the internal lottery, when any winning combination (including an operating combination) is won internally, the flag of the winning combination is turned ON. In step SA111, reel stop data is selected based on the internal lottery result.

  In step SA113, rotation of all reels 1110 to 1112 is started. In step SA115, the stop buttons 1137 to 1139 can be received. When any one of the stop buttons is pressed, the reel stop control in which one of the reels 1110 to 1112 corresponding to the pressed stop button is selected in step SA111. Stop based on data. When all the reels 1110 to 1112 are stopped, the process proceeds to Step SA117. In step SA117, a winning determination is performed. In this case, when a picture combination corresponding to some winning combination is displayed on the activated winning line 1114, it is determined that the winning combination is won. For example, if “bell-bell-bell” is aligned on the activated winning line, it is determined that the player has won the bell. In step SA119, if any winning combination with payout is won, the number of medals corresponding to the winning combination is paid out according to the number of winning lines. In step SA121, game state control processing is performed. In the game state control process, a process related to transition of each game state of normal game, BB game, RB game, and internal winning game is performed, and the game state is shifted when those start conditions and end conditions are satisfied. Thus, one game is completed. Thereafter, returning to step SA103 and repeating the above-described processing, the game proceeds.

<Main control unit 1300 timer interrupt processing>
The main control unit timer interrupt process executed by the CPU 1304 of the main control unit 1300 will be described with reference to FIG. This figure is a flowchart showing the flow of the main control unit timer interrupt process.

  The main control unit 1300 includes a counter timer 1312 that generates a timer interrupt signal at a predetermined cycle (in this embodiment, about once every 2 ms), and the main control unit timer interrupt is triggered by this timer interrupt signal. The process is started at a predetermined cycle.

  In step SB101, timer interrupt start processing is performed. In this timer interrupt start process, a process of temporarily saving the value of each register of the CPU 1304 to the stack area is performed.

  In step SB103, the WDT 1314 is periodically changed to the initial value (32.8 ms in this embodiment) so that no WDT interruption occurs (so as not to detect a processing abnormality). In the embodiment, the restart is performed once every about 2 ms, which is the period of the main control unit timer interrupt.

  In step SB105, input port state update processing is performed. In this input port state update process, the detection signals of the sensor circuits 1320 of the various sensors 1318 are input via the input ports of the I / O 1310 to monitor the presence or absence of the detection signals, and each of the various sensors 1318 is partitioned in the RAM 1308. Store in the provided signal state storage area.

  In step SB107, various game processes are performed. Specifically, an interrupt status is acquired (various interrupt statuses are acquired based on signals from various sensors 1318), and processing according to this status is performed (for example, the interrupt statuses of the acquired stop buttons 1137 to 1139). Based on the stop button reception process).

  In step SB109, timer update processing is performed. Various timers are updated for each time unit.

  In step SB111, command setting transmission processing is performed, and various commands are transmitted to the first sub-control unit 1400. The output schedule information transmitted to the first sub-control unit 1400 is composed of 16 bits in the present embodiment, bit 15 is strobe information (indicating that data is set when ON), bit 11 -14 are command types (in this embodiment, basic command, start lever reception command, production command accompanying production lottery processing, rotation start command when rotation of reels 1110 to 1112 starts, and operation of stop buttons 1137 to 1139 are accepted. Bits 0 to 10 are command data (stop button reception command accompanying the reels 1110 to 1112, stop position information command accompanying the stop processing of the reels 1110 to 1112, payout number command and payout end command accompanying the medal payout processing, etc.) Predetermined information corresponding to the command type).

  The first sub-control unit 1400 can determine the effect control according to the change in the game control in the main control unit 1300 by the command type included in the received output schedule information, and is included in the output schedule information. Based on the information of the command data, the contents of effect control can be determined.

  In step SB113, an external output signal setting process is performed. In this external output signal setting process, game information stored in the RAM 1308 is output to an information input circuit 1652 that is separate from the slot machine 1100 via the information output circuit 1334.

    In step SB109, device monitoring processing is performed. In this device monitoring process, first, the signal states of the various sensors 1318 stored in the signal state storage area in step SB105 are read, and the presence / absence of errors relating to medal insertion abnormality and medal payout abnormality is monitored. (Not shown) Error processing is executed. Further, according to the current gaming state, the medal selector 1170 (medal blocker in which a solenoid provided in the medal selector 1170 operates), various lamps 1338, and various 7-segment (SEG) indicators are set.

  In step SB117, it is monitored whether or not the low voltage signal is on. Then, when the low voltage signal is on (when power supply shutoff is detected), the process proceeds to step SB121, and when the low voltage signal is off (power supply shutoff is not detected), the process proceeds to step SB119.

  In step SB119, various processes for ending the timer interrupt end process are performed. In this timer interrupt end process, the value of each register temporarily saved in step SB101 is set in each original register. Thereafter, the process returns to the main control unit main process shown in FIG.

  On the other hand, in step SB121, a specific variable or stack pointer for returning to the power-off state at the time of power recovery is saved in a predetermined area of the RAM 1308 as return data, and power-off processing such as initialization of the input / output port is performed. After that, the process returns to the main process of the main control unit shown in FIG.

<Processing of First Sub-Control Unit 1400>
The process of the first sub control unit 1400 will be described with reference to FIG. FIG. 53A is a flowchart of the main processing executed by the CPU 1404 of the first sub control unit 1400. FIG. 53B is a flowchart of the command reception interrupt process of the first sub control unit 1400. FIG. 53C is a flowchart of the timer interrupt process of the first sub control unit 1400.

  First, in step SC101 in FIG. 53A, various initial settings are performed. When power is turned on, initialization processing is first executed in step SC101. In this initialization process, initial setting of input / output ports, initialization processing of a storage area in the RAM 1408, and the like are performed.

  In step SC103, it is determined whether or not the timer variable is 10 or more. This process is repeated until the timer variable becomes 10. When the timer variable becomes 10 or more, the process proceeds to step SC105.

  In step SC105, 0 is assigned to the timer variable.

  In step SC107, command processing is performed. In the command processing, the CPU 1404 of the first sub control unit 1400 determines whether a command is received from the main control unit 1300.

  In step SC109, effect control processing is performed. For example, if there is a new command in step SC107, processing corresponding to this command is performed. This process includes, for example, performing a process such as reading effect data from the ROM 1406, and performing an effect data update process when the effect data needs to be updated.

  In step SC111, sound control processing is performed based on the processing result of step C09. For example, if there is a command to the sound source IC 1418 in the effect data read in step SC109, this command is output to the sound source IC 1418.

  In step SC113, lamp control processing is performed based on the processing result of step C09. For example, if there is a command to the various lamps 1420 in the effect data read in step SC109, this command is output to the drive circuit 1422.

  In step SC115, an information output process is performed for setting to transmit a control command to the second sub-control unit 500 based on the processing result of step C09. For example, if there is a control command to be transmitted to the second sub control unit 1500 in the effect data read in step SC109, the control command is set to be output, and the process returns to step SC103.

  Next, a command reception interrupt process of the first sub control unit 1400 will be described with reference to FIG. This command reception interrupt process is a process executed when the first sub control unit 1400 detects the strobe signal output from the main control unit 1300. In step SD101 of the command reception interrupt process, the command output from the main control unit 1300 is stored in the command storage area provided in the RAM 1408 as an unprocessed command.

  Next, the first sub control unit timer interrupt process executed by the CPU 1404 of the first sub control unit 1400 will be described with reference to FIG. The first sub-control unit 1400 includes a hardware timer that generates a timer interrupt at a predetermined cycle (in this embodiment, once every 2 ms), and this timer interrupt is used as a trigger to perform timer interrupt processing. Execute in the cycle.

  In step SE101, 1 is added to the value of the timer variable storage area of the RAM 1408 described in step SC103 in the first sub control unit main process shown in FIG. 53A, and the result is stored in the original timer variable storage area. Therefore, in step SC103, the value of the timer variable is determined to be 10 or more every 20 ms (2 ms × 10).

  In step SE103, control command transmission to second sub-control unit 1500 set in step SC115, effect random number update processing, and the like are performed.

<Processing of Second Sub-Control Unit 1500>
The process of the second sub control unit 1500 will be described with reference to FIG. FIG. 54A is a flowchart of main processing executed by the CPU 1504 of the second sub-control unit 1500. FIG. 54B is a flowchart of the command reception interrupt process of the second sub-control unit 1500. FIG. 54C is a flowchart of the timer interrupt process of the second sub control unit 1500. FIG. 54D is a flowchart of the image control process of the second sub control unit 1500.

  First, in step SG01 in FIG. 54A, various initial settings are performed. When the power is turned on, an initialization process is first executed in step SF101. In this initialization process, input / output port initialization, storage area initialization in the RAM 1508, and the like are performed.

  In step SF103, it is determined whether or not the timer variable is 10 or more. This process is repeated until the timer variable becomes 10, and when the timer variable becomes 10 or more, the process proceeds to step SF105.

  In step SF105, 0 is substituted for the timer variable.

  In step SF107, command processing is performed. In the command processing, the CPU 1504 of the second sub control unit 1500 determines whether a command is received from the CPU 1404 of the first sub control unit 1400.

  In step SF109, effect control processing is performed. For example, if there is a new command in step SF107, processing corresponding to this command is performed. This process includes, for example, performing a process such as reading effect data from the ROM 1506 and performing an effect data update process when the effect data needs to be updated.

  In step SF111, shutter control processing is performed based on the processing result of step SF109. For example, if there is a shutter control command in the effect data read in step SF109, shutter control corresponding to this command is performed.

  In step SF113, image control processing is performed based on the processing result of step SF109. For example, if there is an image control command in the effect data read in step SF109, image control corresponding to this command is performed (details will be described later), and the process returns to step SF103.

  Next, the command reception interrupt process of the second sub control unit 1500 will be described with reference to FIG. This command reception interrupt process is a process executed when the second sub control unit 1500 detects a strobe signal output from the first sub control unit 1400. In step SG101 of the command reception interrupt process, the command output from the first sub control unit 1400 is stored in the command storage area provided in the RAM 1508 as an unprocessed command.

  Next, the second sub control unit timer interrupt process executed by the CPU 1504 of the second sub control unit 1500 will be described with reference to FIG. The second sub-control unit 1500 includes a hardware timer that generates a timer interrupt at a predetermined cycle (in this embodiment, once every 2 ms). Execute in the cycle.

  In step SH101, 1 is added to the value of the timer variable storage area of the RAM 1508 described in step SF103 in the second sub-control unit main process shown in FIG. 54A, and the result is stored in the original timer variable storage area. Therefore, in step SF103, the value of the timer variable is determined to be 10 or more every 20 ms (2 ms × 10). In step SH103, an effect random number update process is performed.

  Next, the image control process in step SF113 in the main process of the second sub control unit 1500 will be described with reference to FIG. FIG. 5 is a flowchart showing the flow of image control processing.

  In step SI101, an instruction to transfer image data is issued. Here, the CPU 1504 first swaps the designation of the display areas A and B in the VRAM 1536. As a result, the one-frame image stored in the display area not designated as the drawing area is displayed on the effect image display device 1157. Next, the CPU 1504 sets the ROM coordinates (transfer source address of the ROM 1506), VRAM coordinates (transfer destination address of the VRAM 1536) and the like in the attribute register of the VDP 1534 based on the position information table, and then the image from the ROM 1506 to the VRAM 1536. Set an instruction to start data transfer. The VDP 1534 transfers image data from the ROM 1506 to the VRAM 1536 based on the command set in the attribute register. Thereafter, the VDP 1534 outputs a transfer end interrupt signal to the CPU 1504.

  In step SI103, it is determined whether or not a transfer end interrupt signal from VDP 1534 is input. If a transfer end interrupt signal is input, the process proceeds to step SI105. If not, a transfer end interrupt signal is input. Wait for it. In step SI105, parameters are set based on the production scenario configuration table and attribute data. Here, in order to form a display image in the display area A or B of the VRAM 1536 based on the image data transferred to the VRAM 1536 in step SI101, the CPU 1504 has information on the image data constituting the display image (coordinate axis and image size of the VRAM 1536). , VRAM coordinates (arrangement coordinates, etc.) are instructed to the VDP 1534. The VDP 1534 performs parameter setting according to the attribute based on the instruction stored in the attribute register.

  In step SI107, a drawing instruction is performed. In this drawing instruction, the CPU 1504 instructs the VDP 1534 to start drawing an image. The VDP 1534 starts drawing an image in the frame buffer in accordance with an instruction from the CPU 1504.

  In step SI109, it is determined whether or not a generation end interrupt signal from the VDP 1534 based on the end of image drawing is input. If a generation end interrupt signal is input, the process proceeds to step SI111. If not, the generation end interrupt signal is determined. Wait for input. In step SI111, a scene display counter that is set in a predetermined area of the RAM 1508 and counts how many scene images have been generated is incremented (+1), and the process is terminated.

Claims (5)

A first substrate;
Cover means;
A game machine equipped with
The first substrate is a substrate having a first light emitting means,
The first substrate is a substrate having first substrate constituting means,
The cover means is means having a transmission part,
The cover means is means having a non-transmissive portion,
The first light emitting means is located between the first substrate and the non-transmissive portion,
The first substrate constituting means is located between the first substrate and the non-transmissive portion,
The position of the first substrate constituting means is a position where light from the first light emitting means reaches,
The posture of the first light emitting means is changed so that the confirmer can visually recognize the first light emitting means from a direction perpendicular to the game table .
With movable movable means,
The movable means is means having the first substrate,
The movable means is means having the cover means,
When the movable means operates, the posture of the first light emitting means changes .
A game stand characterized by that. The game stand according to claim 1 ,
The first substrate constituting means is an electronic circuit constituting means.
A game stand characterized by that. The game stand according to claim 1 or 2 ,
The first substrate constituting means is an identification display.
A game stand characterized by that. It is a game stand as described in any one of Claims 1 thru | or 3 , Comprising:
The game machine is a pachinko machine,
A game stand characterized by that. It is a game stand as described in any one of Claims 1 thru | or 3 , Comprising:
The gaming table is a slot machine,
A game stand characterized by that.

Images