JP6372883B2 - Game machine - Google Patents

Description

  The present invention relates to a gaming machine.

A gaming machine is usually provided with an operation unit operated by a player.
As a specific example, when the gaming machine is a slot machine, there are a bet button for placing a credit medal in the game, a start lever for starting the rotation of the reel, a stop button for stopping the rotation of the reel, etc. As provided.
Some of these operation units have built-in light emitting elements such as LEDs that emit light at a predetermined timing.
Some light emitting elements emit one color, but some emit multiple colors such as a full color LED. In the operation unit including the full-color LED, light can be emitted in different colors according to the progress of the game (for example, Patent Document 1).

JP 2014-28271 A

  However, the conventional gaming machine has room for improvement.

  The gaming machine of the present invention is a gaming machine including a plurality of light emitting devices having predetermined light emitting elements and a control unit that controls lighting of the light emitting elements, and each of the plurality of light emitting devices has a different light emission color. The control unit has a plurality of light emitting elements, and includes a first control circuit that controls lighting of the light emitting elements for each light emitting device, and a second control circuit that controls lighting of the light emitting elements for each color, Is configured to control lighting by dividing a plurality of light emitting elements provided in each of the plurality of light emitting devices in units of colors.

It is a front view which shows the structure of a slot machine. It is a figure which shows the internal structure of a slot machine. It is a circuit diagram which shows the structure of a main control part and a stop button apparatus. It is a chart which shows the stop button which lights up, and the color which lights up based on the combination of the color (system | group) of the light emitting element selected by the selection circuit of a main control part, and the light-emitting device selected by a drive circuit. It is a circuit diagram which shows the structure of a main control part, a stop button apparatus, and a MAX bet button. It is a circuit diagram which shows the structure of the main control part provided with the memory | storage part and the displacement detection circuit, and a stop button apparatus. It is a circuit diagram which shows the structure of the conventional main control part and a stop button apparatus. FIG. 8 is a circuit diagram illustrating a configuration of a conventional main control unit and a stop button device, which is different from FIG. 7.

  Hereinafter, preferred embodiments of a gaming machine according to the present invention will be described with reference to the drawings.

[Game machine]
There are various types of gaming machines including a light emitting device having a plurality of light emitting elements, such as a slot machine, a pachinko machine, and a parrot. In this embodiment, a case where the present invention is applied to a slot machine will be described.

The slot machine of the present embodiment is configured as a revolving game machine that can acquire a medal as a game value by rotating a plurality of reels, and a light-emitting device having a plurality of light-emitting elements, and lighting those light-emitting elements And a controller for controlling the lighting of the light-emitting elements for each light-emitting device, and systematically controlling the lighting for each color unit.
Hereinafter, the slot machine according to the present embodiment will be described in detail.

  As shown in FIGS. 1 and 2, the slot machine 1 of the present embodiment bets from the number of medals actually inserted from the medal slot 2 (for example, three), or from credit medals stored internally. When the button 30 is operated, the game can be started according to the number of medals (for example, 3) inserted in the signal format. When the start lever 3 is operated (starting operation) in this state, the reels 4 When (4a to 4c) starts rotating and the stop button 21 (21a to 21c) corresponding to each reel 4 (4a to 4c) is pressed, a lottery process performed at the operation timing of the start lever 3 The reels 4 (4a to 4c) are controlled to stop at a combination of symbols corresponding to the lottery result, and the presence / absence of a winning is determined based on the stopped combination of symbols. That the medals from the medal payout device 5 in accordance with the result being paid out, and a feasible structure of ordinary slot machine game.

In the slot machine 1 capable of realizing such a slot machine game, the stop button device 20 for stopping the rotation of each reel 4 (4a to 4c) is provided on the front surface of the front door 1a constituting the main body of the slot machine 1. It is provided in the middle.
The stop button device 20 is provided with a plurality of stop buttons 21 (three in the present embodiment) that are pressed by the player. When these stop buttons 21 are pressed, this operation is the main control. Control to stop the rotation of the reels 4 (4a to 4c) corresponding to the stop buttons 21 (21a to 21c) detected and operated by the unit 10 is performed.

Further, a light emitting element 23 that emits light of a predetermined color is provided inside the stop button 21, and the light emitting elements 23 emit light at a predetermined timing after the rotation of the reels 4 (4 a to 4 c) is started. The main control unit 10 controls so as to.
Here, a conventional circuit configuration of the stop button device 20 and the main control unit 10 when the emission color of the light emitting element 23 is a single color will be described with reference to FIG.
As shown in FIG. 7, the stop button device 20 includes three stop buttons 21 (21 a to 21 c), and one light emitting element 23 is provided inside each of the stop buttons 21. Yes. That is, the stop button device 20 is provided with a total of three light emitting elements 23.
On the other hand, the main control unit 10 is provided with a drive circuit 11 corresponding to each of the three light emitting elements 23. That is, the drive circuit 11 is provided with the same three as the light emitting elements 23.

Here, if the combination of one drive circuit 11, a wiring connected to the drive circuit 11, and the light emitting element 23 connected to the wiring is one system, the circuit configuration shown in FIG. Lighting control of the light emitting element 23 is performed by three systems.
That is, with respect to the light emitting element 23 provided on the stop button 21a located on the left, one drive circuit 11 connected to the system is controlled to light through the one system to which the light emitting element 23 is connected. In addition, with respect to the light emitting element 23 provided in the stop button 21b located inside, one driving circuit 11 connected to the system is controlled to light through the one system to which the light emitting element 23 is connected. Further, with respect to the light emitting element 23 provided on the stop button 21c located on the right, one drive circuit 11 connected to the system is controlled to light through the one system to which the light emitting element 23 is connected.
With such a circuit configuration, it is possible to control lighting of the three light emitting elements 23 provided in the stop button device 20 by three systems.

Here, the stop button device 20 is usually provided in any type of slot machine 1, but the specifications and effects differ depending on the model, so the stop button 21 is lit for each model. You may change the color when you do.
However, in order to change the lighting color of the stop button 21 for each model in this way, the stop button 21 is configured separately for each model, or a full color LED is used.

A circuit configuration of the stop button device 20 including the stop button 21 provided with the full color LED and the main control unit 10 is shown in FIG.
As shown in FIG. 8, a full color LED 22 is provided inside each of the three stop buttons 21 (21 a to 21 c) provided in the stop button device 20.
The full color LED 22 includes a light emitting element 23R composed of an LED emitting red (R), a light emitting element 23G composed of an LED emitting green (G), and a light emitting element 23B composed of an LED emitting blue (B). Electronic parts.
Thus, the full color LED 22 is provided with a total of three light emitting elements 23 (23R, 23G, 23B) that emit light in different colors, one for each color. For this reason, the stop button device 20 is provided with a total of nine light emitting elements 23.
On the other hand, the main control unit 10 is provided with a drive circuit 11 corresponding to each of the nine light emitting elements 23. That is, the main control unit 10 is provided with the same number of nine drive circuits 11 as the light emitting elements 23.
In such a configuration, the main control unit 10 performs the lighting control of the light emitting elements 23 in nine systems as many as the number of the light emitting elements 23, drives the drive circuit 11 for each system, and is connected to the system. Lighting control of the light emitting element 23 is performed.

  However, in such a configuration, the number of systems for controlling the light emitting elements 23 increases, and the number of wirings connecting the drive circuit 11 and the stop button device 20 increases.

Accordingly, the gaming machine according to the present invention includes a first control circuit that controls lighting of the light emitting elements 23 for each light emitting device 25 provided with the plurality of light emitting elements 23, and a second control that controls lighting of the light emitting elements 23 for each color. And a control circuit. The first control circuit performs lighting control of the light emitting elements 23 in one system for one light emitting device 25, and the second control circuit includes a plurality of light emitting elements provided in each of the plurality of light emitting devices 25. Among these, the light emitting elements 23 that emit light of the same color are collectively controlled to be turned on by one system.
With such a configuration, the lighting control of the light emitting element 23 can be performed for each stop button 21 while the number of systems is reduced, and the lighting control of the light emitting element 23 can be performed for each color.
Hereinafter, the configuration of the stop button device 20 and the main control unit 10 of the present embodiment will be described with reference to FIG.

[Stop button device and main control unit]
As illustrated in FIG. 3, the stop button device 20 includes a plurality of stop buttons 21 (21 a to 21 c) that are operation units pressed by a player.
The stop button 21 is stop operation means configured to be able to accept a pressing operation, and has a full color LED 22 that emits visible light inside.

The full color LED 22 can emit light of different colors at different timings, and a plurality of light emitting elements 23 having different light emission colors are provided therein.
Specifically, inside the full-color LED 22 are a light emitting element 23R composed of an LED that emits light in red (R), a light emitting element 23G composed of an LED that emits light in green (G), and an LED that emits light in blue (B). The light emitting element 23B is provided.
In addition, a resistor 24 is connected to each of the light emitting elements 23 in series.

Note that a light emitting device 25 includes a plurality of light emitting elements 23 that emit different colors. In the present embodiment, the circuit unit including the full color LED 22 and the resistor 24 is referred to as a light emitting device 25.
The stop button device 20 is provided with three stop buttons 21, and a light emitting device 25 is provided corresponding to each of the three stop buttons 21. Specifically, the circuit unit including the full-color LED 22 and the resistor 24 of the stop button 21a located on the left is a light emitting device 25a, and the circuit unit including the full-color LED 22 and the resistor 24 of the stop button 21b positioned inside is a light emitting device 25a. The circuit unit including the full color LED 22 of the stop button 21c located on the right and the resistor 24 is referred to as a light emitting device 25c. As described above, the stop button device 20 of the present embodiment includes three light emitting devices 25.

The main control unit 10 is a control unit that controls the progress of the game performed by the slot machine 1, and includes a drive circuit 11, a CPU 12, and a selection circuit 13.
The drive circuit 11 operates as a first control circuit of the present invention and controls the lighting of the light emitting element 23 for each light emitting device 25 (25a, 25b, 25c).
The drive circuit 11 can control three systems as many as the number of light emitting devices 25.
Here, the system refers to a unit of control that the main control unit 10 (specifically, the drive circuit 11 or the selection circuit 13) performs on devices other than the main control unit 10. Further, the system physically refers to a port (terminal) of the main control unit 10 (the drive circuit 11 or the selection circuit 13), a wiring connected to the port, and a light emitting element 23 connected to the wiring. A combination. That is, one system refers to a range of the light emitting elements 23 that are subjected to lighting control when the main control unit 10 performs lighting control through one port (terminal).
In the present embodiment, the lighting control of the light emitting element 23 includes control related to the lighting of the light emitting element 23 such as lighting, extinguishing, and blinking of the light emitting element 23.

As described above, the drive circuit 11 can control three systems.
Here, if the three systems are a first system, a second system, and a third system, respectively, the first drive circuit 11 is connected to the first system, and the light emitting device of the stop button 21a located on the left side The light emitting element 23 (23R, 23G, 23B) provided in 25a is connected. And the 1st drive circuit 11 carries out lighting control of these light emitting elements 23 (23R, 23G, 23B) through a 1st system | strain.
The second drive circuit 11 is connected to the second system, and the light emitting element 23 (23R, 23G, 23B) provided in the light emitting device 25b of the stop button 21b located therein is connected. And the 2nd drive circuit 11 carries out lighting control of these light emitting elements 23 (23R, 23G, 23B) through a 2nd system | strain.
The third drive circuit 11 is connected to the third system, and the light emitting element 23 (23R, 23G, 23B) provided in the light emitting device 25c of the stop button 21c located on the right side is connected. And the 3rd drive circuit 11 carries out lighting control of these light emitting elements 23 (23R, 23G, 23B) through a 3rd system | strain.

The selection circuit 13 operates as a second control circuit of the present invention, and controls lighting of the light emitting elements 23 for each color. In order to realize the lighting control for each color, the selection circuit 13 performs lighting control by dividing the plurality of light emitting elements 23 provided in each of the plurality of light emitting devices 25 in units of colors.
Specifically, the selection circuit 13 can control three systems. If the three systems are a first system, a second system, and a third system, respectively, the first system is connected to a light emitting element 23R that emits red light, and the second system emits green light. A light emitting element 23G is connected, and a light emitting element 23B that emits blue light is connected to the third system, and the selection circuit 13 controls lighting of the light emitting element 23 connected for each system.

  The configuration of each system will be described more specifically. The first system includes a light emitting element that emits light in red (R) among the plurality of light emitting elements 23 provided in the light emitting device 25a of the stop button 21a located on the left. 23R, a light emitting element 23R that emits red light (R) among the plurality of light emitting elements 23 provided in the light emitting device 25b of the stop button 21b located inside, and a light emitting device 25c of the stop button 21c located on the right Among the plurality of light emitting elements 23 provided, the light emitting element 23R that emits light in red (R) is connected.

  Further, the second system includes a light emitting element 23G that emits green light (G) among the plurality of light emitting elements 23 provided in the light emitting device 25a of the stop button 21a located on the left, and a stop button 21b located inside. Among the plurality of light emitting elements 23 provided in the light emitting device 25b, among the plurality of light emitting elements 23 provided in the light emitting device 25c of the stop button 21c located on the right and the light emitting element 23G emitting light in green (G). A light emitting element 23G that emits green (G) is connected.

  Further, the third system includes a light emitting element 23B that emits blue (B) among the plurality of light emitting elements 23 provided in the light emitting device 25a of the stop button 21a located on the left, and a stop button 21b located inside. Among the plurality of light emitting elements 23 provided in the light emitting device 25b, among the plurality of light emitting elements 23 provided in the light emitting device 25c of the stop button 21c located on the right, and the light emitting element 23B emitting light in blue (B). A light emitting element 23B that emits blue (B) is connected.

The selection circuit 13 selects one or more systems based on the control signal sent from the CPU 12, and supplies power to the selected systems.
For example, when the control signal is an instruction to select all of the first system, the second system, and the third system, the selection circuit 13 includes the first system, the second system, and the third system. Try to power everything.
Further, when the control signal selects the second system and the third system and instructs not to select the first system, the selection circuit 13 supplies power to the second system and the third system. However, power is not supplied to the first system.
Further, when the control signal indicates that all of the first system, the second system, and the third system are not selected, the selection circuit 13 selects the first system, the second system, and the third system. Do not supply power to everything.

The CPU 12 controls the progress of the game performed by the slot machine 1.
Moreover, CPU12 carries out lighting control of the light emitting element 23 of the stop button apparatus 20 with progress of a game.
For example, when the reel 4 starts to rotate and the stop button 21 can be operated after the rotation speed of the reel 4 reaches a constant speed, the CPU 12 lights all three stop buttons 21. Let

The CPU 12 specifies a stop button 21 to be turned on and a color to be turned on when the light emitting element 23 is controlled to be turned on. Next, the CPU 12 sends a light-emitting device control signal indicating a system corresponding to the stop button 21 to be lit to the drive circuit 11 and sends a color control signal indicating a system corresponding to the color to be lit to the selection circuit 13.
Upon receiving the color control signal sent from the CPU 12, the selection circuit 13 selects a system indicated by the color control signal, and supplies power to the selected system.
When the drive circuit 11 receives the light-emitting device control signal sent from the CPU 12, the drive circuit 11 selects the system indicated by the light-emitting device control signal, and causes the power supply current to flow through the selected system.

A specific example will be described.
For example, it is assumed that the CPU 12 lights all three stop buttons 21 (21a, 21b, 21c) and specifies red as a color to be lit. In this case, the CPU 12 sends a light-emitting device control signal indicating all of the three systems corresponding to the three stop buttons 21 (21a, 21b, 21c), that is, all three systems, to the drive circuit 11, and indicates a system corresponding to red. A color control signal is sent to the selection circuit 13.
The selection circuit 13 selects a first system that is a system corresponding to red based on the color control signal, and supplies power to the selected first system. The selection circuit 13 does not select the second system and the third system and does not supply power.
The drive circuit 11 selects all three systems based on the light emitting device control signal, and causes the power source current to flow through all the selected three systems.
Thereby, the red (R) light emitting element 23R emits light in all of the three stop buttons 21 (21a, 21b, 21c). However, the green (G) light emitting element 23G and the blue (B) light emitting element 23B do not emit light because no power is supplied thereto. Therefore, the stop button 21 is lit in red.

Here, an example in which the red light emitting element 23 is caused to emit light has been described. The CPU 12 and the selection circuit 13 select a color when the light emitting element 23 emits light, and the CPU 12 and the drive circuit 11 select a light emitting device 25 that causes the light emitting element 23 to emit light.
FIG. 4 shows the stop button 21 to be lit and the color to be lit based on the combination of the colors (systems) of the light emitting elements 23 selected by the selection circuit 13 and the light emitting device 25 selected by the drive circuit 11.
As shown in FIG. 4, for example, when the selection circuit 13 selects only the first system to which the red light emitting element 23R is connected and does not select the second system and the third system (see “ R (first system) ”), the light emitting device 25 of the stop button 21 selected by the drive circuit 11 (the light emitting device 25 of the stop button 21 indicated“ ON ”in FIG. 4), only the red light emitting element 23R. Is emitted, and the green light emitting element 23G and the blue light emitting element 23B do not emit light, so that the stop button 21 is lit in red.
When the selection circuit 13 selects the first system to which the red light emitting element 23R is connected and the second system to which the green light emitting element 23G is connected, and does not select the third system (shown in FIG. 4). In the light emitting device 25 of the stop button 21 selected by the drive circuit 11, “RG (first, second system)”), the red light emitting element 23R and the green light emitting element 23G emit light, and the blue light emitting element 23B Since no light is emitted, the stop button 21 is lit in yellow.
Further, the selection circuit 13 selects all of the first system to which the red light emitting element 23R is connected, the second system to which the green light emitting element 23R is connected, and the third system to which the blue light emitting element 23R is connected. In the case (“RGB (first to third system)” shown in FIG. 4), the light emitting device 25 of the stop button 21 selected by the driving circuit 11 emits red light emitting element 23R, green light emitting element 23G, and blue light emission. Since all of the elements 23B emit light, the stop button 21 is lit in white.

Although the lighting control of the plurality of light emitting elements 23 is described here for each color, the CPU 12 can also control the lighting of the plurality of light emitting elements 23 for each light emitting device 25.
For example, when the CPU 12 lights all three stop buttons 21 (21a, 21b, 21c) and specifies red as the color to be lit, the selection circuit 13 supplies power to the first system corresponding to red. And the drive circuit 11 causes the power supply current to flow through all three systems.
Thereby, in all the three stop buttons 21 (21a, 21b, 21c), only the red (R) light emitting element 23R emits light, and these three stop buttons 21 (21a, 21b, 21c) are lit in red. .

Further, when the CPU 12 turns on the stop button 21b located inside and the stop button 21c located on the right, specifies red as the color to be turned on, and does not turn on the stop button 21a located on the left. The circuit 13 supplies power to the first system corresponding to red, and the drive circuit 11 causes the power supply current to flow through the system corresponding to the stop button 21b and the system corresponding to the stop button 21c.
Thereby, only the red (R) light emitting element 23R emits light in the stop buttons 21b and 21c, and the stop buttons 21b and 21c are lit in red. However, the stop button 21a is not lit because the corresponding system is not selected by the drive circuit 11 and is controlled so that the power supply current does not flow.

Further, when the CPU 12 turns off all the three stop buttons 21 (21a, 21b, 21c), the drive circuit 11 prevents the power supply current from flowing in all three systems.
Thereby, since all the light emitting elements 23 are turned off in all the stop buttons 21 (21a, 21b, 21c), all the stop buttons 21 (21a, 21b, 21c) are turned off.
In this case, it does not matter which is the system indicated by the color control signal sent from the CPU 12 to the selection circuit 13 or the system selected by the selection circuit 13.

  Thus, the drive circuit 11, the CPU 12, and the selection circuit 13 can control the lighting of the light emitting elements 23 for each light emitting device 25 and can control the lighting of the light emitting elements 23 for each color.

The CPU 12 performs an effect of lighting the stop button 21 when the player can operate the stop button 21 after the reel 4 starts rotating.
In this case, the CPU 12 emits a light emitting element 23 of a predetermined color among the light emitting elements 23 of the three stop buttons 21 (21a, 21b, 21c) that have been extinguished until the operation of the stop button 21 becomes possible. To emit light.
Thereby, it is possible to notify the player that the stop button 21 can be operated.
Further, when detecting that any one of the three stop buttons 21 (21a, 21b, 21c) has been pressed, the CPU 12 turns off the light emitting element 23 of the stop button 21 that has been pressed, and stops the stop. The button 21 is turned off.

Further, in the conventional gaming machine, the same number of systems as the number of the light emitting elements 23 are provided and the lighting control of the light emitting elements 23 is performed. However, in this embodiment, the number of the light emitting elements 23 is smaller than the number of light emitting elements 23. A system is provided so that lighting control of the light emitting elements 23 can be performed.
For example, in the circuit configuration shown in FIG. 7, nine light emitting elements 23 are provided, and the number of systems for the drive circuit 11 to control lighting of the light emitting elements 23 is nine, which is the same as the number of light emitting elements 23. It has become.
In contrast, in the circuit configuration shown in FIG. 3, nine light emitting elements 23 are provided, but the number of systems connected to the drive circuit 11 is three, and the number of systems connected to the selection circuit 13 is three. The number is three. That is, the total number of systems for controlling the lighting of the light emitting elements 23 by the drive circuit 11 and the selection circuit 13 is six, which is smaller than the nine light emitting elements 23.
Thus, in the gaming machine of this embodiment, the number of systems for controlling the lighting of the light emitting elements 23 is smaller than the number of the light emitting elements 23. The gaming machine according to the present embodiment has a simple circuit configuration for controlling the lighting of the light emitting elements 23 as described above, and can control lighting of the light emitting elements 23 for each light emitting device 25. Lighting control is possible for each color.

As described above, according to the gaming machine of the present embodiment, for lighting control of a plurality of light emitting elements provided in the light emitting device of the stop button, the plurality of light emitting elements are grouped for each color to supply power. The configuration is such that the same number of drive circuits as the number of light emitting devices are provided to control lighting of a plurality of light emitting elements for each light emitting device. Thereby, since the gaming machine of this embodiment can control lighting of these light emitting elements with the number of systems smaller than the number of light emitting elements provided in the stop button device, the lighting control of the plurality of stop buttons with a simple configuration. Can be executed. In addition, it is possible to control lighting of the plurality of light emitting elements for each light emitting device and for each color.
In addition, according to the gaming machine of the present embodiment, the three-system control driving circuit that has been conventionally used can be used as it is for the driving circuit mounted on the main control unit, and the power source to be supplied to the light emitting element is selected. Since only the selection circuit to be connected and the system connected thereto are newly provided, the stop button can be lit in a necessary color with a simple configuration.

  Furthermore, when each of the different types of gaming machines is provided with a stop button device, even when the lighting color of the stop button is changed for each of these models, the stop button device of the present embodiment can be directly adopted for each model. . That is, the stop button device of the present embodiment employs a full color LED as a light emitting component, and the full color LED can be lit in a desired color, and this lighting control can be realized with the configuration shown in FIG. It can be mounted on any of various models with different stop button lighting colors. Thereby, the stop button apparatus of this embodiment can be used as a common component irrespective of a model.

Note that the configuration shown in FIG. 3 is a circuit configuration in the case where the light emitting element incorporated in the stop button is the target of lighting control.
However, the target of lighting control is not limited to the light emitting element incorporated in the stop button, but a light emitting element provided in another device in the gaming machine, such as a bet button 30 (MAX bet button 30a or 1 bet button). Further, light emitting elements provided in the operation unit such as a bonus medium lamp, an AT medium lamp, an X mode lamp, a Y mode lamp, and a push order instruction lamp can also be controlled.
Next, taking the MAX bet button 30a as an example, the case where the light emitting elements provided in each of the MAX bet button 30a and the stop button device 20 are subject to lighting control will be described with reference to FIG.

[MAX bet button, stop button device, and main control unit]
The MAX bet button 30a is bet number setting operation means operated when setting a bet number of a predetermined game value.
As shown in FIG. 5, the MAX bet button 30a is provided with a control unit 31a.
The control unit 31a is a unitized light emitting device 31 that performs a function of detecting that the MAX bet button 30a is pressed and a function of causing the light emitting element 33 to emit light and lighting the MAX bet button 30a. is there.

The control unit 31a includes a photo interrupter 35 that detects that the MAX bet button 30a has been pressed, and a full color LED 32 that emits visible light and emits visible light.
The photo interrupter 35 includes a light projecting element 35a such as an infrared LED that emits light of a predetermined wavelength such as infrared light as detection light, and a light receiving element 35b such as a phototransistor that receives the detection light. When the light receiving element 35b is blocked from receiving the detection light by pressing the bet button 30a, a detection signal is sent to the CPU 12 of the main control unit 10. The CPU 12 can determine that the MAX bet button 30a has been operated by receiving the detection signal.

Inside the full color LED 32, a plurality of light emitting elements 33 having different emission colors are provided, one for each color.
Specifically, inside the full color LED 32, there are a light emitting element 33R composed of an LED emitting red (R), a light emitting element 33G composed of an LED emitting green (G), and an LED emitting a blue (B) light. The light emitting element 33B is provided.
In addition, a resistor 34 is connected in series to each of the plurality of light emitting elements 33.

The full color LED 32 and the photo interrupter 35 are mounted on the same substrate and are unitized by being accommodated in the same unit case. The circuit portion including the unitized full color LED 32 and the photo interrupter 35 constitutes the light emitting device 31 in the present embodiment, and this light emitting device 31 is provided corresponding to the MAX bet button 30a.
Thus, since the light emitting device 31 is unitized, the full color LED 32 and the photo interrupter 35 cannot be accessed from the outside. As a result, fraudulent acts targeting the MAX bet button 30a can be effectively prevented.
Further, since the light emitting device 31 is unitized and can be handled as a single unit, the structure of the MAX bet button 30a becomes relatively simple, and assembly is facilitated. Thereby, reduction of assembly work can be aimed at.

The stop button device 20 has the same configuration as the stop button device 20 shown in FIGS.
However, the stop button device 20 shown in FIG. 5 includes a control unit 25z, similarly to the MAX bet button 30a shown in FIG.
The control unit 25z is a unitized light emitting device 25 that performs a function of detecting that the stop button 21 is pressed and a function of causing the light emitting element 23 to emit light and illuminating the stop button 21.

The control unit 25z includes a photo interrupter 26 that detects that the stop button 21 has been pressed, and a full color LED 22 that emits visible light by emitting light at a predetermined timing.
The photo interrupter 26 has the same configuration as that of the photo interrupter 35 provided in the MAX bet button 30a. When the stop button 21 is pressed, the detection light received by the light receiving element is blocked. A detection signal is sent to the CPU 12 of the main control unit 10. The CPU 12 can determine that the stop button 21 has been operated by receiving the detection signal.

  The configuration of the stop button device 20 shown in FIG. 5 is the same as the configuration of the stop button device 20 shown in FIG. 3 except for the configuration including the light emitting device 25 and the photo interrupter 26. Therefore, in FIG. 5, the same components as those in FIG. 3 are denoted by the same reference numerals, and detailed description thereof is omitted.

The main control unit 10 includes a drive circuit 11, a CPU 12, and a selection circuit 13.
The drive circuit 11 controls lighting of the light emitting elements 23 and 33 for each of the light emitting devices 25 (25a, 25b, and 25c) and the light emitting devices 31.
This drive circuit 11 is provided with four as many as the number of the light-emitting devices 25 and 31, and control of four systems is possible.
Here, if the four systems are a first system, a second system, a third system, and a fourth system, respectively, the first system is a light emitting element 23 (23R, 23G, 23B) is a system that controls the lighting, the second system is a system that controls the lighting of the light emitting elements 23 (23R, 23G, and 23B) provided in the stop button 21b located inside, and the third system is the right system. Is a system for controlling the lighting of the light emitting elements 23 (23R, 23G, 23B) provided on the stop button 21c located at the position 4, and the fourth system is a light emitting element 33 (33R, 33G, 33B) provided on the MAX bet button 30a. ) To control lighting.

The selection circuit 13 controls lighting of the light emitting elements 23 and 33 for each color. In addition, the selection circuit 13 performs lighting control by dividing the plurality of light emitting elements 23 and 33 provided in each of the plurality of light emitting devices 25 and 31 by color.
Specifically, the selection circuit 13 can control three systems. If the three systems are a first system, a second system, and a third system, respectively, light emitting elements 23R and 33R that emit red light are connected to the first system, and the second system is green. The light emitting elements 23G and 33G that emit light are connected, and the light emitting elements 23B and 33B that emit blue light are connected to the third system, and the selection circuit 13 includes the light emitting elements 23, The lighting 33 is controlled.

The CPU 12 controls the progress of the game performed by the slot machine 1.
Further, as the game progresses, the CPU 12 controls the lighting of the light emitting element 33 of the MAX bet button 30a and the light emitting element 23 of the stop button device 20.
For example, when the predetermined game value such as a credit medal has a predetermined number or more, the CPU 12 sets the light-emitting element 33 of the MAX bet button 30a when it becomes possible to set the bet number of the predetermined game value. Make it emit light. This notifies the player that the pressing operation of the MAX bet button 30a is possible.
In addition, the CPU 12 turns on all the three stop buttons 21 at a predetermined timing after the start lever 3 is operated to start the rotation of the reel 4 and the rotation speed of the reel 4 reaches a constant speed. Thus, the player is notified that the pressing operation of the stop button 21 is possible.

The CPU 12 specifies the stop button 21 or the MAX bet button 30a to be turned on and the color to be turned on when the light emitting elements 23 and 33 are controlled to be turned on. Next, the CPU 12 sends a light-emitting device control signal indicating a system corresponding to the stop button 21 to be lit or the MAX bet button 30 a to the drive circuit 11, and sends a color control signal indicating a system corresponding to the color to be lit to the selection circuit 13. send.
Upon receiving the color control signal sent from the CPU 12, the selection circuit 13 selects a system indicated by the color control signal, and supplies power to the selected system.
When the drive circuit 11 receives the light-emitting device control signal sent from the CPU 12, the drive circuit 11 selects the system indicated by the light-emitting device control signal, and causes the power supply current to flow through the selected system.

A specific example will be described.
For example, it is assumed that the CPU 12 turns on the MAX bet button 30a and specifies red as the color to be turned on. In this case, the CPU 12 sends a light-emitting device control signal indicating the fourth system, which is a system corresponding to the MAX bet button 30a, to the drive circuit 11, and transmits a color control signal indicating a system corresponding to red to the selection circuit 13.
The selection circuit 13 selects a first system that is a system corresponding to red based on the color control signal, and supplies power to the selected first system. The selection circuit 13 does not select the second system and the third system and does not supply power.
The drive circuit 11 selects the fourth system based on the light emitting device control signal, and causes the power supply current to flow through the selected fourth system. Further, the drive circuit 11 does not select the first system, the second system, and the third system so that the power supply current does not flow.
As a result, the red (R) light emitting element 33R emits light in the MAX bet button 30a. However, since the green (G) light emitting element 33G and the blue (B) light emitting element 33B are not supplied with power, they do not emit light. Therefore, the MAX bet button 30a is lit in red. Further, the stop button 21 does not light up.

Here, the lighting control of the MAX bet button 30a has been described, but the lighting control of the stop button 21 has already been described in [Stop button device and main control unit], and thus description thereof is omitted here.
Further, the stop button 21 to be lit and the color to be lit based on the combination of the colors (systems) of the light emitting elements 23 selected by the selection circuit 13 and the light emitting device 25 selected by the drive circuit 11 are shown in FIG. Although shown in FIG. 4, the contents shown in FIG. 4 can be applied to the lighting state and the lighting color of the MAX bet button 30a that is controlled to be lighted by the selection circuit 13 and the drive circuit 11. Therefore, the description here is omitted. .

As described above, according to the gaming machine of the present embodiment, the lighting control of the plurality of light emitting elements provided in the light emitting device of the stop button and the light emitting elements provided in the light emitting device of the MAX bet button The light emitting elements are grouped for each color to supply power, and the same number of drive circuits as the number of light emitting devices are provided to control lighting of a plurality of light emitting elements for each light emitting device. Thereby, since the gaming machine of this embodiment can control lighting of these light emitting elements with the number of systems smaller than the number of light emitting elements provided in the stop button device or the MAX bet button, the stop button and The lighting control of the MAX bet button can be executed. In addition, it is possible to control lighting of the plurality of light emitting elements for each light emitting device and for each color.
In addition, according to the gaming machine of the present embodiment, the three-system control driving circuit that has been conventionally used can be used as it is for the driving circuit mounted on the main control unit, and the power source to be supplied to the light emitting element is selected. Since only the selection circuit to be connected and the system connected thereto are newly provided, the stop button and the MAX bet button can be lit in necessary colors with a simple configuration.

  Further, when each of the different types of gaming machines is provided with a stop button device or a MAX bet button, even when the lighting color of the stop button or the like is changed for each of these models, the stop button device of the present embodiment is used as it is for each model. Can be adopted. In other words, the stop button device and the MAX bet button of this embodiment employ a full color LED as a light emitting component, and the full color LED can be lit in a desired color, and this lighting control is realized with the configuration shown in FIG. Therefore, it can be mounted on any of various models with different lighting colors such as a stop button. Thereby, the stop button device etc. of this embodiment can be used as a common part irrespective of a model.

  Further, according to the gaming machine of the present embodiment, since the light-emitting elements provided in the stop button and the MAX bet button are controlled to be turned on for each light-emitting device, the CPU of the main control unit is provided for each stop button. The light emitting element of the light emitting device and the light emitting element of the light emitting device provided on the MAX bet button can be controlled to be turned on using different systems. When the light emitting element of the light emitting device provided for each stop button and the light emitting element of the light emitting device provided for the MAX bet button are caused to emit light at different timings, the CPU may cause them to emit light in different colors. it can. As a result, a variety of lighting effects can be achieved.

Heretofore, the function of controlling the lighting of the light emitting elements provided on the stop button and the MAX bet button has been described as the function of the main control unit.
However, in addition to this function, the main control unit can execute various functions related to lighting control of these light emitting elements.
Next, other functions executed by the main control unit will be described.

[Functions of main control unit]
Here, the following functions of the main control unit 10 will be described.
(1) Non-operating system setting function (2) Information storage function at power interruption (3) Disconnection detection function for each system (4) Lighting control function at disconnection The following explanation regarding (1) to (4) In FIG. 5, the function which the main control part 10 (main control part 10 provided with the circuit structure shown in FIG. 6) which performs lighting control of the light emitting element 23 of the stop button apparatus 20 has is demonstrated. However, (1) to (4) described below can also be applied to the main control unit 10 that performs lighting control of light emitting elements provided in devices other than the stop button device 20.

(1) Non-operating system setting function A storage unit 14 (see FIG. 6) such as a main ROM mounted on the main control unit 10 operates as non-operating system setting means of the present invention, and the light emitting element 23 among a plurality of systems. A system that does not perform the lighting control is stored as a non-operating system. The system is set as a non-operating system by the storage in the storage unit 14.
For example, the lighting color of the stop button 21 is different depending on the model of the gaming machine. In some models, the red light emitting element 23R and the green light emitting element 23G emit light, but the blue light emitting element 23B emits light. In such a case, the third system of the selection circuit 13 to which the blue light emitting element 23B is connected is set as a non-operating system.

(2) Information storage function at power interruption The CPU 12 of the main control unit 10 is output from the power supply device 6 installed in the lower part of the casing 1b of the slot machine 1 and the power supply device 6 is turned off. It has a function of detecting the power interruption signal indicating.
The power supply device 6 is a device for supplying power to each device including the main control unit 10 mounted in the slot machine 1, and monitors the voltage or frequency of the power input from the outside of the slot machine 1, When the voltage or frequency drops below a predetermined value, the power supply is cut off and a power interruption signal indicating that the power supply is cut off is output to the CPU 12 of the main control unit 10.
Further, when the power supply device 6 detects supply of power having a voltage or frequency exceeding a predetermined value due to power recovery, it outputs a power recovery signal indicating power recovery to the CPU 12.

Further, the CPU 12 functions as a power interruption information storage processing unit of the present invention. When the power interruption signal output from the power supply device 6 is input, the CPU 12 uses the predetermined information at the time of the power interruption as backup information, the main RAM, etc. The power-off process to be stored (saved) in the storage unit 14 is executed.
The backup information stored in the storage unit 14 includes, for example, lighting state information indicating the lighting state of the light emitting element 23 at the time of power interruption. The breakdown of the lighting state information includes, for example, information indicating ON / OFF of each system in the drive circuit 11 and information indicating ON / OFF of each system in the selection circuit 13.
When the power interruption signal output from the power supply device 6 is input, the CPU 12 stores the lighting state information of each system in the storage unit 14 as backup information.

Further, the CPU 12 is configured not to store the lighting state at the time of power interruption of the light emitting element 23 connected to the system set as the non-operating system by the non-operating system setting unit as backup information in the storage unit 14. Can do.
In this case, for the system set as the non-operating system, the storage unit 14 can store the OFF information indicating the light extinction as the lighting state information of the system.
For example, when the third system to which the blue light emitting element 23 is connected is set as a non-operating system among the three systems controlled by the selection circuit 13, the storage unit 14 stores the lighting status information of the third system. Information indicating OFF is fixedly stored.

After the power interruption signal is output from the power supply device 6, when the power supply recovery signal is output from the power supply device 6, the CPU 12 of the main control unit 10 inputs the power supply recovery signal.
In this case, the CPU 12 executes a power recovery process for reading the backup information stored (saved) in the storage unit 14 and restarting the game. In the power recovery process, the driving circuit 11 and the selection circuit 13 are controlled based on the read backup information, for example, ON / OFF information indicated by the lighting state information, and the light emitting element 23 is controlled to be turned on.
That is, when the power supply return signal is input, the CPU 12 refers to the lighting state information in the backup information, determines each state of each light emitting element 23 when the power supply is cut off, and emits each light emission at the time of power recovery. Each element 23 is returned to the state immediately before the power is turned off.

Further, the CPU 12 executes the same processing for the non-operating system when the power supply return signal is input.
That is, when the CPU 12 inputs a power supply return signal, the CPU 12 refers to the lighting state information. At this time, since the lighting state information is OFF information for the non-operating system, the light emitting element 23 connected to the non-operating system is not lit. That is, the CPU 12 only needs to perform lighting control only for the system whose lighting state information is ON information.
Therefore, the CPU 12 can efficiently execute the power recovery process.

(3) Disconnection detection function for each system The main control unit 10 has a function of detecting disconnection for each system controlled by the selection circuit 13.
In order to realize this function, the main control unit 10 is provided with a displacement detection circuit 15.
The displacement detection circuit 15 is provided for each system connected to the selection circuit 13 and detects an electrical displacement generated in the provided system.
Examples of the electrical displacement include a displacement of a current flowing for each system, a displacement of a potential difference generated at both ends of a resistor connected to the wiring for each system, and a lighting / extinguishing displacement of the light emitting element 23.
The displacement detection circuit 15 sends a detection signal corresponding to the electrical displacement to the CPU 12 of the main control unit 10.
For example, when the electrical displacement is a displacement of a current flowing for each system, the displacement detection circuit 15 outputs a normal operation signal as a detection signal and sends it to the CPU 12 when detecting that the current is a predetermined value or more. .
On the other hand, when it is detected that the current is below a predetermined value, a stop signal is output as a detection signal and sent to the CPU 12.

The CPU 12 operates as a disconnection detection unit of the present invention, and detects disconnection for each system controlled by the selection circuit 13.
This disconnection can be detected based on the color control signal output to the selection circuit 13 and the detection signal input from the displacement detection circuit 15.
For example, it is assumed that the color control signal selects the first system (R power supply) and the second system (G power supply) and does not select the third system (B power supply). The detection signal is assumed to be a normal operation signal for the first system and the second system, and a stop signal for the third system.
In this case, the current normally flows in the first system and the second system, and the current does not flow in the third system. Therefore, the control content instructed by the CPU 12 to the selection circuit 13 by the color control signal It is the same. Therefore, the CPU 12 determines that no disconnection has occurred in any of the three systems.

On the other hand, although the color control signal selects the same system as the color control signal described above, the detection signal is a normal operation signal for the first system and a stop signal for the second system and the third system. Suppose that
In this case, the current normally flows through the first system, and the current does not flow through the second system and the third system. Therefore, the control content instructed by the CPU 12 to the selection circuit 13 by the color control signal Is different. That is, according to the color control signal, current should flow through the second system, but according to the detection signal, current does not flow through the second system. Therefore, the CPU 12 can determine that a disconnection has occurred in the second system.

In this way, the main control unit 10 can detect a disconnection for each system controlled by the selection circuit 13.
And the main control part 10 can alert | report outside that the disconnection was detected. An employee of the game hall that has recognized this notification can know that an abnormality has occurred in the slot machine 1 and can appropriately respond to the disconnection.

(4) Lighting control function at disconnection The CPU 12 of the main control unit 10 operates as the disconnection control unit of the present invention, and when the CPU 12 operating as the disconnection detection unit detects disconnection, other than the system in which the disconnection is detected. Lighting control of the light emitting element 23 connected to this system is performed.
For example, when the color control signal output from the CPU 12 indicates that the first system is selected and the second system and the third system are not selected, the selection circuit 13 supplies power to the first system. Supply power and do not supply power to the second and third systems.
In this case, when the CPU 12 operating as the disconnection detection unit detects the disconnection of the first system, the CPU 12 selects a system other than the system in which the disconnection is detected, for example, the second system, and this selected second system Is sent to the selection circuit 13.
When the color control signal is input, the selection circuit 13 supplies power to the second system indicated by the color control signal. As a result, the stop button 21 selected by the drive circuit 11 is lit in green.

By executing such processing, when the stop button 21 is to be turned on with the color specified by the color control signal, the system corresponding to the color is disconnected, so that the color is turned on. Even when it is not possible, the stop button 21 can be turned on by substituting another color in place of the color.
Therefore, even when the disconnection of the system occurs in this way, the lighting effect of the stop button 21 can be continuously executed without stagnation.

The preferred embodiment of the gaming machine of the present invention has been described above, but the gaming machine according to the present invention is not limited to the above-described embodiment, and various modifications can be made within the scope of the present invention. Needless to say.
For example, in the above-described embodiment, the slot machine is given as an example of the gaming machine, but the gaming machine to which the present invention can be applied is, for example, a pachinko machine, a parrot, an arrangement ball, a sparrow ball, Various game machines such as an enclosed game machine can be given.
If the gaming machine is a slot machine or a pachinko machine, a game is played using a game medium such as a medal or a game ball. However, if the gaming machine is an enclosed game machine, a predetermined quantity data is used. A game is played. These game media and quantity data are collectively referred to as game value.

  In the above-described embodiment, the light emitting element provided in the stop button device and the light emitting element provided in the MAX bet button are exemplified as examples of the light emitting element that the main control unit performs lighting control. However, the present invention can be applied to a light-emitting element provided in another device provided in the gaming machine. Specifically, for example, a light emitting element is provided for a 1-bet button, a start lever, a bonus lamp, an AT lamp, an X-mode lamp, a Y-mode lamp, a push order instruction lamp, a chance button of a pachinko machine, etc. The present invention can be applied to these light emitting elements.

Furthermore, in the above-described embodiment, the drive circuit and the selection circuit are mounted on the main control unit. However, the present invention is not limited to this configuration. For example, one or both of the drive circuit and the selection circuit may be connected to a relay board or It can also be set as the structure provided in a sub-control part.
In the above-described embodiments, the main control unit performs lighting control of the light emitting elements, but is not limited to the main control unit, and may be performed by the sub control unit. In this case, the sub-control unit is equipped with a drive circuit and a selection circuit, and the drive circuit and the selection circuit select a system designated by the control of the CPU of the sub-control unit and control the lighting of the light emitting element.

Furthermore, in the stop button device shown in FIGS. 3, 5, and 6, the number of light emitting elements provided in one light emitting device is three, but the number is not limited to three. There may be a plurality.
3, 5, and 6, one full-color LED is provided corresponding to one stop button. However, the present invention is not limited to this configuration, and a full-color LED corresponding to one stop button is provided. It can also be set as the structure provided with two or more LED. In this case, the light emitting device provided corresponding to one stop button is configured to include a plurality of full-color LEDs. Even in this case, the drive circuit of the main control unit controls lighting of the light emitting element for each light emitting device. The selection circuit can control lighting of the light emitting element for each color.

1 slot machine (game machine)
4 reel 6 power supply device 10 main control unit (non-operating system setting means, power interruption information storage processing unit, disconnection detection unit, disconnection control unit)
11 Drive circuit (first control circuit)
12 CPU
13 Selection circuit (second control circuit)
14 storage unit 20 stop button device 21 (21a, 21b, 21c) stop button (stop operation means)
22 Full color LED
23 (23R, 23G, 23B) Light emitting element 25 (25a, 25b, 25c) Light emitting device 30 Bet button (betting number setting operation means)
30a MAX bet button (betting number setting operation means)
31 Light Emitting Device 32 Full Color LED
33 (33R, 33G, 33B) Light emitting element

Claims (3)

A gaming machine comprising a plurality of light-emitting devices having predetermined light-emitting elements, and a control unit that controls lighting of the light-emitting elements,
Each of the plurality of light emitting devices has a plurality of the light emitting elements having different colors to emit light,
The control unit includes a first control circuit that controls lighting of the light emitting elements for each light emitting device, and a second control circuit that controls lighting of the light emitting elements for each color,
The second control circuit performs lighting control by systematically dividing the plurality of light emitting elements provided in each of the plurality of light emitting devices in units of colors ,
Non-operating system setting means for setting a system that does not perform lighting control of the light emitting element among the plurality of systems as a non-operating system,
The control unit includes a power interruption information storage processing unit that stores predetermined information in the storage unit as backup information when the power of the gaming machine is cut off.
The power interruption information storage processing unit
The lighting state of the light emitting element at the time of the power interruption is stored in the storage unit as the backup information,
About the lighting state at the time of the power interruption of the light emitting element connected to the system set as the non-operating system by the non-operating system setting means, without storing it in the storage unit as the backup information,
The gaming machine is characterized in that information indicating light extinction is fixedly stored for the light emitting elements connected to the system set as the non-operating system . A gaming machine comprising a plurality of light-emitting devices having predetermined light-emitting elements, and a control unit that controls lighting of the light-emitting elements,
Each of the plurality of light emitting devices has a plurality of the light emitting elements having different colors to emit light,
The control unit includes a first control circuit that controls lighting of the light emitting elements for each light emitting device, and a second control circuit that controls lighting of the light emitting elements for each color,
The second control circuit performs lighting control by systematically dividing the plurality of light emitting elements provided in each of the plurality of light emitting devices in units of colors,
The controller is
A disconnection detector for detecting disconnection for each of the systems;
When disconnected at the disconnection detection portion is detected, Yu Technical machine you characterized in that the disconnection and a disconnection time control unit which controls lighting of the connected light emitting elements to the system other than the detected strain . A gaming machine comprising a plurality of light-emitting devices having predetermined light-emitting elements, and a control unit that controls lighting of the light-emitting elements,
Each of the plurality of light emitting devices has a plurality of the light emitting elements having different colors to emit light,
The controller is
A first control circuit for controlling lighting of all light emitting elements of one light emitting device as one system;
A second control circuit that controls lighting of all light emitting elements of the same color of the plurality of light emitting devices as one system,
The first control circuit controls the lighting of all the light emitting elements of only the at least one light emitting device as one system in a state of controlling the lighting of at least one light emitting device,
The second control circuit, in a state of controlling the lighting of the at least one light-emitting device, controls the lighting of the plurality of light-emitting elements provided in each of the plurality of light-emitting devices, systematically divided by color unit,
The plurality of light emitting devices include a stop operation means that is operated when stopping rotation of a reel provided in the gaming machine, and a bet number setting operation means that is operated when setting a bet number of a predetermined game value. Are provided for each of the
The controller is
When it becomes possible to set the bet number of the predetermined game value, the light emitting element of the light emitting device provided corresponding to the bet number setting operation means is turned on, and the bet number setting operation means operates Is turned off the light emitting element of the light emitting device provided corresponding to the betting number setting operation means,
After the light emitting element of the light emitting device provided corresponding to the betting number setting operation means is turned off and after the rotation of the reel is started, the stop operation means can be operated. Lighting the light emitting element of the light emitting device provided corresponding to the means,
Lighting control of the light emitting element of the light emitting device provided corresponding to the stop operation means and the light emitting element of the light emitting device provided corresponding to the betting number setting operation means by different systems of the first control circuit and, the second by lighting controlled by different strains of the control circuit, Yu Technical machine you characterized thereby emitting the betting amount setting operation unit and the stop operation means in different colors.

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