JP2021171556A - Game machine - Google Patents

Abstract

To suppress defects related to a power supply board.SOLUTION: A game machine includes a substrate having a plurality of electronic components and used for a game, and accommodating means for accommodating the substrate. The substrate has an AC circuit to which an AC voltage is supplied, a DC circuit to which a DC voltage converted from the AC voltage is supplied, first identification display for identifying information, and second identification display provided at a position different from the first identification display in the thickness direction of the substrate, which is a display for identifying information. Capacitors are provided in each of the AC circuit and the DC circuit.SELECTED DRAWING: Figure 9

Description

The present invention relates to a gaming machine.

In a gaming machine, for example, Patent Document 1 describes that a power supply board for producing electric power used for a gaming machine main body from a commercial power source is used.

Japanese Unexamined Patent Publication No. 2016-140643

However, in a gaming machine as described in the above patent document, there is room for further improvement in terms of suppressing defects related to the power supply board.

An object of the present invention is to suppress defects related to a power supply board.

The present invention that achieves the above object is realized as the following gaming machine. This gaming machine (for example, the pachinko gaming machine 100) has a substrate (for example, a power supply substrate 40) having a plurality of electronic components and used for a game, and an accommodating means (for example, a power supply substrate 40) for accommodating the substrate (for example, the power supply substrate 40). , Power supply board case 60), and the board (for example, power supply board 40) is supplied with an AC circuit (for example, an AC circuit 41) to which an AC voltage is supplied and a DC voltage converted from the AC voltage. A DC circuit (for example, a DC circuit 50), a first identification display for identifying information, and a display for identifying information, the first identification in the thickness direction of the substrate. It has a second identification display provided at a position different from the display, and the AC circuit (for example, AC circuit 41) and the DC circuit (for example, DC circuit 50) are provided with capacitors, respectively. It is a featured gaming machine.

It should be noted that the above-mentioned reference numerals in this column are exemplarily attached in the description of the present invention, and the present invention is not reduced by these reference numerals.

According to the present invention, it is possible to suppress defects related to the power supply board.

It is a schematic front view of the pachinko gaming machine which concerns on this embodiment. It is a rear view of the pachinko game machine when the pachinko game machine is seen from the rear side. (A) is an enlarged view showing an example of a display arranged at the lower left of the game board, (b) is a partial plan view of the pachinko game machine, and (c) is arranged at the lower left of the game board. It is an enlarged view which shows an example of the sub-information display. It is a figure which shows the internal structure of the control unit of the pachinko game machine of this embodiment. It is explanatory drawing of the image / sound control part and the lamp control part of this embodiment. It is a block diagram which shows the functional structure of the game control part of this embodiment. It is a flowchart which shows the operation of the basic processing by a game control unit. It is a flowchart which shows the operation of the processing at the time of power-off by a game control unit. It is a figure which shows the structure of the electronic circuit in a power-source board. It is a figure which shows the structure of the AC circuit in the power-source board. It is a figure which shows the structure of the rectifier circuit and the PFC circuit in a power supply board. It is a figure which shows the structure of the power generation circuit and the backup circuit in a power supply board. It is a figure which shows the structure of the electronic circuit in the power-source board as a modification. It is a figure which shows the structure of the PFC circuit as a modification. It is an overall perspective view of the power supply board unit of this embodiment. It is a top view of the power supply board when the power supply board of this embodiment is seen from the front side. It is a rear view of the power supply board when the power supply board of this embodiment is seen from the rear side. It is a side view of the power supply board when the power supply board of this embodiment is seen from the upper side. It is sectional drawing of a part of the substrate of this embodiment. (A) is a diagram showing a power supply board in a state before the electronic components are mounted, and (B) is a diagram showing a power supply board in a state in which the electronic components are mounted. (A) is an overall side view of the power supply board unit, and (B) is an enlarged view of a vent hole which will be described later. It is a side view when the power supply board unit of this embodiment is seen from the right side. It is a side view when the power supply board unit of this embodiment is seen from the left side. It is explanatory drawing of the power-source board case of this embodiment. It is the top view which looked at the power-source board of a modification from the front side. It is a front view of the game control board unit. It is a figure which shows the information display sticker. It is a front view of the game control board. It is the figure when the capacitor is viewed from the front side of the capacitor. It is a flowchart which shows the main control process of a game control part. It is a flowchart which shows the content of the start port switch processing. It is a flowchart which shows the content of the gate switch processing. It is a flowchart which shows the content of the special symbol processing. It is a flowchart which shows the content of a jackpot determination process. It is a flowchart which shows the content of the variation pattern selection process. It is a flowchart which shows the content of the processing during stop. It is a flowchart which shows the content of the customer waiting setting process. It is a flowchart which shows the content of ordinary symbol processing. It is a flowchart which shows the content of the big prize opening process. It is a flowchart which shows the content of the game state setting process. It is a flowchart which shows the content of the electric tulip processing. It is a figure which shows the composition example of the random number used in this embodiment, (a) is a figure which shows the composition example of a jackpot random number, (b) is a figure which shows the composition example of a jackpot symbol random number, (c). Is a diagram showing a configuration example of a reach random number, and (d) is a diagram showing a configuration example of a hit random number. It is a figure which shows the setting example of the variation pattern and the table used in the variation pattern selection process. It is a block diagram explaining the structure example of the RAM of the game control part, (a) is a block diagram which shows the structure of a storage area, (b) is a block diagram which shows each structure of the storage part shown in (a). Is. It is a block diagram explaining the structure example of the RAM of the effect control part, (a) is a block diagram which shows the structure of the hold storage area, (b) is a block which shows each structure of the storage part shown in (a). It is a figure. It is a flowchart which shows the content of the preliminary determination processing. It is a flowchart which shows the operation of an effect control part, (a) is a figure which shows the main process, (b) is a figure which shows the interrupt process. It is a flowchart which shows the content of a command reception process. FIG. 8 is a flowchart showing the contents of the pre-determination effect selection process and the effect selection process of FIG. 48. It is a flowchart which shows the content of the jackpot effect selection process of FIG. 48. It is a flowchart which shows the content of the ending effect selection process of FIG. 48. It is a flowchart which shows the content of the customer waiting command reception process of FIG. 48. It is a flowchart which shows the content of the effect button processing. It is a figure which shows the display information of the information display in each game section. It is a figure which shows the main processing of the integrated control unit. It is a figure which shows the accessory initial processing of a lamp control part. It is a figure which shows the origin return processing of a lamp control part. It is a figure which shows the initial operation process of a lamp control part. (A) is a diagram showing an example of a board accessory initial operation pattern determination table, and (b) is a diagram showing an example of a frame accessory initial operation pattern determination table. It is a figure which shows the specific example at the time of initial operation of various drive sources while changing a setting. It is a figure which shows the specific example at the time of initial operation of various drive sources during preparation for clearing RWM. It is a figure which shows the specific example at the time of initial operation of various drive sources during setting confirmation. It is a figure which shows the specific example at the time of initial operation of various drive sources after a setting change. It is a figure which shows the specific example at the time of initial operation of various drive sources after clearing RWM. It is a figure which shows the specific example at the time of initial operation of various drive sources after confirmation of a setting.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.
[Basic configuration of gaming machines]
FIG. 1 is a schematic front view of the pachinko gaming machine 100 according to the present embodiment.
The pachinko game machine 100 as an example of the game machine shown in FIG. 1 is configured to pay out a prize ball when a game ball launched by a player's instruction operation wins a prize. The pachinko gaming machine 100 includes a game board 110 on which a game ball is launched, and a frame member 150 surrounding the game board 110. The game board 110 is detachably attached to the frame member 150.

The game board 110 has, on the front surface, a game area 111 for playing a game with a game ball, a rail member 112 on which a game ball launched from below rises and forms a passage toward an upper position of the game area 111, and a game. A guide member 113 for guiding the game ball is provided on the right side of the region 111.
In the present embodiment, an image display unit 114 for displaying various images for effect is provided at a position of the game area 111 that is easily visible to the player. The image display unit 114 is provided with a display screen such as a liquid crystal display, and as the game progresses by the player, for example, a decorative symbol for notifying the player of the symbol lottery result (symbol change result) can be displayed. It displays an effect image due to the appearance of a character or an item, or an effect image using the hold display described later.
Further, on the front surface of the game board 110, a movable accessory 115 and a board lamp 116 used for various effects are provided. The movable accessory 115 performs various effects by operating on the game board 110, and the board lamp 116 produces various effects by emitting light.

The game area 111 is provided with a game nail, a windmill, and the like (not shown) for changing the direction in which the game ball falls. Further, in the game area 111, various accessories related to winning a prize or a lottery are arranged at predetermined positions. Further, the game area 111 is provided with an discharge port 117 that discharges a game ball launched into the game area 111 that has not won a prize in the winning port to the outside of the game area 111. The pachinko gaming machine 100 includes an out-ball detection switch (SW) 227 (see FIG. 4 to be described later) that detects an out-ball composed of game balls flowing into the discharge port 117.

In the present embodiment, as various accessories related to winning and lottery, the first starting port 121 and the second starting port 122 where the special symbol lottery (big hit lottery) starts when the game ball wins, and the second starting port 122 when the game ball passes are normal. A starting gate (hereinafter, simply referred to as a gate) 124 at which a symbol lottery (opening / closing lottery) is started is arranged on the game board 110. In FIG. 1, gates 124 are provided on the left and right sides of the game area 111, the gate 124 on the left side is described as 124L, and the gate 124 on the right side is described as 124R. Further, the first starting port 121 and the second starting port 122 referred to here refer to winning openings that trigger the operation of the predetermined special symbol display 1. Specifically, the first starting port 121 and the second starting port 122 are provided with switches (first starting port switch 211 and second starting port switch 212, which will be described later) that detect the passage of a game ball at the time of winning a prize. Has been done. Then, when the game ball wins a prize in the first start port 121 or the second start port 122, the switch detects the passage of the game ball, which triggers the operation of the special symbol display.

The second starting port 122 includes an electric tulip (opening / closing member) 123 as a normal electric accessory that lights up while a pair of tulip flower-shaped blades are opened / closed by an electric solenoid. In the electric tulip 123, when the blades are closed, it is difficult for the game ball to enter the second starting port 122, while when the blades are opened, the entrance of the second starting port 122 expands and the game ball moves to the second starting port 122. It is configured to be easy to enter. Then, when the electric tulip 123 wins the ordinary symbol lottery, the blades open for a specified time (for example, 0.15 seconds to 1.8 seconds) and a specified number of times (for example, 1 to 3 times) while lighting or blinking.

The pachinko gaming machine 100 has, as a gaming state, a low probability state in which the winning probability is low and a high probability state in which the winning probability is higher than the low probability state, based on the winning probability of the jackpot lottery. Then, it is controlled to either a low probability state or a high probability state based on a predetermined condition.
Further, the pachinko gaming machine 100 has a gaming state of no electric support with few chances of winning the second starting port 122 and an electric support state with more chances of winning the second starting port 122 than with no electric support. have. Then, for example, under a predetermined condition such as a big hit or the number of lottery of the special symbol lottery, the state is controlled to either the electric support state or the electric support state. The electric support state is, for example, one or more of shortening the normal symbol fluctuation time, extending the opening time of the electric tulip 123, and increasing the winning probability of the normal symbol lottery. It is a gaming state controlled by a combination.
Further, the pachinko gaming machine 100 has a time-saving state in which the special symbol variation time is long and a time-saving state in which the special symbol variation time is shorter than the time-saving non-state.
In this embodiment, the electric support state and the time saving state are controlled at the same time. Further, in the following description, the electric support state and the time saving state are simply referred to as the time saving state, and the electric support non-state and the time saving non-state are simply referred to as the time saving non-state.

Further, in the present embodiment, as other accessories related to winning and lottery, a large winning opening 125 as a special electric accessory that opens according to the result of the special symbol lottery and a lottery even if the game ball wins are performed. A normal winning opening 126 and a normal winning opening 126 are arranged on the game board 110. The large winning opening 125 is provided with a large winning opening door 125D that opens and closes the large winning opening 125. In the following description, the opening / closing state and opening / closing operation of the large winning opening door 125D may be described as the opening / closing state and opening / closing operation of the large winning opening 125 for convenience.
In the present embodiment, a display 130 for displaying the lottery result and the number of holdings is arranged at the lower left position of the game board 110.

By the way, in the pachinko gaming machine 100 shown in FIG. 1, the second starting port and the large winning opening 125 provided with the electric tulip 123 are arranged in the right area of the game area 111. Therefore, in the pachinko gaming machine 100 of the present embodiment, when trying to win a prize in the second starting port 122 or the large winning opening 125, the game ball is allowed to flow down to the right area of the game area 111. ..

When the player touches the handle 151 to rotate the lever 152 clockwise, the frame member 150 causes the game balls to be hit at a predetermined time interval (for example, 100 pieces per minute) with a striking force according to the operation angle. It is equipped with a launcher (not shown) that launches electrically at. Further, the frame member 150 includes a supply device (not shown) that sequentially supplies game balls to the launcher one by one at a timing linked to an operation by the player's lever 152, and a game ball that the supply device supplies to the launcher. It is equipped with a plate 153 for temporarily storing. For example, a payout ball by a payout unit is paid out to the plate 153.
In the present embodiment, the plate 153 is integrally formed with the upper and lower plates, but a configuration example in which the upper plate and the lower plate are separated can also be considered. Further, a configuration example in which the handle 151 of the launching device is made to emit light under a predetermined condition is also conceivable.

Further, the frame member 150 has a stop button 154 for temporarily stopping the firing of the game ball even when the player is touching the handle 151 of the launching device, and the game ball accumulated in the plate 153. It is provided with an eject button 155 for dropping it into a box (not shown) and ejecting it.
Further, the frame member 150 includes a speaker 156 and a frame lamp 157 for notifying the gaming state and situation of the pachinko gaming machine 100 and performing various effects. The speaker 156 performs various effects by music, voice, and sound effects. The frame lamp 157 is composed of a light emitting body such as an LED, and performs various effects by light depending on a pattern due to lighting / blinking and a difference in light emission color. As for the frame lamp 157, a configuration example that enables an effect of changing the light irradiation direction can be considered.
Further, the frame member 150 includes a transparent plate (not shown) for separating the game board 110 from the player.

FIG. 2 is a rear view of the pachinko gaming machine 100 when the pachinko gaming machine 100 is viewed from the rear side. In FIG. 2, the upper side of the paper surface of the pachinko gaming machine 100 is referred to as “upper side”, the lower side of the paper surface is referred to as “lower side”, and these directions may be referred to as “vertical direction”. Further, the left side of the paper surface of the pachinko gaming machine 100 may be referred to as "left side", the right side of the paper surface may be referred to as "right side", and these directions may be referred to as "left-right direction". Further, the front side of the paper surface of the pachinko gaming machine 100 is referred to as the "front side", the rear side of the paper surface is referred to as the "rear side", and these directions may be referred to as the "front-back direction".

The pachinko gaming machine 100 includes a power plug 158, a power supply board unit 4, a game control board unit 2, an effect control board 300B, an image control board 310B, a lamp control board 320B, a payout control board 330B, and a frame. A control board 360B is provided. The power plug 158 is provided on the frame member 150. Further, the power supply board unit 4 and the frame control board 360B are attached to the back surface of the frame member 150. Further, the game control board unit 2, the effect control board 300B, the image control board 310B, the lamp control board 320B, and the payout control board 330B are attached to the back surface of the game board 110.
When the power plug 158 is plugged into the outlet of the transformer T and the plug of the transformer T is plugged into the outlet (not shown) in the hall where the pachinko game machine 100 is installed, the commercial power supply is AC to the transformer T. (AC: Alternating current) 100V power is supplied. The transformer T converts the supplied AC100V into AC24V. The electric power of AC24V converted to the transformer T is supplied to the pachinko gaming machine 100 via the power plug 158.

The power supply board unit 4 has a power supply board 40 and a power supply board case 60 for accommodating the power supply board 40.
The power supply board 40 is electrically connected to the power supply plug 158. Further, the power supply board 40 is provided with a power supply switch 412 (described later) for switching ON / OFF of the connection with the commercial power supply. When the power switch 412 is turned on, the power supply board 40 receives the alternating current power supplied from the commercial power supply via the transformer T. Then, the power supply board 40 converts the received AC power into direct current (DC) power, and the converted power is converted into the game control board unit 2, the effect control board 300B, the image control board 310B, and the lamp control. It is supplied to the substrate 320B, the payout control substrate 330B, and the frame control substrate 360B. Further, when the power switch 412 is turned off, the power supply to the power supply board 40 is cut off. As a result, the power supply of the pachinko gaming machine 100 is cut off.
The configuration of the power supply board 40 and the power supply board case 60 will be described in detail later.

The game control board unit 2 has a game control board 200B and a game control board case 200C for accommodating the game control board 200B. The game control board 200B determines whether or not a special symbol has been won.
The effect control board 300B controls the effect in an integrated manner.
The image control board 310B controls the effect of images and sounds.
The lamp control board 320B controls the effect of the various board lamps 116 and the movable accessory 115.
The payout control board 330B controls the payout of prize balls.
The frame control board 360B controls the effect of various frame lamps 157 and the like.
The game control board 200B, the effect control board 300B, the image control board 310B, the lamp control board 320B, the payout control board 330B, and the frame control board 360B operate by being supplied with electric power from the power supply board 40.

FIG. 3 is a diagram illustrating the pachinko gaming machine 100 according to the present embodiment, and FIG. 3A is an enlarged view showing an example of a display 130 arranged at the lower left of the gaming board 110. FIG. 3B is a partial plan view of the pachinko gaming machine 100, and FIG. 3C is an enlarged view showing an example of a sub-information display 80 arranged at the lower left of the gaming board.
As shown in FIG. 3A, the display 130 of the pachinko gaming machine 100 wins the first special symbol display 221 and the second starting port 122, which operate in response to the winning of the first starting port 121. It includes a second special symbol display 222 that operates in response to the passage of the gate 124, and a normal symbol display 223 that operates in response to the passage of the gate 124. The first special symbol display 221 displays the lottery result by displaying the special symbol in a variable manner and then stopping the display based on the winning of the first starting port 121. The second special symbol display 222 displays the lottery result by displaying the special symbol in a variable manner and then stopping the display based on the winning of the second starting port 122. The first special symbol display 221 and the second special symbol display 222 perform cycle fluctuation (cycle display) in which the change of the display mode is one cycle (= 256 ms) a plurality of times, and stop when the fluctuation time of the special symbol elapses. indicate.
Based on the fact that the game ball has passed through the gate 124, the normal symbol display 223 displays the normal symbol in a variable manner and then stops and displays the lottery result. In the present embodiment, the first special symbol display 221 and the second special symbol display 222 are each composed of a display device in which LEDs are arranged, and the lottery result of the special symbol lottery is displayed depending on the lighting mode thereof. Similarly, the ordinary symbol display 223 is also composed of a display device in which LEDs are arranged, and the lottery result of the ordinary symbol lottery is displayed depending on the lighting mode thereof.

Further, the display 130 operates in response to the hold on the first special symbol display 221 and the first special symbol hold display 218 and the second special symbol display 222. 2 The special symbol hold indicator 219 and the normal symbol hold indicator 220 that operate in response to the hold on the normal symbol indicator 223 are provided. In the present embodiment, the first special symbol hold indicator 218, the second special symbol hold indicator 219, and the ordinary symbol hold indicator 220 are each composed of a display device in which LEDs are arranged, and the number of holds is determined by the lighting mode thereof. Is displayed.

Here, the hold will be described. If a game ball wins a prize in the first starting port 121 or the second starting port 122 during the variable display operation of the special symbol (while the variable display for one winning is being performed), the special symbol is changing. In addition, it is not possible to start the variable display operation of the special symbol based on the later winning. Therefore, the later winnings are stored up to the specified number (for example, 4), and the right to start the special symbol for the winning game ball is until the variable display operation for the first winning game ball is completed. It is put on hold.
It should be noted that the same processing as for the special symbol is performed for the normal symbol. The fact that such a hold has been made and the number of holds (unchanged number) are displayed on the first special symbol hold indicator 218, the second special symbol hold indicator 219, and the ordinary symbol hold indicator 220.

Further, the display 130 includes a state display 224 that displays the state of the pachinko gaming machine 100. In the present embodiment, the status display 224 is composed of a display device in which three LEDs are arranged. One of the three LEDs lights up to notify whether or not the state of the pachinko gaming machine 100 is in a high probability state in which the winning probability of the special symbol lottery is high. The other one is to notify by lighting whether or not the state of the pachinko gaming machine 100 is in a time-saving state in which the special symbol fluctuation time is short. Yet another one is to notify by lighting whether or not the player is in an advantageous state by hitting right (by changing the hitting force of the game ball).

Further, the display 130 includes a round number display 225 that displays the number of rounds when the big winning opening 125 is operated in the big hit game performed according to the lottery result of the special symbol lottery. The jackpot game will be described later. The round number display 225 is composed of a display device in which LEDs are arranged, and the number of operating rounds of the big winning opening 125 in the big hit game is displayed depending on the lighting mode thereof.

Further, the display 130 includes a state confirmation display 226. The status confirmation display 226 is composed of one LED and is for indicating that the setting change mode described later or the setting confirmation mode described later is set. When the mode is changed to the setting change mode or the setting confirmation mode. The lighting of the LED is started, and when the setting change mode or the setting confirmation mode is completed, the LED is turned off. In this way, since the status confirmation display 226 is provided on the front surface (front surface) of the gaming machine, it is possible to easily confirm whether or not the setting change mode or the setting confirmation mode is set. .. The status confirmation indicator 226 may be installed in front of (the surface) of the pachinko gaming machine 100, or may be installed in another place.

Further, in the present embodiment, the display mode (lighting display) is the same regardless of whether the setting change mode or the setting confirmation mode is set, but it is recognized which mode is set. It may be displayed as possible. For example, in the setting change mode, the status confirmation indicator 226 may be lit and displayed, and in the setting confirmation mode, the status confirmation indicator 226 may be blinked and vice versa.

Further, in the present embodiment, the status confirmation display 226 is provided as a dedicated display to indicate that the setting change mode or the setting confirmation mode is set, but it may also be used as another display. For example, in the setting change mode and the setting confirmation mode, the first special symbol display 221 and the second special symbol display 222, the first special symbol hold indicator 218, the second special symbol hold indicator 219, and the number of rounds indicator Since 225, the status indicator 224, and the like are turned off, one or a plurality of LEDs of these indicators may be turned on.

The frame member 150 of the pachinko gaming machine 100 includes an input device for the player to input an effect. As shown in FIG. 3B, in the present embodiment, as an example of the input device, an effect button 161 and an effect key 162 adjacent to the effect button 161 and composed of a plurality of keys arranged in a substantially cross shape are used. Is arranged on the frame member 150. In the illustrated example, consider a case where an effect of accepting an operation of selecting one image from a plurality of images is performed. In this case, for example, the player operates the effect key 162 composed of four keys arranged in a cross shape to instruct one of the plurality of images displayed on the image display unit 114, and presses the effect button 161. By operating it, it is possible to perform an effect such as selecting an instructed image. Further, as the form of the input device, in addition to the illustrated effect button 161 and effect key 162, various input forms such as a lever and a handle can be adopted depending on the content of the effect and the like.

Further, in the pachinko gaming machine 100 of the present embodiment, the sub first fluctuation display 81, the sub second fluctuation display 82, the sub first hold display 83, and the sub second hold display 84 are inside the game area 111. A sub-information display 80 including a sub-normal figure fluctuation display 85, a sub-normal figure hold display 86, and a sub right-handed display 87 is provided.
The sub-information display 80 is basically composed of LEDs, and is dynamically lit. The sub-information display 80 is not provided with a display indicating that the setting change mode or the setting confirmation mode is set, such as the status confirmation display 226.

The sub first variable display 81 is for displaying (notifying) whether or not the first special symbol is in variable display, and the sub second variable display 82 is for displaying (notifying) whether or not the first special symbol is changing. It is for displaying (notifying) whether or not it is inside, and each is composed of one LED. Then, when the variation display of the corresponding special symbol is started, the LED blinks at a predetermined cycle (1 second) (lights up for 0.5 seconds → turns off for 0.5 seconds), and lights up when the corresponding special symbol is stopped and displayed. do. In other words, the sub-first fluctuation display 81 and the sub-second fluctuation display 82 repeat the cycle display in which one blinking is one cycle (= 1 second), and when the corresponding special symbol is stopped and displayed. Light.

The sub-first variation display 81 and the sub-second variation indicator 82 may be used to notify the result of the jackpot determination of the special symbol. In this case, it is advisable to turn on the LED in the case of a big hit and turn off the LED in the case of a loss.

The sub first hold indicator 83 is for displaying the number of first hold information (first hold number) described later, and the sub second hold indicator 84 is for displaying the number of second hold information described later (the number of second hold information described later). It is for displaying the second hold number), and each is composed of two LEDs. Then, when the number of holds is "0", the left and right LEDs are turned off, when the number of holds is "1", the LED on the left turns on and the LED on the right turns off, and when the number of holds is "2". The left and right LEDs are lit, and when the number of holds is "3", the left LED blinks and the right LED is lit, and when the number of holds is "4", the left and right LEDs blink.

The sub-normal map fluctuation display 85 is for displaying (notifying) the result of the winning lottery, and is composed of one LED. Then, when the variation display of the normal symbol is started, the LED blinks (variation display) at a predetermined interval. Then, when the normal symbol is stopped and displayed, the mode indicating the result of the winning lottery (lights up in the case of a hit, turns off in the case of a loss) is stopped and displayed.

In addition, in the sub-normal symbol variation display 85, it blinks during the fluctuation display of the normal symbol and turns on or off when the stop display is displayed so that only whether or not the fluctuation display of the normal symbol is in progress can be grasped. You may.

The sub-normal figure hold indicator 86 is for displaying the number of normal figure hold storages (the number of normal figure hold), and is composed of two LEDs. Then, when the number of reserved figures is "0", the left and right LEDs are turned off, and when the number of reserved figures is "1", the left LED is turned on and the right LED is turned off. When "2", the LED on the left side blinks and the LED on the right side lights up, and when the number of reserved figures is "4", the left and right LEDs blink.

The sub-right-handed display 87 is for urging the game ball to be launched toward the right side area of the game area 111 (so-called right-handed), and is composed of one LED. Then, the LED is turned on during the jackpot state (special game) and the time-saving game state, and the LED is turned off in other game states.

[Control unit configuration]
Next, a control unit that performs operation control and signal processing in the pachinko gaming machine 100 will be described.
FIG. 4 is a block diagram showing an internal configuration of a control unit of the pachinko gaming machine of the present embodiment.
FIG. 5 is an explanatory diagram of an image / acoustic control unit and a lamp control unit according to the present embodiment.

As shown in FIG. 4, the control unit includes a game control unit 200 as a main control means, which determines whether or not a special symbol has been won. Further, as sub-control means, an effect control unit 300 that comprehensively controls the effect and a payout control unit 330 that controls the payout of payout balls are provided.

[Configuration / function of game control unit]
The game control unit 200 is used as a CPU 201 that performs arithmetic processing when determining the winning of a special symbol, a ROM 202 that stores programs and various data executed by the CPU 201, and a working memory of the CPU 201. RAM 203 and

The game control unit 200 controls the gaming state of the pachinko gaming machine 100 in either a high-probability state or a low-probability state, a time-saving no state, or a time-saving state. As a result, the gaming states of the pachinko gaming machine 100 are the high-probability time-saving game state, which is the high-probability state and the time-saving state, the low-probability time-saving game state, which is the low-probability state and the time-saving state, and the high-probability state and the time-saving non-state. It is one of a low-probability time-saving no-game state, a low-probability state, and a low-probability time-saving no-game state. Then, the game control unit 200 switches between the high-probability state and the low-probability state, and switches between the time-saving non-state and the time-saving state based on a predetermined condition. Further, the game control unit 200 controls such as making the winning probability of the normal symbol lottery higher, shortening the normal symbol fluctuation time, extending the opening time of the electric tulip 123, etc. in the time saving state than in the time saving state. I do.

The game control unit 200 draws a special symbol lottery when the game ball wins a prize in the first start port 121 or the second start port 122. Then, a special game such as a big hit game is performed according to the judgment result of the special symbol lottery. In the special game, the game control unit 200 holds a predetermined number of rounds in which the large winning opening 125, which is a special electric accessory, is maintained in an open state until a predetermined condition (for example, 29.5 seconds have passed or 10 game balls have been won). Control to repeat only. Then, the game control unit 200 controls the opening / closing operation interval when the big winning opening 125 opens.

In addition, the game control unit 200 performs a normal symbol lottery when the game ball passes through the gate 124. Then, the operation of the electric tulip is controlled according to the determination result of the normal symbol lottery.
Further, the game control unit 200 holds the game ball when the game ball wins the first start port 121 or the second start port 122 during the special symbol change, or the game ball passes through the gate 124 during the normal symbol change. Set the hold that occurs as a result.
Further, the game control unit 200 accompanies game control such as determination results of special symbol lottery and normal symbol lottery, change information of high-probability state and low-probability state, change information of time-saving non-state and time-saving state, hold setting information, and the like. The information is sent to the effect control unit 300 by a command described later.

Further, when a game ball wins in the first starting port 121, the second starting port 122, the large winning opening 125, and the normal winning opening 126, the game control unit 200 hits one game ball according to the place where the game ball wins. An instruction is given to the payout control unit 330 to pay out a predetermined number of prize balls. For example, if a game ball wins in the first starting port 121, three prize balls, if a game ball wins in the second starting port 122, four prize balls, and if a game ball wins in the large winning opening 125, 13 prizes. When a game ball wins a ball or a normal winning opening 126, an instruction command (command) is sent to the payout control unit 330 so that 10 prize balls are paid out respectively. Even if it is detected that the game ball has passed through the gate 124, the payout control unit 330 is not instructed to pay out the prize ball linked to the game ball.
When the payout control unit 330 pays out the prize balls according to the instruction of the game control unit 200, the game control unit 200 acquires information regarding the number of paid out prize balls from the payout control unit 330. As a result, the number of prize balls paid out is managed.

As a detection means, the game control unit 200 includes a first start port detection unit (first start port switch (SW)) 211 that detects a winning of the game ball to the first start port 121. , To the second start port detection unit (second start port switch (SW)) 212 for detecting the winning of the game ball to the second start port 122, the electric tulip opening / closing unit 213 for opening / closing the electric tulip 123, and the gate 124. A gate detection unit (gate switch (SW)) 214 for detecting the passage of the game ball is connected to the gate detection unit (gate switch (SW)) 214.
Further, the game control unit 200 includes a large winning opening detection unit (large winning opening switch (SW)) 215 for detecting the winning of a game ball into the large winning opening 125, and a large winning opening door 125D of the large winning opening 125. The large winning opening door opening / closing part 216 that sets the closed state and the protruding inclined open state, and the normal winning opening detection unit (normal winning opening switch (SW)) 217 that detects the winning of the game ball to the ordinary winning opening 126. , Are connected.

In addition, the game control unit 200 has a first special symbol hold indicator 218 that displays the number of unchanged pieces that have won a prize in the first start port 121 during the change of the special symbol, and a second special symbol hold indicator 218 that displays the number of unchanged pieces that have won a prize during the change of the special symbol. The second special symbol hold indicator 219 that displays the number of unchanging holdings that won the starting port 122, and the normal symbol holding indicator that displays the number of unchanging holdings that passed through the gate 124 while the normal symbol was changing. 220 and are connected.
Further, the game control unit 200 has a first special symbol display 221 for displaying the variation display of the special symbol and the result of the special symbol lottery performed by winning the game ball to the first starting port 121, and a second starting port. The second special symbol display 222 that displays the variation display of the special symbol and the result of the special symbol lottery performed by winning the game ball to 122, and the normal symbol display that displays the variation display of the normal symbol and the result of the ordinary symbol lottery. The device 223 and the state display 224 that displays the state of the pachinko gaming machine 100 are connected.

Then, the detection signals detected by the first start port switch 211, the second start port switch 212, the gate switch 214, the large winning opening switch 215, and the normal winning opening switch 217 are sent to the game control unit 200. Further, the control signals from the game control unit 200 are the electric tulip opening / closing unit 213, the grand prize opening / closing unit 216, the first special symbol holding indicator 218, the second special symbol holding indicator 219, and the normal symbol holding indicator 220. , 1st special symbol display 221 and 2nd special symbol display 222, normal symbol display 223 and status display 224. As a result, the game control unit 200 performs various controls related to the number of payout prize balls described above.

Further, on the front surface side of the game control board, a signal for clearing the stored contents of the RAM 203 of the game control unit 200 or updating the set value (probability of being determined to be a big hit) at the stage of the advantage degree of the game is input. RAM clear switch 228, setting key switch 229 for inputting signals for shifting to the setting change mode and setting confirmation mode described later by operation using the setting key, performance information and settings that enable the actual performance of the gaming machine to be grasped. An information display 230 for displaying values, other electronic components, and the like are mounted.

The information display 230 is composed of four 7-segment displays (230a to 230d, see FIG. 61 described later) arranged in the left-right direction. Then, the identification segment for displaying the identification information indicating the type (data type) of the performance information is configured by the two 7-segment displays 230a and 230b from the left, and set by the two 7-segment displays 230c and 230d from the right. A numerical segment for displaying numerical information indicating numerical values of values and performance information is configured (see FIG. 60). When displaying the set value, static lighting is performed, and when displaying performance information, dynamic lighting is performed.

Further, the game control unit 200 is connected to an external information terminal board 350 for a board that transmits various information to a host computer (not shown) installed in the hall. Then, the game control unit 200 transmits information regarding the number of prize balls paid out, information indicating the state of the game control unit 200, etc. acquired from the payout control unit 330 to the host computer via the external information terminal board 350 for the board. do.

[Configuration / function of payout control unit]
The payout control unit 330 includes a CPU 331 that performs arithmetic processing when controlling the payout of payout balls, a ROM 332 that stores programs and various data executed by the CPU 331, and a RAM 333 that is used as a work memory of the CPU 331. And have.
Then, the payout control unit 330 controls the payout of the payout ball based on the command sent from the game control unit 200.
Specifically, the payout control unit 330 acquires a command from the game control unit 200 to pay out a predetermined number of prize balls according to the place where the game ball has won a prize (first starting port 121 or the like). Then, the payout drive unit 334 is controlled so as to pay out the number of prize balls specified in the command. The payout drive unit 334 here is composed of a drive motor that sends out the game ball from the storage unit of the game ball.

Further, the payout control unit 330 includes a payout ball detection unit 335 that detects the number of prize balls actually paid out from the game ball storage unit by the payout drive unit 334, and a game ball in the storage unit (not shown). It detects whether or not the ball presence detection unit 336 that detects the presence or absence of storage of the ball and the plate 153 that holds the game ball used when the player plays the game and the prize ball that has been paid out are in a full state. The full tank detection unit 337 is connected to the full tank detection unit 337. Then, the payout control unit 330 receives the detection signals detected by the payout ball detection unit 335, the ball presence detection unit 336, and the full tank detection unit 337, and performs predetermined processing according to these detection signals.
Further, the payout control unit 330 is connected to a frame external information terminal board 340 for transmitting various information to the host computer installed in the hall. Then, the payout control unit 330 may, for example, provide information on the number of prize balls instructed to pay out to the payout drive unit 334, information on the number of actually paid out prize balls detected by the payout ball detection unit 335, and the like. Is transmitted to the host computer via the external information terminal board 340 for the frame. Further, the same information is transmitted to the game control unit 200.

[Structure / function of production control unit]
The effect control unit 300 includes a CPU 301 that performs arithmetic processing when controlling the effect, a ROM 302 that stores programs and various data executed by the CPU 301, a RAM 303 that is used as a work memory of the CPU 301, and a date and time. It is equipped with a real-time clock (RTC) 304 for measuring.
The effect control unit 300 sets the effect content based on, for example, the determination result of whether or not the special symbol lottery is won or not and the fluctuation pattern sent from the game control unit 200. At that time, in some cases, the effect content is set according to the operation input in response to the operation input from the user using the effect button 161 or the effect key 162. In this case, for example, a signal (operation signal) corresponding to the operation is received from a controller (not shown) such as the effect button 161 and the operation content identified by the operation signal is reflected in the effect setting.
Further, when the game is interrupted for a predetermined period, the effect control unit 300 instructs the setting of the screen display for waiting for customers as one of the effects.
Further, the effect control unit 300 sets the effect content based on the change information of the high-probability state and the low-probability state and the change information of the time-saving non-state and the time-saving state received from the game control unit 200.
Further, the effect control unit 300 sends a command instructing the execution of the set effect content to the image / sound control unit 310 and the lamp control unit 320.

Further, the effect control unit 300 is connected to an image / sound control unit 310 that controls an effect using images and sound, and a lamp control unit 320 that controls an effect using various lamps and movable accessories 115. Has been done.

[Configuration / function of image / acoustic control unit]
As shown in FIG. 5, the image / sound control unit 310 stores a CPU 311 that performs arithmetic processing when controlling an image expressing the effect content and sound, a program executed by the CPU 311 and various data. It includes a ROM 312, a RAM 313 used as a working memory of the CPU 311 and the like, a VDP (Video Display Processor) 314, a CGROM 315, and an SNDROM 316.

Then, the image / sound control unit 310 controls the image displayed on the image display unit 114 and the sound output from the speaker 156 based on the command sent from the effect control unit 300.
Specifically, the CGROM 315 includes a symbol image and a background image to be displayed during the game on the image display unit 114, a decorative symbol for notifying the player of the lottery result, a character for displaying a notice effect to the player, and the like. Image data such as items are stored. Further, the SNDROM 316 stores various acoustic data such as music and sound to be output from the speaker 156 in synchronization with the image data or independently of the image data, and sound effects such as jingles.
The CPU 311 analyzes animation patterns, creates a display list summarizing commands related to drawing, and sends the display list to VDP314 based on the hold number command or the variable effect start command sent from the effect control unit 300. conduct.

The VDP 314 reads out the image data and the acoustic data stored in the CGROM 315 and the SNDROM 316, respectively, based on the display list received from the CPU 311. Further, the VDP 314 performs drawing processing for background image display, symbol image display, symbol image variation, character / item display, etc. using the read image data, and voice processing using the read acoustic data. .. Then, the VDP 314 controls the screen display on the image display unit 114 based on the drawn image data. Further, the VDP 314 controls the sound output from the speaker 156 by the sound processed sound data.
In the present embodiment, the VDP 314 is configured to perform voice processing in addition to the drawing processing, but the present invention is not limited to this, and a processor dedicated to voice processing may be provided separately.

[Configuration / function of lamp control unit]
The lamp control unit 320 stores a CPU 321 that performs arithmetic processing when controlling the light emission of the panel lamp 116 and the frame lamp 157 and the operation of the movable accessory 115, and a program and various data executed by the CPU 321. It includes a ROM 322 and a RAM 323 used as a working memory of the CPU 321 and the like.
Then, the lamp control unit 320 controls lighting / blinking, emission color, and the like of the panel lamp 116 and the frame lamp 157 based on the command sent from the effect control unit 300. It also controls the operation of the movable accessory 115.

Specifically, the ROM 322 of the lamp control unit 320 contains lighting / blinking pattern data and emission color pattern data (emission pattern) of the panel lamp 116 and the frame lamp 157 according to the effect content set by the effect control unit 300. Data) is stored. The CPU 321 selects and reads out the light emission pattern data stored in the ROM 322 that corresponds to the command sent from the effect control unit 300. Then, the lamp control unit 320 controls the light emission of the panel lamp 116 and the frame lamp 157 based on the read light emission pattern data.
Further, the ROM 322 of the lamp control unit 320 stores the operation pattern data of the movable accessory 115 according to the effect content set by the effect control unit 300. The CPU 321 controls the operation of the movable accessory 115 based on the read operation pattern data.
A control unit that controls the frame lamp 157 may be provided separately from the lamp control unit 320. In this case, the control unit that controls the frame lamp 157 may be provided on the frame control board 360B.

In the present embodiment, the game control unit 200, the effect control unit 300, the image / sound control unit 310, the lamp control unit 320, and the payout control unit 330 are the game control board 200B, the effect control board 300B, and the image control, respectively. It is provided on the substrate 310B, the lamp control substrate 320B, and the payout control substrate 330B. Further, the RAM clear switch 228, the setting key switch 229, and the information display 230 are all provided on the game control board 200B.
Further, in the configuration example described with reference to FIG. 5, the effect button 161 and the effect key 162 are connected to the effect control unit 300 and controlled by the effect control unit 300, but the present invention is not limited to this. The effect button 161 and the effect key 162 may be connected to the lamp control unit 320 and controlled by the lamp control unit 320.

[Functional configuration of game control unit]
Subsequently, the functional configuration of the game control unit 200 will be described.
FIG. 6 is a block diagram showing a functional configuration of the game control unit 200. As shown in FIG. 6, the game control unit 200 includes a random number acquisition unit 231, a normal symbol determination unit 232, a special symbol fluctuation control unit 233, and a special symbol determination unit 234 as functional units for executing various lottery processes. , Ordinary symbol fluctuation control unit 236 and.
In addition, the game control unit 200 includes a variation pattern selection unit 235 as a functional unit that executes processing associated with a special symbol variation.
Further, the game control unit 200 has a large winning opening motion control unit 237, an electric tulip motion control unit 238, and a prize ball processing unit 239 as functional units for executing motion control of various accessories and data processing related to prize balls and the like. And an output control unit 240 and a random number control unit 241.

The random number acquisition unit 231 acquires a random number value used for the special symbol lottery and a random number value used for the normal symbol lottery. In the case of the random number value used for the special symbol lottery, specifically, on the condition that the game ball wins in the first starting port 121 and the second starting port 122, the numerical value in a predetermined range is set for each type of random number. One numerical value (random number value) is selected (acquired) from among them. The acquired random number value is used for determination by the special symbol determination unit 234. As will be described in detail later, the random numbers used in the special symbol lottery include a jackpot random number indicating whether or not it is a jackpot, a symbol random number indicating the type of jackpot, a variable pattern random number, a reach random number, and the like.
Further, in the case of the random number value used for the ordinary symbol lottery, specifically, one numerical value (random number value) is selected (acquired) from the numerical values in a predetermined range on condition that the game ball has passed through the gate 124. ). The acquired random number value is usually used for determination by the symbol determination unit 232. As the random numbers used in the ordinary symbol lottery, in addition to the hit random numbers indicating whether or not they are hit, a symbol random number indicating the type of hit, a variable pattern random number, or the like may be set.
When the special symbol lottery is performed, the special symbol fluctuation control unit 233 controls the fluctuation of the special symbol in the first special symbol display 221 or the second special symbol display 222 according to the lottery result.

The special symbol determination unit 234 uses a random number table as shown in FIG. 42, which will be described later, at the start of fluctuation of the special symbol, and the lottery result of the special symbol lottery is "whether or not it is a big hit" and "a big hit when a big hit is won". "Type of" and "whether it is a small hit or a miss when the big hit is not won" is determined. That is, the random number acquisition unit 231 acquires a random number value related to the special symbol when the passage of the game ball is detected by the first start port switch 211 or the second start port switch 212, which is the detection means, and determines the special symbol. Based on the acquired random number value, the unit 234 determines whether or not to perform a special game (big hit game, etc.) that is advantageous to the player. The above-mentioned special symbol lottery (big hit lottery) refers to processing by the random number acquisition unit 231 and the special symbol determination unit 234.

Here, the "big hit" is divided into a plurality of types according to the game state generated after the end of the big hit game. Specifically, the type of jackpot is determined by the combination of the time-saving no state or the time-saving state, and the high-probability state or the low-probability state. That is, as the types of jackpots based on the game state that occurs after the end of the jackpot game, the jackpot that becomes a high-probability time-saving game state after the end of the jackpot game (hereinafter, the jackpot in the high-probability time-saving game state) and the low-probability time-saving game state. Big hit (hereinafter, big hit in low probability time saving game state), big hit in high probability time saving no game state (hereinafter, big hit in high probability time saving no game state), big hit in low probability time saving no game state (hereinafter, low) Probability time saving No game state jackpot) is possible. Each of these jackpots is associated with an individual special symbol, and the type of jackpot is determined according to the type of special symbol won in the special symbol lottery.

Further, the "big hit" may be divided into a jackpot in which the jackpot game time is long and a large amount of game balls can be expected to be paid out, and a jackpot in which the jackpot game time is short and the payout of the game balls can hardly be expected. The former is called "long hit" and the latter is called "short hit". For example, in "long hit", a round in which the open state of the large winning opening 125 is maintained until a predetermined condition (for example, 29.5 seconds have passed or 10 game balls have been won) is repeated a predetermined number of times (for example, 15 times). Is done. Further, in the "short hit", a round in which the large winning opening 125 is opened for a certain period of time (for example, 0.9 seconds) is repeated a predetermined number of times (for example, twice).

In addition, when the big hit is not won, the "small hit" is a small hit game in which the big winning opening 125 is opened for a certain period of time (for example, 0.9 seconds) a predetermined number of times (for example, twice). Will be done. When the small hit is won, the game state before the small hit is continued even after the small hit game is completed. That is, when the game state at the time of winning the small hit is the high-probability time-saving game state, the high-probability time-saving game state is continued even after the end of the small-hit game, and the game state does not shift. Similarly, when the gaming state at the time of winning the small hit is the low-probability time-saving no-game state, the low-probability time-saving no-game state is continued even after the end of the small-hit game, and the gaming state does not shift.
Further, the "small hit" is a kind of "missing", and none of the above-mentioned gaming states that are advantageous to the player is set.

The variation pattern selection unit 235 selects the variation pattern (variation time) of the special symbol to be displayed on the first special symbol display 221 and the second special symbol display 222. Specifically, the variation pattern selection unit 235 can perform a reach effect in the determination result of whether or not to perform the jackpot game and the decorative symbol variation effect accompanying the special symbol variation (for example, 13.5 seconds or more). ), The fluctuation pattern is determined based on the judgment result and the like. Then, the special symbol variation control unit 233 controls the variation of the special symbol based on the variation pattern selected by the variation pattern selection unit 235. Details of the operations of the fluctuation pattern selection unit 235 and the special symbol fluctuation control unit 233 will be described later.
Here, the "reach" is an effect for making the player expect a big hit in the decorative design described later.

The ordinary symbol determination unit 232 determines whether or not the lottery result of the ordinary symbol is "win or not" by using a random number table as shown in FIG. 42 (d) described later at the start of the fluctuation of the ordinary symbol. That is, the ordinary symbol determination unit 232 determines whether or not to perform an auxiliary game for opening and closing the electric tulip 123 based on the random number value for the ordinary symbol lottery acquired by the random number acquisition unit 231. Further, when a plurality of types of hits are set in the ordinary symbol lottery, the ordinary symbol determination unit 232 determines the "type of hit" when the determination result is a hit. The ordinary symbol lottery is a process performed by the random number acquisition unit 231 and the ordinary symbol determination unit 232.
When the normal symbol lottery is performed, the normal symbol fluctuation control unit 236 controls the fluctuation of the normal symbol by the normal symbol display 223 according to the lottery result.
The electric tulip motion control unit 238 opens the electric tulip 123 for a specified time and a specified number of times when the normal symbol lottery determines "hit" by the normal symbol determination unit 232, and a game ball is placed in the second starting port 122. Generate a state that makes it easy to win a prize. Further, when it is determined to be "off", such an open state of the electric tulip 123 is not generated. The operation pattern of the electric tulip 123 will be described later. For example, there are an operation pattern that opens once with an opening time of 0.15 seconds and an operation pattern that opens three times with an opening time of 1.80 seconds.

When the special symbol lottery determines "big hit" by the special symbol determination unit 234, the big prize opening operation control unit 237 has a big winning opening with an operation pattern specified based on the type of the winning jackpot as a big hit game. Controls the opening operation of 125. Further, when the special symbol determination unit 234 determines that the special symbol lottery is a "small hit", the large winning opening operation control unit 237 opens the large winning opening 125 as a small hit game for a specified time and a specified number of times. ..
The prize ball processing unit 239 sets a command for managing the number of prizes for various prizes related to prizes and lottery, and for controlling the payout of prize balls according to the prizes.
The output control unit 240 controls the output of control commands from the game control unit 200 to the effect control unit 300 and the payout control unit 330.
The random number control unit 241 updates various random number values acquired by the random number acquisition unit 231 at a predetermined timing.

[Basic operation of gaming machines]
Next, the basic operation of the pachinko gaming machine 100 will be described.
When the power is turned on, the game control unit 200 of the pachinko game machine 100 initializes and sets various devices as a basic process at the time of startup. Then, after performing the basic processing, the game control unit 200 repeatedly executes the main control processing, which is a series of processing related to the progress of the game. Further, when the power is cut off, the game control unit 200 executes a series of power cut-off processes.

FIG. 7 is a flowchart showing the operation of the basic processing by the game control unit 200.
When the power of the pachinko gaming machine 100 is turned on, the game control unit 200 first permits access to the RAM 203 (see FIG. 4) (step (hereinafter, step is referred to as “S”) 601). Then, the game control unit 200 determines whether or not the RAM clear switch for clearing the RAM 203 is ON (S602).
When the RAM clear switch is OFF (No in S602), the game control unit 200 then determines whether or not the backup flag related to the operation when the power is cut off is ON (S603).
When the backup flag is ON (Yes in S603), the game control unit 200 then determines whether or not the checksum created when the power is cut off is normal (S604).
When the checksum is normal (Yes in S604), the game control unit 200 then executes the return process (S605). In this return process, the game control unit 200 sets sub-control means such as the effect control unit 300 when returning from the state in which the power supply is cut off. Specifically, the game control unit 200 is in a gaming state of the pachinko gaming machine 100 when the power is cut off (whether or not a jackpot game is in progress, either a high-probability state or a low-probability state, a time-saving state and a time-saving no state). A command for setting the sub control means is output to the effect control unit 300 so as to reflect any of the above). Further, in this return process, the game control unit 200 turns off the backup flag.

On the other hand, if the RAM clear switch is ON (Yes in S602), the backup flag is OFF (No in S603), or the checksum is abnormal (No in S604), then the game control unit 200 is initialized. As a process, the stored contents of the RAM 203 are cleared (S606), and the work area of the RAM 203 is set (S607). Then, the game control unit 200 outputs a command for setting (initializing) the sub control means to the effect control unit 300, and sets the sub board (sub control means) (S608). The setting of the sub-board includes clearing the RAM 303, RAM 313, and RAM 323 mounted on each sub-board.

After the return process (see S605) is completed or the sub-board setting (see S608) is completed, the game control unit 200 sets various counters and timers used for the game control (S609). Then, the game control unit 200 determines whether or not the interrupt enable (S610), interrupt disable (S611), symbol random number control process (S612), initial value random number update process (S613), and power cutoff flag are ON. (S614) is repeatedly executed as a loop process.
Here, interrupt enable (S610) and interrupt disable (S611) are provided to enable execution of interrupt processing during execution of this loop processing (S610 to S614). In the present embodiment, the main control process in the game control is executed by this interrupt process. The details of the main control process will be described later.
In the symbol random number control process (S612), the game control unit 200 updates the variable pattern random number used in the special symbol lottery.
In the initial value random number update process (S613), the game control unit 200 updates the initial values of various random numbers used in the game control.
In the determination of the power cutoff flag, when the power cutoff flag is OFF (No in S614), the power supply of the pachinko gaming machine 100 is not cut off, and the game control unit 200 performs main control by interrupt together with loop processing (S610 to S614). Repeat the process. On the other hand, when the power cutoff flag is ON (Yes in S614), the game control unit 200 starts a process for shutting off the power supply of the pachinko gaming machine 100 (process at the time of power cutoff).

FIG. 8 is a flowchart showing the operation of the power cutoff process by the game control unit 200.
In the power cutoff process, the game control unit 200 first clears the setting of the output port for performing various outputs (S701). Next, the game control unit 200 creates a checksum and stores it in the RAM 203 (S702). Next, the game control unit 200 turns on the backup flag (S703), prohibits access to the RAM 203 (S704), and shifts to an infinite loop.

(Power supply board 40)
Next, the power supply board 40 will be described.
FIG. 9 is a diagram showing a configuration of an electronic circuit on the power supply board 40.
The power supply board 40 receives the power of AC24V supplied from the commercial power supply P as an example of the external power supply and converted into the transformer T. Further, the power supply board 40 creates a predetermined voltage from the received electric power. Examples of the predetermined voltage include DC36V, DC12V, DC5V and the like. Then, the power supply board 40 supplies the power of the created voltage to the game control board 200B, the effect control board 300B, the image control board 310B, the lamp control board 320B, the payout control board 330B, and the frame control board 360B.
The power supply board 40 is provided with a plurality of electronic components described later in an electronic circuit, and the plurality of electronic components realize a function of generating electric power and a function of supplying the created electric power to various boards. A plurality of electronic components on the power supply board 40 are electrically connected to each other by a conductive wiring pattern (electric circuit).

The power supply board 40 is provided with an AC circuit 41, a rectifier circuit 43, and a DC circuit 50.
The AC circuit 41 is a circuit to which an AC voltage is supplied. AC24V is supplied to the AC circuit 41.
The rectifier circuit 43 is a circuit that converts an AC voltage that has passed through the AC circuit 41 into a DC voltage. The rectifier circuit 43 converts AC24V to DC24V.

The DC circuit 50 is a circuit to which a DC voltage is supplied through the rectifier circuit 43. The DC circuit 50 is provided with a power factor correction (PFC) circuit 44, a power generation circuit 48, and a backup circuit 49.
The PFC circuit 44 is a circuit for improving the power factor of electric power. The PFC circuit 44 boosts the DC voltage through the rectifier circuit 43 to DC 36V as the power factor of the electric power is improved.
The power creation circuit 48 is a circuit that creates DC12V and DC5V using DC36V that has passed through the PFC circuit 44.
The backup circuit 49 is a circuit that creates electric power as a backup used in the pachinko gaming machine 100.

(AC circuit 41)
FIG. 10 is a diagram showing a configuration of an AC circuit 41 on the power supply board 40.
In the following, among the terminals provided on each electronic component on the power supply board 40, the terminal on the side where the voltage is input is referred to as an "input terminal", and the terminal on the side where the voltage is output is referred to as an "output terminal". Sometimes referred to.
The AC circuit 41 is provided with an AC connection connector 411, a power switch 412, an input side fuse 413, a bidirectional surge absorbing element 414, a connector side fuse 415, and a CR connection connector 416. Further, the AC circuit 41 is provided with a noise filter circuit 42.

The AC connection connector 411 as an example of the AC voltage input unit is a connector for connecting the electric wire to which AC24V converted to the transformer T is supplied and the AC circuit 41. The AC24V is input to the AC circuit 41 via the AC connection connector 411.

The power switch 412 has one side input terminal 412a, the other side input terminal 412b, one side output terminal 412c, and the other side output terminal 412d. One side of AC24V input via the AC connection connector 411 is input to the one-side input terminal 412a. The other side of AC24V (the side that is not input to the one side input terminal 412a) is input to the other side input terminal 412b. Hereinafter, the voltage input to one side input terminal 412a of AC24V may be referred to as AC24Va, and the voltage input to the other side input terminal 412b of AC24V may be referred to as AC24Vb. The one-side output terminal 412c outputs AC24Va. Further, the output terminal 412d on the other side outputs AC24Vb.
The power switch 412 has an electrically connected state and a non-electrically connected state with respect to the one-side input terminal 412a and the one-side output terminal 412c, and the other-side input terminal 412b and the other-side output terminal 412d. Switch to either one. When the clerk in the hall where the pachinko machine 100 is installed turns on the power switch 412, the one-side input terminal 412a and the one-side output terminal 412c, and the other-side input terminal 412b and the other-side output terminal 412d are electrically connected. Connected to. In this case, power is supplied to various circuits on the power supply board 40, and power is supplied from the power supply board 40 to various boards. Further, when the clerk turns off the power switch 412, the one-side input terminal 412a and the one-side output terminal 412c, and the other-side input terminal 412b and the other-side output terminal 412d are electrically disconnected. In this case, the supply of electric power to the power supply board 40 is cut off, whereby the power supply of the pachinko gaming machine 100 is cut off.

In the input side fuse 413 as an example of the protection element, the input terminal is electrically connected to the one side output terminal 412c of the power switch 412. Further, the input side fuse 413 is provided on the input side of AC24V rather than the noise filter circuit 42 in the AC circuit 41.
The input side fuse 413 supplies AC24V supplied to the AC circuit 41 to the downstream side via the power switch 412. Further, when a current larger than the rated value of the input side fuse 413 flows through the input side fuse 413, the input side fuse 413 is blown. As a result, a current larger than the rated value is prevented from flowing to the downstream side of the input side fuse 413. The rated value is, for example, that the clerk connects the commercial power supply P and the pachinko gaming machine 100 without going through the transformer T, and when AC100V is input to the input side fuse 413, the input side fuse 413 is blown. It is decided to do.

The bidirectional surge absorbing element 414 is an element that suppresses the output of a voltage higher than the rated value of the bidirectional surge absorbing element 414 to the output side of the bidirectional surge absorbing element 414. One end of the bidirectional surge absorbing element 414 is electrically connected to the output terminal of the input side fuse 413, and the other end is electrically connected to the other side output terminal 412d of the power switch 412.
The bidirectional surge absorbing element 414 is short-circuited when a voltage higher than the rated value is input. When the bidirectional surge absorbing element 414 is short-circuited, a large current flows through the circuit C1 formed by the AC connection connector 411, the power switch 412, the input side fuse 413, and the short-circuited bidirectional surge absorbing element 414. When a large current flows through the circuit C1, the input side fuse 413 blows and the circuit C1 is opened. This prevents the voltage from being input to the downstream side of the circuit C1.
Examples of the bidirectional surge absorbing element 414 include a semiconductor type surge absorber and a discharge tube type surge absorber. Further, as the bidirectional surge absorbing element 414, a bidirectional type that short-circuits even when a current having a voltage higher than the rated value is input from either one end or the other end is used. Further, in the present embodiment, a bidirectional surge absorbing element 414 whose rated value is set so as to cause a short circuit when a surge voltage or AC100V is input to the bidirectional surge absorbing element 414 is used.

The noise filter circuit 42 is a circuit that removes noise contained in AC24V supplied to the AC circuit 41. The noise filter circuit 42 includes an input side capacitor 421, one side varistor 422, the other side varistor 423, a frame ground (FG: Frame Ground) side surge absorbing element 424, an FG connection connector 425, and a resistance side surge absorbing. An element 426, a resistor 427, a choke coil 428, and an output side capacitor 429 are provided.

The input side capacitor 421 removes normal mode noise contained in AC24V. One end of the input side capacitor 421 is electrically connected to the output terminal of the input side fuse 413, and the other end is electrically connected to the other side output terminal 412d of the power switch 412. Further, the input side capacitor 421 is provided on the voltage input side of the AC circuit 41 with respect to the output side capacitor 429. Further, the input side capacitor 421 is connected in parallel with the bidirectional surge absorbing element 414.
The input side capacitor 421 suppresses the output of this specific frequency component to the output side of AC24V by inputting a specific frequency component. Specific frequencies include frequencies defined as noise. Examples of the input side capacitor 421 include a ceramic capacitor and a film capacitor.

The one-side varistor 422 as an example of the protection element removes common mode noise contained in AC24V. One end of the one-side varistor 422 is electrically connected to the output terminal of the input-side fuse 413, and the other end is electrically connected to the FG-side surge absorbing element 424.
The other side varistor 423 as an example of the protection element removes the common mode noise contained in AC24V. One end of the other side varistor 423 is electrically connected to the other side output terminal 412d of the power switch 412, and the other end is electrically connected to the FG side surge absorbing element 424.
The electrical resistance of the one-side varistor 422 and the other-side varistor 423 decreases when a voltage higher than the rated value is supplied. In this case, a voltage higher than the rated value is likely to be supplied to the side where the FG side surge absorbing element 424 is provided via the one-side varistor 422 and the other-side varistor 423. In other words, a voltage higher than the rated value is less likely to be supplied to the side where the resistance side surge absorbing element 426 is provided or the side where the choke coil 428 is provided. In this embodiment, one-side varistor 422 and the other-side varistor 423 whose rated values are set so as to protect the electronic components provided on the power supply board 40 are used.

The FG side surge absorbing element 424 removes noise contained in AC24V. One end of the FG side surge absorbing element 424 is electrically connected to the one side varistor 422 and the other side varistor 423, and the other end is electrically connected to the FG connection connector 425. Further, the FG side surge absorbing element 424 is provided on the FG connection connector 425 side of the resistance side surge absorbing element 426.
When a voltage higher than the rated value is supplied to the FG side surge absorbing element 424, the electric resistance of the FG side surge absorbing element 424 decreases. In this case, a voltage higher than the rated value is likely to be supplied to the FG connector 425 via the FG side surge absorbing element 424. In the present embodiment, the FG side surge absorbing element 424 whose rated value is determined so as to protect the electronic components provided on the power supply board 40 is used.

The FG connector 425 is a connector that connects the AC circuit 41 and the housing of the pachinko gaming machine 100 as an FG. The FG of the pachinko gaming machine 100 is grounded at the store where the pachinko gaming machine 100 is installed. Therefore, the noise input to the FG connection connector 425 via the FG side surge absorbing element 424 is removed after being guided to the FG.

The resistance side surge absorbing element 426 removes noise contained in AC24V. One end of the resistance-side surge absorbing element 426 is electrically connected to the output terminal of the input-side fuse 413, and the other end is electrically connected to the resistor 427.
The electrical resistance of the resistance-side surge absorbing element 426 decreases when a voltage higher than the rated value is supplied. In this case, a voltage higher than the rated value is likely to be supplied to the resistor 427 via the resistance-side surge absorbing element 426. In other words, a current having a voltage higher than the rated value is less likely to be supplied to the side where the choke coil 428 is provided. In the present embodiment, the resistance side surge absorbing element 426 whose rated value is determined so as to protect the electronic components provided on the power supply board 40 is used.

The resistor 427 as an example of the coil has a predetermined resistance value. The supply of voltage to the resistor 427 is limited according to the resistance value of the resistor 427. One end of the resistor 427 is electrically connected to the resistance side surge absorbing element 426, and the other end is grounded.

The choke coil 428 removes common mode noise contained in AC24V. The choke coil 428 has one side input terminal 428a, the other side input terminal 428b, one side output terminal 428c, and the other side output terminal 428d. The output terminal of the input side fuse 413 is electrically connected to the one side input terminal 428a. Further, the other side output terminal 412d of the power switch 412 is electrically connected to the other side input terminal 428b. In the choke coil 428, AC24Va is input to the one-side input terminal 428a, and AC24Vb is input to the other-side input terminal 428b. Further, in the choke coil 428, the one-side output terminal 428c outputs AC24Va, and the other-side output terminal 428d outputs AC24Vb.
When common mode noise is input to the one-side input terminal 428a and the other-side input terminal 428b, the choke coil 428 attenuates the noise by generating an electromotive force that cancels the noise.

The output side capacitor 429 removes noise contained in AC24V. One end of the output side capacitor 429 is electrically connected to the one side output terminal 428c of the choke coil 428, and the other end is electrically connected to the other side output terminal 428d of the choke coil 428. Further, the output side capacitor 429 is provided on the output side of AC24V with respect to the input side capacitor 421 in the AC circuit 41.
The input side capacitor 421 suppresses the supply of this voltage to the output side of AC24V in the AC circuit 41 by inputting a voltage having a specific frequency. Specific frequencies include frequencies defined as noise. Examples of the output side capacitor 429 include a ceramic capacitor and a film capacitor.

The input terminal of the connector-side fuse 415 is electrically connected to the output terminal of the input-side fuse 413, and the output terminal is electrically connected to the CR connection connector 416. Further, the connector-side fuse 415 is provided on the CR connection connector 416 side of the input-side fuse 413.
The connector side fuse 415 supplies the input AC24V to the CR connection connector 416 side. Further, when a current larger than the rated value of the connector-side fuse 415 flows through the connector-side fuse 415, the connector-side fuse 415 is blown. This prevents a current larger than the rated value of the connector-side fuse 415 from flowing through the CR connection connector 416.

The CR connector 416 is a connector for connecting the AC circuit 41 and the CR unit (not shown). AC24V input to the CR connection connector 416 via the power switch 412, input side fuse 413, bidirectional surge absorbing element 414, input side capacitor 421, one side varistor 422, other side varistor 423, and connector side fuse 415. The current is supplied to the CR unit.

Further, the AC24V input to the AC circuit 41 is a bidirectional surge absorbing element 414, an input side capacitor 421, one side varistor 422, the other side varistor 423, a resistance side surge absorbing element 426, a choke coil 428, and an output side capacitor 429. Reduces noise. The noise-reduced AC24V current is input to the rectifier circuit 43.

As described above, in the present embodiment, the AC circuit 41 is connected to the electric circuit to which the AC voltage is supplied, and the bidirectional surge absorbing element 414 short-circuits the AC circuit 41 when a voltage higher than a predetermined voltage is applied. And an input side fuse 413 connected to an electric circuit between the commercial power supply P and the bidirectional surge absorbing element 414 and protecting the electronic component from a current larger than a predetermined current.
In this case, when a voltage higher than a predetermined voltage is supplied to the power supply board 40, the bidirectional surge absorbing element 414 is short-circuited and a large current flows through the circuit C1. Further, when a large current flows through the circuit C1, the input side fuse 413 is blown and the circuit C1 is opened to prevent the voltage from being supplied to the downstream side of the circuit C1. Therefore, in the power supply board 40, it is possible to suppress a defect of an electronic component provided on the voltage output side of the circuit C1.

In the present embodiment, it has been described that the input side fuse 413 is provided on the power supply board 40, but the present invention is not limited to this.
The input-side fuse 413 may be provided, for example, on the input side of AC24V rather than the power supply board 40. That is, the input-side fuse 413 may be provided in a portion different from the power supply board 40 as long as it is provided on the input side of AC24V with respect to the bidirectional surge absorbing element 414.

Further, in the present embodiment, the input side capacitor 421, the resistor 427, the choke coil 428, and the output side capacitor 429 are not connected to the electric circuit between the commercial power supply P and the bidirectional surge absorbing element 414, and are bidirectional. It is connected to the electric circuit between the type surge absorbing element 414 and the rectifier circuit 43.
When a voltage higher than a predetermined voltage is supplied to the power supply board 40, the circuit C1 is opened before this voltage is supplied to the output side of the circuit C1. Therefore, even when a large current is input to the power supply board 40, defects such as the input side capacitor 421, the resistor 427, the choke coil 428, and the output side capacitor 429 can be suppressed.

Further, in the present embodiment, the AC circuit 41 has a protective means for protecting the electronic components provided in the AC circuit 41. Here, the protective means is, for example, an input side fuse 413, a bidirectional surge absorbing element 414, or the like. Then, the AC connection connector 411 is connected to the electric circuit between the commercial power supply P and the protective means.
In this case, the AC voltage input through the AC connection connector 411 is supplied to the input side fuse 413 and the bidirectional surge absorbing element 414. Therefore, compared to the case where the input side fuse 413 and the bidirectional surge absorbing element 414 are connected to the electric circuit between the commercial power supply P and the AC connection connector 411, the input side fuse 413 and the bidirectional surge absorbing element 414 It is also possible to suppress defects in electronic components provided on the rectifier circuit 43 side.

Further, in the present embodiment, no other electronic component is connected to the electric circuit between the one-side varistor 422 or the other-side varistor 423 and the choke coil 428.
In this case, the common mode noise in the AC circuit 41 is removed. In other words, the radiation noise mainly contained in the common mode noise can be removed. Therefore, it is possible to suppress the occurrence of defects in the electronic components of the power supply board 40 due to radiation noise.

Further, in the present embodiment, no other electronic component is connected to the electric circuit between the one-side varistor 422 or the other-side varistor 423 and the input side capacitor 421.
In this case, the input side capacitor 421 can remove noise consisting of a specific frequency. Further, the one-side varistor 422 and the other-side varistor 423 can remove noise contained in a current having a voltage higher than a predetermined voltage. That is, different types of noise can be removed by using the input side capacitor 421 and the one side varistor 422 and the other side varistor 423. Therefore, it is possible to suppress the occurrence of defects in the electronic components of the power supply board 40 due to various noises.

In particular, in this embodiment, a ceramic capacitor or a film capacitor is used as the input side capacitor 421. Therefore, as compared with the case where an electrolytic capacitor is used as the input side capacitor 421, it becomes easier to remove noise having a specific frequency.

Further, the one-side varistor 422, the other-side varistor 423, and the resistance-side surge absorbing element 426 mainly remove electrostatic noise in order to remove noise contained in a voltage higher than the rated value. In other words, the one-side varistor 422, the other-side varistor 423, and the resistance-side surge absorbing element 426 are easier to remove electrostatic noise than radiation noise. On the other hand, the input side capacitor 421, the choke coil 428, and the output side capacitor 429 all remove electrostatic noise and radiation noise.

(Rectifier circuit 43)
FIG. 11 is a diagram showing the configuration of the rectifier circuit 43 and the PFC circuit 44 on the power supply board 40.
The rectifier circuit 43 is a full-wave rectifier circuit. In the rectifier circuit 43 of the present embodiment, a single-phase bridge rectifier circuit is used as the full-wave rectifier circuit.
The rectifier circuit 43 is provided with four diodes. In the following, of the two diodes connected to one input terminal 43a of the rectifier circuit 43, the diode on the right side in the figure is referred to as the first diode 431, and the diode on the left side in the figure is referred to as the second diode 432. There is. Of the two diodes connected to the other input terminal 43b of the rectifier circuit 43, the diode on the right side in the figure may be referred to as the third diode 433, and the diode on the left side in the figure may be referred to as the fourth diode 434. be.

One input terminal 43a of the rectifier circuit 43 is electrically connected to the anode of the first diode 431 and the cathode of the second diode 432. Further, the other input terminal 43b of the rectifier circuit 43 is electrically connected to the anode of the third diode 433 and the cathode of the fourth diode 434. Further, AC24Va is supplied to one input terminal 43a of the rectifier circuit 43, and AC24Vb is supplied to the other input terminal 43b.
The AC voltage that has passed through the AC circuit 41 is converted into a DC voltage by the rectifier circuit 43. As a result, 24V DC is output from the rectifier circuit 43.

The rectifying element used as the rectifying circuit 43 is not limited to the diode.
For example, in the rectifier circuit 43, a transistor may be used as a rectifier element. In this case, a FET (Field effect transistor) bridge circuit may be used as the rectifier circuit 43.

Further, the power supply board 40 is provided with a rectifying side capacitor 435. The rectifying side capacitor 435 is provided on the rectifying circuit 43 side of the PFC circuit 44. The rectifying side capacitor 435 smoothes the pulsating current output from the rectifying circuit 43. One end of the rectifying side capacitor 435 is electrically connected to one output terminal 43c of the rectifying circuit 43, and the other end is grounded. Examples of the rectifying side capacitor 435 include a ceramic capacitor and a film capacitor.

(PFC circuit 44)
The PFC circuit 44 is provided with a booster circuit 45, an input detection circuit 46, an output detection circuit 47, a current detection unit 441, a first smoothing capacitor 442, and a second smoothing capacitor 443.
The booster circuit 45 boosts the voltage at this power as the power factor in the power output from the rectifier circuit 43 improves. The booster circuit 45 is provided with an inductor 451, a diode 452, a transistor 453, and a circuit control unit 454.

The input detection circuit 46 detects the DC voltage input to the PFC circuit 44. The input detection circuit 46 is provided with a first resistor 461 and a second resistor 462. The first resistor 461 and the second resistor 462 are connected in series.
One end of the first resistor 461 is electrically connected to one output terminal 43c of the rectifier circuit 43, and the other end is electrically connected to the second resistor 462.
One end of the second resistor 462 is electrically connected to the first resistor 461, and the other end is grounded.
Further, the portion of the input detection circuit 46 between the first resistor 461 and the second resistor 462 is electrically connected to the circuit control unit 454. The DC voltage input to the PFC circuit 44 is divided by the first resistor 461 and the second resistor 462, and the input voltage dividing value V1 which is the value of the divided voltage is input to the circuit control unit 454.

The output detection circuit 47 detects the voltage boosted by the booster circuit 45. The output detection circuit 47 is provided with a third resistor 471 and a fourth resistor 472. The third resistor 471 and the fourth resistor 472 are connected in series.
One end of the third resistor 471 is electrically connected to the cathode of the diode 452, and the other end is electrically connected to the fourth resistor 472.
One end of the fourth resistor 472 is electrically connected to the third resistor 471, and the other end is grounded.
Further, the portion of the output detection circuit 47 between the third resistor 471 and the fourth resistor 472 is electrically connected to the circuit control unit 454. The DC voltage boosted by the booster circuit 45 is divided by the third resistor 471 and the fourth resistor 472, and the output voltage dividing value V2, which is the value of the divided voltage, is input to the circuit control unit 454. ..

One end of the current detection unit 441 is electrically connected to the other output terminal 43d of the rectifier circuit 43, and the other end is electrically connected to the circuit control unit 454. The current detection unit 441 is a resistor that detects the current value I1 which is the value of the current output from the rectifier circuit 43. The current value I1 detected by the current detection unit 441 is input to the circuit control unit 454.

One end of the inductor 451 as an example of the coil is electrically connected to one output terminal 43c of the rectifier circuit 43, and the other end is electrically connected to the anode of the diode 452. The inductor 451 and the diode 452 are connected in series.
The transistor 453 is a switch such as a MOSFET. In the transistor 453, the gate is connected to the circuit control unit 454, the drain is connected to the portion between the inductor 451 and the diode 452, and the source is grounded.

The circuit control unit 454 is an integrated circuit (IC) that controls the electric power in the PFC circuit 44. When the circuit control unit 454 acquires the input voltage dividing value V1, the output voltage dividing value V2, and the current value I1, the circuit control unit 454 improves the power factor of the electric power based on these acquired parameters. More specifically, the circuit control unit 454 sets the reference value Vs of the voltage based on the input voltage dividing value V1 and the output voltage dividing value V2. Then, by controlling while switching ON and OFF of the transistor 453 so that the voltage value in the current detection unit 441 becomes the reference value Vs, the current in the current detection unit 441 is brought closer to a sine wave. The voltage value in the current detection unit 441 is calculated from the current value I1 and the resistance value of the current detection unit 441.
In the control of the transistor 453 by the circuit control unit 454, when the transistor 453 is turned on, the DC24V input to the PFC circuit 44 is stored in the inductor 451. Then, when the transistor 453 is turned off, the voltage stored in the inductor 451 is output to the downstream side in addition to the voltage input to the PFC circuit 44. As a result, the voltage boosted to DC36V is output from the booster circuit 45.

Further, the circuit control unit 454 operates the PFC circuit 44 when the input voltage dividing value V1 acquired from the input detection circuit 46 becomes equal to or higher than a predetermined upper limit value when the PFC circuit 44 is not operating. Further, when the input voltage dividing value V1 acquired from the input detection circuit 46 while the PFC circuit 44 is operating becomes equal to or less than a predetermined lower limit value, the circuit control unit 454 stops the PFC circuit 44 and described above. Turn on the power cutoff flag (see S614 in FIG. 7). Therefore, the circuit control unit 454 and the input detection circuit 46 can be regarded as a power failure monitoring circuit for monitoring a power failure in the pachinko gaming machine 100.
Further, the circuit control unit 454 stops the PFC circuit 44 when the output voltage dividing value V2 acquired from the output detection circuit 47 becomes equal to or less than a predetermined lower limit value while the PFC circuit 44 is operating. Therefore, the circuit control unit 454 and the output detection circuit 47 are regarded as a power failure monitoring circuit.
The power failure monitoring circuit is not limited to the above-mentioned example. The power failure monitoring circuit may be provided in, for example, the AC circuit 41.

The first smoothing capacitor 442 and the second smoothing capacitor 443 are connected in parallel. One end of the first smoothing capacitor 442 and the second smoothing capacitor 443 is electrically connected to the cathode of the diode 452, and the other end is grounded. The first smoothing capacitor 442 and the second smoothing capacitor 443 charge and discharge the electric power output from the booster circuit 45. Further, the first smoothing capacitor 442 and the second smoothing capacitor 443 smooth the pulsating current output from the booster circuit 45. The capacitance of the first smoothing capacitor 442 and the capacitance of the second smoothing capacitor 443 are larger than any of the capacitance of the input side capacitor 421, the capacitance of the output side capacitor 429, and the capacitance of the rectifying side capacitor 435. More specifically, the first smoothing capacitor 442 and the second smoothing capacitor 443 are the capacitors having the largest capacity among the capacitors provided on the power supply board 40. Examples of the first smoothing capacitor 442 and the second smoothing capacitor 443 include an electrolytic capacitor.

Further, the power supply board 40 is provided with a first connector side fuse 445, a first board connection connector 446, a second connector side fuse 447, a second board connection connector 448, and a third board connection connector 449. ing.
In the first connector side fuse 445, the input terminal is electrically connected to the cathode of the diode 452, and the output terminal is electrically connected to the first board connection connector 446. Further, the first connector side fuse 445 is provided on the first board connection connector 446 side of the second connector side fuse 447. The first connector side fuse 445 supplies DC36V output from the PFC circuit 44 to the first board connection connector 446. Further, when a current larger than the rated value of the first connector side fuse 445 flows through the first connector side fuse 445, the first connector side fuse 445 is blown. This prevents a large current from flowing through the first board connection connector 446.

The first board connection connector 446 is a connector for connecting the power supply board 40 to the game control board 200B, the effect control board 300B, the image control board 310B, the lamp control board 320B, the payout control board 330B, and the frame control board 360B. The DC36V input to the first board connection connector 446 is supplied to the game control board 200B, the effect control board 300B, the image control board 310B, the lamp control board 320B, the payout control board 330B, and the frame control board 360B.

The second connector side fuse 447 is provided in parallel with the first connector side fuse 445. In the second connector side fuse 447, the input terminal is electrically connected to the cathode of the diode 452, and the output terminal is electrically connected to the second board connection connector 448 and the third board connection connector 449. The second connector side fuse 447 outputs DC36V output from the PFC circuit 44 to the second board connection connector 448 and the third board connection connector 449. Further, when a current larger than the rated value of the second connector side fuse 447 flows through the second connector side fuse 447, the second connector side fuse 447 blows. This prevents a large current from flowing through the second board connection connector 448 and the third board connection connector 449.

The second board connection connector 448 is a connector for connecting the power supply board 40 to the game control board 200B, the effect control board 300B, the image control board 310B, the lamp control board 320B, the payout control board 330B, and the frame control board 360B. The DC36V input to the second board connection connector 448 is supplied to the game control board 200B, the effect control board 300B, the image control board 310B, the lamp control board 320B, the payout control board 330B, and the frame control board 360B.
The third board connection connector 449 is a connector for connecting the power supply board 40 to the game control board 200B, the effect control board 300B, the image control board 310B, the lamp control board 320B, the payout control board 330B, and the frame control board 360B. The DC36V input to the third board connection connector 449 is supplied to the game control board 200B, the effect control board 300B, the image control board 310B, the lamp control board 320B, the payout control board 330B, and the frame control board 360B.

The first board connection connector 446, the second board connection connector 448, and the third board connection connector 449 are a game control board 200B, an effect control board 300B, an image control board 310B, a lamp control board 320B, a payout control board 330B, and a frame. It does not have to be connected to any of the control boards 360B. Each of the first board connection connector 446, the second board connection connector 448, and the third board connection connector 449 is a game control board 200B, an effect control board 300B, an image control board 310B, a lamp control board 320B, a payout control board 330B, and a frame. It does not have to be connected to any of the control boards 360B.

As described above, in the present embodiment, the DC circuit 50 has an inductor 451 connected to an electric circuit to which a DC voltage is supplied and a first smoothing capacitor 442 connected to an electric circuit to which a DC voltage is supplied via the inductor 451. And a second smoothing capacitor 443.
In this case, the pulsating flow flowing through the inductor 451 can be smoothed.

Further, in the present embodiment, the first smoothing capacitor 442 and the second smoothing capacitor 443 connected to the electric circuit to which the DC voltage is supplied through the rectifier circuit 43 are provided.
In this case, the pulsating current flowing through the rectifier circuit 43 can be smoothed.

Further, in the present embodiment, an electrolytic capacitor is used as the first smoothing capacitor 442 and the second smoothing capacitor 443. Therefore, the chargeable capacity is larger than when a ceramic capacitor or a film capacitor is used as the first smoothing capacitor 442 or the second smoothing capacitor 443.

Further, in the present embodiment, capacitors are provided in the AC circuit 41 and the DC circuit 50, respectively.
In this case, noise can be removed from the input side capacitor 421 and the output side capacitor 429 provided in the AC circuit 41. Further, the rectifying side capacitor 435, the first smoothing capacitor 442, and the second smoothing capacitor 443 provided in the DC circuit 50 can smooth the pulsating current. That is, each capacitor can exhibit a function according to the circuit in which the capacitor is provided.

Further, in the present embodiment, the choke coil 428 provided in the AC circuit 41 removes noise. Further, the inductor 451 provided in the direct current circuit 50 stores the input direct current. That is, the characteristics of the coil provided in the AC circuit 41 and the coil provided in the DC circuit 50 are different.

Further, in the present embodiment, the input side fuse 413 is provided in the AC circuit 41 in order to prevent the electronic components of the power supply board 40 from being defective due to the flow of a large current. Further, in order to prevent the electronic components of the power supply board 40 from being defective due to the input of an overvoltage, the AC circuit 41 is provided with a one-side varistor 422 and a other-side varistor 423. Further, a rectifying side capacitor 435, a first smoothing capacitor 442, a second smoothing capacitor 443, and the like are provided in order to suppress the occurrence of defects in electronic components due to the flow of alternating current in the DC circuit 50. That is, a plurality of types of suppressing means for suppressing defects of electronic components are provided.
In this case, it is possible to deal with each of a plurality of types of causes as causes of defects in electronic components.

Further, in the pachinko gaming machine 100, the distance from the power plug 158 to the electric circuit (wiring pattern) in which the noise filter circuit 42 is provided is defined as the distance A. Further, the distance from the electric circuit provided with the noise filter circuit 42 to the electric circuit provided with the rectifier circuit 43 is defined as the distance B. Further, the distance from the electric circuit provided with the rectifier circuit 43 to the electric circuit provided with the first substrate connector 446 is defined as the distance C. In this case, in the present embodiment, the relationship of distance A> distance C> distance B is established.
In this case, it is possible to suppress the generation of noise between the noise filter circuit 42 and the rectifier circuit 43 as compared with the case where the distance B is longer than the distance A.
The reference at one end of the distance A may be a specific position in the electric circuit provided with the noise filter circuit 42. For example, the distance A may be the distance from the power plug 158 to the electric circuit where the choke coil 428 is provided. Further, the reference at one end of the distance B and the distance C may be not the electric circuit provided with the rectifier circuit 43 but the electric circuit provided with the PFC circuit 44. Further, the reference at one end of the distance B and the distance C may be, for example, the position of the electric circuit between the electric circuit provided with the rectifier circuit 43 and the electric circuit provided with the PFC circuit 44.

(Power creation circuit 48)
FIG. 12 is a diagram showing the configuration of the power generation circuit 48 and the backup circuit 49 on the power supply board 40.
The power creation circuit 48 is provided with a 12V creation circuit 481 and a 5V creation circuit 482. The 12V creation circuit 481 and the 5V creation circuit 482 are provided in parallel.
The 12V creation circuit 481 creates power consisting of 12V. The 12V creation circuit 481 is provided with an inductor 4811, a 12V control unit 4812, a first capacitor 4813, and a second capacitor 4814.
One end of the inductor 4811 is electrically connected to the 12V control unit 4812, and the other end is electrically connected to the first board connection connector 446, the second board connection connector 448, and the third board connection connector 449.

The 12V control unit 4812 is an IC that creates 12V power. The 12V control unit 4812 is provided with a transistor and a diode (not shown). When the 12V control unit 4812 turns on the transistor, the power input from the PFC circuit 44 (see FIG. 11) is stored in the inductor 4811. Then, when the 12V control unit 4812 turns off the transistor, the supply of electric power to the inductor 4811 is stopped, and the electric power stored in the inductor 4811 is output to the output side of the electric power from the inductor 4811. In this way, the 12V control unit 4812 controls while switching the transistor ON and OFF, so that DC12V is output to the power output side of the inductor 4811.
The first capacitor 4813 and the second capacitor 4814 are provided in parallel. One end of the first capacitor 4813 and the second capacitor 4814 is electrically connected to the inductor 4811, and the other end is grounded. The first capacitor 4813 and the second capacitor 4814 charge and discharge the electric power output from the inductor 4811. Further, the first capacitor 4813 and the second capacitor 4814 smooth the pulsating current output from the inductor 4811. The capacity of the first capacitor 4813 and the capacity of the second capacitor 4814 are larger than any of the capacity of the input side capacitor 421, the capacity of the output side capacitor 429, and the capacity of the rectifying side capacitor 435. Examples of the first capacitor 4813 and the second capacitor 4814 include an electrolytic capacitor.

The 5V creation circuit 482 is an IC that creates 5V power. The 5V creation circuit 482 is provided with an inductor 4821, a 5V control unit 4822, and a capacitor 4823.
One end of the inductor 4821 is electrically connected to the 5V control unit 4822, and the other end is electrically connected to the third substrate connector 449.

The 5V control unit 4822 creates 5V power. The 5V control unit 4822 is provided with a transistor and a diode (not shown). When the 5V control unit 4822 turns on the transistor, the electric power input from the PFC circuit 44 (see FIG. 11) is stored in the inductor 4821. Then, when the 5V control unit 4822 turns off the transistor, the supply of electric power to the inductor 4821 is stopped, and the electric power stored in the inductor 4821 is output to the output side of the electric power rather than the inductor 4821. In this way, the 5V control unit 4822 controls while switching the transistor ON and OFF, so that DC5V is output to the power output side of the inductor 4821.
One end of the capacitor 4823 is electrically connected to the inductor 4821, and the other end is grounded. The capacitor 4823 charges and discharges the electric power output from the inductor 4821. Further, the capacitor 4823 smoothes the pulsating current output from the inductor 4821.
The capacity of the capacitor 4823 is larger than any of the capacity of the input side capacitor 421, the capacity of the output side capacitor 429, and the capacity of the rectifying side capacitor 435. Examples of the capacitor 4823 include an electrolytic capacitor.

(Backup circuit 49)
The backup circuit 49 is provided with a diode 491 and a backup capacitor 492.
In the diode 491, the anode is electrically connected to the inductor 4821 of the 5V creation circuit 482, and the cathode is electrically connected to the third substrate connector 449.

One end of the backup capacitor 492 is electrically connected to the cathode of the diode 491, and the other end is grounded. The capacity of the backup capacitor 492 is larger than any of the capacity of the input side capacitor 421, the capacity of the output side capacitor 429, and the capacity of the rectifying side capacitor 435. Examples of the backup capacitor 492 include an electrolytic capacitor.
When the power of the pachinko gaming machine 100 is turned on, the DC5V power output from the 5V creation circuit 482 is charged to the backup capacitor 492. Then, when the power supply of the pachinko gaming machine 100 is cut off, the backup capacitor 492 starts discharging. As a result, even when the power of the pachinko gaming machine 100 is cut off, the electric power stored in the backup capacitor 492 is supplied to the game control board 200B via the third board connection connector 449, and the game control board 200B is supplied. Various information is held in the RAM 203 of 200B. Further, the electric power stored in the backup capacitor 492 is supplied to the payout control board 330B via the third board connection connector 449, and various information is held in the RAM 333 of the payout control board 330B.

As described above, in the present embodiment, the AC circuit 41 is provided with surge absorbing elements such as the bidirectional surge absorbing element 414, the FG side surge absorbing element 424, and the resistance side surge absorbing element 426. On the other hand, the rectifier circuit 43 and the DC circuit 50 are not provided with a surge absorbing element.
The voltage supplied to the DC circuit 50 of the power supply board 40 is the voltage that has passed through the surge absorbing element in the AC circuit 41. Therefore, by providing the surge absorbing element in the AC circuit 41, it is possible to prevent the DC circuit 50 from being supplied with an overvoltage even when the DC circuit 50 is not provided with the surge absorbing element.

Further, in the present embodiment, the AC circuit 41 is provided with capacitors such as an input side capacitor 421 and an output side capacitor 429. On the other hand, the DC circuit 50 is provided with capacitors such as a rectifying side capacitor 435, a first smoothing capacitor 442, a second smoothing capacitor 443, a first capacitor 4813, a second capacitor 4814, a capacitor 4823, and a backup capacitor 492. There is. That is, in the present embodiment, as a result of providing capacitors to protect each of the ICs provided in the DC circuit 50, the DC circuit 50 is provided in the DC circuit 50 more than the number of capacitors provided in the AC circuit 41. There are more capacitors. The capacitors provided in the DC circuit are provided in the vicinity of the ICs provided in the DC circuit 50, respectively.

Further, in the present embodiment, capacitors are provided in the PFC circuit 44, the 12V creation circuit 481 and the 5V creation circuit 482, respectively. Therefore, each electric power can be charged and discharged.

Further, in the pachinko gaming machine 100, the distance from the 12V control unit 4812 to the third board connection connector 449 is defined as the distance D. Further, the distance from the 5V control unit 4822 to the third board connection connector 449 is defined as the distance E. In this case, in the present embodiment, the distance E is longer than the distance D.

In the present embodiment, it has been described that the power supply board 40 is provided with the PFC circuit 44, but the present invention is not limited to this.
The power supply board 40 may not be provided with the PFC circuit 44. In this case, in the rectifier circuit 43, the alternating current may be rectified to direct current and boosted. That is, in the rectifier circuit 43, AC24V may be converted to DC36V.

(Modification example)
FIG. 13 is a diagram showing a configuration of an electronic circuit in the power supply board 40A as a modification.
Although the configuration of the electronic circuit in the power supply board 40 has been described with reference to FIGS. 9 to 12, the electronic circuit of the power supply board 40 is not limited to the above configuration.
Hereinafter, the configuration of the electronic circuit in the power supply board 40A as a modification will be described with reference to FIGS. 13 and 14.

The power supply board 40A receives AC24V supplied from the commercial power supply P and converted by the transformer T. Further, the power supply board 40A creates a predetermined voltage from the received voltage. Examples of the predetermined voltage include DC36V, DC12V, DC5V and the like. Then, the power supply board 40A supplies the created electric power to the game control board 200B, the effect control board 300B, the image control board 310B, the lamp control board 320B, the payout control board 330B, and the frame control board 360B.

The power supply board 40A is provided with an AC circuit 41, a rectifier circuit 43, a PFC circuit 44, and a power generation circuit 48. On the other hand, the power supply board 40A is not provided with the backup circuit 49 (see FIG. 12). In this modification, a backup circuit is provided on the game control board 200B. Therefore, when the power supply of the pachinko gaming machine 100 is cut off, power is supplied from the backup circuit of the game control board 200B to the game control board 200B and the payout control board 330B.

FIG. 14 is a diagram showing a configuration of a PFC circuit 44 as a modified example.
A booster circuit 45 is provided in the PFC circuit 44 of the power supply board 40A. On the other hand, the PFC circuit 44 is not provided with the input detection circuit 46 (see FIG. 11) and the output detection circuit 47. In other words, the power supply board 40A is not provided with a power failure monitoring circuit. In this modification, a power failure monitoring circuit is provided on the game control board 200B. Therefore, it is detected whether or not the power supply of the pachinko gaming machine 100 is cut off from the change in the voltage on the gaming control board 200B. A power failure monitoring circuit may be provided on the payout control board 330B.

Subsequently, the structures of the power supply board 40 and the power supply board case 60 in the power supply board unit 4 will be described.
FIG. 15 is an overall perspective view of the power supply board unit 4 of the present embodiment.

As shown in FIG. 15, the power supply board unit 4 has a power supply board 40 and a power supply board case 60 for accommodating the power supply board 40 by covering at least a part of the power supply board 40. The power supply board 40 and the power supply board case 60 are fixed to each other by a fixing portion (not shown).
Then, the power supply board unit 4 is installed in the pachinko gaming machine 100 so that the board surface 400L (see FIG. 16 described later) of the board 400 constituting the power supply board 40 is along the board surface of the game board 110 (see FIG. 1). NS. Further, the power supply board case 60 is formed in a box shape. The power supply board case 60 is provided on the front side of the power supply board 40 and covers various electronic components mounted on the power supply board 40.

FIG. 16 is a top view of the power supply board 40 when the power supply board 40 of the present embodiment is viewed from the front side.

As shown in FIG. 16, the power supply board 40 of this embodiment has a board 400 formed in a rectangular shape. The general shape of the power supply board 40 is a rectangular shape whose length in the left-right direction is longer than that in the up-down direction. Then, on the power supply board 40, various components constituting the AC circuit 41, the rectifier circuit 43, and the DC circuit 50 described above are mounted on the board 400.
The power supply board 40 of the present embodiment is installed so that the left-right direction of the power supply board 40 shown in FIG. 16 is along the left-right direction of the pachinko gaming machine 100 (see FIG. 2), and the vertical direction of the power supply board 40 shown in FIG. 16 is It is installed along the vertical direction (see FIG. 2) of the pachinko gaming machine 100.

The power supply board 40 has the above-mentioned shape, and when installed in the above-mentioned orientation, the power supply board 40 is provided so that the longitudinal direction of the power supply board 40 is along the left-right direction. That is, the power supply board 40 is provided so that the short side direction (short side direction) is along the vertical direction. In this way, by providing the power supply board 40 so that the lateral direction is along the vertical direction, the number of electronic components arranged along the vertical direction on the power supply board 40 is, for example, the longitudinal direction of the power supply board 40 in the vertical direction. It will be less than when it is provided along the line.
Here, the heat generated in a certain electronic component moves upward along the vertical direction due to natural convection in terms of heat transfer among heat transfer. In the present embodiment, the influence of heat between the electronic components is reduced by relatively reducing the number of electronic components arranged in the vertical direction on the power supply board 40.

Then, as shown in FIG. 16, the AC circuit 41 is generally arranged in the region on the left side of the power supply board 40 in the left-right direction. In particular, the AC connector 411, the power switch 412, the CR connector 416, and the FG connector 425 are arranged side by side in the vertical direction at the left end of the power supply board 40.
Further, the rectifier circuit 43 is generally arranged in the region on the left side of the power supply board 40 in the left-right direction, and is arranged on the right side with respect to the AC circuit 41.
Further, the DC circuit 50 is generally arranged in a region on the right side of the power supply board 40 in the left-right direction. In particular, the first board connection connector 446, the second board connection connector 448, and the third board connection connector 449 are located on the right side of the power supply board 40 in the left-right direction and at the lower end portion in the up-down direction along the left-right direction. Arranged side by side.

In the rectifier circuit 43 of the present embodiment, the electronic components constituting the rectifier circuit 43 are packaged and formed in a rectangular shape. The rectifier circuit 43 is provided along the direction perpendicular to the plate surface 400L so as to stand out from the plate surface 400L of the substrate 400. Further, the rectifier circuit 43 is mounted so that the two surfaces having the largest areas face each other in the left-right direction.
Further, the rectifier circuit 43 is provided with a heat radiating member 43hs. The heat radiating member 43hs is made of a material having relatively high thermal conductivity such as aluminum. The heat radiating member 43hs is provided along the rectifying circuit 43 so as to surround the rectifying circuit 43. Then, the heat radiating member 43hs absorbs the heat generated by the rectifier circuit 43 and releases it to the outside of the rectifier circuit 43.

The rectifier circuit 43 and the heat radiating member 43hs of the present embodiment are provided so as to extend along the vertical direction of the power supply board 40, so that the heat generated in the power supply board 40 can be easily released to the upper side in the vertical direction. For example, when the rectifier circuit 43 and the heat radiating member 43hs are provided so as to extend in the left-right direction on the power supply board 40, there is a high possibility that heat stays under the rectifying circuit 43 and the heat radiating member 43hs. On the other hand, in the power supply board 40 of the present embodiment, heat retention due to the rectifier circuit 43 and the heat radiating member 43hs is suppressed.

Further, the circuit control unit 454 of the present embodiment is packaged in the same manner as the rectifier circuit 43 and is formed in a rectangular shape. Then, the circuit control unit 454 is installed in the same manner as the rectifier circuit 43. Further, the circuit control unit 454 is provided with a heat radiating member 454hs as in the rectifier circuit 43.

Further, in the power supply board 40 of the present embodiment, the electronic components that generate a large amount of heat as compared with other electronic components are arranged away from the power supply switch 412. That is, in the power supply board 40 of the present embodiment, another electronic component is interposed between the electronic component having a relatively large amount of heat generation and the power switch 412. In this case, the height of the other electronic components is preferably higher than that of the power switch 412 when the plate surface 400L of the substrate 400 is used as a reference.
In the power supply board 40 of the present embodiment, the electronic component having the largest heat generation is the circuit control unit 454 in the PFC circuit 44. Therefore, in the power supply board 40 of the present embodiment, the input side capacitor 421, the rectification side capacitor 435, and the choke coil 428 are arranged between the circuit control unit 454 and the power supply switch 412.

The circuit control unit 454 of this embodiment is provided with a heat radiating member 454hs. Therefore, in the power supply board 40, it can be considered that another electronic component is interposed between the heat radiating member 454hs and the power supply switch 412. Even in this case, the height of the other electronic components is preferably higher than that of the power switch 412 when the plate surface 400L is used as a reference.

Further, in the power supply board 40 of the present embodiment, a heat radiating member is provided between the capacitor and the coil. Capacitors and coils generate heat due to internal resistance components due to the flow of current. Therefore, in the power supply board 40 of the present embodiment, the heat radiating member is arranged so as to be interposed between the capacitor and the coil so that the heat generated by the capacitor and the coil is absorbed by the heat radiating member. In the power supply board 40 of the present embodiment, for example, the heat radiating member 43hs is arranged between the rectifying side capacitor 435 and the choke coil 428.

Further, among the plurality of electronic components provided on the power supply board 40 of the present embodiment, there is one having front side component information 400j. The front side component information 400j is provided on a surface of the electronic component facing the front side, and indicates information related to the electronic component such as a model number and specifications. The front component information 400j is most easily visible when the power supply board 40 is viewed from the front. Further, the front part information 400j of the present embodiment is composed of white characters (hereinafter, including numbers and symbols).

As shown in FIG. 16, the first smoothing capacitor 442 and the second smoothing capacitor 443 of the present embodiment each have front side component information 400j (for example, “KLM 10000 μF 50V”) on a surface facing the front side. doing. Further, the capacitor 4823 of the present embodiment has front side component information 400j (for example, "680 μF 25V") on a surface facing the front side. Further, the input side capacitor 421 of the present embodiment has front side component information 400j (for example, "HT DDT29") on a surface facing the front side.

Further, the size of the characters as the front component information 400j of each electronic component increases in the order of the first smoothing capacitor 442 (or the second smoothing capacitor 443), the capacitor 4823, and the input side capacitor 421. In this embodiment, the size of the characters as the front component information 400j is set according to the height of the electronic component from the plate surface 400L. The relationship between the size of the characters and the height of the electronic components will be described later.

Further, as shown in FIG. 16, the power supply board 40 has maker name information 400m indicating a maker name for manufacturing the pachinko gaming machine 100, and board identification information 400i capable of identifying the power supply board 40. The maker name information 400m and the substrate identification information 400i of the present embodiment are formed by forming the front conductive layer 4002, which will be described later, into a shape corresponding to the characters of the maker name information 400m and the substrate identification information 400i. That is, the manufacturer name information 400m and the substrate identification information 400i are formed in the front conductive layer 4002 in the same manner as the wiring pattern.

For the manufacturer name information 400m, it is sufficient that the manufacturer that manufactures the pachinko gaming machine 100 can be specified, and the name of the manufacturer, a registered trademark that can identify the manufacturer, or the like can be used. In the example shown in FIG. 16, the maker name information 400 m is composed of the characters "Aiu" corresponding to "Aiu Co., Ltd.", which is a manufacturer of the pachinko gaming machine 100.
The board identification information 400i is provided for managing the power supply board 40 and the like, and is information for distinguishing from other power supply boards of different types and other boards such as a game control board. The board identification information 400i is composed of characters. In the example shown in FIG. 16, the board identification information 400i is composed of the characters "EFG0123".

The manufacturer name information 400m and the substrate identification information 400i are provided on the outer peripheral portion of the substrate 400. That is, the manufacturer name information 400m and the substrate identification information 400i are provided at the end of the substrate 400. Therefore, in the power supply board 40, no electronic component is arranged outside the manufacturer name information 400m and the board identification information 400i (on the edge side of the board 400).

FIG. 17 is a rear view of the power supply board 40 when the power supply board 40 of the present embodiment is viewed from the rear side.

As shown in FIG. 17, the power supply board 40 has rear side manufacturer name information 400m2 and rear side board identification information 400i2 on the rear side of the board 400. The rear-side maker name information 400m2 and the rear-side substrate identification information 400i2 of the present embodiment are formed by forming the rear-side conductive layer 4004, which will be described later, into a shape corresponding to the characters of the rear-side maker name information 400m2 and the rear-side substrate identification information 400i2. It is formed. That is, the rear side manufacturer name information 400m2 and the rear side substrate identification information 400i2 are formed in the rear side conductive layer 4004 in the same manner as the wiring pattern.

Then, the rear side maker name information 400m2 and the rear side board identification information 400i2 are provided on the outer peripheral portion of the power supply board 40 in the same manner as the maker name information 400m and the board identification information 400i on the front side of the board 400.
However, the rear side maker name information 400m2 and the rear side board identification information 400i2 are arranged at different positions from the front side maker name information 400m and the board identification information 400i in the front-rear direction (that is, the thickness direction) of the board 400. That is, the rear side maker name information 400m2 and the rear side board identification information 400i2 and the front side maker name information 400m and the board identification information 400i are provided at different positions in the left-right direction and the up-down direction.

Further, as shown in FIG. 17, the power supply board 40 of the present embodiment has a board identification information sticker 400s on the back surface side of the board 400. The substrate identification information sticker 400s is a paper or film-like plastic coated with an adhesive. The board identification information sticker 400s is provided for managing the power supply board 40 and the like, and is information for distinguishing the power supply board 40 from other boards such as the game control board 204. The board identification information sticker 400s includes characters and the like. In the example shown in FIG. 17, the characters "0123 CBA" are provided on the substrate identification information sticker 400s. The substrate identification information sticker 400s has a white base portion different from the color of the plate surface 400L and a black character portion.

Next, the height of the electronic component provided on the power supply board 40 will be described in detail.
FIG. 18 is a side view of the power supply board 40 when the power supply board 40 of the present embodiment is viewed from above.
In FIG. 18, the positions of the main surface portion 61 (described later) of the power supply board case 60 are aligned and displayed.

As shown in FIG. 18, the power supply board 40 is provided with a plurality of electronic components on the plate surface 400L side. In the power supply board 40 of the present embodiment, a so-called DIP (Dual-in-line package) component is used in which a part of electronic components such as leads is inserted into the substrate 400 and mounted. In the power supply board 40 of the present embodiment, the electronic components are electrically connected to the plate surface 400L of the substrate 400 without inserting a part of the electronic components into the substrate 400, so-called SMD (Surface Mount Device). ) No parts are provided.

Further, among the plurality of electronic components provided on the power supply board 40 of the present embodiment, there is one having side component information 400f. The side component information 400f is provided on the side surface of the electronic component that faces the left-right direction side, and indicates information related to the electronic component such as a model number and specifications. The side component information 400f is most easily visible when the power supply board 40 is viewed from the left-right direction side.

As shown in FIG. 18, in the power supply board 40, the height relationship between the electronic components when the plate surface 400L is used as a reference is as follows. First, the first smoothing capacitor 442 and the second smoothing capacitor 443 are components having the same structure and substantially the same height. The height H1 of the first smoothing capacitor 442 is higher than the height H2 of the capacitor 4823. That is, the height H1 of the second smoothing capacitor 443 is higher than the height H2 of the capacitor 4823.
Further, the height H3 of the inductor 451 (coil) is higher than the height H1 of the first smoothing capacitor 442 (or the second smoothing capacitor 443).

Further, the height H4 of the heat radiating member 43hs is higher than the height H1 of the first smoothing capacitor 442 (or the second smoothing capacitor 443). However, the height H4 of the heat radiating member 43hs is lower than the height H5 of the heat radiating member 454hs.
Further, the height H5 of the heat radiating member 454hs is higher than the height H3 of the inductor 451 (coil). In the power supply board 40 of the present embodiment, the height H5 of the heat radiating member 454hs is the highest among the electronic components provided on the power supply board 40. Further, although the height H4 of the heat radiating member 43hs is lower than the height H5 of the heat radiating member 454hs, it is higher than other electronic components. By making the height of the heat radiating member 43hs and the heat radiating member 454hs higher than those of other electronic components in this way, in the power supply board 40 of the present embodiment, when heat is released from the heat radiating member 43hs and the heat radiating member 454hs, respectively. In addition, the transfer of released heat is less likely to be blocked by other electronic components.

Further, in the power supply board 40 of the present embodiment, the height of the capacitor provided in the DC circuit 50 (see FIG. 16) is higher than that of the capacitor provided in the AC circuit 41 (see FIG. 16).

As shown in FIG. 18, in the power supply board unit 4 of the present embodiment, the plate surface 400L of the substrate 400 and the main surface portion 61 of the power supply board case 60 are provided substantially in parallel. Therefore, the distance between the electronic component provided on the power supply board 40 and the main surface portion 61 becomes shorter according to the height of the electronic component described above. For example, the highest heat radiating member 454hs in the power supply board 40 of the present embodiment has the shortest distance from the main surface portion 61. The relationship between the height of the electronic component based on the plate surface 400L and the distance between the electronic component and the main surface portion 61 is the same for other electronic components.

Then, when there is one electronic component having a predetermined height and another electronic component higher than the one electronic component, the characters as the front component information 400j (see FIG. 16) provided in the one electronic component. The size is larger than the size of the character as the front side component information 400j provided in the other electronic component. For example, in the power supply board 40 of the present embodiment, as described above, the height of the capacitor 4823 is lower than that of the first smoothing capacitor 442. Therefore, the size of the characters as the front part information 400j of the capacitor 4823 is larger than the size of the characters as the front part information 400j of the first smoothing capacitor 442.

Here, when the power supply board 40 is viewed from the front side, the electronic component having a low height is located farther than the electronic component having a high height. Then, if the character size of the front side component information 400j provided in the electronic component having a low height is the same as or smaller than the character size of the front side component information 400j provided in the electronic component having a height higher than that. , The front component information 400j of a low-height electronic component that will be located farther away becomes difficult to see. Therefore, in the present embodiment, the size of the characters as the front side component information 400j of the electronic component having a low height is made larger than that of the electronic component having a high height, so that it is easy to confirm.

Further, as shown in FIG. 16, in the power supply board 40 of the present embodiment, the character size as the manufacturer name information 400m or the board identification information 400i on the front side is the character of the front side component information 400j provided on the front side of the electronic component. It's bigger than the size. When the power supply board 40 is viewed from the front side, the manufacturer name information 400m or the board identification information 400i is located farther than the front side component information 400j provided on the front side of the electronic component. Therefore, by making the size of the characters as the front side maker name information 400m or the board identification information 400i larger than the front side part information 400j of the electronic component, the maker name information 400m or the board identification information 400i can be easily recognized. There is.

FIG. 19 is a cross-sectional view of a part of the substrate 400 of the present embodiment.
Note that FIG. 19 also shows a resistor 40R as an example of an electronic component for the sake of explanation.

As shown in FIG. 19, the power supply board 40 has a board 400 on which various electronic components are mounted. Then, a plurality of electronic components constituting the AC circuit 41, the rectifier circuit 43, and the DC circuit 50 (see FIG. 16) described above are mounted on the substrate 400.

The substrate 400 of the present embodiment is provided on the front side of a plate-shaped base material 4001 having an insulating property using, for example, a glass epoxy resin as a material, and the base material 4001, and has conductivity and a wiring pattern is formed. It includes a front conductive layer 4002 and a front resist layer 4003 that has insulating properties and covers the front side of the base material 4001 and the front conductive layer 4002. Further, the substrate 400 has a rear conductive layer 4004 which is provided on the rear side of the base material 4001 and has conductivity and a wiring pattern, and has insulating properties on the rear side and the rear side of the base material 4001. A rear side resist layer 4005 that covers the layer 4004 is provided.
In addition, in this embodiment, the plate surface 400L can exemplify the front surface of the front resist layer 4003.

The substrate 400 of the present embodiment has a through hole 400H corresponding to a position where an electronic component is mounted. Then, the electronic component mounted on the substrate 400 is provided with a lead which is a portion electrically connected to the substrate 400 through the through hole 400H. For example, the resistor 40R shown in FIG. 19 is provided so that the lead 40L penetrates the substrate 400. Then, the lead 40L of the resistor 40R is electrically connected to the front conductive layer 4002 or the rear conductive layer 4004 by the solder Hd.

Next, the positional relationship of the information display on the power supply board 40 in the front-rear direction will be described.
As shown in FIG. 19, in the power supply board 40 of the present embodiment, in the front-rear direction (that is, the thickness direction of the board 400), the component mounting information 400 g, the manufacturer name information 400 m on the front side, or the board is directed from the front side to the rear side. Various types of information are arranged in the order of the identification information 400i, the rear side manufacturer name information 400m2 or the rear side board identification information 400i2, and the board identification information sticker 400s.

FIG. 20 is an explanatory diagram of component mounting information 400g provided on the substrate 400 of the present embodiment.
Note that FIG. 20A shows a power supply board 40 in a state before the electronic components are mounted, and FIG. 20B shows a power supply board 40 in a state in which the electronic components are mounted.

As shown in FIG. 20, the substrate 400 of this embodiment has component mounting information 400g indicating information regarding mounting of electronic components. The component mounting information 400g is provided according to the position where the electronic component is mounted. Further, the component mounting information 400g of the present embodiment is composed of white characters. The component mounting information 400g of the present embodiment is formed by being printed on the plate surface 400L (on the front resist layer 4003 (see FIG. 19)) of the substrate 400.

The component mounting information 400g of this embodiment has different contents depending on the type of electronic component.
As shown in FIG. 20 (A), for example, in a place where the surge absorbing element 40S (see FIG. 20 (B)) is provided, the text information s1 of "SA1" indicating the surge absorbing element 40S is used as the component mounting information 400 g. And the circuit diagram symbol s2 indicating the surge absorbing element 40S are displayed.
Further, in the place where the resistor 40R (see FIG. 20B) is provided, the text information r1 indicating the resistor 40R and the circuit diagram symbol r2 indicating the resistor 40R are provided as component mounting information 400g. Is displayed.
Further, in a place where the IC package 40P (see FIG. 20B), which is a packaged component such as a PFC circuit, is provided, the text information p1 of "IC3" indicating the IC package 40P is used as the component mounting information 400g. And a rectangular frame p2 indicating the mounting position of the IC package 40P are displayed.

Further, in the place where the connector 40N (see FIG. 20B) is provided, the text information n1 indicating the connector 40N and the frame n2 indicating the mounting position of the connector 40N are displayed as the component mounting information 400g. Has been done. The frame n2 has a shape corresponding to the outer shape of the connector 40N, and indicates the vertical direction and the horizontal direction of the connector 40N.
Further, in the place where the capacitor 40C (see FIG. 20B) is provided, the component mounting information is 400 g, the text information c1 indicating the capacitor 40C and the text information c1 indicating the capacitor 40C, and the circle indicating the mounting position of the capacitor 40C. The frame c2 of the shape is displayed. Further, inside the frame c2, a colored (white in this embodiment) filled region c21 indicating the negative pole of the capacitor and a non-filled region c22 indicating the positive pole of the capacitor are provided. Further, on the outside of the frame c2, the symbol c3 indicating the positive pole of the capacitor is provided.

Then, as shown in FIG. 20B, each electronic component is mounted on the corresponding portion on the substrate 400.
For example, when the surge absorbing element 40S is mounted on the substrate 400, at least a part of the circuit diagram symbol s2 (see FIG. 20A) is hidden by the surge absorbing element 40S when viewed from the vertical direction of the plate surface 400L. Therefore, it becomes invisible or difficult to see. On the other hand, the text information s1 is visible or easy to see even if the surge absorbing element 40S is mounted on the substrate 400.
Further, when the resistor 40R is mounted on the substrate 400, at least a part of the circuit diagram symbol r2 (see FIG. 20A) is hidden by the resistor 40R when viewed from the vertical direction of the plate surface 400L. It becomes invisible or difficult to see. On the other hand, the text information r1 is visible or easy to see even if the resistor 40R is mounted on the substrate 400.

Further, when the IC package 40P is mounted on the substrate 400, the text information p1 and the frame p2 are visible or easily visible when viewed from the vertical direction of the plate surface 400L, respectively.
Further, when the connector 40N is mounted on the substrate 400, the text information n1 and the frame n2 are visible or easily visible when viewed from the vertical direction of the plate surface 400L, respectively.

When the capacitor 40C is mounted on the substrate 400, the text information c1, the frame c2, and the symbol c3 are visible or easily visible when viewed from the vertical direction of the plate surface 400L, respectively. On the other hand, at least a part of the filled area c21 and the unfilled area c22 is hidden by the capacitor 40C when viewed from the vertical direction of the plate surface 400L, and becomes invisible or difficult to see.

Then, in the present embodiment, when a plurality of components are arranged relatively densely, the component mounting information 400 g is formed by a plurality of electronic components, not a region sandwiched between the plurality of electronic components. It is placed outside the group to be. For example, as shown in FIG. 20B, when a plurality of capacitors 40C are provided next to each other, the text information c1 is provided outside the group of the plurality of capacitors 40C. As a result, in the power supply board 40 of the present embodiment, in a state where a plurality of electronic components are mounted on the board 400, at least text information c1 out of 400 g of component mounting information is hidden between the electronic components so as not to be obscured. There is.

Further, in the power supply board 40 of the present embodiment, the top and bottom of the characters as text information (s1, r1, p1, n1, c1) provided on the board 400 correspond to the top and bottom of the pachinko gaming machine 100. That is, the upper side of the character as text information is the upper side of the pachinko game machine 100, and the lower side of the character is the lower side of the pachinko game machine 100. In the power supply board 40 of the present embodiment, the board 400 is not provided with text information such that the upper side of the characters is the lower side of the pachinko gaming machine 100. Further, in the power supply board 40 of the present embodiment, the plurality of text information have the same character size and font.

By aligning the orientation of the characters as text information provided on the board 400 in this way, when the power supply board unit 4 is installed in the pachinko gaming machine 100, it is difficult for the operator to mistake the orientation of the power supply board unit 4. doing. That is, by attaching the power supply board unit 4 so that the top and bottom of the characters as the text information (s1, r1, p1, n1, c1) provided on the board 400 correspond to the vertical direction of the pachinko gaming machine 100, the operator However, the mounting direction of the power supply board unit 4 is not mistaken.

When forming text information on the substrate 400, due to the arrangement of electronic components provided on the substrate 400, the characters must be provided so that the top and bottom of the characters as the text information are along the left and right directions of the pachinko gaming machine 100. It may not be there. In such a case, the operator attaches the power supply board unit 4 by increasing the number of text information in which the top and bottom of the character correspond to the vertical direction more than the number of text information in which the top and bottom of the character correspond to the horizontal direction. It is possible to make it difficult to make a mistake in the direction.

As described above, in the present embodiment, the power supply board 40 has a plurality of information identification displays provided at different positions in the thickness direction of the power supply board 40.
When a problem occurs in the power supply board 40, it may be necessary to check the power supply board 40 to identify the location where the problem occurs. In this case, if a plurality of identification displays are provided at different positions in the thickness direction of the power supply board 40, each identification display is provided as compared with a case where a plurality of identification displays are provided at the same position in the thickness direction. It becomes easy to distinguish. Therefore, it is possible to suppress the progress of the defect by taking measures for the identified defect at an early stage as much as the source of the defect is identified at an early stage.

Subsequently, the power supply board case 60 will be described in detail.
A resin material such as polycarbonate can be used for the power supply substrate case 60 of the present embodiment. Further, the power supply board case 60 is configured to have at least translucency for transmitting visible light. Therefore, the power supply board case 60 is configured so that various electronic components of the power supply board 40 provided inside the power supply board case 60 can be visually recognized.

As shown in FIG. 15, the power supply board case 60 has a main surface portion 61 provided on the front side in the front-rear direction and substantially parallel to the plate surface 400L of the substrate 400. Further, the power supply board case 60 is provided on the upper side in the vertical direction and is provided on the upper wall surface portion 62 substantially perpendicular to the plate surface 400L of the substrate 400, and is provided on the lower side in the vertical direction and the plate surface of the substrate 400. It has a lower side wall surface portion 63 provided substantially perpendicular to 400 L. Further, the power supply board case 60 is provided on the left side in the left-right direction and is provided on the left side wall surface portion 64 substantially perpendicular to the plate surface 400L of the substrate 400, and is provided on the right side in the left-right direction and the plate surface 400L of the substrate 400. It has a right side wall surface portion 65 provided substantially perpendicular to the relative direction. The power supply board case 60 has an operation surface portion 66 on the left side with respect to the left side wall surface portion 64.

The power supply board case 60 covers various electronic components provided on the power supply board 40 by the main surface portion 61, the upper wall surface portion 62, the lower side wall surface portion 63, the left side wall surface portion 64, and the right side wall surface portion 65. However, the power supply board case 60 does not cover the first board connection connector 446, the second board connection connector 448, the third board connection connector 449, and a part of the board surface 400L of the board 400 around these connectors. Further, the operation surface portion 66 covers these electronic components in a state where a part of the front side of the AC connection connector 411, the power switch 412, the CR connection connector 416 and the FG connection connector 425 is exposed.

The main surface portion 61 is formed in a flat shape. In the power supply board case 60 of the present embodiment, the main surface portion 61 is any of the upper wall surface portion 62, the lower side wall surface portion 63, the left side wall surface portion 64, the right side wall surface portion 65, and the operation surface portion 66 constituting the power supply board case 60. The area is larger than.
The main surface portion 61 has a mounting portion 61S for attaching the case seal 600, which will be described later, and identification information 60i for managing the power supply board case 60. The case seal 600, the mounting portion 61S, and the identification information 60i will be described in detail later.

Further, the main surface portion 61 of the present embodiment is provided on the upper wall surface portion 62 and the lower side wall surface portion 63, and no through hole is formed except for the ventilation hole 60H described later which is formed extending to the main surface portion 61. For example, in the pachinko gaming machine 100 of the present embodiment, another unit may be provided on the front side (that is, the main surface portion 61 side) of the power supply board unit 4 so as to be laminated on the power supply board unit 4. In this case, the heat generated in the other unit may be transferred to the power supply board unit 4 from the front-rear direction. Therefore, in the present embodiment, in order to make it difficult for the heat generated in the other units to be transferred to the power supply board unit 4 from the front-rear direction in the power supply board unit 4, the main surface portion 61 is not provided with a through hole.

However, in the power supply board unit 4 of the present embodiment, the present invention is not limited to not providing a through hole in the main surface portion 61.
When the through hole is provided in the main surface portion 61, the through hole in the main surface portion 61 may have a shape different from that of, for example, the ventilation hole 60H. Further, the through hole of the main surface portion 61 is made smaller than the opening area of the ventilation hole 60H. Further, the total opening area of the plurality of through holes provided in the main surface portion 61 is made smaller than the total opening area of the plurality of ventilation holes 60H.

Further, the power supply board case 60 may have, for example, a plate-shaped bottom surface portion on the rear side of the power supply board 40. The bottom surface portion is provided so as to face the main surface portion 61 with the power supply board 40 sandwiched between them. In this way, when the bottom surface portion is provided, the power supply board case 60 can cover the power supply board 40 from all directions of the vertical direction, the horizontal direction, and the front-rear direction.
In this case, the bottom surface portion can be made of the same resin member as the main surface portion 61, the upper wall surface portion 62, the lower side wall surface portion 63, the left side wall surface portion 64, and the right side wall surface portion 65. Alternatively, a metal member or the like may be used for the bottom surface portion, and the main surface portion 61, the upper wall surface portion 62, the lower side wall surface portion 63, the left side wall surface portion 64, and the right side wall surface portion 65 may be made of a different material.

Further, when the power supply board case 60 is provided with the bottom surface portion, the bottom surface portion is not provided with a through hole. Thereby, for example, it is possible to make it difficult for the heat generated in the other unit to be transferred to the power supply board unit 4 from the front-rear direction of the power supply board unit 4.
However, the power supply board unit 4 of the present embodiment is not limited to not providing a through hole in the bottom surface portion. When a through hole is formed in the bottom surface portion, the through hole in the bottom surface portion can have a shape different from that of, for example, the ventilation hole 60H. Further, the through hole on the bottom surface is made smaller than the opening area of the ventilation hole 60H. Further, the total opening area of the plurality of through holes provided on the bottom surface portion is made smaller than the total opening area of the plurality of ventilation holes 60H.

Further, the upper wall surface portion 62 or the lower side wall surface portion 63 may be provided with a connection portion for connecting to the bottom surface portion. In this case, the connection portion and the ventilation hole 60H are arranged side by side along the vertical direction of the power supply board case 60. For example, when the connection portion has a structure in which the upper wall surface portion 62 or the lower side wall surface portion 63 and the bottom surface portion are engaged with each other, the connection portion is relatively easily deformed by arranging the connection portion and the ventilation hole 60H side by side. Therefore, the work when engaging is facilitated.

FIG. 21 is a side view of the power supply board unit 4 of the present embodiment when viewed from above.
21 (A) shows an overall side view of the power supply board unit 4, and FIG. 21 (B) is an enlarged view of the ventilation hole 60H described later.
FIG. 22 is a side view of the power supply board unit 4 of the present embodiment when viewed from the right side.
FIG. 23 is a side view of the power supply board unit 4 of the present embodiment when viewed from the left side.

As shown in FIG. 21 (A), the upper wall surface portion 62 has a plurality of ventilation holes 60H. Each of the ventilation holes 60H is formed in the upper wall surface portion 62 so as to penetrate in the vertical direction of the upper wall surface portion 62. Further, each of the ventilation holes 60H is formed so as to extend long in the front-rear direction. The plurality of ventilation holes 60H are formed side by side in the left-right direction.
As shown in FIG. 21B, the ventilation holes 60H have different opening widths in the left-right direction in the longitudinal direction. In the present embodiment, in the ventilation hole 60H, the opening width W1 on the front side is larger than the opening width W2 on the rear side. That is, the ventilation holes 60H are formed so that the opening width becomes smaller from the front side to the rear side in the front-rear direction.

Further, the opening width (for example, the widest portion) of the ventilation hole 60H in the present embodiment in the left-right direction is smaller than the width in the left-right direction of the heat radiating member 43hs or the heat radiating member 454hs. The position of the heat radiating member 43hs or the heat radiating member 454hs in the left-right direction is determined so as to face the ventilation hole 60H in the vertical direction.
Further, the length of the vent hole 60H in the front-rear direction is longer than the length in the front-rear direction of the capacitor 4823, and shorter than the length in the front-rear direction of the first smoothing capacitor 442 (or the second smoothing capacitor 443). .. Further, the front end portion of the ventilation hole 60H is located on the front side of the heat radiating member 454hs in the front-rear direction when the plate surface 400L is used as a reference.

The opening width of the ventilation hole 60H is smaller than the outer diameter (diameter) of the gaming ball used for the game of the pachinko gaming machine 100. As a result, the power supply board case 60 prevents the game ball from entering the power supply board case 60. This content is the same not only in the ventilation holes 60H but also in various openings provided in the power supply board case 60.

Then, as shown in FIG. 21 (A), the front end portion of the ventilation hole 60H is provided at the front end portion of the upper wall surface portion 62. The rear end of the vent 60H is provided in the center of the upper wall surface 62. That is, the ventilation holes 60H are formed in the front-rear direction of the upper wall surface portion 62 from the front end portion to the middle toward the rear end portion. Then, on the upper wall surface portion 62, a ventilation hole region 62R1 in which the ventilation hole 60H is provided and a non-ventilation hole region 62R2 in which the ventilation hole 60H is not provided are formed. As described above, the vent region 62R1 is provided on the front side of the upper wall surface portion 62 in the front-rear direction, and the non-vent region 62R2 is provided on the rear side in the front-rear direction. In the upper wall surface portion 62 of the present embodiment, the width of the region occupied by the vent hole region 62R1 in the front-rear direction is larger than the width of the region occupied by the non-vent hole region 62R2 in the front-rear direction.

Then, the ventilation hole region 62R1 forms a path in which the heat generated from the power supply board 40 is discharged to the outside of the power supply board case 60 inside the power supply board case 60.
Further, when the power supply board unit 4 is viewed from above in the vertical direction, the non-vent hole region 62R2 is formed at a position facing the plate surface 400L of the board 400. Further, the non-vented hole region 62R2 of the present embodiment faces the gap Ws between the electronic component and the plate surface 400L. As a result, the non-vent hole region 62R2 suppresses foreign matter such as dust from entering the gap Ws between the electronic component and the plate surface 400L, and the electrical connection point (for example, for example) between the electronic component and the substrate 400. It suppresses foreign matter from coming into contact with the lead 40L of the capacitor 40C).

Further, as shown in FIG. 15, the lower side wall surface portion 63 has a plurality of ventilation holes 60H, similarly to the upper wall surface portion 62. The ventilation holes 60H provided in the lower side wall surface portion 63 and the ventilation holes 60H provided in the upper wall surface portion 62 are displaced in the left-right direction.

Then, as shown in FIG. 22, the upper wall surface portion 62 is inclined by an angle θ1 with respect to the horizontal direction HL. The upper wall surface portion 62 of the present embodiment is inclined so as to be lowered downward from the rear side to the front side in the front-rear direction. The upper wall surface portion 62 is inclined so that, for example, when foreign matter such as a game ball or dust gets on the upper wall surface portion 62, they do not stagnate or accumulate.
Similarly, the lower side wall surface portion 63 of the present embodiment is also inclined by an angle θ2 with respect to the horizontal HL.

Subsequently, the left side wall surface portion 64 of the power supply board case 60 will be described.
As shown in FIG. 23, the left side wall surface portion 64 of the present embodiment does not have a through hole. Here, as described above, in the power supply board 40, the temperature rises due to the heat generated by the electronic components. Further, in the power supply board unit 4 of the present embodiment, by not providing a through hole in the left side wall surface portion 64 adjacent to the power supply switch 412, it is difficult for the operator to feel heat when operating the power supply switch 412. ing.

However, the present invention is not limited to not providing a through hole in the left wall surface portion 64. For example, when a through hole is provided in the left side wall surface portion 64, the through hole is not provided at least in the portion of the power switch 412 facing the off portion (for example, “◯” shown in FIG. 16), and the other portion is provided with the through hole. A through hole may be provided. When the power switch 412 is turned on in the power supply board unit 4, the temperature of the power supply board 40 is low because the power supply has not been turned on until then. On the other hand, when the power switch 412 is turned off, the power is already turned on, so that the temperature of the power supply board 40 rises as the power supply board 40 generates heat. Therefore, when a through hole is formed in the left side wall surface portion 64, the left side wall surface is not provided with a through hole at least in the portion adjacent to the off portion (for example, “◯” shown in FIG. 16) of the power switch 412. Through holes may be provided in other parts of the portion 64.
In the power switch 412 of the present embodiment, the power supply board unit 4 is arranged on the upper side where the temperature is relatively high (for example, "-" shown in FIG. 16), and is turned off on the lower side where the temperature is relatively low. (For example, "○" shown in FIG. 16) is arranged.

Next, the right side wall surface portion 65 of the power supply board case 60 will be described.
The right side wall surface portion 65 of the present embodiment does not have a through hole. As described with reference to FIG. 18, for example, the second smoothing capacitor 443 of the present embodiment is provided at a position lower than the front component information 400j (see FIG. 16), and has a side surface facing the left-right direction. It has part information 400f. The side component information 400f is the information most easily recognized when viewed from the left-right direction in the power supply board unit 4. Here, for example, the upper wall surface portion 62 and the lower side wall surface portion 63 are provided with ventilation holes 60H. Since the ventilation holes 60H form irregularities on the upper wall surface portion 62, it becomes difficult to visually recognize the side component information 400f of the second smoothing capacitor 443 provided from the outside to the inside of the power supply board case 60. Therefore, the electronic components provided inside the power supply board case 60 are easily visible from the outside without forming the ventilation holes 60H in the right side wall surface portion 65 of the present embodiment.

However, the present invention is not limited to not providing a through hole in the right side wall surface portion 65. For example, when a through hole is provided in the right side wall surface portion 65, for example, a through hole is not provided in a portion facing the electronic component provided with the side component information 400f, and the electronic component facing the electronic component provided with the side component information 400f is not provided. Through holes may be provided in other places where the holes are not provided.

Further, the operation surface portion 66 of the power supply board case 60 will be described.
As shown in FIG. 23, the operation surface portion 66 has an opening provided inside through which an electronic component penetrates, and the periphery of the opening is formed in a planar shape. The portion on the surface around the opening is substantially parallel to the plate surface 400L.
The operation surface portion 66 is provided for the first operation surface portion 661 provided for the AC connection connector 411 and the CR connection connector 416, the second operation surface portion 662 provided for the FG connection connector 425, and the power switch 412. It has a third operation surface portion 663.

The heights of the first operation surface portion 661 and the second operation surface portion 662 with respect to the plate surface 400L of the substrate 400 are the heights H11, which are substantially the same. Further, the height H12 of the third operation surface portion 663 with respect to the plate surface 400L of the substrate 400 is higher than the height H11 of the first operation surface portion 661 and the second operation surface portion 662. Further, the height H13 of the main surface portion 61 is higher than the height H12 of the third operation surface portion 663. That is, the height of each surface portion in the power supply board case 60 is higher in the order of the height H11 of the first operation surface portion 661 and the second operation surface portion 662, the height H12 of the third operation surface portion 663, and the height H13 of the main surface portion 61. It has become.

The relationship between the operation surface portion 66 and each electronic component is as follows.
Here, in the power supply board 40 of the present embodiment, the height H6 of the CR connection connector 416, the height H7 of the FG connection connector 425, the height H8 of the AC connection connector 411, and the height H9 of the power switch 412 increase in this order. ing. On the other hand, the height H11 of the first operation surface portion 661 is lower than the height H6 of the CR connection connector 416 and the height H8 of the AC connection connector 411. Further, the height H11 of the second operation surface portion 662 is lower than the height H7 of the FG connection connector 425. Further, the height H12 of the third operation surface portion 663 is lower than the height H9 of the power switch 412. The height H12 of the third operation surface portion 663 is higher than the height H8 of the AC connection connector 411, which is the highest among the connectors.

Subsequently, the case seal 600 and the identification information 60i will be described in detail.
FIG. 24 is an explanatory diagram of the power supply board case 60 of the present embodiment.

As shown in FIG. 24A, the case seal 600 of this embodiment is provided in the vicinity of the power switch 412. The case seal 600 conveys information about the power supply board unit 4, such as warnings and management information regarding the handling of the power supply board unit 4.
Here, in the power supply board unit 4 of the present embodiment, it is the power supply switch 412 that the operator operates. The power switch 412 is located at the upper end in the vertical direction and on the left end in the horizontal direction. Therefore, the case seal 600 is provided on the main surface portion 61 at the upper end portion in the vertical direction on the power switch 412 side and on the left side end portion in the horizontal direction. This makes it easier for the operator to check the contents of the case seal 600 provided in the vicinity when operating the power switch 412.

Further, the mounting portion 61S to which the case seal 600 is attached is formed to be one size larger than the case seal 600. Further, as shown in FIG. 24 (B), the mounting portion 61S is formed in the main surface portion 61 so as to be recessed on the rear side in the front-rear direction. The case seal 600 attached to the mounting portion 61S does not protrude forward from the main surface portion 61. This makes it difficult for the case seal 600 to come off when the operator touches the vicinity of the case seal 600, for example, when handling the power supply board unit 4.

As shown in FIG. 24C, the case seal 600 includes an information display unit 610 that conveys information such as characters, and a base portion 620 that serves as a base in the case seal 600.
The information display unit 610 of the present embodiment is printed in black. Here, the above-mentioned front part information 400j (see FIG. 16) is composed of white characters. Therefore, in the power supply board unit 4 of the present embodiment, the colors of the characters and ruled lines (frames) provided on the case seal 600 are different from the colors of the characters provided on the board 400 and the electronic components mounted on the board 400. This makes it easier to visually recognize each piece of information.

The character size and font of the information display unit 610 of the present embodiment may be different from the character size and font provided on the substrate 400 and the electronic components mounted on the substrate 400. Also in this case, the character information provided on the information display unit 610 and the character information provided on the power supply board 40 can be easily visually recognized.

The information display unit 610 has management information 611 for managing the power supply board unit 4, a warning mark 612 that prompts a warning to the user graphically, and a warning text 613 that alerts the user in characters. .. In addition, the information display unit 610 has a first warning sentence 614, a second warning sentence 615, and a third warning sentence 616 that specifically indicate the content of the warning to the user. The first warning sentence 614 indicates a warning regarding the handling of the power supply board case 60, for example, "Please do not open the case". Further, the second warning sentence 615 indicates a warning regarding the temperature of the power supply board 40, for example, "Be careful of high temperature". Further, the third warning sentence 616 indicates a warning related to the environment of the power supply board case 60, for example, "Please do not block the ventilation holes".

Further, the information display unit 610 has spec information 617 regarding the specifications of the power supply board 40 and maintenance information 618 regarding maintenance of the power supply board 40 and the like. In this embodiment, the spec information 617 indicates an input voltage to the power supply board unit 4. Further, the maintenance information 618 indicates a current value related to the fuse.

Further, the base portion 620 of the present embodiment is configured to be capable of transmitting at least visible light. Thereby, even in the place where the case seal 600 is provided, the power supply board 40 arranged on the rear side of the case seal 600 can be visually recognized through the case seal 600.
The base portion 620 is not limited to being transparent. For example, the base portion 620 may have the same system as the color of the characters provided on the substrate 400. For example, the text information s1 (see FIG. 20) of the substrate 400 of the present embodiment is white. In this case, the base portion 620 can be white.

Further, in the present embodiment, the case seal 600 is provided at a position on the power supply board 40 that does not face the highest electronic component in the front-rear direction. For example, in this embodiment, the heat radiating member 454 hs is the tallest electronic component (see FIG. 18). Therefore, the case seal 600 is arranged not at the central portion where the heat radiating member 454 hs is provided, but at the end portion of the main surface portion 61 deviated from the central portion. If the electronic components are provided close to the case seal 600 in the front-rear direction, there is a high possibility that the information display unit 610 of the case seal 600 will be difficult to see. Therefore, in the present embodiment, the case seal 600 is provided at a position different from the position facing the highest heat radiating member 454 hs.

Further, in the present embodiment, the densities of the plurality of electronic components provided in the power supply board 40 facing the case seal 600 in the front-rear direction (hereinafter referred to as the seal facing region) are such that the power supply board 40 faces the case seal 600. The density is lower than the density of a plurality of electronic components provided in places where they are not used (hereinafter, non-seal facing regions). Here, if the density of the plurality of electronic components provided in the seal facing region is high, there is a high possibility that the information display unit 610 of the case seal 600 will be difficult to recognize. Therefore, in the power supply board 40 of the present embodiment, the information display unit 610 is easily recognized by relatively reducing the density of the plurality of electronic components in the seal facing region.

Further, the density of the plurality of characters provided in the seal facing region (for example, text information s1 (see FIG. 20)) may be lower than the density of the plurality of characters provided in the non-seal facing region. As a result, the characters provided on the rear side of the information display unit 610 of the case seal 600 are not complicated, and the information display unit 610 of the case seal 600 can be easily recognized.

Further, the orientation of the plurality of characters provided in the seal facing region may be different from the orientation of the characters on the information display unit 610 of the case seal 600. This makes it easier to distinguish between the information display unit 610 of the case seal 600 and the characters provided on the substrate 400, and makes it easier to recognize the information display unit 610 of the case seal 600.

Further, as shown in FIG. 24 (A), the identification information 60i is provided on the main surface portion 61. The identification information 60i is integrally formed when the main surface portion 61 is molded. Then, as shown in FIG. 24B, the identification information 60i is formed on the rear surface of the main surface portion 61 in the front-rear direction. As a result, for example, even when an object comes into contact with the power supply board case 60 from the outside, the identification information 60i is less likely to be affected.
The identification information 60i and the information display unit 610 of the case seal 600 similarly convey information, but their positions in the front-rear direction are different. That is, as shown in FIG. 24 (B), the distance L1 of the case seal 600 from the plate surface 400L is larger than the distance L2 of the identification information 60i when the plate surface 400L (see FIG. 18) of the substrate 400 is used as a reference. It's getting longer. That is, for the operator looking at the power supply board case 60 from the outside, the case seal 600 is closer than the identification information 60i. Here, the case seal 600 is more important than the identification information 60i in terms of transmitting information such as a warning to the operator. Therefore, in the present embodiment, the case seal 600 is arranged so as to be closer than the identification information 60i.

Subsequently, the structure of the power supply board 40A of the modified example shown in FIGS. 13 and 14 described above will be described.
FIG. 25 is a top view of the power supply board 40A of the modified example as viewed from the front side.

As shown in FIG. 25, unlike the power supply board 40, the power supply board 40A of the modified example does not have the input detection circuit 46, the output detection circuit 47, and the backup circuit 49.
Further, as the power supply board 40A, so-called SMD components are used in addition to the so-called DIP components.

Further, the power supply board 40A of the modified example is not provided with the manufacturer name information 400m provided on the power supply board 40 described above, and in this example, only the board identification information 400i is provided. As described above, the power supply board 40A is provided with a plurality of SMD components. Since the SMD parts are soldered on the plate surface 400L, the area occupied by the plate surface 400L in the surface direction is relatively large. As a result, there is a restriction on the space for providing the manufacturer name information 400 m on the board 400 of the power supply board 40A. Therefore, the power supply board 40A of the present embodiment is configured to provide only the board identification information 400i without providing the manufacturer name information 400m.

(Game control board unit 2)
Next, the game control board unit 2 will be described.
FIG. 26 is a front view of the game control board unit 2.
In the game control board unit 2, the game machine control board case 200C and the game control board 200B are provided so as to overlap each other. The game control board case 200C is provided on the front side of the game control board 200B. An information display sticker 250 is attached to the game control board case 200C. Further, the game control board case 200C is made of a material having light transmission.

FIG. 27 is a diagram showing an information display sticker 250.
The information display sticker 250 displays information about the pachinko gaming machine 100. The information display sticker 250 is provided with a code unit 2501, an identification display unit 2502, a description area 2503, and a transmission unit 2504.
In the code unit 2501, a black QR (Quick Response) code (registered trademark) is displayed on a white background. When the QR code displayed on the code unit 2501 is read by the terminal device (not shown), information about the game control board 200B is displayed on the display screen (not shown) of the terminal device. Examples of the information regarding the game control board 200B include information indicating the delivery destination of the game control board 200B. Further, as the information regarding the game control board 200B, for example, information indicating the control number of the game control board 200B can be mentioned.

Information for identifying the game control board 200B is displayed on the identification display unit 2502. More specifically, on the identification display unit 2502, the control number of the game control board 200B is displayed in black on a white background. Therefore, the information display sticker 250 can also be regarded as a control number sticker on which the control number of the game control board 200B is shown. In the identification display unit 2502, the texts are displayed side by side in the left-right direction. In the illustrated example, the text "XX001" is displayed in black as the control number of the game control board 200B. Further, in the identification display unit 2502, the vertical direction of the text is along the vertical direction of the game control board 200B.

The description area 2503 is provided with a white base. In the description area 2503, the name of the person who opened the game control board case 200C (the inspector who inspects the game control board unit 2), the date when the game control board case 200C was opened, and the like are described.
The transmitting portion 2504 is a portion having light transmission. Therefore, even when the game control board 200B is housed in the game control board case 200C, the inspector can confirm the game control board 200B through the transmission portion 2504 of the information display sticker 250.

FIG. 28 is a front view of the game control board 200B.
The game control board 200B is provided with a board body 200S. The above-mentioned RAM 203, RAM clear switch 228, setting key switch 229, and information display 230 are attached to the substrate main body 200S. Further, a plurality of electronic components are attached to the substrate body 200S. The game control board 200B of the present embodiment is provided with an IC (Integrated Circuit) 251, a connector 252, a resistor 253, and a capacitor 254 as electronic components. All of these electronic components are DIP (Dual inline Package) components that are inserted into the substrate body 200S.
In addition to the above-mentioned ones, electronic components may be further provided on the game control board 200B.

The game control board 200B is provided with six ICs 251 in addition to the ROM 203. Each IC 251 is provided with a model display unit 2511. In the model display unit 2511, the text indicating the model of the IC 251 is displayed in white.
Here, in the IC 251 in which the model display unit 2511 is "CD01", "EF01", and "EF02", the texts of the model display unit 2511 are displayed side by side in the left-right direction. Further, the vertical direction of these texts is along the vertical direction of the game control board 200B. On the other hand, in the IC 251 in which the model display unit 2511 is "GH01", "GH02", and "IJ01", the texts of the model display unit 2511 are displayed side by side in the vertical direction. Further, the vertical direction of these texts is along the horizontal direction of the game control board 200B.
Further, the IC 251 whose model display unit 2511 is "IJ01" is located in the overlapping region RE of the game control board 200B, which overlaps the region where the information display sticker 250 is provided in the front-rear direction.

Further, the identification display unit 2512 corresponding to each IC 251 is displayed on the substrate main body 200S. The text for identifying the IC 251 is displayed in white on the identification display unit 2512. Each identification display unit 2512 is provided in the vicinity of the corresponding IC 251.
Here, in the IC 251 whose identification display unit 2512 is "IC2", "IC3", and "IC4", the identification display unit 2512 is displayed side by side in the left-right direction. Further, the vertical direction of the text shown on these identification display units 2512 is along the vertical direction of the game control board 200B. On the other hand, in the IC 251 whose identification display unit 2512 is "IC5", "IC6", and "IC7", the identification display unit 2512 is displayed side by side in the vertical direction. Further, the vertical direction of the text shown on these identification display units 2512 is along the horizontal direction of the game control board 200B.

Further, the game control board 200B is provided with three connectors 252. Further, on the board body 200S, an identification display unit 2521 corresponding to each connector 252 is displayed. On the identification display unit 2521, text for identifying the connector 252 is displayed in white. Each identification display unit 2521 is provided in the vicinity of the corresponding connector 252. Further, the identification display units 2521 are all displayed side by side in the left-right direction. Further, the vertical direction of the text shown on each identification display unit 2521 is along the vertical direction of the game control board 200B.

Further, the game control board 200B is provided with six resistors 253. Further, on the substrate main body 200S, an identification display unit 2531 corresponding to each resistor 253 is displayed. On the identification display unit 2531, the text for identifying the resistor 253 is displayed in white. Further, each of the identification display units 2531 is displayed side by side in the vertical direction. Further, the vertical direction of the text shown on each identification display unit 2531 is along the horizontal direction of the game control board 200B.
Further, the resistor 253 whose identification display unit 2531 is "R6" is provided in the superimposition region RE.

Further, the game control board 200B is provided with a capacitor 254. The capacitor 254 is the highest (longer in the front-rear direction) electronic component among the electronic components provided on the game control board 200B. As the capacitor 254, for example, an electrolytic capacitor is used. Further, on the substrate main body 200S, an identification display unit 2541 corresponding to the capacitor 254 is displayed. On the identification display unit 2541, a text for identifying the capacitor 254 is displayed in white. The identification display unit 2541 is displayed side by side in the left-right direction. Further, the vertical direction of the text shown on the identification display unit 2541 is along the vertical direction of the game control board 200B. The capacitor 2541 is provided in a region of the substrate main body 200S different from the superposed region RE.

FIG. 29 is a view when the capacitor 254 is viewed from the front side of the capacitor 254.
A model display unit 2542 and a capacitance display unit 2543 are provided on the side surface of the capacitor 254.
Information indicating the model of the capacitor 254 is displayed in white on the model display unit 2542. In the illustrated example, the text "KL01" is shown on the model display unit 2542.
Information indicating the capacity of the capacitor 254 is displayed in white on the capacity display unit 2543. In the illustrated example, the text "680 μF" is shown on the capacitance display unit 2543.

As described above, in the present embodiment, if the color of the characters printed on the information display sticker 250 provided on the game control board case 200C is different from the color of the characters printed on the board body 200S of the game control board 200B. I'm letting you. Here, as the characters printed on the information display sticker 250, for example, the text shown on the identification display unit 2502 can be mentioned. Examples of the characters printed on the board body 200S include an identification display unit 2512, an identification display unit 2521, an identification display unit 2531, and an identification display unit 2541.
Further, in the present embodiment, the color of the characters printed on the information display sticker 250 and the color of the characters printed on the electronic components mounted on the game control board 200B are different from each other. Here, as the characters printed on the electronic components mounted on the game control board 200B, for example, the model display unit 2511 of the IC 251 and the like can be mentioned.

As described above, since the game control board case 200C has light transmission, when the inspector visually inspects the game control board unit 2, the game control board case 200C is printed on the game control board 200B via the game control board case 200C. The characters that are present will also be visible to the inspector. In this case, the inspector may mistakenly recognize that the characters printed on the game control board 200B are the characters printed on the information display sticker 250, which may hinder the visual inspection.
Therefore, in the present embodiment, by making the color of the characters printed on the information display sticker 250 different from the color of the characters printed on the game control board 200B, the characters printed on the game control board 200B display information. It prevents the inspector from misidentifying the characters as printed on the sticker 250.

Further, in the present embodiment, the size of the characters printed on the information display sticker 250 provided on the game control board case 200C and the size of the characters printed on the board body 200S of the game control board 200B are made different. There is. Here, as the characters printed on the information display sticker 250, for example, the text shown on the identification display unit 2502 can be mentioned. Examples of the characters printed on the board body 200S include an identification display unit 2512, an identification display unit 2521, an identification display unit 2531, and an identification display unit 2541. Here, the size of the characters printed on the board body 200S of the game control board 200B may be larger than the size of the characters printed on the information display sticker 250 provided on the game control board case 200C. .. Further, the size of the characters printed on the information display sticker 250 provided on the game control board case 200C may be larger than the size of the characters printed on the board body 200S of the game control board 200B. Further, the font of the characters printed on the information display sticker 250 provided on the game control board case 200C may be different from the font of the characters printed on the board body 200S of the game control board 200B.

Further, in the present embodiment, the size of the characters printed on the information display sticker 250 and the size of the characters printed on the electronic components mounted on the game control board 200B are different from each other. Here, as the characters printed on the electronic components mounted on the game control board 200B, for example, the model display unit 2511 of the IC 251 and the like can be mentioned. Here, the size of the characters printed on the electronic component mounted on the game control board 200B may be larger than the size of the characters printed on the information display sticker 250. Further, the size of the characters printed on the information display sticker 250 may be larger than the size of the characters printed on the electronic components mounted on the game control board 200B. Further, the font of the characters printed on the information display sticker 250 may be different from the font of the characters printed on the electronic component mounted on the game control board 200B.

Further, in the present embodiment, the number of electronic components provided in the area other than the superimposed area RE in the substrate body 200S is larger than the number of electronic components provided in the overlapping area RE of the substrate body 200S. ing. Further, the number of characters printed in the area other than the superimposed area RE in the board body 200S is larger than the number of characters printed in the superimposed area RE of the board body 200S. Further, the number of characters printed on the electronic components provided in the area other than the superimposed area RE in the board body 200S is larger than the number of characters printed on the electronic components provided in the superimposed area RE of the board body 200S. Is trying to increase.

Further, in the present embodiment, the color (white) of the area in which the characters are written on the information display sticker 250 is the color of the characters (white) printed on the board body 200S or the electronic component provided on the board body 200S. It is the same color as the color of the printed characters (white). Examples of the area in which the characters of the information display sticker 250 are written include a base portion in the code unit 2501, a base portion in the identification display unit 2502, and a base portion in the description area 2503. Examples of the characters printed on the board body 200S include an identification display unit 2512, an identification display unit 2521, an identification display unit 2531, and an identification display unit 2541. Examples of the characters printed on the electronic components provided on the board body 200S include the model display unit 2511 of the IC251.
In this case, in the area where the characters are written on the information display sticker 250, the color of the characters printed on the board body 200S and the color of the characters printed on the electronic components provided on the board body 200S are different. Is written. Therefore, it is possible to prevent the inspector from misidentifying the written characters and the characters printed on the board body 200S or the characters printed on the electronic components provided on the board body 200S.

[Main control processing of gaming machines]
Next, the main control process of the pachinko gaming machine 100 will be described.
In the main control process, the game control unit 200 controls the game in the pachinko gaming machine 100, instructs the effect control unit 300, which is a sub control means, to control the effect, and gives the payout control unit 330 a prize ball. Instruct to control the payout of.

FIG. 30 is a flowchart showing the main control process of the game control unit 200.
The main control process consists of a series of processes in game control, and is repeatedly executed at predetermined fixed time (for example, 4 milliseconds). In the present embodiment, the game control unit 200 generates an interrupt at preset fixed time intervals, and when the interrupt is enabled in the loop process shown in FIG. 7 (see S610), the main control is performed as the interrupt process. Execute the process. As shown in FIG. 30, in the main control process, random number update process, switch process, symbol process, electric accessory process, prize ball process, and output process are sequentially executed (S801 to S806).

In the random number update process (S801), the game control unit 200 calls the function (subroutine) of the random number control unit 241 to update the values of various random numbers used in the game control by the game control unit 200. Details of setting the random number and updating the random number value will be described later.

As the switch process (S802), a start port switch process and a gate switch process are performed.
In the start port switch process, the game control unit 200 calls the function (subroutine) of the random number acquisition unit 231 to monitor the states of the first start port switch 211 and the second start port switch 212 in FIG. 4, and the switch is turned on. If this happens, the process for the special symbol lottery is executed. Further, as will be described in detail later, when the pre-determination process is performed by the first start port switch 211 and the second start port switch 212, each function (subroutine) of the special symbol determination unit 234 and the variation pattern selection unit 235 is called. Execute the process for pre-judgment.
In the gate switch process, the game control unit 200 calls the function (subroutine) of the random number acquisition unit 231 to monitor the state of the gate switch 214 in FIG. 4, and when the switch is turned on, for a normal symbol lottery. Execute the process.
The detailed contents of these switch processes will be described later.

As the symbol processing (S803), a special symbol processing and a normal symbol processing are performed.
In the special symbol processing, the game control unit 200 calls each function (subroutine) of the special symbol variation control unit 233, the special symbol determination unit 234, and the variation pattern selection unit 235, and executes the special symbol variation and the processing associated with the symbol variation. do.
In the normal symbol processing, the game control unit 200 calls the functions (subroutines) of the normal symbol determination unit 232 and the normal symbol variation control unit 236, and executes the normal symbol variation and the processing associated with the symbol variation.
The detailed contents of these symbol processing will be described later.

As the electric accessory processing (S804), a large winning opening processing and an electric tulip processing are performed.
In the large winning opening process, the game control unit 200 calls the function (subroutine) of the large winning opening operation control unit 237 and controls the opening operation of the large winning opening 125, which is a special electric accessory, based on a predetermined condition.
In the electric tulip processing, the game control unit 200 calls the function (subroutine) of the electric tulip motion control unit 238 and controls the opening operation of the electric tulip 123, which is an ordinary electric accessory, based on a predetermined condition.
The detailed contents of these electric accessory processing will be described later.

In the prize ball processing (S805), the game control unit 200 calls the function (subroutine) of the prize ball processing unit 239, and sets a command for managing the number of prizes and controlling the payout of the prize balls according to the prize.

In the output process (S806), the game control unit 200 calls the function (subroutine) of the output control unit 240, outputs a command for effect control to the effect control unit 300, and outputs a command for payout control to the payout control unit 330. Output. The effect control command is generated in each process from S802 to S804, and is stored (set) in the control command storage area provided in the RAM 203. The payout control command is generated in the process of S805 and is stored (set) in the storage area of the control command provided in the RAM 203. A storage area is set in the RAM 203 for each type of control command.

The output control unit 240 examines the storage area of each control command of the RAM 203 in order, and if the control command is stored in each storage area (that is, the control command is generated by the processing of S802 to S805). (B), the control command is read and output to the output destination (effect control unit 300 or payout control unit 330).

In the present embodiment, as shown in FIG. 30, an output process is performed at the end of a series of main control processes. That is, the commands generated in each of the processes S802 to S805 by each of the above functions as the first processing means are stored in the corresponding storage area of the RAM 203 in each of the processes. Then, after these processes, the output control unit 240 as the second processing means collectively outputs the commands generated in each process accumulated in the storage area of the RAM 203. In other words, in the present embodiment, when the main control process is executed for one cycle, the command generated in the execution of the one cycle is output after the last command generation in the execution of the one cycle is performed.

[Modification example of basic operation of gaming machine]
In the operation example described with reference to FIGS. 7, 8 and 30, interrupts are permitted in the loop processing portion of the basic processing, and the main control processing including a series of processing is executed as the interrupt processing. However, the main control process may be configured to be repeatedly executed at regular intervals, and the specific realization means (execution procedure) is limited to the examples shown in FIGS. 7, 8 and 30. Not done. For example, the main control process may be incorporated into a series of operations of the basic process, the elapsed time may be measured at a predetermined timing, and the process may be returned to the main control process at regular time intervals (for example, 4 milliseconds). Further, while incorporating the main control process into a series of operations of the basic process, an interrupt is generated at regular intervals and an interrupt is generated as in the operation described with reference to FIGS. 7, 8 and 30. If so, it may be configured to return to the main control process incorporated in the basic process.

Further, when outputting the command generated in the basic processing, as a general rule, each time the command is generated, it is stored in the command storage area of the RAM 203, and the function of the output control unit 240 which is the second processing means is called. Output. The basic process is different from the main control process related to the progress of the game, and is a special process such as an initial operation performed only when the power is turned on. In addition, since the processing procedure of the basic processing may change due to branching based on conditions such as the state of the pachinko gaming machine 100 when the power is turned on, the generated command is promptly output so that there is no omission in the output processing. It is a process. In addition, when a command is continuously generated by a plurality of related processes, a processing procedure is adopted in which a plurality of commands are stored in the command storage area of the RAM 203 and output collectively in response to a specific processing request. You may.

[Random number update processing by the game control unit]
The random number value as the determination information used for various lottery in the game control such as the special symbol lottery is counted by the counter, and the random number update process (S801) of the main control process shown in FIG. 30 starts from a predetermined initial value. One is added each time it is done. Then, the value at the time when each lottery is performed is acquired by the start port switch process (FIG. 31) and the gate switch process (FIG. 32), and is used in the special symbol process (FIG. 33) and the normal symbol process (FIG. 38). NS. This random number value counter is an infinite loop counter, and after the counted random number value reaches the maximum value of the set random number (for example, 299 for the jackpot random number shown in FIG. 42 (a) described later). , Returns to the initial value again. Further, since the random number update process is performed at regular intervals, if the initial value of each random number is specified, the winning value may be estimated based on the update interval and the information of the initial value. Therefore, after returning from the main control process to the basic process shown in FIG. 7, the initial value of each random number is randomly changed in the initial value random number update process of S613.

[Starting port switch processing by the game control unit]
FIG. 31 is a flowchart showing the contents of the start port switch process among the switch processes shown in S802 of FIG. 30.
In this start port switch process, a process for winning a prize at the first start port 121 and a process for winning a prize at the second start port 122 are sequentially performed. With reference to FIG. 31, the game control unit 200 first determines whether or not the game ball has won a prize in the first start port 121 and the first start port switch 211 has been turned on (S901). When the first start port switch 211 is turned on, the game control unit 200 then determines whether or not the number of unchanged hold numbers U1 in the winning of the first start port 121 is less than the upper limit value (S902). .. In the example shown in FIG. 31, the upper limit is set to four. When the number of holds U1 has reached the upper limit (No in S902), the winning of the unvariable portion cannot be held any more, so that the processing for winning at the first starting port 121 ends.

On the other hand, when the hold number U1 is less than the upper limit value (Yes in S902), the random number acquisition unit 231 of the game control unit 200 acquires the random number value for the determination by the winning this time and stores it in the RAM 203 (S903). .. Here, since the first starting port 121 is won, a random number value for a special symbol lottery is acquired. The random number value acquired at this time is a value updated by the random number update process of S801. Then, the result of the special symbol lottery is determined by the random value in the subsequent special symbol processing. The random number values referred to here are the jackpot random value that determines the jackpot, small hit or miss, and the type of jackpot (time saving state or time saving no state after the end of the big hit game, high probability state and low probability state, long hit, short). Set the symbol random value (big hit symbol random value) that determines the hit), the fluctuation pattern random value for specifying the fluctuation pattern in the symbol fluctuation, and the fluctuation pattern (variation time) that can execute the reach effect described later when the symbol is out of order. Includes reach random values, etc. that determine whether or not.

Next, the game control unit 200 performs a pre-determination process (S904). In the pre-judgment process, a random number is generated by a special symbol process for a winning ball (holding ball) whose random number has already been acquired by winning a prize at the starting port but has not yet been determined by the special symbol process described later. This is a process of determining the random number before it is determined (preliminary determination).

Then, the effect control unit 300 of the present embodiment determines the random number by the special symbol processing based on the determination result (pre-determination result) of the random number determined by the pre-determination process, and the determination result is notified. Before that, a notice effect suggesting the determination result can be performed. In this advance notice effect, for example, the image display unit responds to the occurrence of a winning ball (holding ball) in which a random number has already been acquired by winning a prize at the starting port but the random number has not yet been determined by special symbol processing. It is performed by using the hold display effect (described later) displayed on 114. By the advance notice effect based on this advance determination, the player is suggested to the player the determination result when the random number is subsequently determined by the special symbol processing with respect to the reserved ball corresponding to the advance determination related to the advance notice effect. As a result, the player can play the game while having an expectation for the reserved ball. The details of the advance notice production based on the preliminary judgment will be described later.

Then, the game control unit 200 adds 1 to the value of the reserved number U1 (S905).
After that, the game control unit 200 sets the pre-determination result command including the pre-determination information by the pre-determination process of S904 in the RAM 203 in order to notify the effect control unit 300 of the pre-determination result (S906).
Further, the game control unit 200 sets the hold number increase command for notifying the effect control unit 300 of the increase in the hold number U1 due to S905 in the RAM 203 (S907), and ends the process for winning the prize at the first start port 121. ..

Next, processing for winning a prize at the second starting port 122 is performed. With reference to FIG. 31, the game control unit 200 then determines whether or not the game ball has won a prize in the second start port 122 and the second start port switch 212 has been turned on (S908). When the second start port switch 212 is turned on, the game control unit 200 then determines whether or not the number of unchanged hold numbers U2 in the winning of the second start port 122 is less than the upper limit value (S909). ). In the example shown in FIG. 31, the upper limit is set to four. When the number of holds U2 has reached the upper limit (No in S909), the winning of the unvariable portion cannot be held any more, so that the processing for winning at the second starting port 122 ends.

On the other hand, when the number of reservations U2 is less than the upper limit value (Yes in S909), the random number acquisition unit 231 of the game control unit 200 acquires the random number value for the lottery by winning this time and stores it in the RAM 203 (S910). .. Here, since the second starting port 122 is won, the random number values for the special symbol lottery (big hit random value, jackpot symbol random value, reach random value, variable pattern random value, etc.) are acquired in the same manner as in S903 above. NS. The random number value acquired at this time is a value updated by the random number update process of S801. Then, the result of the special symbol lottery is determined in the later special symbol processing by this random value.

Next, the game control unit 200 performs a pre-determination process (S911). The content of this pre-determination process is the same as that of S904 described above.
Then, the game control unit 200 adds 1 to the value of the reserved number U2 (S912).
After that, the game control unit 200 sets the pre-determination result command including the pre-determination information by the pre-determination process of S911 in the RAM 203 in order to notify the effect control unit 300 of the pre-determination result (S913).
Further, the game control unit 200 sets the hold number increase command for notifying the effect control unit 300 of the increase in the hold number U2 due to S912 in the RAM 203 (S914), and ends the process for winning the prize at the second start port 122. ..

[Gate switch processing by the game control unit]
FIG. 32 is a flowchart showing the contents of the gate switch processing when the game ball passes through the gate 124.
In this gate switch process, the game control unit 200 first determines whether or not the game ball has passed through the gate 124 and the gate switch 214 is turned on (S1001). When the gate switch 214 is turned ON, the game control unit 200 then determines whether or not the number of unchanged hold numbers G is less than the upper limit value (S1002). In the example shown in FIG. 32, the upper limit is set to four. If the number of holds G has reached the upper limit (No in S1002), the winning of the unvariable portion cannot be held any more, so the gate switch process is terminated.

On the other hand, when the hold number G is less than the upper limit value (Yes in S1002), the random number acquisition unit 231 of the game control unit 200 acquires the random number value for the lottery by the winning this time and stores it in the RAM 203 (S1003). .. Here, since the prize is won at the gate 124, a random number value (a winning random number value, etc.) for a normal symbol lottery is acquired.

Next, the game control unit 200 adds 1 to the value of the hold number G (S1004).
After the value of the hold number G is added in S1004, the game control unit 200 sets the hold number G increase command in the RAM 203 to notify the effect control unit 300 of the increase in the hold number G by S1004 (S1005). The process for winning a prize at the gate 124 is terminated.

[Special symbol processing by the game control unit]
FIG. 33 is a flowchart showing the contents of the special symbol processing among the symbol processing shown in S803 of FIG. 30.
In this special symbol processing, the special symbol variation control unit 233 of the game control unit 200 first checks whether or not the jackpot game flag is ON in the flag setting (hereinafter, flag setting) set in the RAM 203 (hereinafter, flag setting). S1101). Here, the jackpot game flag is a flag set to identify that the result of the special symbol lottery is a jackpot.

When the jackpot game flag is ON, the pachinko gaming machine 100 is already in the jackpot, so the special symbol processing is terminated without starting the special symbol variation (Yes in S1101). On the other hand, when the jackpot game flag is OFF (No in S1101), the special symbol variation control unit 233 then determines whether or not the current state of the pachinko gaming machine 100 is undergoing special symbol variation (S1102). When the special symbol is not changing (No in S1102), the special symbol change control unit 233 then performs processing related to the pending numbers U1 and U2 (see FIG. 31) of the unchanged portion of the special symbol (S1103 to S1106). In the present embodiment, since the number of reservations U1 related to the winning of the first starting port 121 and the number of holdings U2 related to the winning of the second starting port 122 are distinguished, this process is also performed individually for each corresponding starting port. ..

Specifically, the special symbol fluctuation control unit 233 first determines whether the number of reservations U2 related to the winning of the second starting port 122 is 1 or more (S1103). When the hold number U2 is 1 or more (Yes in S1103), the special symbol fluctuation control unit 233 subtracts 1 from the value of the hold number U2 (S1104). On the other hand, when the number of reservations U2 = 0 (No in S1103), the special symbol fluctuation control unit 233 then determines whether the number of reservations U1 related to the winning of the first starting port 121 is 1 or more (S1105). When the hold number U1 is 1 or more (Yes in S1105), the special symbol fluctuation control unit 233 subtracts 1 from the value of the hold number U1 (S1106). On the other hand, when the number of reservations U1 = 0 (No in S1105), it means that there is no prize for starting the lottery of the special symbol. Therefore, the special symbol change is not started and the customer waiting setting process of another routine is performed. Is executed to end the process (S1116).
In the present embodiment, the process related to the number of reservations U2 related to the winning of the second starting port 122 is prioritized. That is, when the hold number U2 is 1 or more, the process related to the hold number U2 is performed, and when the hold number U2 = 0, the process related to the hold number U1 is performed (see S803 to S806). On the other hand, regardless of which of the first starting port 121 and the second starting port 122 is won, the number of holds U1 and U2 can be subtracted in the order of winning.

After subtracting the hold number U1 or the hold number U2 in S1104 or S1106, the special symbol variation control unit 233 turns off the customer waiting flag set in the flag setting of the RAM 203 (S1107). The customer waiting flag is a flag for identifying that the pachinko gaming machine 100 is in the customer waiting state, and is set in the customer waiting setting process (S1116, see FIG. 37 described later).

Next, the special symbol variation control unit 233 executes a jackpot determination process and a variation pattern selection process by another routine (S1108, S1109). Although details will be described later, setting information for fluctuation of the special symbol (big hit symbol, game) that is variablely displayed on the first special symbol display 221 and the second special symbol display 222 by the jackpot determination process and the variation pattern selection process. State, fluctuation pattern, etc.) is determined. It should be noted that these pieces of information are included in the fluctuation start command sent to the effect control unit 300.

After that, the special symbol variation control unit 233 is displayed by the first special symbol display 221 and the second special symbol display 222 shown in FIG. 3 based on the setting contents determined by the jackpot determination process and the variation pattern selection process. The change of the special symbol is started (S1110). Then, a fluctuation start command including setting information (big hit symbol, game state, fluctuation pattern, etc.) indicating the setting contents is generated and set in the RAM 203 (S1111). The fluctuation start command set in S1111 is transmitted to the effect control unit 300 in the output process shown in S806 of FIG.

When it is determined in S1102 that the special symbol is changing (Yes in S1102), or after the change start command is set in S1111, the special symbol change control unit 233 determines whether or not the fluctuation time has elapsed (S1112). ). That is, it is determined whether or not the elapsed time since the start of the fluctuation of the special symbol in S1110 has reached the fluctuation time set in the fluctuation pattern selection process of S1109. If the fluctuation time has not elapsed (No in S1112), the special symbol variation is continued, so that the special symbol processing ends as it is.

On the other hand, when the fluctuation time has elapsed (Yes in S1112), the special symbol fluctuation control unit 233 first determines the fluctuation of the special symbol in the first special symbol display 221 and the second special symbol display 222 in the jackpot determination process of S1108. It stops at the symbol determined in (S1113). A variable stop command for stopping the decorative symbol described later is set in the RAM 203 (S1114). Then, the stopped processing of another routine is executed (S1115). The details of the stopped processing will be described later. The fluctuation stop command set in S1114 is transmitted to the effect control unit 300 by the output process shown in S806 of FIG.

[Big hit judgment processing by the game control unit]
FIG. 34 is a flowchart showing the contents of the jackpot determination process (S1108 in FIG. 33).
In this jackpot determination process, the special symbol determination unit 234 of the game control unit 200 first determines the jackpot random number value in the special symbol lottery this time (S1201), and determines whether or not it is a jackpot or a small hit (S1202). , S1205). Whether or not a jackpot or a small hit is determined is whether or not the value of the jackpot random number acquired in S903 or S910 in FIG. 31 matches the value set as the jackpot winning value or the value set as the small hit winning value. It is determined by determining whether or not (see FIG. 42 (a)).

When the result of the random number determination in S1201 is a big hit (Yes in S1202), the special symbol determination unit 234 then determines the jackpot symbol random number value (S1203). Depending on the result of this determination, the type of jackpot (big hit in the high-probability time-saving gaming state, jackpot in the low-probability time-saving non-game state, etc.) is determined. Which jackpot will be won is determined by which of the values preset for each type of jackpot matches the value of the jackpot symbol random number acquired in S903 or S910 of FIG. 31 (FIG. 42 (Fig. 42). b) See).

After the above determination, the special symbol determination unit 234 sets the symbol (big hit symbol) representing the type of jackpot determined by the determination of the jackpot symbol random number in the RAM 203 as setting information (S1204).

When the result of the random number determination in S1201 is a small hit (No in S1202, Yes in S1205), then the special symbol determination unit 234 uses a symbol indicating that it is a small hit (hereinafter, small hit symbol) as setting information. It is set in the RAM 203 (S1206).

When the result of the random number determination in S1201 is neither a big hit nor a small hit (No in S1202 and S1205), then the special symbol determination unit 234 uses the symbol indicating that the lottery has been lost (hereinafter, the missed symbol) as setting information in the RAM 203. (S1207).

[Variation pattern selection process by the game control unit]
FIG. 35 is a flowchart showing the contents of the variation pattern selection process (S1109 in FIG. 33).
In this variation pattern selection process, the variation pattern selection unit 235 of the game control unit 200 first refers to the gaming state of the pachinko gaming machine 100 (whether it is a time saving state or a time saving state, and a high probability state or a low probability state). (S1301). Then, using the determination result of S1202 of the jackpot determination process (FIG. 34), it is determined whether or not a jackpot has been achieved in this special symbol lottery (S1302). Then, in the case of a big hit (Yes in S1302), the fluctuation pattern selection unit 235 reads the fluctuation pattern table for the big hit from the ROM 202 and sets it in the RAM 203 (S1303).

On the other hand, if there is no big hit (No in S1302), then the fluctuation pattern selection unit 235 determines a random number value for determining whether or not to perform a so-called reach effect for the player to expect a big hit. (S1304). Whether or not to perform the reach effect is determined by determining whether or not the value of the reach random number acquired in S903 or S910 of FIG. 31 matches the preset value (see FIG. 42 (c)). ..
When the reach effect is performed as a result of the determination using the random value (Yes in S1305), the variation pattern selection unit 235 reads the variation pattern table for reach from the ROM 202 and sets it in the RAM 203 (S1306). Further, when the reach effect is not performed (No in S1305), the variation pattern selection unit 235 reads the variation pattern table for detachment from the ROM 202 and sets it in the RAM 203 (S1307).
Here, the fluctuation pattern table is a plurality of fluctuation patterns (variation time 3 seconds, 7 seconds, 13 seconds, 15 seconds, 30 seconds, 60 seconds, 90 seconds, etc.) prepared in advance and the value of the fluctuation pattern random number. It is a table associated with.

Next, the fluctuation pattern selection unit 235 determines the fluctuation pattern random value using the fluctuation pattern random value acquired in S903 or S910 of FIG. 31 and the fluctuation pattern table set in S1303, S1306, and S1307 (S1308). ). That is, the variation pattern selection unit 235 refers to the variation pattern table set in the RAM 203, and selects the variation pattern according to the random number value of the variation pattern random number. Therefore, even if the same random number value is acquired, the gaming state of the pachinko gaming machine 100 (whether it is in a time-saving state or a time-saving state, and a high-probability state or a low-probability state), and the result of a special symbol lottery (whether or not it is a big hit). , If there is no big hit, whether or not to perform reach effect), etc., the reference variation pattern table is different, so the determined variation pattern is different.

After that, the fluctuation pattern selection unit 235 sets the fluctuation pattern selected in S1308 in the RAM 203 as setting information (S1309). The fluctuation pattern setting information set in S1309 is included in the fluctuation start command set in S1111 of FIG. 33, and is transmitted to the effect control unit 300 by the output process shown in S806 of FIG. Details of the fluctuation pattern selected in this embodiment and its setting will be described later.

[Processing during stop by the game control unit]
FIG. 36 is a flowchart showing the contents of the stopped processing (S1115 of FIG. 33).
In this stopped processing, the game control unit 200 first checks whether or not the flag indicating the time saving state (hereinafter, the time saving flag) is turned on in the flag setting of the RAM 203 (S1401). When the time saving flag is ON (Yes in S1401), the game control unit 200 subtracts 1 from the value of the lottery number (variation number) J in the time saving state (S1402), and whether or not the lottery number J becomes 0. (S1403). Then, if the number of lottery times J = 0 (Yes in S1403), the time saving flag is turned off (S1404). The operation of turning on the time saving flag and the setting of the initial value of the lottery number J are performed in the game state setting process (FIG. 40) in the large winning opening process (FIG. 39) described later.

When the time saving flag is OFF (No in S1401), after turning off the time saving flag in S1404, or when the value of the lottery number J after subtraction in S1402 is not 0 (No in S1403), then the game control The unit 200 checks whether or not the flag indicating the high probability state (hereinafter, the high probability flag) is turned ON in the flag setting of the RAM 203 (S1405). If both the high-probability flag and the previous time-saving flag are ON, the game is in the high-probability time-saving game state, and if the high-probability flag is ON and the time-saving flag is OFF, the game is in the high-probability time-saving non-game state. be.

When the high probability flag is ON (Yes in S1405), the game control unit 200 subtracts 1 from the value of the lottery number (variation number) X in the high probability state (S1406), and has the lottery number X become 0? Check whether or not (S1407). Then, if the number of lottery times X = 0 (Yes in S1407), the high accuracy flag is turned off (S1408). The operation of turning on the high accuracy flag and the setting of the initial value of the lottery number X are performed in the game state setting process (FIG. 40) in the large winning opening process (FIG. 39) described later.

When the high accuracy flag is OFF (No in S1405), after the high accuracy flag is turned OFF in S1408, or when the value of the lottery count X after subtraction in S1406 is not 0 (No in S1407), then The game control unit 200 determines whether or not a big hit has been made in this special symbol lottery (S1409). Then, in the case of a big hit (Yes in S1409), the game control unit 200 then determines the type of big hit (S1410). Here, as an example of determining the type of jackpot, whether or not it is a long hit is determined.

Here, the determination of whether or not the jackpot is a jackpot can be determined based on the determination result of the jackpot determination process (FIG. 34). For example, if any of the symbols shown in the chart of FIG. 42 (b) described later is set, it is Yes in S1409. If a missed symbol or a small hit symbol is set in the RAM 203 by the jackpot determination process, the result is No in S1409.

When the type of jackpot is a long hit (Yes in S1410), the game control unit 200 turns on the long hit game flag (S1411). As a result, the game state of the RAM 203 is set to the big hit game state (long hit game state) in which the type of big hit is a long hit. It should be noted that here, in the long hit, there is no distinction between a high probability state and a low probability state. Whether the state becomes a high probability state or a low probability state is specified by turning on the corresponding flag in the game state setting process (FIG. 40) in the large winning opening process (FIG. 39) described later.

When the type of big hit is not a long hit (No in S1410), the game control unit 200 turns on the short hit game flag (S1412). As a result, the setting of the gaming state of the RAM 203 becomes the jackpot gaming state (short hit gaming state) in which the type of jackpot is a short hit. As in the case of long hits, short hits do not distinguish between high-probability states and low-probability states.

After turning on the jackpot game flag in S1411 or S1412, the game control unit 200 initializes the values of the lottery times J and X (S1413). Further, the game control unit 200 turns off the time saving flag when the time saving flag is ON in S1401 and the lottery number J is not 0 in S1403 (S1414). Similarly, when the high accuracy flag is ON in S1405 and the lottery number X is not 0 in S1407, the high accuracy flag is turned OFF (S1414).

After initializing the values of the lottery times J and X in S1413, the game control unit 200 starts the opening operation (S1417). Here, the content of the opening operation differs depending on which of S1411 and S1412 the winning game flag is turned ON. In other words, the opening operation is set according to the determination result of the special symbol lottery.
After that, the game control unit 200 sets the opening command for performing the effect in the opening operation according to the jackpot game flag in the effect control unit 300 in the RAM 203 (S1418), and ends the stopped processing. This opening command is transmitted to the effect control unit 300 in the output process shown in S806 of FIG.

On the other hand, if the result of the special symbol lottery this time is not a big hit (No in S1409), then the game control unit 200 determines whether or not the result of the special symbol lottery this time is a small hit (S1415). ). If it is not a small hit (No in S1415), the stopped processing is terminated.
On the other hand, if it is a small hit (Yes in S1415), the game control unit 200 starts the small hit game (S1416). As a result, the game state setting of the RAM 203 becomes the small hit game state. In the small hit game, as described above, the large winning opening 125 is opened and closed a predetermined number of times, and the game ends after a predetermined time has elapsed.

[Customer waiting setting processing by the game control unit]
FIG. 37 is a flowchart showing the contents of the customer waiting setting process (S1116 in FIG. 33).
In this customer waiting setting process, the game control unit 200 first checks whether or not the customer waiting flag is ON in the flag setting of the RAM 203 (S1501). Here, the customer waiting flag is a flag set to identify that the pachinko gaming machine 100 is in the customer waiting state.

When the customer waiting flag is ON, the pachinko gaming machine 100 is in the customer waiting state, so the process ends as it is (Yes in S1501). On the other hand, when the customer waiting flag is OFF, the game control unit 200 generates a customer waiting command and sets it in the RAM 203 (S1502), and turns the customer waiting flag ON (S1503). The customer waiting command set in S1502 is transmitted to the effect control unit 300 by the output process shown in S806 of FIG. The customer waiting flag is set in a state where the fluctuation of the special symbol is stopped and there is no hold.

[Normal symbol processing by the game control unit]
FIG. 38 is a flowchart showing the contents of the normal symbol processing among the symbol processing shown in S803 of FIG. 30.
In this normal symbol processing, the normal symbol fluctuation control unit 236 of the game control unit 200 first checks whether or not the auxiliary game flag is ON in the flag setting of the RAM 203 (S1601). Here, the auxiliary game flag is a flag that is set when a player wins a normal symbol lottery. The state in which the auxiliary game flag is set is a state in which the electric tulip 123 is opened according to the electric tulip process (FIG. 41) described later, and it is easy to win a prize in the second starting port 122 (auxiliary game state).

When the auxiliary game flag is ON, the auxiliary game state is already in effect and the normal symbol is stopped. Therefore, the normal symbol processing is terminated without starting the normal symbol change (Yes in S1601). On the other hand, when the auxiliary game flag is OFF (No in S1601), the normal symbol variation control unit 236 then determines whether or not the current state of the pachinko gaming machine 100 is in the normal symbol variation (S1602). When the normal symbol is not changing (No in S1602), the normal symbol fluctuation control unit 236 then determines whether the number of pending numbers G (see FIG. 32) of the unchanged portion of the normal symbol is 1 or more (S1603). When the number of holds G = 0 (No in S1603), it means that there is no prize for starting the lottery of the normal symbol, so the process ends without starting the normal symbol change.

On the other hand, when the hold number G is 1 or more (Yes in S1603), the normal symbol fluctuation control unit 236 subtracts 1 from the value of the hold number G (S1604). Then, the ordinary symbol determination unit 232 determines the winning random number in the ordinary symbol lottery this time, and determines whether or not the ordinary symbol lottery has been won (S1605). Whether or not the winning value is determined is determined by determining whether or not the value of the winning random number acquired in S1003 of FIG. 32 matches the value set as the winning value in the table or the like shown in FIG. 42 (d) described later. It is determined.

Next, the normal symbol fluctuation control unit 236 sets the normal symbol according to the result of the normal symbol lottery (S1606). That is, when the normal symbol lottery is won, the symbol indicating the winning (hereinafter, the winning symbol) is set in the RAM 203 as the setting information. On the other hand, when the normal symbol lottery is not won, a symbol indicating that the lottery has been lost (hereinafter referred to as a missed symbol) is set in the RAM 203 as setting information.

Next, the normal symbol fluctuation control unit 236 sets the fluctuation time of the normal symbol (S1607). This fluctuation time is set based on the time reduction flag set in the processes of S1404 and S1414 in FIG. 36 and S1804 and S1807 in FIG. 40 described later. That is, when the time saving flag is ON at the time of setting by S1607, it is set to a short time (for example, 1.5 seconds), and when the time saving flag is OFF, it is set to a long time (for example, 4.0 seconds). Will be done. After this setting, the normal symbol fluctuation control unit 236 starts the fluctuation of the normal symbol on the normal symbol display 223 shown in FIG. 3A based on the setting content of S1607 (S1608). It should be noted that the fluctuation pattern of the normal symbol can also be determined by lottery. In this case, for example, when the game ball passes through the gate 124, the random number acquisition unit 231 acquires the fluctuation pattern random number value of the normal symbol, and in S1607, the normal symbol fluctuation control unit 236 obtains the fluctuation pattern random number value of the normal symbol. By determining, the fluctuation time is set.

After starting the fluctuation of the normal symbol in S1608, or when it is determined in S1602 that the normal symbol is changing (Yes in S1602), the normal symbol fluctuation control unit 236 determines whether or not the fluctuation time has elapsed (S1609). ). That is, it is determined whether or not the elapsed time since the start of the fluctuation of the normal symbol in S1608 has reached the fluctuation time set in S1607. If the fluctuation time has not elapsed (No in S1609), the normal symbol fluctuation is continued, so that the normal symbol processing ends as it is.

On the other hand, when the fluctuation time ends (Yes in S1609), the normal symbol fluctuation control unit 236 stops the fluctuation of the normal symbol on the normal symbol display 223 (S1610). Then, the normal symbol variation control unit 236 determines whether or not the determination result of S1605 is a winning (S1611). If it is won (Yes in S1611), the auxiliary game flag is turned ON (S1612). On the other hand, if the lottery is missed (No in S1611), the normal symbol processing is completed without turning on the auxiliary game flag.

[Large winning opening processing by the game control unit]
FIG. 39 is a flowchart showing the contents of the large winning opening processing among the electric accessory processing shown in S804 of FIG. 30.
In this big prize opening process, the big winning opening operation control unit 237 of the game control unit 200 first checks whether or not the big hit game flag is ON in the flag setting of the RAM 203 (S1701). When the jackpot game flag is OFF, there is no winning in the jackpot 125, so the jackpot processing ends (No in S1701). On the other hand, when the jackpot game flag is ON (Yes in S1701), the jackpot operation control unit 237 then opens the pachinko gaming machine 100 in the operation control at the time of the jackpot started in the stopped processing (FIG. 36). It is determined whether or not the operation is in progress (S1702).

When the pachinko gaming machine 100 is opening (Yes in S1702), the large winning opening operation control unit 237 then determines whether or not the preset opening operation should be performed (opening time). (S1703). If the opening time has not elapsed, the opening operation at the large winning opening 125 is continued, so the large winning opening process is terminated (No in S1703). On the other hand, if the opening time has elapsed (Yes in S1703), then the large winning opening operation control unit 237 sets the operation of the large winning opening 125 (S1704) and initializes the winning number C (C = 0). Then (S1705), the value of the number of rounds R of the operation of the large winning opening 125 is added by 1 from the current value (S1706), and the large winning opening 125 is started (opened) (S1707).

In the operation setting of S1704, the operation pattern of the large winning opening 125 and the number of rounds (the number of operation rounds) to be operated by the operation pattern are set. As an example of the case where the big winning opening 125 operates, there are a case where it is a big hit of a long hit or a short hit and a case where it is a small hit in a special symbol lottery. The operation pattern and the number of rounds are set variously according to the types of these hits. In the jackpot game, it is stipulated that the jackpot 125 is operated a plurality of times (multiple rounds) in succession. As an example, in the case of a long hit, for example, 15 rounds (15R) are operated, and in one round, 29.5 seconds of opening is performed once. In the case of a short hit, for example, two rounds (2R) are operated, and in one round, 0.9 seconds are opened once. To further explain, it is opened for 0.9 seconds, closed for 1.0 second, and then opened for 0.9 seconds. On the other hand, in the case of a small hit, for example, it is opened for 0.9 seconds, closed for 1.0 second, and then opened for 0.9 seconds. Here, comparing the operation with a short hit and the operation with a small hit in the above example, both of them are opened for 0.9 seconds twice. That is, the operation of the large winning opening 125 seen by the player is the same in the case of the short hit and the case of the small hit, and the short hit and the small hit are distinguished only from the operation of the large winning opening 125 on the game board 110. You can't.

In the case of a small hit, the law stipulates that the cumulative opening time of the large winning opening 125 must be set within 1.8 seconds. On the other hand, in the case of a big hit (long hit or short hit), the big winning opening 125 must be opened a plurality of times in a row. Therefore, when it is difficult to visually distinguish between the operation with a small hit and the operation with a short hit as described above, in the case of a small hit, the cumulative opening time in one operation is within 1.8 seconds. An operation mode in which the large winning opening 125 is opened twice or more is set, and in the short hit, the number of rounds equal to the number of times the small hit is opened is set.

Next, the large winning opening operation control unit 237 determines whether or not the opening time in the operation pattern set in S1704 has elapsed (S1708). If the open state of the large winning opening 125 has not passed the opening time (No in S1708), then the large winning opening operation control unit 237 has a specified number C of winnings in the large winning opening 125 (for example, 9). It is determined whether or not the number is greater than or equal to (S1709). If the opening time has not passed and the number of winnings C is less than the specified number, the operating state (opening state) of the large winning opening 125 is continued, so that the large winning opening process is terminated (No in S1709). ). On the other hand, when the opening time has elapsed (Yes in S1708) or when the number of winnings C reaches the specified number (Yes in S1709), the large winning opening operation control unit 237 ends the operation of the large winning opening 125 (closing). (S1710).

Next, the large winning opening operation control unit 237 determines whether or not the number of rounds R of operation of the large winning opening 125 has reached the maximum value set in S1704 (S1711). Then, if the maximum value is not reached, the remaining operations are performed, so that the large winning opening process is terminated (No in S1711).

When the number of rounds R of operation of the large winning opening 125 reaches the maximum value (Yes in S1711), the large winning opening operation control unit 237 then starts the ending operation (S1712). Here, the content of the ending operation corresponds to the state of the jackpot game flag among the ending operations set in each of the long-hit game and the short-hit game.
After that, the big prize opening operation control unit 237 sets the ending command in the RAM 203 to perform the effect in the ending operation according to the jackpot game flag in the effect control unit 300 (S1713). This ending command is transmitted to the effect control unit 300 in the output process shown in S806 of FIG.

Next, the large winning opening operation control unit 237 resets the number of rounds R of the operation of the large winning opening 125 to 0 (S1714), and then performs the ending operation in which the elapsed time from the start of the ending operation is preset. It is determined whether or not the desired time (ending time) has passed (S1717). If the ending time has not elapsed, the ending operation is continued, so the large winning opening process is terminated (No in S1717). On the other hand, if the ending time has elapsed (Yes in S1717), then the big winning opening operation control unit 237 turns off the big hit game flag after the game state setting process by the game control unit 200 (S1718). The large winning opening process is completed (S1719). The content of the game state setting process will be described later.

When it is determined in S1702 that the pachinko gaming machine 100 is not in the opening (No in S1702), then the grand prize opening operation control unit 237 determines whether or not it is in the ending (S1715). Then, if the ending is in progress (Yes in S1715), the operations after S1717 are executed.

On the other hand, if the pachinko gaming machine 100 is not in the ending (No in S1715), then the large winning opening operation control unit 237 determines whether or not the large winning opening 125 is operating (opening) (S1716). Then, if it is not in operation (No in S1716), the operation after S1705 is executed, and if it is in operation (Yes in S1716), the operation after S1708 is executed.
It should be noted that the effect performed in the small hit game described above is the same as the effect performed in the short hit game, and it is not possible to distinguish between the short hit and the small hit from the effect.

[Game state setting process]
FIG. 40 shows the contents of the game state setting process (S1718) by the game control unit 200, which is executed when the ending time has elapsed (Yes in S1717).
When the game state setting process is performed, the jackpot game flag is ON in S1701 of FIG. 39 as a premise. Therefore, as shown in FIG. 40, the game control unit 200 first determines the type of the jackpot (S1801, S1802, S1803, S1806). These determinations can be made based on, for example, the type of symbol set in the RAM 203 as setting information in the jackpot determination process (FIG. 34). Since these determinations are substantially the same as those of S1202, S1203, and S1205 in the jackpot determination process (FIG. 34), the determination results of S1202, S1203, and S1205 may be used.

If it is a small hit (Yes in S1801), the game state is not changed, so the game state setting process ends.
When the type of jackpot is a jackpot in a low-probability time-saving game state (No in S1801, Yes in S1802, Yes in S1803), the game control unit 200 turns on the time-saving flag (S1804). As a result, the game state of the RAM 203 is set to the low-probability time-saving game state. Further, the game control unit 200 sets an initial value of the lottery number J (S1805), and ends the game state setting process. The initial value of the lottery number J is 100 times in the illustrated example. Therefore, if the lottery in the low-probability time-saving game state is performed 100 times, the low-probability time-saving game state ends and the low-probability time-saving non-game state is reached.

On the other hand, when the type of jackpot is a jackpot in a low-probability time-saving non-game state (No in S1801, Yes in 1802, No in S1803), the game control unit 200 performs processing without turning on both the time-saving flag and the high-accuracy flag. finish. Therefore, the setting of the game state of the RAM 203 for the game after the jackpot is a low-probability time-saving non-game state.

When the type of jackpot is a jackpot in a high-probability time-saving game state (No in S1801 and S1802, Yes in S1806), the game control unit 200 turns on the time-saving flag (S1807) and sets the initial value of the number of lottery J. (S1808). The initial value of the lottery number J in this case is 10,000 times in the illustrated example. Further, the game control unit 200 turns on the high accuracy flag (S1809) and sets the initial value of the lottery number X (S1810). The initial value of the lottery number X is 10,000 times in the illustrated example. As a result, the game state of the RAM 203 is set to the high-probability time-saving game state. Then, if the lottery in this high-probability time-saving game state is performed 10,000 times, the high-probability time-saving game state ends, and the low-probability time-saving non-game state is established.

On the other hand, when the type of jackpot is a jackpot in a high-probability time-saving non-game state (No in S1801, S1802, S1806), the game control unit 200 turns on only the high-probability flag (S1809) and sets the initial value of the number of lottery X. (10000 times) is set (S1810). As a result, the game state of the RAM 203 is set to the high-probability time-saving non-game state. Then, if the lottery in this high-probability time-saving no-game state is performed 10,000 times, the high-probability time-saving no-game state ends, and the low-probability time-saving no-game state is established.

[Electric tulip processing by the game control unit]
FIG. 41 is a flowchart showing the contents of the electric tulip processing among the electric accessory processing shown in S804 of FIG. 30.
In the electric tulip processing, the electric tulip motion control unit 238 of the game control unit 200 first checks whether or not the auxiliary game flag is ON in the flag setting of the RAM 203 (S1901). When the auxiliary game flag is OFF, the electric tulip 123 is not opened, so the electric tulip processing is terminated (No in S1901). On the other hand, when the auxiliary game flag is ON (Yes in S1901), the electric tulip motion control unit 238 then determines whether or not the electric tulip 123 is operating (S1902).

When the electric tulip 123 is not operating (No in S1902), the electric tulip operation control unit 238 sets the operation pattern of the electric tulip 123 (S1903) and operates the electric tulip 123 with the set operation pattern (S1904). .. Here, the operation pattern is set based on the time reduction flag set in the processes of S1404 and S1414 in FIG. 36 and S1804 and S1807 in FIG. 40. For example, when the time saving flag is OFF at the time of setting by S1903, an operation pattern of opening once with an opening time of 0.15 seconds is set, and when the time saving flag is ON, opening of 1.80 seconds. An operation pattern that opens three times in time is set. In this way, normally, when the time saving flag is ON (when the time saving state is in the state), the electric tulip 123 is opened a plurality of times for a long time, and it becomes easy to win a prize in the second starting port 122 (electric chew support). Is done. In addition, a plurality of operation patterns (types of auxiliary games) of the electric tulip 123 when the time saving flag is ON or OFF are prepared, and the operation is performed according to the type of hit determined by the normal symbol processing (see FIG. 38). It may be configured to set a pattern.

When it is determined in S1902 that the electric tulip 123 is operating (Yes in S1902), or after the electric tulip 123 is operated in S1904, the electric tulip motion control unit 238 elapses the opening time in the set operation pattern. It is determined whether or not it has been done (S1905). If the opening time has not elapsed, the operating state (opening state) of the electric tulip 123 is continued, so that the electric tulip processing is terminated (No in S1905). On the other hand, when the opening time has elapsed (Yes in S1905), the electric tulip motion control unit 238 turns off the auxiliary game flag and ends the electric tulip processing (S1906).

[Random number judgment method]
Here, a random number determination method performed in the jackpot determination process (FIG. 34), the variation pattern selection process (FIG. 35), the ordinary symbol process (FIG. 38), and the like will be described in detail.
FIG. 42 is a diagram showing a configuration example of a random number (determination table) used in the special symbol lottery and the ordinary symbol lottery in the present embodiment.
FIG. 42 (a) shows a configuration example of a jackpot random number used in a special symbol lottery, FIG. 42 (b) shows a configuration example of a jackpot symbol random number used in a special symbol lottery, and FIG. 42 (c) shows a special symbol lottery. A configuration example of the reach random number used and a configuration example of the winning random number used in the ordinary symbol lottery are shown in FIG. 42 (d), respectively.

With reference to FIG. 42 (a), as the determination value of the jackpot random number, the jackpot when the gaming state of the pachinko gaming machine 100 at the time of jackpot determination is in the low probability state and the jackpot when the gaming state at the time of jackpot determination is in the high probability state. Two types and a small hit are set. The range of random numbers (big hit random numbers) is 300, from 0 to 299. In the case of a special symbol lottery (big hit lottery) in a low probability state, only one winning value is set, and the winning probability is 1/300. Further, in the case of a special symbol lottery in a high probability state, 10 winning values are set, and the winning probability is 10/300 (= 1/30). That is, in the illustrated example, when the starting ports 121 and 122 are won in the high probability state and the special symbol lottery is performed, the winning probability is 10 times higher than in the case where the special symbol lottery is performed in the low probability state. Further, the winning value of the small hit is set to three regardless of whether it is in the low probability state or the high probability state, and the winning probability is 3/300 (= 1/100).
Here, to explain by taking a special symbol lottery in a low probability state as an example, the jackpot random number values (see S903 and S910) acquired by winning a prize in the first starting port 121 or the second starting port 122 are shown in FIG. 42. It is determined whether or not it matches the winning value "5" of the jackpot lottery in the low probability state in (a). Although detailed description is omitted, the same applies to the special symbol lottery in the high probability state and the special symbol lottery for small hits.

With reference to FIG. 42 (b), five types of jackpot symbols are prepared: low-probability symbol A, low-probability symbol B, high-probability symbol A, high-probability symbol B, and latent symbol. Here, the low-probability symbol A and the low-probability symbol B are symbols indicating that they are jackpots in the low-probability state, and among them, the low-probability symbol A is a jackpot in the long-probability (8 rounds) and low-probability short-time gaming state. Indicates that there is. The low-probability symbol B indicates that it is a long hit (4 rounds) and a big hit in a low-probability short-time gaming state. The high-probability symbol A and the high-probability symbol B indicate that they are long hits (15 rounds) and big hits in a high-probability short-time gaming state. The high-probability symbol C and the high-probability symbol D indicate that they are long hits (8 rounds) and big hits in a high-probability short-time gaming state. The high-probability symbol E indicates a short hit (2 rounds) and a high-probability short-time non-game state jackpot. The latent probability symbol is a symbol indicating that it is a short hit (2 rounds) and a big hit in a high-probability short-time non-game state. Therefore, the high-probability symbol B and the latent probability symbol have the same gaming state after the jackpot game, but the latent probability symbol is a condition for performing a latent effect that does not clearly notify the player that the high-probability symbol is in the high-probability state. Therefore, it is provided separately from the high-probability symbol B. The range of random number values is 250 from 0 to 249. Further, in the jackpot symbol random number, winning values are set for each of the first starting port 121 and the second starting port 122, which trigger the special symbol lottery.

In the low-probability symbol A, 35 values are assigned as winning values to both the first starting port 121 and the second starting port 122. Therefore, when the jackpot is won, the probability of winning the low probability symbol A is 35/250 (= 7/50).
In the low-probability symbol B, 15 values are assigned as winning values to both the first starting port 121 and the second starting port 122. Therefore, when the jackpot is won, the probability of winning the low probability symbol B is 15/250 (= 3/50).

In the high-probability symbol A, 20 values are assigned as winning values when the first starting port 121 is won. Therefore, if a big hit is won in the special symbol lottery started by winning the first starting port 121, the probability of winning the high probability symbol A is 20/250 (= 2/25).
On the other hand, 150 values are assigned as winning values when the second starting port 122 is won. Therefore, if a big hit is won in the special symbol lottery started by winning the second starting port 122, the probability of winning the high probability symbol A is 150/250 (= 15/25).

In the high-probability symbol B, five values are assigned as winning values when the first starting port 121 is won. Therefore, if a big hit is won in the special symbol lottery started by winning the first starting port 121, the probability of winning in the high probability symbol B is 5/250 (= 1/50).
On the other hand, 25 values are assigned as winning values when the second starting port 122 is won. Therefore, if a big hit is won in the special symbol lottery started by winning the second starting port 122, the probability of winning in the high probability symbol B is 25/250 (= 1/10).

In the high-probability symbol C, 25 values are assigned as winning values when the first starting port 121 is won. Therefore, if a big hit is won in the special symbol lottery started by winning the first starting port 121, the probability of winning in the high probability symbol C is 25/250 (= 1/10).
On the other hand, 10 values are assigned as winning values when the second starting port 122 is won. Therefore, if a big hit is won in the special symbol lottery started by winning the second starting port 122, the probability of winning in the high probability symbol B is 10/250 (= 1/25).

In the high-probability symbol D, 25 values are assigned as winning values when the first starting port 121 is won. Therefore, if a big hit is won in the special symbol lottery started by winning the first starting port 121, the probability of winning the high probability symbol D is 25/250 (= 1/10).
On the other hand, 10 values are assigned as winning values when the second starting port 122 is won. Therefore, if a big hit is won in the special symbol lottery started by winning the second starting port 122, the probability of winning the high probability symbol D is 10/250 (= 1/25).

In the high-probability symbol E, 25 values are assigned as winning values when the first starting port 121 is won. Therefore, if a big hit is won in the special symbol lottery started by winning the first starting port 121, the probability of winning in the high probability symbol E is 25/250 (= 1/10).
On the other hand, five values are assigned as winning values when the second starting port 122 is won. Therefore, if a big hit is won in the special symbol lottery started by winning the second starting port 122, the probability of winning the high probability symbol E is 5/250 (= 1/50).

In the latent probability symbol, 100 values are assigned as winning values when the first starting port 121 is won. Therefore, if a big hit is won in the special symbol lottery started by winning the first starting port 121, the probability of winning the latent symbol is 100/250 (= 2/5).
On the other hand, the winning value in the latent probability symbol is not assigned to the second starting port 122, and if the second starting port 122 is won, the winning value in the latent probability symbol will not be won.

Here, to explain using the low-probability symbol A as an example, the jackpot symbol random value (see S903 and S910) acquired by winning a prize in the first starting port 121 or the second starting port 122 is shown in FIG. 42 (b). ), It is determined whether or not the value matches the winning value of the low-probability symbol A, "0 to 34". Although detailed description is omitted, the same applies to special symbol lottery such as low-probability symbol B.

As described above, by making the winning probability of the type of jackpot different between the case where the first starting port 121 is won and the case where the second starting port 122 is won, various playability can be provided. In addition, the arrangement of the first start port 121 and the second start port 122 on the game board 110 is devised so that it becomes easier to aim at either the first start port 121 or the second start port 122 in a specific state (mode). It is also possible to encourage the player to participate in a more active game by configuring the above.

Here, the pachinko gaming machine 100 of the present embodiment can set a set value which is a stage of the degree of advantage of the game. In the pachinko gaming machine 100, the set value can be set to any one of, for example, six stages of "1", "2", "3", "4", "5" and "6".
In the pachinko gaming machine 100, when the set value is set to "1", the winning probability is the lowest. For example, when the set value is "1" and the probability is low, the winning probability is 1/300. Further, when the set value is "1" and the probability is high, the winning probability is 10/300.
Further, in the pachinko gaming machine 100, when the set value is set to "6", the winning probability is the highest. For example, when the set value is "6" and the game is in a low probability gaming state, the winning probability is 1/285. Further, when the set value is "6" and the probability is high, the winning probability is 10/285.
As described above, in the pachinko gaming machine 100, the winning probability is set to increase in the order of the set values "1"<"2"<"3"<"4"<"5"<"6".

Next, the determination of the reach random number will be described. The reach random number is set according to the number of holds, as will be described later. Here, as an example, a reach random number when the number of pending numbers is 0 will be described.
With reference to FIG. 42 (c), the range of random number values is 250 from 0 to 249, and the reach effect is a feasible fluctuation pattern (variation time) (for example, 13.5 seconds or more). Twenty-two random number values are assigned to (with reach), and 228 random number values are assigned to the lottery result (without reach) in which the reach effect is not a feasible variation pattern (for example, less than 13.5 seconds). That is, in the illustrated example, if a big hit is not made in the special symbol lottery, the reach effect is performed with a probability of 22/250 (= 11/125). Here, the reach effect is an effect performed on the image display unit 114 when the special symbol fluctuates. Hereinafter, the effect at the time of special symbol change in which the reach effect is not a feasible variation pattern is referred to as a non-reach effect, and the effect at the time of a special symbol change in which the reach effect is a feasible variation pattern is referred to as a reach effect. Called.

Here, demonstrating the presence of reach as an example, the reach random value (see S903 and S910) acquired by winning a prize in the first starting port 121 or the second starting port 122 is the reach in FIG. 42 (c). It is determined whether or not it matches the winning value of "0 to 21". Although detailed explanation is omitted, the same applies to the special symbol lottery without reach.

In many cases, when the special symbol changes, it is linked to the display control of the first special symbol display 221 and the second special symbol display 222 (hereinafter, when these are not distinguished, they are referred to as special symbol indicators 221 and 222). , The image display unit 114 performs an effect using a decorative pattern. The decorative design is configured by displaying, for example, three rows of symbols consisting of a number sequence in which numbers 1 to 9 are continuously written in the vertical direction. Then, at the same time that the variable display of the special symbol on the special symbol display 221, 222 is started, the decorative symbol displayed on the image display unit 114 starts scrolling. In addition, after a predetermined time has elapsed from the start of the variable display of the special symbol (the start of scrolling of the decorative symbol), the special symbol is stopped and displayed, and at the same time, the decorative symbol is also fixedly stopped. In general, when the judgment result of the special symbol lottery is a big hit, three identical numbers are lined up in a straight line extending horizontally or diagonally in the stop display of the decorative symbol. The effect using the decorative symbol that is performed along with the variable display of this special symbol is called a variable effect.

In the effect with reach, the following operations are performed with respect to the decorative pattern as a variable effect. First, one of the two symbols (sequential sequence) is temporarily stopped before the decorative symbol that scrolls in the vertical (horizontal) direction is fixedly stopped. At this time, the same numbers are temporarily stopped on a straight line extending horizontally (vertically) or diagonally. To further explain, if the decorative pattern is scrolled in the vertical direction, the same numbers are temporarily stopped in a row in the horizontal direction.
Next, the last row gradually slows down the scrolling speed, giving the player the expectation that three identical numbers will line up in a straight line. Then, after the last row is temporarily stopped, the three symbols are fixedly stopped.
Here, in the effect with reach, the SP reach effect or the SP / SP reach effect may be performed before the three symbols are fixedly stopped. The SP reach production is generally called super reach or special reach, and is a production that expects a bigger hit than the reach, and is a production of moving images in which various characters appear and the story develops. .. In addition, SP / SP reach is generally called super super reach or special special reach, and it is a production that makes you expect a bigger hit than SP reach, and it is a moving image that various characters appear and the story develops. It is a production of.
Further, as shown in FIG. 43, which will be described later, in the present embodiment, the SP reach or the SP / SP reach effect is set to be executed when the fluctuation time is longer (for example, 90 seconds or 60 seconds). .. It should be noted that the above-mentioned variable effect performed together with the effect with reach is also referred to as a variable effect at the time of reach.
On the other hand, in the non-reach production, the horizontal (vertical) or horizontal (horizontal) or horizontal (horizontal) or horizontal (horizontal) or horizontal (horizontal) or horizontal (horizontal) or horizontal (horizontal) or horizontal (horizontal) or horizontal (horizontal) or horizontal (horizontal) or horizontal (horizontal) or horizontal (horizontal) or horizontal (horizontal) or vertical The symbol is fixed and stopped when the same numbers are not aligned on a straight line that extends diagonally.

In this way, when the result of the determination of the jackpot random number is lost, the reach random number can be produced with a reach as a variable pattern in which the reach effect can be executed on the image display unit 114, or the reach effect can be executed. Decide whether to perform a non-reach effect that does not have a variable pattern. In addition, the reach random number is designed to give the player an appropriate sense of expectation while enabling efficient game progress by changing the execution ratio of the effect with reach according to the number of holds.
In addition, if the jackpot is won, the effect with reach will be performed, and finally the decorative pattern will be fixed and stopped with the same numbers aligned on a straight line extending horizontally (vertically) or diagonally. Can be done. On the other hand, in the case of a small hit or a loss, the decorative pattern is fixedly stopped in the state where the same numbers are not aligned on the above straight line.

Next, the determination of the winning random number used in the ordinary symbol lottery will be described.
With reference to FIG. 42 (d), the range of random number values is 10 from 0 to 9, and one value is assigned as the winning value when the time saving flag is OFF, and as the winning value when the time saving flag is ON. Nine values are assigned. Therefore, if the game ball passes through the gate 124 and the normal symbol lottery is performed in the state of no time saving, the player wins with a probability of 1/10. On the other hand, if the game ball passes through the gate 124 and the normal symbol lottery is performed in the time saving state, the player wins with a probability of 9/10.

Here, when the time saving flag OFF is described as an example, the winning random number value (see S1003) acquired when the game ball of the gate 124, the first starting port 121, or the second starting port 122 passes is shown in FIG. 42 (see S1003). It is determined whether or not the value matches “0”, which is the winning value of the time saving flag OFF in d). Although detailed description is omitted, the same applies to the ordinary symbol lottery with the reduced working hours flag ON.

Further, although not particularly shown, it is possible to set a plurality of hits having different contents (opening pattern of the electric tulip 123) of the auxiliary game to be performed when it is determined to be a hit in the ordinary symbol lottery. In this case, for example, a winning symbol random number for specifying the type of winning in the ordinary symbol lottery is set as in the case of the jackpot symbol random number for specifying the type of jackpot in the special symbol lottery (see FIG. 39 (b)). Then, the game control unit 200 acquires the random number value of the hit symbol random number together with the random number value of the hit random number by the gate switch process (see FIG. 32) by the random number acquisition unit 231 and is acquired by the normal symbol determination unit 232. Identify the type of hit based on the random number value.
The range of random numbers, the ratio of winning values, and the values of winning values shown in the configuration example of each random number in FIG. 42 are merely examples, and are not limited to the values shown.

[Example of setting fluctuation pattern]
Next, a variation pattern and a table setting example used in the variation pattern selection process shown in FIG. 35 will be described.
FIG. 43 is a diagram showing a variation pattern and a table setting example used in the variation pattern selection process shown in FIG. 35. Note that FIG. 43 shows a setting example of a low-probability time-saving non-game state. Although not shown, for other gaming states such as the high-probability time-saving gaming state, a table for setting the variation pattern selected in the variation pattern selection process is individually provided.
Further, FIG. 43 shows a setting example when the game ball wins the first starting port 121. When the game ball wins in the second starting port 122, a table for setting the fluctuation pattern selected in the fluctuation pattern selection process may be individually provided, or the game ball wins in the first starting port 121. The table to be referred to in some cases may be shared and referred to.

As shown in FIG. 43, when the determination result of the special symbol lottery is a big hit (Yes in S1302 of FIG. 35), the special symbol fluctuation control unit 233 determines the fluctuation pattern based on the jackpot symbol and the fluctuation pattern random number. .. Specifically, in the special symbol variation control unit 233, the variation pattern random number value (see S903) acquired together with the jackpot random number value by the random number acquisition unit 231 matches any of the variation pattern random number values assigned to each jackpot symbol. Determine the variation pattern based on what you do. For example, when the jackpot symbol is "high probability symbol A" and the variation pattern random number is "51", it matches the variation pattern random number range "50 to 69" assigned to "high probability symbol A" in FIG. 43. Therefore, "PB3" is selected as the fluctuation pattern. The special symbol fluctuation time in this "PB3" is "90.18 seconds".

Further, when the determination result of the special symbol lottery is wrong (when No in S1302 of FIG. 35), the special symbol fluctuation control unit 233 is based on the hold number U1 of the first special symbol lottery, the reach random number, and the fluctuation pattern random number. To determine the fluctuation pattern. Specifically, when the hold number U1 of the first special symbol lottery is "0", the special symbol fluctuation control unit 233 receives the reach random number value (see S903) acquired by the random number acquisition unit 231 together with the jackpot random number value. , It is determined whether it is allocated to the reach random number range "0 to 21" or the reach random number range "22 to 249" allocated to the reserved number "0" of "off" in FIG. 43. When the acquired reach random number is included in the reach random number range "0 to 21", the variation pattern random number value (see S903) acquired together with the jackpot random number value by the random number acquisition unit 231 is the reach random number range "0 to 21". The fluctuation pattern is determined based on which of the fluctuation pattern random number values assigned to "21" is matched. For example, when the fluctuation pattern random number is "51", it matches the fluctuation pattern random number range "50 to 89", so "PR4" is selected as the fluctuation pattern.

As described above, the game control unit 200 has the fluctuation pattern random value (see S903 and S910 in FIG. 31) acquired when the game ball wins the start ports 121 and 122, and the gaming state and reach of the pachinko gaming machine 100. The fluctuation pattern of the special symbol is determined based on the conditions such as the presence or absence of the effect and the number of holds. Then, the information on the fluctuation pattern of the determined special symbol is included in the fluctuation start command, and is sent from the game control unit 200 to the effect control unit 300. As will be described later, in the effect control unit 300, as an effect when the special symbol changes, an effect corresponding to the variation time specified based on the information of the variation pattern included in the variation start command (executable in the variation time). Is selected and executed.

[Structure of the RAM of the game control unit and the RAM of the effect control unit for performing the advance notice effect based on the prior determination]
Subsequently, the configuration of the RAM 203 of the game control unit 200 and the RAM 303 of the effect control unit 300 in the present embodiment for executing the advance notice effect based on the prior determination will be described.
FIG. 44 is a block diagram illustrating a configuration example of the RAM 203 (see FIG. 3) of the game control unit 200 according to the present embodiment. FIG. 44A is a block diagram showing the configuration of the storage area 204, and FIG. 44B is a block diagram showing the configuration of each of the storage units shown in FIG. 44A.

As shown in FIG. 44A, the RAM 203 includes a storage area 204 as a special symbol hold storage area for storing the jackpot random numbers acquired by the jackpot random number lottery. The storage area 204 has eight storage units corresponding to the maximum number of holdings of the first starting port 121 and the number of holdings of the second starting port 122 (when the upper limit of each holding number is 4). .. Specifically, the storage area 204 includes a first storage unit 204a, a second storage unit 204b, a third storage unit 204c, a fourth storage unit 204d, a fifth storage unit 204e, a sixth storage unit 204f, and a seventh storage unit. It has a unit 204g and an eighth storage unit 204h.

Further, as shown in FIG. 44 (b), each of these storage units 204a to 204h is an area in which information indicating the distinction between the winning start ports (first start port 121 or second start port 122) is stored. It has an area where the acquired jackpot random number is stored, an area where the symbol random number is stored, an area where the reach random number is stored, and an area where the fluctuation pattern random number is stored. That is, a jackpot random number, a symbol random number, a reach random number, and a fluctuation pattern random number are stored in each of the storage units 204a to 204h.

Here, each random number is stored in order from the first storage unit 204a. More specifically, for example, when no random number is stored in any of the first storage unit 204a to the eighth storage unit 204h, the acquired random number is stored in the first storage unit 204a. Further, for example, when a random number is already stored in the first storage unit 204a to the fourth storage unit 204d, the acquired random number is stored in the fifth storage unit 204e.

FIG. 45 is a block diagram illustrating a configuration example of the RAM 303 (see FIG. 3) of the effect control unit 300 according to the present embodiment. FIG. 45 (a) is a block diagram showing the configurations of the reserved storage areas 305 and 306, and FIG. 45 (b) is a block diagram showing the configurations of the storage units shown in FIG. 45 (a).
As shown in FIG. 45 (a), the RAM 303 includes a first hold storage area 305 and a second hold storage area 306 as hold status storage areas for storing the state in which the hold ball is held. The first reserved storage area 305 and the second reserved storage area 306 correspond to a hold for winning a prize in the first starting port 121 and a holding for winning a prize in the second starting port 122, respectively, and each has four storage units. Have. Specifically, the first reserved storage area 305 has a first storage unit 305a, a second storage unit 305b, a third storage unit 305c, and a fourth storage unit 305d. Further, the second reserved storage area 306 has a first storage unit 306a, a second storage unit 306b, a third storage unit 306c, and a fourth storage unit 306d.

Further, as shown in FIG. 45B, each of these storage units 305a to 305d and 306a to 306d has a hold flag storage area for turning on / off the hold flag and a notification flag storage for turning on / off the notification flag. Has an area and. The hold flag is a flag for identifying the presence or absence of a hold ball for each of the storage units 305a to 305d and 306a to 306d. That is, for example, when the number of holdings due to winning the first starting port 121 is 3, the holding flag is turned ON in the three holding flag storage areas of the 1st to 3rd storage units 305a, 305b, and 305c. The notification flag is a flag for setting whether or not to perform the advance notice effect for each reserved ball based on the preliminary determination result. In the pachinko gaming machine 100 of the present embodiment, the effect control unit 300 can set whether or not to perform the advance notice effect based on the preliminary determination result according to the game state and the state of the effect. Therefore, the notification flag is turned ON when the advance notice effect is performed, and the notification flag is turned OFF when the advance notice effect is not performed. For example, when the advance notice effect is given to the third reserved ball among the above three reserved balls, the notification flag is turned ON in the notification flag storage area of the third storage unit 305c.

Further, although not particularly shown, the RAM 203 has an area in which the pre-determination information is stored (hereinafter, a pre-determination information storage area), in addition to the configuration shown in FIG. 44 (a). The pre-determination information is information obtained by the pre-determination process (see S904 and S911 in FIG. 31) based on each of the above random numbers. The content of the pre-judgment information is the same as the information obtained as various judgment results in the special symbol processing (see FIG. 33). If this is the case, it is information for indicating that the type of jackpot, the fluctuation pattern (fluctuation time) is the length at which the reach effect can be executed, or the content of the fluctuation pattern. The pre-judgment information stored in the pre-judgment information storage area is unique to the hold information (hereinafter referred to as hold information) corresponding to the winning ball (holding ball) for which the pre-judgment processing has been performed, or separately from this hold information. At the timing, it is included in the pre-determination result command and sent from the game control unit 200 to the effect control unit 300.

[Preliminary judgment processing]
Next, the pre-determination process (see S904 and S911 in FIG. 31) will be described in detail.
In the pre-determination process according to the present embodiment, the game control unit 200 performs pre-determination as follows using a random number table similar to the random number configuration example described with reference to FIGS. 42 and 43.

FIG. 46 is a flowchart showing the contents of the pre-determination process (S904, S911 in FIG. 31) according to the present embodiment.
As shown in FIG. 46, the game control unit 200 first determines whether or not the game state is a high-probability state (S2401), and if it determines that the game state is a high-probability state (Yes in S2401), the game control unit 200 is for the high-probability state. A table is selected and the jackpot random number and the jackpot symbol random number are pre-determined (S2402). On the other hand, when it is determined as No in S2401, the table for the low probability state is selected, and the jackpot random number and the jackpot symbol random number are pre-determined (S2403).

After the pre-determination of the jackpot random number and the jackpot symbol random number of S2402 or S2403, the game control unit 200 determines whether or not the game state is the time saving state (S2404), and determines that the game state is the time saving state (Yes in S2404). A table for the time saving state is selected, and the reach random number is pre-determined (S2405). Further, a table for the time saving state is selected, and the fluctuation pattern random number is preliminarily determined (S2406).
On the other hand, when it is determined as No in S2404, the table for the time saving stateless state is selected and the reach random number is preliminarily determined (S2407). Further, a table for time saving and no state is selected, and the fluctuation pattern random number is pre-determined (S2408).

After that, the game control unit 200 obtains the result of the pre-determination of the jackpot random number obtained as described above, the result of the pre-determination of the jackpot symbol random number, the result of the pre-determination of the reach random number, and the result of the pre-determination of the fluctuation pattern. It is stored in the pre-judgment information storage area as the pre-judgment information (S2409). Further, in order to transmit the pre-determination information to the effect control unit 300, a pre-determination result command including the pre-determination information is set in the RAM 203 (S2410).

Here, the above-mentioned pre-judgment includes a random number value (see S903 and S910 in FIG. 31) acquired according to the winning of the game ball to the starting ports 121 and 122, and a determination table used in the jackpot determination process (FIG. 42). This was performed using a judgment table having the same configuration as (see). That is, the determination itself after selecting the determination table to be used is the same as the determination in the jackpot determination process (see S1201 in FIG. 34). Therefore, in the present embodiment, the subroutine of the jackpot determination process (see S1108 and FIG. 34 in FIG. 33) used in the special symbol processing (see FIG. 33) is called to determine the random number in the above-mentioned preliminary determination.

With such a configuration, in the present embodiment, it is not necessary to prepare a processing function (subroutine) for determining a random number separately from the jackpot determination process in order to determine the random number in the pre-determination process. Therefore, the number of control instructions can be reduced, and an increase in the size of the program related to the jackpot determination process and the pre-determination process can be suppressed. Further, as described above, when the determination table used for the pre-judgment has the same configuration as the determination table used for the jackpot determination, the determination table used for the jackpot determination may also be used for the pre-judgment.

Further, although only the preliminary determination (whether or not it is a big hit) regarding the special symbol lottery has been described here, in the present embodiment, the variation pattern when performing the variation display and the stop display of the special symbol is also pre-read (preliminary determination). I do. For the selection of the variation pattern in the special symbol lottery, the random value for the variation pattern selection (see S903 and S910 in FIG. 31) and the variation pattern table (see FIG. 43) acquired according to the winning of the game balls to the starting ports 121 and 122. (See) and (see S1109 and FIG. 35 in FIG. 33). Therefore, even in the look-ahead of the fluctuation pattern, the random value for selecting the fluctuation pattern acquired at the time of winning and the look-ahead table having the same configuration as the fluctuation pattern table used in the fluctuation pattern selection processing of the special symbol processing are used for selection. Fluctuation patterns can be pre-read.

In this case, in order to pre-read the variation pattern selected in the variation pattern selection process, the subroutine of the variation pattern selection process used in the special symbol process (see FIG. 33) (see S1109 and FIG. 35 in FIG. 33) is called and used. be able to. Further, as the look-ahead table used for the look-ahead of the change pattern selection, the change pattern table used in the change pattern selection process of the special symbol processing may be used. With this configuration, the number of control instructions related to look-ahead of variation pattern selection can be reduced, and an increase in the size of the program can be suppressed.

If the pre-judgment process and the jackpot judgment process at the time of special symbol change are performed by the same subroutine using the same judgment table group, the execution time of each process is different, so that the pre-judgment result and the special symbol change time. The judgment result by the jackpot judgment processing of the above may be different. That is, after the execution of the pre-determination process, the gaming state of the pachinko gaming machine 100 (whether it is a high probability state or a low probability state, a time saving state or a time saving no state) has changed by the start of the special symbol change. In this case, since different types of judgment tables are used depending on the game state, the specific judgment table used for the judgment differs between the time when the pre-judgment process is executed and the time when the jackpot judgment process is executed. .. Therefore, even if the same random number value acquired at the time of winning the starting ports 121 and 122 is used, the preliminary determination result and the determination result of the jackpot determination process may differ. In such a case, if the game state changes by the start of the special symbol change after the pre-determination process is executed in the effect control unit 300, the effect based on the pre-determination result is not executed (prohibited) control or the like. You may do.

In addition, according to the command output from the game control unit 200 to the effect control unit 300 as described above, the effect control unit 300 controls, for example, the image display unit 114, the board lamp 116, the speaker 156, the frame lamp 157, and the like. For example, when the effect control unit 300 receives a command indicating the start of a door opening error, the effect control unit 300 displays a message "Please call a staff member" or an image indicating an abnormal state. It is displayed on 114. In addition, the effect control unit 300 limits the output of an alarm or the like indicating an abnormal state from the speaker 156 and the output of music, voice, sound effects, or the like. In addition, the effect control unit 300 lights the panel lamp 116 and the frame lamp 157 in red, for example, as a mode of indicating an abnormal state.

In addition, here, it has been explained that the effect control unit 300 uses all of the image display unit 114, the panel lamp 116, the speaker 156, and the frame lamp 157 to notify that an error has occurred, but one of these It may be the aspect which uses the part. In addition, the mode of notification may be switched according to the content of the error. For example, when a door opening error occurs, all of the image display unit 114, the panel lamp 116, the speaker 156, and the frame lamp 157 may be used as described above. Further, when a payout error occurs, the image display unit 114 and the speaker 156 notify that the error has occurred. This makes it possible for a clerk of a game store (pachinko hall) or the like to easily determine the urgency of an error that has occurred in a game machine.

[Operation of production control unit]
Next, the operation of the effect control unit 300 will be described.
FIG. 47 is a flowchart showing the operation of the effect control unit 300.
The operation of the effect control unit 300 includes the main process shown in FIG. 47 (a) and the interrupt process shown in FIG. 47 (b). With reference to FIG. 47 (a), the effect control unit 300 first makes initial settings at startup (S2501), sets the CTC (Counter / Timer Circuit) cycle (S2502), and then follows the set cycle. , While updating the random number used in the effect control (S2503), the interrupt process is accepted.

The interrupt processing is periodically performed according to the cycle set in S2502. Referring to FIG. 47 (b), in this interrupt process, the effect control unit 300 receives a command from the game control unit 200 and performs a command reception process (S2511). In this command reception process, the effect content (effect pattern) is selected. In addition, the effect control unit 300 performs an effect button process for accepting an operation of the effect button 161 or the like by the player (S2512). After that, the effect control unit 300 performs a command transmission process of transmitting a command including information of the selected effect pattern to the image / sound control unit 310 and the lamp control unit 320 (S2513). As a result, the image display and sound output to the image display unit 114, the operation of the movable accessory 115, the light emission of the panel lamp 116 and the frame lamp 157, and the like are performed.

[Command reception processing by the production control unit]
FIG. 48 is a flowchart showing the contents of the command reception process (S2511 in FIG. 47 (b)).
In this command reception process, the effect control unit 300 first determines whether or not the pre-determination result command and the hold number increase command have been received (S2601). The pre-determination result command and the hold number increase command are set in the start port switch process shown in FIG. 31 in the game control unit 200 (S906, S907, S913, S914), and the output process (S806) shown in FIG. ) Is a command transmitted to the effect control unit 300.
Then, when the effect control unit 300 determines that the pre-determination result command and the hold number increase command have been received (Yes in S2601), the value of the hold number held in the RAM 303 is added by 1 (S2602). Further, the effect control unit 300 performs the pre-determination effect selection process based on the pre-determination result command and the hold number increase command (S2603). The content of the pre-determination effect selection process will be described later.

When the received command is not the pre-determination result command or the hold number increase command (No in S2601), the effect control unit 300 determines whether or not the received command is the fluctuation start command (S2604). This fluctuation start command is a command set in the game control unit 200 in the special symbol processing shown in FIG. 33 (S1111) and transmitted to the effect control unit 300 in the output processing (S806) shown in FIG. 30.
When the received command is a fluctuation start command (Yes in S2604), the effect control unit 300 executes the effect selection process (S2605). Further, when the fluctuation start command is received, a random value for effect control used in the effect selection process is acquired. This random number value is a random number value that is periodically updated in S2503 of the main process shown in FIG. 47 (a). The details of the effect selection process will be described later.

If the received command is not a pre-determination result command, a hold number increase command, or a fluctuation start command (No in S2601 and S2604), the effect control unit 300 determines whether or not the received command is a fluctuation stop command (S2606). This fluctuation stop command is a command set in the game control unit 200 in the special symbol processing shown in FIG. 33 (S1114) and transmitted to the effect control unit 300 in the output processing (S806) shown in FIG. 30.
If the received command is a variable stop command (Yes in S2606), the effect control unit 300 executes the process during the end of the variable effect (S2607). In the process during the end of the variation effect, the effect control unit 300 analyzes the received variation stop command and sets the variation effect end command for instructing the end of the effect of the symbol variation in the RAM 303.

If the received command is not a pre-judgment result command, a hold number increase command, a fluctuation start command, or a fluctuation stop command (No in S2601, S2604, and S2606), the effect control unit 300 starts the opening operation of the jackpot game with the received command. It is determined whether or not it is an opening command for the command (S2608). This opening command is a command set in the stopped processing shown in FIG. 36 (S1418) and transmitted to the effect control unit 300 in the output processing (S806) shown in FIG. 30.
When the received command is an opening command (Yes in S2608), the effect control unit 300 executes the jackpot effect selection process (S2609). The details of the jackpot effect selection process will be described later.

If the received command is not a pre-judgment result command, a hold number increase command, a fluctuation start command, a fluctuation stop command, or an opening command (No in S2601, S2604, S2606, and S2608), the effect control unit 300 receives a jackpot game. It is determined whether or not the ending command is for starting the ending operation of (S2610). This ending command is a command set in the large winning opening process shown in FIG. 39 (S1713) and transmitted to the effect control unit 300 in the output process (S806) shown in FIG. 30.
When the received command is an ending command (Yes in S2610), the effect control unit 300 executes the ending effect selection process (S2611). The details of the ending effect selection process will be described later.

If the received command is not a pre-judgment result command, a hold number increase command, a fluctuation start command, a fluctuation stop command, an opening command, and an ending command (No in S2601, S2604, S2606, S2608, and S2610), then the effect control unit 300 , The customer waiting command reception process for shifting the received command to the customer waiting state is executed (S2612). The details of the customer waiting command reception process will be described later.

FIG. 49 is a flowchart showing the contents of the pre-determination effect selection process (S2603) and the effect selection process (S2605) of FIG. 48.
In the pre-determination effect selection process, the effect control unit 300 first analyzes the pre-determination result command received from the game control unit 200 (S2801). Further, the effect control unit 300 analyzes the hold number increase command received from the game control unit 200 (S2802). Then, the effect control unit 300 selects an effect pattern (pre-determination effect pattern) used in the pre-determination effect based on the pre-determination result command and the hold number increase command (S2803).

Here, as the pre-judgment effect pattern, various effect patterns can be provided to foretell the random number determination result by the special symbol processing before the start of the fluctuation based on the random number determination result by the special symbol processing. For example, an effect such as a hold display effect or a continuous advance notice effect can be provided as a pre-determination effect pattern. In the present embodiment, when a reserved ball is generated, a display indicating the number of reserved balls is displayed on the first special symbol hold indicator 218 and the second special symbol hold indicator 219 of the display 130 (see FIG. 3). At the same time, the image display unit 114 is displayed on hold to indicate the occurrence of hold and the number of holds (hold display effect). Therefore, in this hold display effect, by reflecting the pre-judgment result in the display mode of the hold display, the player is notified of the judgment result when the random number is subsequently determined by the special symbol processing for the hold ball. It can be a suggestive pre-judgment effect.

In addition, although the case where the hold display effect is used as the pre-judgment effect has been described here, various advance notice effects can be produced by reflecting it in various effects performed before the start of the fluctuation based on the random number determination result by the special symbol processing. Will be able to do. For example, an effect using an effect image displayed on the image display unit 114, an effect by emitting light from a board lamp 116 or a frame lamp 157, an effect by an operation of a movable accessory, an effect by acoustic output such as music or sound effects, etc. are performed in advance. It can be set as a judgment effect pattern.

Further, the pre-determination effect is executed in accordance with the symbol change for other winning balls performed before the symbol change for the winning ball (reserved ball) for which the pre-determination is performed. In the present embodiment, the maximum number of reserved balls is four per one starting port (first starting port 121 or second starting port 122) (see FIG. 31). In addition, priority shall be given to the digestion of the reserved ball at the second starting port 122. In this case, for example, if a preliminary determination is made for a reserved ball having the second starting port 122, the fluctuation currently being changed (referred to as the fluctuation) is included before the symbol change for the reserved ball is performed. The symbols of up to four winning balls will be changed. In the advance notice effect related to the reserved ball for which the pre-judgment has been made, if the symbol change is performed a plurality of times before the symbol change is performed for the reserved ball, the advance notice effect (continuous notice effect) that spans the multiple symbol changes. ) May be performed.

Then, the effect control unit 300 sets the hold number command including the value of the hold number after addition and the information of the pre-determination effect pattern selected in the pre-determination effect selection process in the RAM 303 (S2804). The hold number command includes information indicating the pattern in order to notify the CPU 311 of the image / sound control unit 310 of the selected pre-determination effect pattern. By receiving the hold number command, the CPU 311 creates a display list or the like for drawing and outputting the image or sound corresponding to the selected pre-determination effect pattern on the VDP 314. Based on the display list or the like, the VDP 314 reads image data and acoustic data for representing the selected pre-determination effect pattern from the CGROM 315 and SNDROM 316, and expresses the pre-determination effect using the image display unit 114 and the speaker 156. ..

In the effect selection process, the effect control unit 300 first analyzes the received fluctuation start command (S2811). Further, the value of the number of holds held in the RAM 303 is subtracted by 1 (S2812). Then, the effect control unit 300 displays on the image display unit 114 based on various setting information (information such as the type of jackpot, the game state after the jackpot game, the fluctuation pattern, etc.) obtained from the analysis result of the fluctuation start command. A variation effect pattern of symbol variation due to an image is selected (S2813).

Finally, the effect control unit 300 sets a variable effect start command in the RAM 303 to instruct the execution start of the selected effect (S2814). The variation effect start command includes information indicating the pattern in order to notify the CPU 311 of the selected variation effect pattern. By receiving the variation effect start command, the CPU 311 creates a display list or the like for drawing and outputting the image or sound corresponding to the selected variation effect pattern on the VDP 314. Based on the display list or the like, the VDP 314 reads image data or acoustic data for representing the selected variation effect pattern from the CGROM 315 or SNDROM 316, and expresses the variation effect using the image display unit 114 or the speaker 156.

Although not described in detail, in the selection process of the variation effect pattern of the symbol variation in S2813, the variation effect pattern is determined based on the variation pattern. Based on the variation effect pattern determined here, the variation display of the decorative pattern, the background effect, the notice effect, and the like are determined. The decorative symbol variation display is an effect display performed by the image display unit 114 in accordance with the variation display of the special symbol performed by the first special symbol display 221 or the second special symbol display 222. In the variable display of this decorative pattern, a reach effect or the like is executed. In addition, unlike the present embodiment, when a plurality of fluctuation effect patterns are set for the variation pattern, it is one of the effect random numbers (one of the random numbers updated in S2503 of FIG. 47 (a)). , The effect random number value is acquired when the variation start command is received), and the variation effect pattern may be selected by lottery.

FIG. 50 is a flowchart showing the contents of the jackpot effect selection process (S2609) of FIG. 48.
In this jackpot effect selection process, the effect control unit 300 first analyzes the received opening command (including information about the type of jackpot symbol) (S3001), and selects an effect pattern (big hit effect pattern) (S3002). .. Then, the effect control unit 300 reads the image data and acoustic data used for the effect according to the selected jackpot effect pattern from the ROM 302, sets the jackpot effect start command instructing the selected effect together with these data in the RAM 303, and sets the RAM 303. The jackpot effect selection process ends (S3003). As a result, the production during the jackpot is determined. In the selection of the jackpot effect pattern (S3002), a determination may be made based on a random number value acquired when a command is received.

FIG. 51 is a flowchart showing the contents of the ending effect selection process (S2611) of FIG. 48.
In this ending effect selection process, the effect control unit 300 first analyzes the received ending command (including information about the type of jackpot symbol) (S3101), and selects an effect pattern (ending effect pattern) (S3102). .. Then, the effect control unit 300 reads the image data and acoustic data used for the effect according to the selected ending effect pattern from the ROM 302, sets the ending effect start command instructing the selected effect together with these data in the RAM 303, and sets the RAM 303. The ending effect selection process ends (S3103). In the selection of the ending effect pattern (S3102), a determination may be made based on a random number value acquired when the command is received.

FIG. 52 is a flowchart showing the contents of the customer waiting command reception process (S2612) of FIG. 48.
The effect control unit 300 determines whether or not a customer waiting command for shifting to the customer waiting state has been received (S3201). When the customer waiting command is received (Yes in S3201), the effect control unit 300 starts measuring the elapsed time (S3202) and turns on the measurement flag in the RAM 303 (S3203). On the other hand, when the received command is not a customer waiting command (No in S3201), the effect control unit 300 determines whether or not the measurement flag held in the RAM 303 is ON (S3204). If the measurement flag is OFF (No in S3204), the customer waiting command reception process is terminated.

When the measurement flag is ON (after Yes in S3204 or ON in S3203), the effect control unit 300 then determines whether or not the measurement time has reached a predetermined time-up time (for example, 10 seconds). Is determined (S3205). If the time is not up (No in S3205), the customer waiting command reception process is terminated. On the other hand, when the time is up (Yes in S3205), the effect control unit 300 turns off the measurement flag held in the RAM 303 (S3206), and issues a customer wait effect command for performing the customer wait effect (demo effect) to the RAM 303. Is set to and the customer waiting command reception process is terminated (S3207).

When the command reception process is completed as described above, any one of the variable effect start command, the variable effect end command, the jackpot effect start command, the ending effect start command, and the customer waiting effect command is set in the RAM 303.

FIG. 53 is a flowchart showing the contents of the effect button processing (S2512 in FIG. 47 (b)).
In this effect button process, the effect control unit 300 first determines whether or not the operation means such as the effect button 161 by the player has been operated during the predetermined reception period (valid period) (S3301). Here, the operation of the operating means includes pressing the effect button 161 to turn it on, and pressing the center key and surrounding keys of the effect key 162 to turn it ON. Further, when the pachinko gaming machine 100 is provided with an operation device other than the effect button 161 and the effect key 162, such as a touch panel, the operation of the device is detected. The effect control unit 300 receives an operation signal from the controller of these devices and detects that the operation has been performed.

If the operation means such as the effect button 161 is operated (Yes in S3301), the effect control unit 300 sets the effect button command including the information indicating the operation content of the operation means in the RAM 303 and ends the effect button process. (S3302).

After that, the effect control unit 300 performs the command transmission process (S2513) of FIG. 47 (b), and sends the command set in the RAM 303 by the above command reception process and effect button process to the image / sound control unit 310 and the lamp. It is transmitted to the control unit 320. Then, based on the received command, the image / acoustic control unit 310 and the lamp control unit 320 display an image on the image display unit 114, sound output, operate the movable accessory 115, emit light from the panel lamp 116 and the frame lamp 157, and the like. To execute the set effect.

[Display information of information display in each game section]
Next, the display information of the information display 230 in each game section will be described with reference to FIG. 54. In the table of display information of FIG. 54, the section counter value (type of game section), the number of normal outs, the data selection counter value, and the display content of the information display 230 are associated with each other.
Here, the first game section shown in FIG. 54 starts when the power is turned on for the first time. In addition, the setting of a total of 60,000 outs is a value that can approximately guarantee the daily operation of 100 pachinko machines per minute. Normally, the medium base value is always displayed in 2 digits in the numerical segment. Further, when the number of normal medium outs is "0" and when the normal medium base value is 100 or more, "99." is displayed in the numerical segment.

The identification information displayed on the identification segment of the information display 230 is "bL.", Which indicates that it is the normal base value of the current game section, and "bL.", Which indicates that it is the normal base value of the previous game section. There are "b1.", "B2." Indicates that it is the normal base value of the game section two times before, and "b3.", Which indicates that it is the normal base value of the game section three times before.

The numerical information displayed on the numerical segment of the information display 230 is "---" indicating that there is no calculated normal medium base value, the normal base value is "0", or the number of normal medium outs is "0". "00" indicating that there is, "01" to "99" indicating that the number of outs in normal is "1" or more and the normal base value is "1" to "99", and the normal base value. There is "99." indicating that is "100" or more. Normally, when the base value is less than "10", the tens digit of the numerical information is always "0" and displayed in two digits.

The display mode of the numerical information displayed in the numerical segment does not change (lights up) regardless of the game section or the number of outs during normal operation, but the identification information displayed in the identification segment includes the game section or The display mode changes (blinks or lights up) depending on the number of outs during normal times (whether or not there is a calculated normal base value or whether or not the calculated normal base value is credible).

Specifically, in the first to fourth game sections, when the identification information of the game section without the calculated normal base value is displayed, the identification information is displayed blinking. Further, in the game section after the second game section, when the identification information (“bL.”) Of the current game section is displayed, the calculated normal base value has a low credibility period (the number of outs during normal use is high). If it is 0 to 5999), the identification information will be displayed blinking. In other cases, the identification information is lit and displayed.

Here, to show an example of the display of the information display 230, the interval counter value is "1", the number of normal outs is in the range of 0 to 5999, and the data selection counter value is "0". When the normal base value stored in the first area of the base storage area is "35", "bL." Is blinking and displayed in the identification segment of the information display 230, and "35" is displayed in the numerical segment. Will be lit and displayed.

In this way, when the normal base value is "99" or less, the performance information of "00" to "99" that does not use the decimal point DP of the 7-segment display is displayed in the numerical segment, while the normal base value is displayed. When the value is "100" or more, the performance information using the decimal point DP of the 7-segment display "99." is displayed in the numerical segment, so it is easy to grasp that it is an abnormal normal base value. ..

In addition, when the base value is usually less than "10", "0" is always displayed in the tens digit of the numerical segment and displayed in two digits (for example, "01"), so 2 as a numerical segment. It is possible to make an easy-to-understand display by effectively using the two 7-segment displays.

Further, when the normal base value of the current game section is displayed, and the number of normal outs in the current game section is 0 to 5999, which is not sufficient for calculating the normal base value. Since the identification information "bL." Displayed in the identification segment is blinking and displayed, it becomes easy to grasp that the normally displayed base value currently displayed is low credibility information.

In addition, if there is no calculated normal base value, a non-numerical "---" is displayed in the numerical segment, so the normal base value is calculated in the game section corresponding to the identification information displayed in the identification segment. It becomes easier to understand that it is not.

The game ball counting process, the performance information calculation process, and the performance display data setting process are not executed as an information program, but any one or two are executed as a game program (for example, a game ball counting process). The process may be executed in the input control process that monitors the presence or absence of signal input from various switches), while the rest may be executed as an information program.

Further, the process of outputting the display data for displaying the performance information on the information display 230 may be executed by the performance program instead of being executed by the output control process which is the game program.

Further, an out ball composed of a game ball that has won a prize in the normal winning opening 126, the first starting port 121, the second starting opening 122, and the large winning opening 125 by the out ball detection switch 227, and a game ball that has flowed into the discharge port 117. May be made to detect only the game ball that has flowed into the out port by the out ball detection switch 227 instead of detecting. In that case, the number of outs (total number of outs) each time the game ball is detected by the out ball detection switch 227, the normal winning opening switch 217, the first starting opening switch 211, the second starting opening switch 212, and the large winning opening switch 215. , Usually the number of outs in the middle) should be added one by one.

(Main processing of the overall control unit)
The main process of the image / sound control unit 310 will be described with reference to FIG. 55. FIG. 55 is a flowchart showing the main processing of the image / acoustic control unit 310. This main process is performed by inputting a system reset generated by supplying a power supply voltage from a power supply board (not shown) to the CPU 311.

First, the CPU 311 prohibits all interrupts in step T1 and performs initial setting processing in step T2. Specifically, the initial setting of the CPU such as the setting of the built-in register, the access permission to the RAM 313, the initialization of the entire RAM area of the RAM 313 (0 clear), and the CTC (counter timer circuit) for generating the timer interrupt. Start up, etc., and allow all interrupts in step T3.

The CPU 311 performs the adjustment mode switching process in step T4. Specifically, the volume (value) of the effect sound output from the speaker 156 and the light intensity (value) of the backlight of the image display unit 114 with reference to the input signal from the changeover switch (not shown) that can be operated by the game clerk. ) And the adjustment mode related to the adjustment of the volume and the amount of light (whether or not the volume can be adjusted, whether or not the amount of light can be adjusted, the initial value of the volume value (any of 0 to 5) and the initial value of the amount of light (0 to 5). Any), a process for switching the volume value adjustment range (0 to 5 or 1 to 5) and the light intensity value adjustment range (0 to 5 or 1 to 5)) is performed.

Here, the changeover switch (not shown) is provided on the game control board as the main board, and the volume of the effect sound output from the speaker 156 and the display device (image display unit 114, sub-display device 114). Separately, the adjustment mode related to the adjustment of the light amount of the display device)) and various lighting devices (frame lamp 157, panel lamp 116) is switched.
It should be noted that the setting (adjustment) of the volume value and the light amount value by the changeover switch (not shown) can always be performed if the pachinko gaming machine 100 is in the power ON state (after the image / sound control unit 310 is activated). It has become.

The CPU 311 performs the volume adjustment process in step T5. Specifically, the volume of the effect sound output from the speaker 156 is based on the detection signals (left button detection signal, right button detection signal) from the detection switch that detects the operation of the effect key 162 that can be operated by the player. Perform processing to adjust (value).

The CPU 311 performs the light amount adjustment process in step T6. Specifically, based on the detection signals (lower button detection signal, upper button detection signal) from the detection switch that detects the operation of the effect key 162 that can be operated by the player, the amount of light of the backlight of the image display unit 114 ( Perform processing to adjust the value).

It should be noted that the setting (adjustment) of the volume value and the light amount value by the effect key 162 is regulated (restricted) at the start of the variable effect and at the end of the variable effect (stop of the decorative symbol 41). .. Further, between the time when the power of the pachinko gaming machine 100 is turned on and the time when the progress control of the game is started (specifically, during the setting change mode, the RAM clear preparation mode, the setting confirmation mode, and various drive sources Important (high security level) abnormalities (power on, power recovery) that should be notified prior to dish full error and payout error (until the timer interruption is started on the game control board during initial operation) , Unauthorized winning, abnormal winning, magnetic error, radio wave error, door opening error) are also regulated (restricted) during notification (output of notification sound).

Further, during the output of the abnormal notification sound, various production sounds (BGM) output from the speaker 156 even when the current volume value is lower than the maximum volume value. Etc.), and when the output of the abnormal notification sound ends, the volume of various production sounds is restored to the volume before the reduction.

The CPU 311 performs the eco-mode control process in step T7. Specifically, processing is performed to control the start and end of the eco-mode in which the amount of light of the backlight of the image display unit 114 is reduced to suppress power consumption.

In step T8, the CPU 311 determines whether or not the effect instruction command or the notification instruction command transmitted from the effect control unit 300 has been received. If the effect instruction command or the notification instruction command is not received, the process is transferred to step T11, and if the effect instruction command or the notification instruction command is received, the process is transferred to step T9.

The CPU 311 performs the animation pattern setting process in step T9. Specifically, a process is performed in which an animation pattern is determined from an animation group of the type corresponding to the received production instruction command or notification instruction command and set (set) in a predetermined area of the RAM 313.

The CPU 311 performs the sound pattern setting process in step T10. Specifically, a process is performed in which a sound pattern is determined from a sound group of a type corresponding to the received effect instruction command or notification instruction command and set (set) in a predetermined area of the RAM 313.

In step T11, the CPU 311 determines whether or not the frame switching flag indicating that it is the frame update timing for updating the display image of the image display unit 114 is set in the RAM 313. If there is a frame switching flag, the process is transferred to step T12, and if there is no frame switching flag, the process is transferred to step T4.

The frame switching flag is set every time the image / acoustic control unit 310 receives a V blank signal transmitted from the VDP 314 every 1/30 second (the time when the drawing / display of the production image for one frame is scheduled to be completed). It is set by the V blank interrupt process executed in. Therefore, the processes of steps T12 to T15 described below are executed every time the V blank interrupt process is executed (frame update timing).

The CPU 311 clears the frame switching flag set in the RAM 313 in step T12, and performs the scene update process in step T13. Specifically, the address of the animation scene is updated based on the animation pattern determined in step T9 by referring to the scene switching counter, the weight frame counter, and the frame counter updated by the above-mentioned V blank interrupt processing. , The process of updating the address of the sound scene is performed based on the sound pattern determined in step T10.

The CPU 311 performs drawing control processing in step T14. Specifically, it consists of a drawing control command group from the display information (sprite identification number, display position, etc.) of one frame of the animation scene at the updated address according to the priority (drawing order) of the animation group to which the animation scene belongs. A display list is generated, the display list is output to VDP314, and a process of instructing drawing of a display image based on the display list is performed.

As a result, in the VDP 314, the display image based on the display list is drawn in the drawing frame buffer, and the image (effect image, abnormality notification image) drawn in the display frame buffer is displayed on the image display unit 114. It will be done. That is, the frame update timing is set to the start timing and end timing of various effects (image display and sound output such as hold display, variable effect, jackpot notice effect, look-ahead effect, etc.) performed by the image display unit 114. .. The effect directly controlled by the effect control unit 300 and the lamp control unit 320 (the effect operation of the movable accessory 115) may or may not match the frame update timing.

The CPU 311 performs voice control processing in step T15. Specifically, a voice control command is generated from the sound information at the updated address, and the voice control command is output to the image / sound control unit 310.

As a result, the image / sound control unit 310 performs a process of outputting various effect sounds and notification sounds based on the voice control command from the speaker 156. When this process is completed, the process is moved to step T4.

In this way, at the start of the variable effect and at the end of the variable effect (stop of the decorative symbol 41), the volume can be adjusted and the amount of light can be adjusted by the changeover switch (not shown) that can be operated by the game clerk, but the player can adjust the amount of light. Volume adjustment and light intensity adjustment by the operable effect key 162 are regulated (restricted). Therefore, it is difficult for the player to overlook important points such as the start of the variable effect and the end of the variable effect, and it is possible to prevent the game from being less enjoyable.

In addition, important (high security level) abnormalities (power on, power restoration, unrecoverable error, illegal winning, abnormal winning, magnetic error, radio wave error, etc.) that should be notified prior to dish full error and payout error, During the notification of (door opening error) (output of notification sound), the volume can be adjusted and the amount of light can be adjusted by the changeover switch (not shown) that can be operated by the game clerk, but the volume can be adjusted by the effect key 162 that can be operated by the player. And light amount adjustment is regulated (restricted). Therefore, it is possible to improve the convenience of the game store side regarding the volume adjustment and the light amount adjustment while avoiding the inconvenience that the player who is trying to adjust the volume and the light amount does not notice the occurrence of the abnormality.

Further, during the output of the abnormal notification sound, various production sounds (BGM) output from the speaker 156 even when the current volume value is lower than the maximum volume value. Etc.), and when the output of the abnormal notification sound ends, the volume of various production sounds is restored to the volume before the reduction. Therefore, it is possible to avoid the inconvenience of not noticing the abnormal notification sound due to various production sounds, and it is possible to ensure the security of the gaming machine.

It should be noted that during the notification of abnormality (output of the notification sound), the setting (adjustment) of the volume value and the light amount value by the effect key 162 that can be operated by the player may be disabled, and the adjustment range of the volume value and the light amount value. May be limited to, for example, between 0 and 2.

(Initial processing of the accessory of the lamp control unit)
The initial processing of the accessory of the lamp control unit 320 will be described with reference to FIG. 56. FIG. 56 is a flowchart showing the initial processing of the accessory of the lamp control unit 320, and this processing is executed in the timer interrupt processing executed at predetermined intervals (4 milliseconds) in the lamp control unit 320.

In step R101, the CPU 321 determines whether or not a power ON command (power on designation command, power recovery designation command) has been received from the game control unit 200. When the power ON command is received, the process is transferred to step R102, and when the power ON command is not received, the process is transferred to step R103.

In step R102, the CPU 321 executes the origin return process of the accessory (movable accessory 115, sub-image display unit (not shown), effect button 161) to the initial process number updated in each process of the accessory initial process. Set "1" for.

In step R103, the CPU 321 determines whether or not the initial processing number is "1". If the initial processing number is not "1", the processing is transferred to step R105 assuming that the origin return processing of the accessory is not executed, and if the initial processing number is "1", the origin return processing is performed in step R104. This is done, and the initial processing of the character this time is completed. Specifically, based on the input signal from the position detection sensor, the return operation of the accessory (movable accessory 115, sub-image display unit (not shown), effect button 161) to the origin position is executed, or initial processing is performed. Perform processing such as setting the number to "2". The details of the origin return processing will be described later.

In step R105, the CPU 321 determines whether or not the initial processing number is "2". If the initial processing number is not "2", the initial operation processing of the accessory is not executed, and the initial operation processing of the accessory is terminated. If the initial processing number is "2", the initial operation processing is performed. , Finish the initial processing of the character this time. Specifically, processing such as performing initial operation and initial light emission for confirming whether or not the accessory operates normally, and setting the initial processing number to "0" is performed. The details of the initial operation processing will be described later.

As described above, according to the accessory initial process shown in FIG. 56, the origin return process for performing the return operation to the origin position of the various accessories, and the initial operation for performing the initial operation and the initial light emission of the various accessories are performed. The operation process is not executed at the same time. Therefore, the return operation of the various accessories to the origin position and the initial operation and the initial light emission of the various accessories do not coexist, and the return operation, the initial operation, and the initial light emission can be confirmed separately. ..

Further, according to the accessory initial processing shown in FIG. 56, the origin return processing is executed before the initial operation processing. Therefore, the various accessories will initially operate from the origin position, and it will be possible to easily grasp whether or not there is an abnormality in the operation of the various accessories.

(Origin return processing of lamp control unit)
The origin return process of the lamp control unit 320 will be described with reference to FIG. 57. FIG. 57 is a flowchart showing the origin return process in the lamp control unit 320.

In step R105-1, the CPU 321 determines whether or not the board accessory processing number indicating the transition of the origin return status of the board accessory (movable accessory 115, sub-image display unit (not shown)) is “0”. judge. If the board accessory processing number is not "0", the process is transferred to step R105-3, and if the board accessory processing number is "0", the drive target for returning to the origin is movable in step R105-2. It is set to the accessory 115 (movable effect device), and the process is transferred to step R105-5.

In step R105-3, the CPU 321 determines whether or not the board accessory processing number is "1". If the board accessory processing number is not "1", the process is transferred to step R105-12, and if the board accessory processing number is "1", the drive target to be returned to the origin is set in step R105-4. It is set in the sub display device (not shown), and the process is transferred to step R105-5.

In step R105-5, the CPU 321 determines whether or not the accessory to be driven is at the origin position (standby position). Specifically, the input signal from the position detection sensor that detects that each board accessory is at the origin position is determined. If the board accessory to be driven is not at the origin position, the process is transferred to step R105-6, and if the board accessory to be driven is at the origin position, the process is transferred to step R105-11.

In step R105-6, the CPU 321 drives a drive motor for moving the board accessory to be driven so that the board accessory to be driven returns to the origin position, and in step R105-7, the board accessory is moved. The board accessory abnormality determination timer for determining the occurrence of a return abnormality that does not return to the origin position within a predetermined time is updated by +1.

In step R105-8, the CPU 321 determines whether or not the updated board accessory abnormality determination timer has an upper limit value (for example, 5 seconds). When the board accessory abnormality determination timer has the upper limit value, the process is transferred to step R105-9 assuming that a return abnormality has occurred in the board accessory to be driven, and when the board accessory abnormality determination timer is not the upper limit value. Moves the process to step R105-12.

In step R105-9, the CPU 321 sets the return abnormality information (movable effect device return abnormality information, sub-display device return abnormality information) indicating that a return abnormality has occurred in the board accessory to be driven in the RAM 323, and sets the RAM 323 to step R105. At -10, the board accessory abnormality determination timer is cleared.

In step R105-11, the CPU 321 updates the board accessory processing number by +1. Specifically, if the board accessory processing number is "0", the board accessory processing number is updated to "1" so that the sub-image display unit (not shown) is driven. If the processing number is "1", the board accessory processing number is updated to "2" in order to end the process of returning the board accessory (movable accessory 115, sub-image display unit (not shown)) to the origin. do.

In step R105-12, the CPU 321 determines whether or not the frame accessory processing number indicating the transition of the origin return status of the frame accessory (effect button 161) is “0”. If the frame accessory processing number is "0", the processing is transferred to step R105-13, and if the board accessory processing number is not "0", the processing is transferred to step R105-20.

In step R105-13, the CPU 321 determines whether or not the effect button 161 is at the origin position (standby position). Specifically, the input signal from the position detection sensor that detects that the effect button 161 is at the origin position is determined. If the effect button 161 is not at the origin position, the process is transferred to step R105-14, and if the effect button 161 is at the origin position, the process is transferred to step R105-19.

The CPU 321 drives an effect button drive motor for moving the effect button 161 so that the effect button 161 returns to the origin position in step R105-14, and the effect button 161 is set within a predetermined time in step R105-15. The frame accessory abnormality determination timer for determining the occurrence of a return abnormality that does not return to the origin position is updated by +1.

In step R105-16, the CPU 321 determines whether or not the updated frame accessory abnormality determination timer has an upper limit value (for example, 5 seconds). If the frame accessory abnormality determination timer is the upper limit value, the process is transferred to step R105-17 assuming that a return abnormality has occurred in the effect button 161. If the frame accessory abnormality determination timer is not the upper limit value, this time. The origin return processing of is finished.

In step R105-17, the CPU 321 sets the return abnormality information indicating that a return abnormality has occurred in the effect button 161 in the RAM 323, and in step R105-18, clears the frame accessory abnormality determination timer.

In step R105-19, the CPU 321 updates the frame accessory processing number by +1. Specifically, if the frame accessory processing number is "0", the frame accessory processing number is updated to "1" in order to end the process of returning the frame accessory (effect button 161) to the origin.

In step R105-20, the CPU 321 determines whether or not the board accessory processing number and the frame accessory processing number satisfy the end condition. Specifically, it is determined whether or not the board accessory processing number is "2" and the frame accessory processing number is "1". If the end condition is satisfied, the process is moved to step R105-21, and if the end condition is not satisfied, the origin return process this time is ended.

The CPU 321 clears the board accessory processing number and the frame accessory processing number in step R105-21, and executes the initial operation processing of the accessory to the above-mentioned initial processing number in step R105-22. 2 ”is set, and the origin return processing this time is completed.

As described above, according to the origin return process shown in FIG. 57, the movable accessory 115 and the sub-image display unit (not shown) whose effect positions (movement areas) overlap when the power is turned on are the origin positions (standby positions). If not, do not return both to the origin position (standby position) at the same time (at the same time), but return them to the origin position in a predetermined order (movable accessory 115 → sub-image display unit (not shown)). It has become. Therefore, it is possible to easily confirm whether or not various board accessories have returned to the origin position. Further, when the movable accessory 115 and the sub image display unit (not shown) are in contact with each other due to difficulty in separation, it is possible to prevent both accessories from exerting a load on each other, and both accessories are damaged at the same time. It is possible to suppress such inconveniences.

Further, according to the origin return processing shown in FIG. 57, the return operation of the board accessory (movable accessory 115, sub-image display unit (not shown)) to the origin position and the frame accessory (effect button 161) are returned to the origin position. It is possible to execute the return operation to the origin position at the same time (at the same time). Therefore, it is possible to shorten the time required for the return operation of the various accessories, and it is possible to smoothly shift to the initial operation of the various accessories to be executed next.

Further, according to the origin return processing shown in FIG. 57, an upper limit is set for the time of the return operation to the origin position of each accessory. Therefore, it is possible to suppress the inconvenience that the return operation of various accessories is not completed forever. Therefore, it is possible to avoid a situation in which various characters are returning and not performing the effect even during the variable effect, and it is possible to prevent the game from being less enjoyable.

Further, according to the origin return processing shown in FIG. 57, the return operation of the board accessory (movable accessory 115, sub-image display unit (not shown)) to the origin position and the frame accessory (effect button 161) are returned to the origin position. When both the return operations to the origin position are completed, the process for shifting to the initial operation process is performed. Therefore, the return operation of the various accessories to the origin position and the initial operation of the various accessories are not executed at the same time, and it is possible to separately check the return operation and the initial operation of the various accessories. ..

The movable accessory 115 and the sub-image display unit (not shown) are returned to the origin position in a predetermined order (movable accessory 115 → sub-image display unit (not shown)). At the same time, the operation of returning to the origin position may be started. By doing so, it is possible to shorten the time required for the return operation of the movable accessory 115 and the sub-image display unit (not shown), and it is possible to smoothly shift to the initial operation of the various accessories to be executed next. It becomes.

(Initial operation processing of lamp control unit)
The initial operation process of the lamp control unit 320 will be described with reference to FIG. 58. FIG. 58 is a flowchart showing the initial operation processing of the lamp control unit 320.

In step R107-1, the CPU 321 determines whether or not the board accessory processing number indicating the transition of the initial operation status of the board accessory is “0”. If the board accessory processing number is "0", the process is transferred to step R107-2, and if the board accessory processing number is not "0", the process is transferred to step R107-7.

In step R107-2, the CPU 321 determines whether or not the return abnormality information of the board accessory (movable accessory 115, sub-image display unit (not shown)) is set in the RAM 323. If the return abnormality information is not set, the process is transferred to step R107-4 assuming that the initial operation and initial light emission of the board accessory are performed, and if the return abnormality information is set, step R107-3. In, "2" is set in the board accessory processing number assuming that the initial operation of the board accessory is not performed, and the process is transferred to step R107-7.

In step R107-4, the CPU 321 selects a board accessory initial operation pattern determination table (see FIG. 59 (a)) for determining the initial operation pattern of the board accessory. The details of the board accessory initial operation pattern determination table will be described later.

In step R107-5, the CPU 321 determines the initial operation pattern of the board accessory (movable accessory 115, sub-image display unit (not shown)) and sets it in the RAM 323. Specifically, with reference to the board accessory initial operation pattern determination table shown in FIG. 59 (a), from among a plurality of initial operation patterns, based on the type of command when the power is turned on and the presence or absence of return abnormality information. Determine one initial motion pattern.

In step R107-6, the CPU 321 updates the board accessory processing number by +1. Specifically, if the board accessory processing number is "0", the board accessory processing number is updated to "1" in order to execute the initial operation of the board accessory.

In step R107-7, the CPU 321 determines whether or not the board accessory processing number is "1". If the board accessory processing number is not "1", the process is transferred to step R107-11, and if the board accessory processing number is "1", it is set in the RAM 323 in step R107-8. The initial operation of the board accessory is executed according to the initial operation pattern of the board accessory.

In step R107-9, the CPU 321 determines whether or not the initial operation of the board accessory has completed all the steps. If the initial operation of the board accessory has not completed all steps, the process is transferred to step R107-11, and if the initial operation of the board accessory has completed all steps, the board accessory is in step R107-10. Update the processing number by +1. Specifically, if the board accessory processing number is "1", the board accessory processing number is updated to "2" in order to end the process of initial operation of the board accessory.

In step R107-11, the CPU 321 determines whether or not the frame accessory processing number indicating the transition of the initial operation status of the frame accessory (effect button 161) is “0”. If the frame accessory processing number is "0", the process is transferred to step R107-12, and if the frame accessory processing number is not "0", the process is transferred to step R107-17.

In step R107-12, the CPU 321 determines whether or not the return abnormality information of the effect button 161 is set in the RAM 323. If the return abnormality information is not set, the process is transferred to step R107-14 to perform the initial operation of the frame accessory, and if the return abnormality information is set, the frame is set in step R107-13. Assuming that the initial operation of the accessory is not performed, "2" is set in the frame accessory processing number, and the processing is transferred to step R107-17.

In step R107-14, the CPU 321 selects a frame accessory initial operation pattern determination table (see FIG. 59B) for determining the initial operation pattern of the frame accessory. The details of the frame accessory initial operation pattern determination table will be described later.

In step R107-15, the CPU 321 determines the initial operation pattern of the frame accessory (effect button 161) and sets it in the RAM 323. Specifically, referring to the frame accessory initial operation pattern determination table shown in FIG. 59 (b), one initial operation pattern is determined from a plurality of initial operation patterns based on the type of the power ON command. ..

In step R107-16, the CPU 321 updates the frame accessory processing number by +1. Specifically, if the frame accessory processing number is "0", the frame accessory processing number is updated to "1" in order to execute the initial operation of the frame accessory.

In step R107-17, the CPU 321 determines whether or not the frame accessory processing number is "1". If the frame accessory processing number is not "1", the process is transferred to step R107-21, and if the frame accessory processing number is "1", it is set in the RAM 323 in step R107-18. The initial operation of the frame accessory is executed according to the initial operation pattern of the frame accessory.

In step R107-19, the CPU 321 determines whether or not the initial operation of the frame accessory has completed all the steps. If the initial operation of the frame accessory is not completed in all steps, the process is transferred to step R107-21, and if the initial operation of the frame accessory is completed in all steps, the frame accessory is in step R107-20. Update the processing number by +1. Specifically, if the frame accessory processing number is "1", the frame accessory processing number is updated to "2" in order to end the processing for initial operation of the frame accessory.

In step R107-21, the CPU 321 determines whether or not the board accessory processing number and the frame accessory processing number satisfy the end condition. Specifically, it is determined whether the board accessory processing number is "2" and the frame accessory processing number is "2". If the end condition is satisfied, the process is moved to step R107-22, and if the end condition is not satisfied, the current initial operation process is ended.

The CPU 321 clears the board accessory processing number and the frame accessory processing number in step R107-22, clears the above-mentioned initial processing number in step R107-23, and ends the current initial operation processing.

As described above, according to the initial operation process shown in FIG. 58, the initial operation of the board accessory (movable accessory 115, sub-image display unit (not shown)) and the initial operation of the frame accessory (effect button 161). Can be executed at the same time (at the same time). Therefore, it is possible to shorten the time required for the initial operation of the various accessories, and it is possible to prevent the production operation of the various accessories from being hindered during the game.

Further, according to the initial operation process shown in FIG. 58, if there is a return abnormality in the movable accessory 115 and the sub-image display unit (not shown) constituting the board accessory, the movable accessory 115 and the sub-image are displayed. The initial operation of the part (not shown) is not executed. Therefore, it is possible to prevent the board accessory from completely breaking down or being damaged by forcibly performing the initial operation of the board accessory in which the return abnormality has occurred.

Further, according to the initial operation process shown in FIG. 58, when the effect button 161 constituting the frame accessory has a return abnormality, the initial operation of the effect button 161 is not executed. Therefore, it is possible to prevent the inconvenience that the effect button 161 is completely broken or damaged by forcibly initializing the effect button 161 in which the return abnormality has occurred.

Further, according to the initial operation process shown in FIG. 58, even if the initial operation of the board accessory in which the return abnormality has occurred is not executed, the initial operation of the frame accessory in which the return abnormality has not occurred is executed and the return abnormality is executed. Even if the initial operation of the frame accessory in which is generated is not executed, the initial operation of the board accessory in which the return abnormality has not occurred is executed. Therefore, it is possible to confirm whether or not there is an abnormality in the operation of the accessory that does not have a return abnormality.

Further, according to the initial operation process shown in FIG. 58, both the initial operation of the board accessory (movable accessory 115, sub-image display unit (not shown)) and the initial operation of the frame accessory (effect button 161) are both. The initial operation processing is finished when is finished. Therefore, even though one of the board accessory and the frame accessory is performing the initial operation, it may be unclear whether it is the initial operation or the effect operation, such as the other performing the effect operation. It disappears.

(Table for determining the initial operation pattern of the board)
FIG. 59A is a diagram showing a board accessory initial operation pattern determination table for determining the initial operation pattern of the board accessory (movable accessory 115, sub-image display unit (not shown)).

The board accessory initial operation pattern determination table is associated with the type of command when the power is turned on, the presence / absence of return abnormality information, and the selected initial operation pattern. For reference, the operation mode at the time of initial operation and the initial operation The number of steps is described.

The initial operation pattern is determined when patterns 01 to 03, which are determined when the power-on designation command is received, or when the first power recovery designation command, which indicates that the customer is waiting for a customer, is received. Patterns 04 to 06, a pattern determined when a second power recovery designation command indicating that a special symbol is being displayed, or a third power recovery designation command indicating that a jackpot game is in progress is received. 07 to 09 are set.

"Movable effect device small descent" is an operation in which the movable accessory 115 moves (descends) from the standby position to an intermediate position slightly below the standby position. The movable accessory 115 moves (descends) from the standby position to the effect position below the intermediate position, and the "movable effect device origin return" is an operation in which the movable accessory 115 returns to the standby position. It has become.

"Sub-display device movement" is an operation in which the sub-image display unit (not shown) rises from the standby position to the effect position, and "sub-display device origin return" is the sub-image display unit (not shown). Is an operation to return to the standby position.

The "movable effect device LED" is a plurality of LEDs provided on the movable accessory 115, and the "sub display device LED" is a plurality of LEDs provided around the screen of the sub image display unit (not shown). It is the LED of.

In the initial operation pattern 02, the initial operation pattern 05, and the initial operation pattern 08, the lighting color of the movable effect device LED is not described, but this point is due to the return abnormality of the first movable member 115a. Is flashing red to notify the abnormality.

Further, in the initial operation pattern 03, the initial operation pattern 06, and the initial operation pattern 09, the lighting color of the sub display device LED is not described, but this point is sub due to the return abnormality of the sub image display unit (not shown). This is because the display device LED blinks red to notify the abnormality.

The first feature of the board accessory initial operation pattern determination table shown in FIG. 59 (a) is that the board is used when the power is turned on with the initialization of the RAM 203 and when the power is restored without the initialization of the RAM 203. The point is that the operation mode (number of steps, operation of each step) of the initial operation of the object (movable accessory 115, sub-image display unit (not shown)) is the same. Therefore, it is possible to appropriately confirm whether or not there is an abnormality in the operation of the panel accessory regardless of whether the power is turned on or restored.

It should be noted that the operation mode of the initial operation is the same as long as the movement pattern of the board accessory in each process is the same, the operation time in each process may be the same, and the operation time in each process is the same. It may be different.

Further, the operation mode (number of processes, operation of each process) of one of the movable accessory 115 and the sub image display unit (not shown) may be different between when the power is turned on and when the power is restored. The operation mode (number of steps, operation of each step) of the initial operation of both the movable accessory 115 and the sub-image display unit (not shown) may be different. In this way, it is possible to easily grasp whether it is the initial operation by turning on the power (the control state of the game is initialized) or the initial operation by restoring the power (the control state of the game is restored). It becomes.

Further, when the operation mode (number of processes, operation of each process) of the initial operation of the movable accessory 115 and / or the sub image display unit (not shown) is different between when the power is turned on and when the power is restored, the power is turned on. An operation that is not in the initial operation at the time may be executed in the initial operation at the time of power restoration, or an operation that is not in the initial operation at the time of power restoration may be executed in the initial operation at the time of power-on. In this way, it becomes easier to grasp whether it is the initial operation by turning on the power (the control state of the game is initialized) or the initial operation by restoring the power (the control state of the game is restored). ..

The second feature of the board accessory initial operation pattern determination table shown in FIG. 59 (a) is that the board accessory (movable accessory 115, A point is that the light emission mode of the initial light emission during the initial operation of the sub-image display unit (not shown) is different. Therefore, it is possible to grasp whether it is the initial operation by turning on the power (the control state of the game is initialized) or the initial operation by restoring the power (the control state of the game is restored).

The third feature of the board accessory initial operation pattern determination table shown in FIG. 59 (a) is that the initial light emission of the movable effect device LED is emitted when the power is turned on and when the power is restored to the customer waiting state. While the modes are the same, the mode of initial light emission of the sub-display device LED is different. Therefore, it is possible to grasp whether it is the initial operation by turning on the power (the control state of the game is initialized) or the initial operation by restoring the power (the control state of the game is restored).

It should be noted that while the initial light emission mode of the movable effect device LED is the same when the power is turned on and when the power supply is restored to the customer waiting state, the initial light emission mode of the sub display device LED is different. However, on the contrary, the light emission mode of the initial light emission of the movable effect device LED differs between when the power is turned on and when the power is restored to the customer waiting state, while the initial light emission of the sub display device LED is emitted. The modes may be the same.

Further, both the light emission mode of the initial light emission of the movable effect device LED and the light emission mode of the initial light emission of the sub display device LED may be different between when the power is turned on and when the power is restored to the customer waiting state. .. By doing so, it is possible to easily grasp whether the initial operation is the initial operation by turning on the power (the control state of the game is initialized) or the initial operation by restoring the power (the control state of the game is restored). It becomes.

The fourth feature of the board accessory initial operation pattern determination table shown in FIG. 59 (a) is that when the power is turned on, when the special symbol is displayed in a variable manner, or when the power is restored during the jackpot game. A point is that the light emission mode of the initial light emission during the initial operation of the board accessory (movable accessory 115, sub-image display unit (not shown)) is different. Therefore, it is possible to grasp whether it is the initial operation by turning on the power (the control state of the game is initialized) or the initial operation by restoring the power (the control state of the game is restored).

The fifth feature of the board accessory initial operation pattern determination table shown in FIG. 59 (a) is that it is restored when the power is restored to the customer waiting state, during the variable display of the special symbol, or during the jackpot game. It can be mentioned that the mode of initial light emission during the initial operation of the board accessory (movable accessory 115, sub-image display unit (not shown)) differs from that at the time of power restoration. Therefore, it is possible to grasp whether it is the initial operation by the power restoration that restores the customer waiting state, the fluctuation display of the special symbol, or the initial operation by the power restoration that restores during the jackpot game.

It should be noted that both the movable effect device LED and the sub display device LED are turned off when the power is restored during the variable display of the special symbol or during the jackpot game, but the movable effect device LED and the sub display are turned off. The device LED may be turned on in the same light emitting mode as when the power supply is restored to restore the customer waiting state.

The sixth feature of the board accessory initial operation pattern determination table shown in FIG. 59 (a) is that the movable accessory 115 has a return abnormality regardless of whether the power is turned on or the power is restored. If there is no return abnormality in the sub image display unit (not shown), the initial operation of the sub image display unit (not shown) is performed without performing the initial operation of the movable accessory 115, and the return abnormality occurs in the movable accessory 115. If there is a return abnormality in the sub image display unit (not shown), the initial operation of the movable accessory 115 is performed and the initial operation of the sub image display unit (not shown) is not performed. Can be mentioned. By doing so, it is possible to perform a suitable initial operation depending on the presence or absence of a return abnormality.

(Frame accessory initial operation pattern determination table)
FIG. 59B is a diagram showing a frame accessory initial operation pattern determination table that is referred to when determining the initial operation pattern of the frame accessory (effect button 161).

The frame accessory initial operation pattern determination table is associated with the type of command when the power is turned on and the initial operation pattern to be selected. For reference, the operation mode at the time of initial operation and the number of steps of initial operation are described. ing.

The "effect button large rise" is an operation in which the effect button 161 rises from the standby position (initial position) to the effect position (upper position), and the "effect button origin return" means that the effect button 161 is in the standby position. It is an operation to return to.

The first feature of the frame accessory initial operation pattern determination table shown in FIG. 59B is that when the power is turned on with the initialization of the RAM 203 and when the power is restored without the initialization of the RAM 203, the frame combination It can be mentioned that the operation mode (number of processes, operation of each process) of the initial operation of the object (effect button 161) is different. Therefore, it is possible to easily grasp whether it is the initial operation by turning on the power (the control state of the game is initialized) or the initial operation by restoring the power (the control state of the game is restored).

The second feature of the frame accessory initial operation pattern determination table shown in FIG. 59 (b) is that the initial operation of the effect button 161 when the power is turned on is not included in the initial operation of the effect button 161 when the power is restored. The point is that the operation is executed. Therefore, it is possible to more easily grasp whether it is the initial operation by turning on the power (the control state of the game is initialized) or the initial operation by restoring the power (the control state of the game is restored). ..

The operation mode (number of steps, operation of each step) of the initial operation of the effect button 161 may be the same when the power is turned on and when the power is restored. In this way, it is possible to appropriately confirm whether or not there is an abnormality in the operation of the frame accessory regardless of whether the power is turned on or restored.

The third feature of the frame accessory initial operation pattern determination table shown in FIG. 59 (b) is that the frame accessory (effect button 161) is used when the power is turned on and when the power is restored to the customer waiting state. The point that the light emission mode of the initial light emission during the initial operation is different can be mentioned. Therefore, it is possible to grasp whether it is the initial operation by turning on the power (the control state of the game is initialized) or the initial operation by restoring the power (the control state of the game is restored).

The fourth feature of the frame accessory initial operation pattern determination table shown in FIG. 59 (b) is that when the power is turned on, when the special symbol is changed, or when the power is restored during the jackpot game. It can be mentioned that the light emission mode of the initial light emission during the initial operation of the frame accessory (effect button 161) is different. Therefore, it is possible to grasp whether it is the initial operation by turning on the power (the control state of the game is initialized) or the initial operation by restoring the power (the control state of the game is restored).

The effect button LED is turned off when the power is restored during the variable display of the special symbol or during the jackpot game, but it is the same as when the power is restored to restore the effect button LED to the customer waiting state. It may be turned on in a light emitting mode.

The fifth feature of the frame accessory initial operation pattern determination table shown in FIG. 59 (b) is the number of emission colors in the initial light emission of the effect button 161 when the power is turned on and the initial light emission of the effect button 161 when the power is restored. The point is that the number of emitted colors in the above is different. Therefore, it is possible to more easily grasp whether it is the initial operation by turning on the power (the control state of the game is initialized) or the initial operation by restoring the power (the control state of the game is restored). ..

The number of emission colors in the initial emission of the effect button 161 when the power is turned on is larger than the number of emission colors in the initial emission of the effect button 161 when the power is restored, but it may be reversed.

The sixth feature of the frame accessory initial operation pattern determination table shown in FIG. 59 (b) is that the emission color of the effect button 161 when the power is turned on is the initial light emission of the effect button 161 when the power is restored. The point is that the emission color in the above is not included in the emission color. Therefore, it is possible to more easily grasp whether it is the initial operation by turning on the power (the control state of the game is initialized) or the initial operation by restoring the power (the control state of the game is restored). ..

It should be noted that the emission color in the initial emission of the effect button 161 when the power is restored may include an emission color that is not included in the emission color in the initial emission of the effect button 161 when the power is turned on.

The seventh feature of the frame accessory initial operation pattern determination table shown in FIG. 59 (b) is that the time during which the effect button 161 vibrates when the power is turned on or when the power is restored is effective during the execution of the variable effect. It is different from the time when the effect button 161 vibrates during the operation effect executed by operating the effect button 161 during the period. Therefore, it is possible to grasp that the vibration is in the initial operation of the effect button 161.

The eighth feature of the frame accessory initial operation pattern determination table shown in FIG. 59 (b) is that the initial vibration of the button vibration motor, which does not detect whether or not it is at the origin position, is at the origin position. It can be mentioned that the effect button 161 for which the presence or absence is detected is overlaid on the initial operation of the effect button 161 to be executed. Therefore, the operation confirmation of the effect button 161 and the operation confirmation of the button vibration motor can be performed at the same time, and the time required for the operation confirmation can be shortened.

(Specific example when various drive sources are initially operated while changing settings)
A specific example of the initial operation of various drive sources during the setting change will be described with reference to FIG. 60. FIG. 60 is a diagram showing a timing chart and an example of effect when various drive sources are initially operated while the setting is changed.

First, at the timing of T0, the power of the pachinko gaming machine 100 is turned off. At this time, a movable body that affects the result of the game, such as changing whether or not the game ball enters the predetermined area (second start opening 122, first large winning opening 125) (ball entry difficulty). Various drive sources (electric tulip opening / closing part 213, big winning door opening / closing part 216) for operating the electric tulip 123, the big prize opening door 125D) are in a stopped state.

Further, during the round game, the large winning opening LED that causes the large winning opening (first large winning opening 125) to emit light in a predetermined mode is turned off, and the display 130 (first special symbol display 221 and second) is turned off. Special symbol indicator 222, normal symbol indicator 223, first special symbol hold indicator 218, second special symbol hold indicator 219, ordinary symbol hold indicator 220, round number indicator 225, status indicator 224, status confirmation The display 226), the image display unit 114, and the information display 230 are in a non-display (non-operating, turning off, erasing) state.

At the timing of T1, the power switch 412 is switched from OFF to ON while the setting key switch 229 is ON and the RAM clear switch 228 is ON, and the power of the pachinko gaming machine 100 is turned ON. Even after the power of the pachinko gaming machine 100 is turned on, the RAM clear switch 228 continues to be turned on.
The setting key switch 229 is provided with a keyway (not shown). When the setting key switch 229 is OFF and a key is inserted into the setting key switch 229 and the key is rotated 90 ° clockwise, the setting key switch 229 is turned ON.
The RAM clear switch 228 is a push button. While the RAM clear switch 228 is pressed, the RAM clear switch 228 remains ON. When the RAM clear switch 228 is no longer pressed, the RAM clear switch 228 is turned off.

If the RAM clear switch 228 is in the ON state until the timing of T2 when a predetermined time (3 seconds in this example) elapses after the power of the pachinko game machine 100 is turned on, the game control unit 200 sets the setting change mode. It is in the pre-start state before it is started and the progress control of the game is started.

At this time, a status confirmation display indicating that the setting is being changed is displayed on the status confirmation display 226, and operation (drive source = ON) is started as an initial operation of various drive sources. In addition, the setting change notification (display of the setting changing screen, setting changing voice "setting is being changed" and the initial operation confirmation voice "solenoid operation" to prompt the operation confirmation of various drive sources and that the setting is being changed "Please check" (alternate output) is started. Further, the current set value (here, "6") is displayed on the 7-segment display 230d at the right end of the information display 230.

At the timing of T3, when the operating time of various drive sources (0.512 seconds in this case) elapses, the operation of various drive sources is stopped (drive source = OFF), and thereafter, various drives are performed from the timing of T3 to the timing of T10. The source is repeatedly activated and stopped.

When the RAM clear switch 228 is pressed at the timing of T7, the set value displayed on the rightmost 7-segment display 230d of the information display 230 is switched to "5". As described above, in the present embodiment, the RAM clear switch 228 is also used as a setting change switch for changing the setting value of the pachinko gaming machine 100. Further, each time the RAM clear switch 228 is pressed, a lower set value is set one by one. If the RAM clear switch 228 is pressed while the set value is "1", the set value becomes "6".

At the timing of T11, if the set value confirmation operation (setting key switch 229 is OFF) is performed in a state where the operating time of various drive sources started from the timing of T10 has not elapsed, the setting change mode and the setting change notification are sent. Upon termination, the operation of various drive sources is immediately stopped (drive source = OFF), the initial operation of various drive sources is terminated, and the set value is displayed on the 7-segment display 230d at the right end of the information display 230. finish. Then, the game control unit 200 shifts from the state before the start to the game-enabled state in which the progress control of the game is performed.

At this time, various displays (display of special symbol, display of normal symbol, display of number of reserved special figures, display of number of reserved symbols, etc.) on the display 130 are started, and the above-mentioned power-on notification is started. NS. In addition, the return operation and the initial operation of various accessories (movable accessories 115 (115a, 115b), sub-image display unit (not shown), effect button 161) controlled by the effect control unit 300 are started, and information is also provided. In the display 230, all the 7-segment displays 230a to 230d are all lit, and the lighting confirmation is started. The initial operation of various accessories ends after the lighting confirmation of the information display 230 is completed. In addition, a text notifying that the RAM 203 has been cleared is displayed on the image display unit 114.

At the timing of T12, when the confirmation time (here, 5 seconds) elapses from the start of the lighting confirmation of the information display 230, the 7-segment displays 230a to 230d are completely turned off for a predetermined time (here, 5 seconds). Then, all the lights of the 7-segment displays 230a to 230d are turned off, and the display of the performance information (here, the normal base value of the current game section) is started. After that, every time the display switching time (5 seconds) elapses, the performance information (normal base value) of the four game sections including the current game section and the past three game sections is displayed in order.

(Specific example when various drive sources are initially operated during RAM clear preparation)
A specific example of the initial operation of various drive sources during the preparation for clearing the RAM will be described with reference to FIG. 61. FIG. 61 is a diagram showing a timing chart and an production example when various drive sources are initially operated during RAM clear preparation.

First, at the timing of T0, the power of the pachinko gaming machine 100 is turned off. At this time, a movable body that affects the result of the game, such as changing whether or not the game ball enters the predetermined area (second start opening 122, first large winning opening 125) (ball entry difficulty). Various drive sources (electric tulip opening / closing part 213, big winning door opening / closing part 216) for operating the electric tulip 123, the big prize opening door 125D) are in a stopped state.

Further, during the round game, the large winning opening LED that causes the large winning opening (first large winning opening 125) to emit light in a predetermined mode is turned off, and the display 130 (first special symbol display 221 and second) is turned off. Special symbol indicator 222, normal symbol indicator 223, first special symbol hold indicator 218, second special symbol hold indicator 219, ordinary symbol hold indicator 220, round number indicator 225, status indicator 224, status confirmation The display 226), the image display unit 114, and the information display 230 are in a non-display (non-operating, turning off, erasing) state.

When the RAM clear operation (RAM clear switch 228 is ON) is performed when the power of the pachinko gaming machine 100 is turned on at the timing of T1, the game control unit 200 starts the RAM clear preparation mode to control the progress of the game. It will be in the pre-start state before it is started.

At this time, the status confirmation display 226 displays a status confirmation display indicating that the RAM is being prepared for clearing, and an operation (drive source = ON) is started as an initial operation of various drive sources. In addition, the RAM clear preparation is being prepared and the RAM clear preparation notification (display of the clear preparation screen, "Please press RAM clear again" and "Confirm the operation of the solenoid" are confirmed to prompt the operation confirmation of various drive sources. (Alternative output of the initial operation confirmation voice) of "Please" is started.

At the timing of T2, when the operation time (0.512 seconds in this case) elapses from the start of operation of the various drive sources, the operation of the various drive sources is stopped (drive source = OFF), and thereafter, the timing of T3 to the timing of T10. The operation and stop of various drive sources are repeated until.

At the timing of T10, if the RAM clear approval operation (RAM clear switch 228 is ON) is performed in a state where the operating time of various drive sources started from the timing of T9 has not elapsed, the RAM clear preparation mode and the RAM clear preparation are performed. When the notification ends, the operation of the various drive sources is immediately stopped (drive source = OFF), the initial operation of the various drive sources ends, and the game control unit 200 controls the progress of the game from the state before the start. Move to the possible state.

At this time, various displays (display of special symbol, display of normal symbol, display of number of reserved special figures, display of number of reserved symbols, etc.) on the display 130 are started, and the above-mentioned power-on notification is started. NS. In addition, the return operation and the initial operation of various accessories (movable accessories 115 (115a, 115b), sub-image display unit (not shown), effect button 161) controlled by the effect control unit 300 are started, and information is also provided. In the display 230, all the 7-segment displays 230a to 230d are all lit, and the lighting confirmation is started. The initial operation of the movable accessory 115 ends after the lighting confirmation of the information display 230 is completed. In addition, a text notifying that the RAM 203 has been cleared is displayed on the image display unit 114.

At the timing of T11, when the confirmation time (here, 5 seconds) elapses from the start of the lighting confirmation of the information display 230, the 7-segment displays 230a to 230d are completely turned off for a predetermined time (here, 5 seconds). Then, all the lights of the 7-segment displays 230a to 230d are turned off, and the display of the performance information (here, the normal base value of the current game section) is started. After that, every time the display switching time (5 seconds) elapses, the performance information (normal base value) of the four game sections including the current game section and the past three game sections is displayed in order.

The RAM clearing method is not limited to the above example.
With the RAM clear switch 228 ON, the power switch 412 is switched from OFF to ON, and the power of the pachinko gaming machine 100 is turned ON. Then, when a predetermined time (for example, 3 seconds) elapses while the RAM clear switch 228 is ON, the RAM 203 may be cleared. At this time, all the 7-segment displays 230a to 230d are all lit on the information display 230, and the lighting confirmation is started. When the confirmation time (5 seconds in this case) elapses from the start of the lighting confirmation of the information display 230, the 7-segment displays 230a to 230d are completely turned off for a predetermined time (5 seconds in this case). Then, all the lights of the 7-segment displays 230a to 230d are turned off, and the display of the performance information (here, the normal base value of the current game section) is started. When the RAM 203 is cleared, the image display unit 114 displays a text notifying that the RAM 203 has been cleared.

(Specific example when various drive sources are initially operated during setting confirmation)
A specific example of the initial operation of various drive sources during the setting confirmation will be described with reference to FIG. 62. FIG. 62 is a diagram showing a timing chart and an production example when various drive sources are initially operated during setting confirmation.

First, at the timing of T0, the power of the pachinko gaming machine 100 is turned off. At this time, a movable body that affects the result of the game, such as changing whether or not the game ball enters the predetermined area (second start opening 122, first large winning opening 125) (ball entry difficulty). Various drive sources (electric tulip opening / closing part 213, big winning door opening / closing part 216) for operating the electric tulip 123, the big prize opening door 125D) are in a stopped state.

Further, during the round game, the large winning opening LED that causes the large winning opening (first large winning opening 125) to emit light in a predetermined mode is turned off, and the display 130 (first special symbol display 221 and second) is turned off. Special symbol indicator 222, normal symbol indicator 223, first special symbol hold indicator 218, second special symbol hold indicator 219, ordinary symbol hold indicator 220, round number indicator 225, status indicator 224, status confirmation The display 226), the image display unit 114, and the information display 230 are in a non-display (non-operating, turning off, erasing) state.

At the timing of T1, when the power switch 412 is switched from OFF to ON and the setting confirmation operation (setting key switch 229 is ON) is performed when the power of the pachinko gaming machine 100 is turned ON, the game control unit 200 is in the setting confirmation mode. Is started and the state before the start is set before the progress control of the game is started.
In addition, a text notifying that the set value of the pachinko gaming machine 100 is being confirmed is displayed on the image display unit 114. Further, an image imitating the effect button 161 is displayed on the image display unit 114.

At this time, a status confirmation display indicating that the setting is being confirmed is displayed on the status confirmation display 226, and operation (drive source = ON) is started as an initial operation of various drive sources. In addition, the setting confirmation notification (display of the setting confirmation screen, setting confirmation voice "setting is being confirmed" and the initial operation confirmation voice "solenoid operation" is also being performed to prompt the operation confirmation of various drive sources. "Please check" (alternate output) is started. Further, the current set value (here, "6") is displayed on the 7-segment display 230d at the right end of the information display 230.
Further, when the effect button 161 is operated, the setting history screen is displayed on the image display unit 114. The setting history screen is a screen showing the history of the setting values of the pachinko gaming machine 100. On the setting history screen, "No", "content", and "date and time" are shown. "Content" indicates whether the setting change mode or the setting confirmation mode has been performed. Further, when the setting change mode is performed, the changed setting value is shown in "Content". Further, when the setting confirmation mode is performed, the setting value when the setting confirmation mode is performed is shown in "Content". Further, the "date and time" indicates the date and time when either the setting change mode or the setting confirmation mode is performed. Here, the smaller the "No", the newer the "date and time". Further, if the effect button 161 is operated while the setting history screen is displayed, the text notifying that the setting value of the pachinko gaming machine 100 is being confirmed is displayed again on the image display unit 114. ..
The setting history screen may be displayed during the setting change mode.

At the timing of T2, when the operation time (0.512 seconds in this case) elapses from the start of operation of the various drive sources, the operation of the various drive sources is stopped (drive source = OFF), and thereafter, the timing of T3 to the timing of T10. The operation and stop of various drive sources are repeated until.

At the timing of T10, if the confirmation end operation (setting key switch 229 is OFF) is performed while the operating time of various drive sources started from the timing of T9 has not elapsed, the setting confirmation mode and the setting confirmation notification are completed. At the same time, the operation of the various drive sources is immediately stopped (drive source = OFF), the initial operation of the various drive sources is completed, and the display of the set value on the 7-segment display 230d at the right end of the information display 230 is also completed. do. Then, the game control unit 200 shifts from the state before the start to the game-enabled state in which the progress control of the game is performed.

At this time, various displays (display of special symbol, display of normal symbol, display of number of reserved special figures, display of number of reserved symbols, etc.) on the display 130 are started, and the above-mentioned power restoration notification is started. NS. In addition, the return operation and the initial operation of various accessories (movable accessory 115, sub-image display unit (not shown), effect button 161) controlled by the effect control unit 300 are started, and all of them are displayed on the information display 230. The 7-segment displays 230a to 230d are all lit and the lighting confirmation is started. The initial operation of the movable accessory 115 ends after the lighting confirmation of the information display 230 is completed.

At the timing of T11, when the confirmation time (here, 5 seconds) elapses from the start of the lighting confirmation of the information display 230, the 7-segment displays 230a to 230d are completely turned off for a predetermined time (here, 5 seconds). Then, all the lights of the 7-segment displays 230a to 230d are turned off, and the display of the performance information (here, the normal base value of the current game section) is started. After that, every time the display switching time (5 seconds) elapses, the performance information (normal base value) of the four game sections including the current game section and the past three game sections is displayed in order.

As described above, according to the present embodiment, in order to operate the movable body (electric tulip 123, grand prize opening door 125D) that affects the result of the game in the state before the start before the progress control of the game is started. Since the various drive sources (electric tulip opening / closing part 213, grand prize opening door opening / closing part 216) are initially operated, the progress of the game when the pachinko gaming machine 100 is shipped from the factory or replaced at a game store. It is possible to easily confirm the operation of the drive source controlled by the main control means for controlling.

Further, according to the present embodiment, when various drive sources for operating the movable body that affect the result of the game are initially operated (during the state before the start), the display excluding the state confirmation indicator 226 is displayed. Instrument 130 (1st special symbol display 221, 2nd special symbol display 222, normal symbol display 223, 1st special symbol hold indicator 218, 2nd special symbol hold indicator 219, normal symbol hold indicator 220, Since the round number indicator 225 and the status indicator 224) are in a non-display (non-operating) state, it is possible to prevent an extra processing load from being given to the game control unit 200, and to check the operation of various drive sources. It becomes possible to concentrate on.

Further, according to the present embodiment, when the various drive sources for operating the movable body that affect the result of the game are initially operated, the setting is being changed and the operation confirmation of the various drive sources is urged. Setting change notification for (RAM clear preparation notification for prompting RAM clear preparation and operation confirmation of various drive sources, setting confirmation notification for setting confirmation and operation confirmation of various drive sources) Therefore, it is possible to inform the workers (workers, game clerk) who check the operation of the pachinko gaming machine 100 that it is time to check the operation of various drive sources, and check the operation appropriately. Can be done.

Further, according to the present embodiment, in the setting change mode (RAM clear preparation mode, setting confirmation mode), various drive sources for operating the movable body that affects the result of the game are initially operated. It is not necessary to create a plurality of states in the pre-start state before the game progress control is started, and it is possible to reduce the development cost of the pachinko gaming machine 100 (shorten the development period, etc.).

Further, according to the present embodiment, when the set value confirmation operation (RAM clear approval operation, confirmation end operation) is performed and the pre-start state ends, the operation time of various drive sources is immediately before elapse. Since the operation of various drive sources is terminated, the initial operation of various drive sources is no longer performed in a game-enabled state, and it may be confused with the operation of various drive sources according to the progress of the game. It is possible to avoid inconvenience.

Further, according to the present embodiment, the progress control of the game is performed by performing the initial operation of various drive sources for operating the movable body that affects the result of the game in the state before the start before the progress control of the game is performed. Since the initial operation of the movable accessory 115 that does not affect the result of the game is performed in the playable state to be performed, two types of initial operations can be confirmed in order, and the operation is appropriately confirmed. It becomes possible.

Further, according to the present embodiment, when the various drive sources for operating the large winning opening door 125D are initially operated, the large winning opening LED is left off, so that the light from the large winning opening LED is turned off. This makes it possible to avoid inconveniences such as difficulty in confirming the operation of the large winning door 125D, and it is possible to appropriately confirm the operation.

Further, according to the present embodiment, when various drive sources for operating the large winning opening door 125D are initially operated, an opening signal is output even though the first large winning opening 125 is open. Since it is not output, it is possible to prevent an extra processing load from being given to the game control unit 200, and an information collecting device such as a hall computer that collects information output from the pachinko game machine 100 is used for the game. It is possible to avoid inconveniences such as collecting information that does not correspond to the progress of.

Further, according to the present embodiment, the performance information (normal base value) of the gaming machine is not displayed on the information display 230 from the power-on of the gaming machine to the start of the progress control of the game (the display of the performance information is displayed). Since it is regulated), it is possible to prevent the game control unit 200 from being given an extra processing load.

Further, according to the present embodiment, the performance information (normal base value) of the gaming machine is displayed (display of the performance information is permitted) after the progress control of the game is started. It is possible to confirm whether or not the progress control of the game has been started, and to inform that the performance information is related to the game.

Further, according to the present embodiment, the performance information is not displayed on the 7-segment displays 230a to 230c other than the 7-segment display 230d on which the current setting value is displayed in the setting change mode or the setting confirmation mode. As a result, the current set value can be appropriately notified, and the convenience on the amusement store side can be ensured.

In this embodiment, in the setting change notification, RAM clear preparation notification, and setting confirmation notification, "during the initial operation of the drive source" or "check the operation of the solenoid" that prompts the visual confirmation of the initial operation of various drive sources. Etc. were not displayed, but such characters may be displayed.

Further, in the present embodiment, after the progress control of the game is started, all the 7-segment displays 230a to 230d of the information display 230 are turned on to confirm the lighting. After the RAM clear preparation mode or the setting confirmation mode, the lighting confirmation may not be performed.

(Modification example when various drive sources are initially operated)
Hereinafter, a modification of the initial operation of various drive sources will be specifically described with reference to the drawings. Note that this modification differs from the above embodiment in that the drive source processing operation processing is performed after the setting change mode, the RAM clear preparation mode, and the setting confirmation mode are completed.

(Specific example when various drive sources are initially operated after changing the settings)
A specific example of the case where various drive sources are initially operated after the setting is changed in the modified example will be described with reference to FIG. 63. FIG. 63 is a diagram showing a timing chart and an effect example when various drive sources are initially operated after the setting is changed in the modified example.

First, at the timing of T0, the power of the pachinko gaming machine 100 is turned off. At this time, a movable body that affects the result of the game, such as changing whether or not the game ball enters the predetermined area (second start opening 122, first large winning opening 125) (ball entry difficulty). Various drive sources (electric tulip opening / closing part 213, big winning door opening / closing part 216) for operating the electric tulip 123, the big prize opening door 125D) are in a stopped state.

Further, during the round game, the large winning opening LED that causes the large winning opening (first large winning opening 125) to emit light in a predetermined mode is turned off, and the display 130 (first special symbol display 221 and second) is turned off. Special symbol indicator 222, normal symbol indicator 223, first special symbol hold indicator 218, second special symbol hold indicator 219, ordinary symbol hold indicator 220, round number indicator 225, status indicator 224, status confirmation The display 226), the image display unit 114, and the information display 230 are in a non-display (non-operating, turning off, erasing) state.

At the timing of T1, when the setting change operation (setting key switch 229 is ON, RAM clear switch 228 is ON) is performed when the power of the pachinko gaming machine 100 is turned on, the setting change mode is started in the game control unit 200. It becomes the state before the start before the progress control of the game is started. At this time, a status confirmation display indicating that the setting is being changed is displayed on the status confirmation display 226, and the setting change notification described above is started. Further, the current set value (here, "6") is displayed on the 7-segment display 230d at the right end of the information display 230.

When the set value confirmation operation (setting key switch 229 is OFF) is performed at the timing of T2, the setting change mode and the setting change notification are terminated, the initial operation of various drive sources is started, and the right end of the information display 230 is used. The set value displayed on the 7-segment display 230d is erased and hidden. At this time, the status confirmation display on the status confirmation display 226 ends, and the initial operation notification for prompting the operation confirmation of various drive sources (display of the initial operation screen, initial operation confirmation voice "Check the operation of the solenoid" Please output) is started.

At the timing of T3, when the operation standby time (7 seconds in this case) elapses after the initial operation notification is started, the first operation of various drive sources (drive source = ON) is started, and at the timing of T4, various types are started. When the operation time of the drive source (0.512 seconds in this case) elapses, the operation of various drive sources is stopped (drive source = OFF).

At the timing of T5, when the stop time (0.512 seconds in this case) elapses after the operation of the various drive sources is stopped, the second operation of the various drive sources is started, and at the timing of T6, the various drive sources When the operating time (0.512 seconds in this case) elapses, the operation of various drive sources is stopped (drive source = OFF).

At the timing of T7, when the stop time (0.512 seconds in this case) elapses after the operation of the various drive sources is stopped, the third operation of the various drive sources is started, and at the timing of T8, the various drive sources When the operating time (0.512 seconds in this case) elapses, the operation of various drive sources is stopped (drive source = OFF).

At the timing of T9, when the stop time (0.512 seconds in this case) elapses after the operation of the various drive sources is stopped, the initial operation and the initial operation notification of the various drive sources are completed, and the game control unit 200 is before the start. The state shifts to a game-enabled state in which the progress of the game is controlled.

At this time, various displays (display of special symbol, display of normal symbol, display of number of reserved special figures, display of number of reserved symbols, etc.) on the display 130 are started, and the above-mentioned power-on notification is started. NS. In addition, the return operation and the initial operation of various accessories (movable accessory 115, sub-image display unit (not shown), effect button 161) controlled by the effect control unit 300 are started, and all of them are displayed on the information display 230. The 7-segment displays 230a to 230d are all lit and the lighting confirmation is started. The initial operation of various accessories ends after the lighting confirmation of the information display 230 is completed.

At the timing of T10, when the confirmation time (5 seconds in this case) elapses from the start of the lighting confirmation of the information display 230, all the lighting of the 7-segment displays 230a to 230d is completed and the performance information (here, the current one) is completed. The display of the normal base value of the game section) is started. After that, every time the display switching time (5 seconds) elapses, the performance information (normal base value) of the four game sections including the current game section and the past three game sections is displayed in order.

(Specific example when various drive sources are initially operated after clearing RAM)
A specific example of the case where various drive sources are initially operated after the RAM is cleared in the modified example will be described with reference to FIG. 64. FIG. 64 is a diagram showing a timing chart and an production example when various drive sources are initially operated after the RAM is cleared in the modified example.

First, at the timing of T0, the power of the pachinko gaming machine 100 is turned off. At this time, a movable body that affects the result of the game, such as changing whether or not the game ball enters the predetermined area (second start opening 122, first large winning opening 125) (ball entry difficulty). Various drive sources (electric tulip opening / closing part 213, big winning door opening / closing part 216) for operating the electric tulip 123, the big prize opening door 125D) are in a stopped state.

Further, during the round game, the large winning opening LED that causes the large winning opening (first large winning opening 125) to emit light in a predetermined mode is turned off, and the display 130 (first special symbol display 221 and second) is turned off. Special symbol indicator 222, normal symbol indicator 223, first special symbol hold indicator 218, second special symbol hold indicator 219, ordinary symbol hold indicator 220, round number indicator 225, status indicator 224), image The display unit 114 and the information display 230 are in a non-display (non-operating, turning off, erasing) state.

When the RAM clear operation (RAM clear switch 228 is ON) is performed when the power of the pachinko gaming machine 100 is turned on at the timing of T1, the game control unit 200 starts the RAM clear preparation mode to control the progress of the game. It will be in the pre-start state before it is started. At this time, the RAM clear preparation notification described above is started.

When the RAM clear approval operation (RAM clear switch 228 is ON) is performed at the timing of T2, the RAM clear preparation mode ends and the initial operation of various drive sources is started. At this time, the initial operation notification (display of the initial operation screen, output of the initial operation confirmation voice of "Please confirm the operation of the solenoid") for prompting the operation confirmation of various drive sources is started.

At the timing of T3, when the operation standby time (7 seconds in this case) elapses after the initial operation notification is started, the first operation of various drive sources (drive source = ON) is started, and at the timing of T4, various types are started. When the operation time of the drive source (0.512 seconds in this case) elapses, the operation of various drive sources is stopped (drive source = OFF).

At the timing of T5, when the stop time (0.512 seconds in this case) elapses after the operation of the various drive sources is stopped, the second operation of the various drive sources is started, and at the timing of T6, the various drive sources When the operating time (0.512 seconds in this case) elapses, the operation of various drive sources is stopped (drive source = OFF).

At the timing of T7, when the stop time (0.512 seconds in this case) elapses after the operation of the various drive sources is stopped, the third operation of the various drive sources is started, and at the timing of T8, the various drive sources When the operating time (0.512 seconds in this case) elapses, the operation of various drive sources is stopped (drive source = OFF).

At the timing of T9, when the stop time (0.512 seconds in this case) elapses after the operation of the various drive sources is stopped, the initial operation and the initial operation notification of the various drive sources are completed, and the game control unit 200 is before the start. The state shifts to a game-enabled state in which the progress of the game is controlled.

At this time, various displays (display of special symbol, display of normal symbol, display of number of reserved special figures, display of number of reserved symbols, etc.) on the display 130 are started, and the above-mentioned power-on notification is started. NS. In addition, the return operation and the initial operation of various accessories (movable accessory 115, sub-image display unit (not shown), effect button 161) controlled by the effect control unit 300 are started, and all of them are displayed on the information display 230. The 7-segment displays 230a to 230d are all lit and the lighting confirmation is started. The initial operation of various accessories ends after the lighting confirmation of the information display 230 is completed.

At the timing of T10, when the confirmation time (5 seconds in this case) elapses from the start of the lighting confirmation of the information display 230, all the lighting of the 7-segment displays 230a to 230d is completed and the performance information (here, the current one) is completed. The display of the normal base value of the game section) is started. After that, every time the display switching time (5 seconds) elapses, the performance information (normal base value) of the four game sections including the current game section and the past three game sections is displayed in order.

(Specific example when various drive sources are initially operated after confirming the settings)
A specific example of the case where various drive sources are initially operated after confirming the settings in the modified example will be described with reference to FIG. 65. FIG. 65 is a diagram showing a timing chart and an effect example when various drive sources are initially operated after confirming the settings in the modified example.

First, at the timing of T0, the power of the pachinko gaming machine 100 is turned off. At this time, a movable body that affects the result of the game, such as changing whether or not the game ball enters the predetermined area (second start opening 122, first large winning opening 125) (ball entry difficulty). Various drive sources (electric tulip opening / closing part 213, big winning door opening / closing part 216) for operating the electric tulip 123, the big prize opening door 125D) are in a stopped state.

Further, during the round game, the large winning opening LED that causes the large winning opening (first large winning opening 125) to emit light in a predetermined mode is turned off, and the display 130 (first special symbol display 221 and second) is turned off. Special symbol indicator 222, normal symbol indicator 223, first special symbol hold indicator 218, second special symbol hold indicator 219, ordinary symbol hold indicator 220, round number indicator 225, status indicator 224, status confirmation The display 226), the image display unit 114, and the information display 230 are in a non-display (non-operating, turning off, erasing) state.

At the timing of T1, when the setting confirmation operation (setting key switch 229 is ON) is performed when the power of the pachinko gaming machine 100 is turned on, the game control unit 200 starts the setting confirmation mode and starts the game progress control. It becomes the state before the start before it is done. At this time, a status confirmation display indicating that the setting is being confirmed is displayed on the status confirmation display 226, and the setting confirmation notification described above is started. Further, the current set value (here, "6") is displayed on the 7-segment display 230d at the right end of the information display 230.

When the confirmation end operation (setting key switch 229 is OFF) is performed at the timing of T2, the setting confirmation mode and the setting confirmation notification are terminated, the initial operations of various drive sources are started, and the 7 at the right end of the information display 230 is started. The set value displayed on the segment display 230d is erased and hidden. At this time, the status confirmation display on the status confirmation display 226 ends, and the initial operation notification for prompting the operation confirmation of various drive sources (display of the initial operation screen, initial operation confirmation voice "Check the operation of the solenoid" Please output) is started.

At the timing of T3, when the operation standby time (7 seconds in this case) elapses after the initial operation notification is started, the first operation of various drive sources (drive source = ON) is started, and at the timing of T4, various types are started. When the operation time of the drive source (0.512 seconds in this case) elapses, the operation of various drive sources is stopped (drive source = OFF).

At the timing of T5, when the stop time (0.512 seconds in this case) elapses after the operation of the various drive sources is stopped, the second operation of the various drive sources is started, and at the timing of T6, the various drive sources When the operating time (0.512 seconds in this case) elapses, the operation of various drive sources is stopped (drive source = OFF).

At the timing of T7, when the stop time (0.512 seconds in this case) elapses after the operation of the various drive sources is stopped, the third operation of the various drive sources is started, and at the timing of T8, the various drive sources When the operating time (0.512 seconds in this case) elapses, the operation of various drive sources is stopped (drive source = OFF).

At the timing of T9, when the stop time (0.512 seconds in this case) elapses after the operation of the various drive sources is stopped, the initial operation and the initial operation notification of the various drive sources are completed, and the game control unit 200 is before the start. The state shifts to a game-enabled state in which the progress of the game is controlled.

At this time, various displays (display of special symbol, display of normal symbol, display of number of reserved special figures, display of number of reserved symbols, etc.) on the display 130 are started, and the above-mentioned power-on notification is started. NS. In addition, the return operation and the initial operation of various accessories (movable accessory 115, sub-image display unit (not shown), effect button 161) controlled by the effect control unit 300 are started, and all of them are displayed on the information display 230. The 7-segment displays 230a to 230d are all lit and the lighting confirmation is started. The initial operation of various accessories ends after the lighting confirmation of the information display 230 is completed.

At the timing of T10, when the confirmation time (5 seconds in this case) elapses from the start of the lighting confirmation of the information display 230, all the lighting of the 7-segment displays 230a to 230d is completed and the performance information (here, the current one) is completed. The display of the normal base value of the game section) is started. After that, every time the display switching time (5 seconds) elapses, the performance information (normal base value) of the four game sections including the current game section and the past three game sections is displayed in order.

As described above, according to this modification, in order to operate the movable body (electric tulip 123, grand prize opening door 125D) that affects the result of the game in the state before the start before the progress control of the game is started. Since the various drive sources (electric tulip opening / closing part 213, grand prize opening door opening / closing part 216) are initially operated, the progress of the game when the pachinko gaming machine 100 is shipped from the factory or replaced at a game store. It is possible to easily confirm the operation of the drive source controlled by the main control means for controlling.

Further, according to this modification, when various drive sources for operating the movable body that affect the result of the game are initially operated (during the state before the start), the display excluding the state confirmation indicator 226 is displayed. Instrument 130 (1st special symbol display 221, 2nd special symbol display 222, normal symbol display 223, 1st special symbol hold indicator 218, 2nd special symbol hold indicator 219, normal symbol hold indicator 220, Since the round number indicator 225 and the status indicator 224) are in a non-display (non-operating) state, it is possible to prevent an extra processing load from being given to the game control unit 200, and to check the operation of various drive sources. It becomes possible to concentrate on.

Further, according to this modification, when various drive sources for operating a movable body that affect the result of the game are initially operated, initial operation notification is performed to prompt confirmation of the operation of the various drive sources. Therefore, it is possible to inform the workers (workers, game clerk) who check the operation of the pachinko gaming machine 100 that it is time to check the operation of various drive sources, and check the operation appropriately. It becomes possible to make it.

Further, according to this modification, even if the state is before the start of the game progress control, the result of the game is affected after the setting change mode (RAM clear preparation mode, setting confirmation mode) is completed. Since various drive sources for operating the given movable body are initially operated, it is not necessary to check the operation of various drive sources while changing the settings (RAM clear, setting confirmation). , It is possible to properly check the operation.

Further, according to this modification, various drive sources for operating a movable body that affects the result of the game after the operation standby time has passed after the setting change mode (RAM clear preparation mode, setting confirmation mode) is completed. Since the operation is started, it is possible to allow time from the completion of the setting change (setting confirmation) to the operation confirmation of various drive sources, and the operation confirmation should be performed appropriately. Is possible.

Further, according to this modification, whether the initial operation of various drive sources for operating the movable body that affects the result of the game is after the end of the setting change mode or after the end of the RAM clear preparation mode. Since the same initial operation notification is performed regardless of whether the setting confirmation mode is completed, the control of the initial operation notification can be simplified, and the development cost of the pachinko gaming machine 100 is high. (Reduction of development period, etc.) can be achieved.

Further, according to this modification, when the various drive sources for operating the large winning opening door 125D are initially operated, the large winning opening LED is left off, so that the light from the large winning opening LED is turned off. This makes it possible to avoid inconveniences such as difficulty in confirming the operation of the large winning door 125D, and it is possible to appropriately confirm the operation.

Further, according to this modification, the progress control of the game is performed by performing the initial operation of various drive sources for operating the movable body that affects the result of the game in the state before the start before the progress control of the game is performed. Since the initial operation of the movable accessory 115 that does not affect the result of the game is performed in the playable state to be performed, two types of initial operations can be confirmed in order, and the operation is appropriately confirmed. It becomes possible.

Further, according to this modification, when various drive sources for operating the large winning opening door 125D are initially operated, the opening signal is output even though the first large winning opening 125 is open. Since it is not output, it is possible to prevent an extra processing load from being given to the game control unit 200, and an information collecting device such as a hall computer that collects information output from the pachinko game machine 100 is used for the game. It is possible to avoid inconveniences such as collecting information that does not correspond to the progress of.

Further, according to this modification, the performance information (normal base value) of the gaming machine is not displayed on the information display 230 from the power-on of the gaming machine to the start of the progress control of the game (the display of the performance information is displayed). Since it is regulated), it is possible to prevent the game control unit 200 from being given an extra processing load.

Further, according to this modification, the performance information (normal base value) of the gaming machine is displayed (display of the performance information is allowed) after the progress control of the game is started. It is possible to confirm whether or not the progress control of the game has been started, and to inform that the performance information is related to the game.

Further, according to this modification, in the setting change mode, the RAM clear preparation mode, or the setting confirmation mode, the 7-segment displays 230a to 230c other than the 7-segment display 230d on which the current setting value is displayed are displayed. However, by not displaying the performance information, the current set value can be appropriately notified, and the convenience on the amusement shop side can be ensured.

Further, according to this modification, the information display 230 does not display the set value or the performance information of the gaming machine during the initial operation of the various drive sources, so that the initial operation of the various drive sources can be confirmed. On the other hand, it is possible to concentrate the consciousness of the employees of the amusement shop, and it is possible to accurately judge the failure of various drive sources.

Further, in the above-described embodiment, when a jackpot is determined in the jackpot determination, a jackpot game is performed, and a gaming machine in which the gaming state is changed via the jackpot game has been described. In another embodiment, even if it is not determined to be a big hit, the low-probability time-saving non-game state may be shifted to the time-saving game state. For example, when the number of fluctuations of a special symbol (the number of consecutive times determined to be lost in the jackpot determination) in the low-probability time-saving no-game state reaches a predetermined upper limit number (for example, 900 times), the fluctuation is determined to be a jackpot. Even if it is not, the player may shift to the time-saving gaming state for a predetermined number of times (for example, 50 times, or 100 times or more). In this case, if the special symbol does not become a big hit by the time the special symbol fluctuates a predetermined number of times, the time-saving game state ends and the game returns to the low-probability time-saving non-game state. Alternatively, even if the result of the jackpot judgment is a loss (that is, even if the random number value for the special symbol lottery acquired at the time of winning the starting port is a value indicating a loss), the special symbol acquired at the time of winning When the random number value for the lottery (big hit symbol random value) is a predetermined value, the player may shift to the time-saving game state for a predetermined number of times. Further, in the case of shifting to the time-saving gaming state based on the number of fluctuations of the special symbol, the predetermined upper limit number of times may be variable or fixed. For example, when the predetermined upper limit number of times is variable, the time saving game state is given when the number of times the special symbol changes becomes the first number, and the number of times the special symbol changes becomes the second number. In some cases, a time-saving game state may be granted. In this case, the number of time reductions given may be different according to the number of fluctuations of the special symbol, and the larger the number of fluctuations, the larger the number of time reductions may be set. Further, in the case of shifting to the time saving game state based on the jackpot symbol random value, the number of time saving given may be different depending on the acquired jackpot symbol random value. For example, when the acquired jackpot symbol random value is the first value, the first time reduction number is given, and when the acquired jackpot symbol random value is the second value, the second time reduction number is given. May be done. Further, there may be a case where the player shifts to the time-saving game state based on the number of fluctuations of the special symbol, or a case where the player shifts to the time-saving game state based on the jackpot symbol random value. In this case, the number of time reductions to be given may be different between the case of shifting to the time saving game state based on the number of fluctuations of the special symbol and the case of shifting to the time saving gaming state based on the jackpot symbol random value. For example, when shifting to the time-saving game state based on the number of fluctuations of the special symbol, the time-saving game state is shifted to 50 times, and when shifting to the time-saving game state based on the jackpot symbol random value, it is more than that. It is possible to shift to a time-saving game state of less than 30 times. On the contrary, the number of time reductions may be increased in the case of shifting to the time saving game state based on the jackpot symbol random value than in the case of shifting to the time saving game state based on the number of fluctuations of the special symbol. In addition, in the case of shifting to the time-saving game state without going through the jackpot in this way, if the time-saving game state is further granted during the shifted time-saving game state without going through the jackpot, a new time-saving game state is granted. The time-saving game state may be continued for the number of time-saving times given to. For example, if 50 times of time saving game state is given without going through the jackpot, and when the special symbol fluctuates 30 times in the time saving game state, 50 times of time saving game state is given without going through the big hit. You may shift to the time saving game state of 50 times. Alternatively, in this case, the number of time reductions may be added. For example, if 50 times of time saving game state is given without going through the jackpot, and when the special symbol fluctuates 30 times in the time saving game state, 50 times of time saving game state is given without going through the big hit. In addition to the remaining 20 times, 50 times newly granted may be added, and 70 times of time saving game state may be given. Further, during such a time-saving game state that does not go through the jackpot, the time-saving game state that does not go through the big hit may not be given. Further, in a configuration in which the transition to the time-saving gaming state is performed based on the number of fluctuations of the special symbol or the jackpot symbol random value without going through the jackpot, a time-saving suggestion effect suggesting the transition to the time-saving gaming state may be performed. For example, when the number of fluctuations of the special symbol is close to the above-mentioned upper limit number of times, the time saving suggestion effect may be easily executed. On the contrary, when the number of fluctuations of the special symbol is close to the above-mentioned upper limit number of times, the time saving suggestion effect may be difficult to be performed.

Although various effects of the pachinko game machine 100 have been described above, it is possible to apply or combine all or part of the described contents to other effects, controls, etc., even if there is no particular mention. In addition, although various embodiments and modifications have been mentioned, it is possible to apply or combine the contents of the embodiments and modifications to other productions, etc., even if this document is not mentioned. .. In addition, it is possible to combine various embodiments and modifications, or to replace some of them, even if not mentioned in this document.

4 ... Power supply board unit, 40 ... Power supply board, 60 ... Power supply board case 60, 100 ... Pachinko game machine, 114 ... Image display unit, 200 ... Game control unit, 300 ... Production control unit

Claims (1)

A board that has multiple electronic components and is used for games,
The accommodation means for accommodating the substrate is provided.
The substrate is
An AC circuit to which AC voltage is supplied and
A DC circuit to which a DC voltage converted from an AC voltage is supplied, and
The first identification display, which is a display for identifying information, and
It is a display for identifying information, and has a second identification display provided at a position different from the first identification display in the thickness direction of the substrate.
A gaming machine characterized in that capacitors are provided in the AC circuit and the DC circuit, respectively.

Images