JP4512757B2 - Game machine - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a gaming machine. In particular, the present invention relates to a power supply device that supplies power to each control device of the gaming machine.
[0002]
[Prior art]
The pachinko machine includes a main control device that controls the operation of the entire pachinko machine, a prize ball control device that controls a prize ball, a display control device that controls a display unit such as a liquid crystal unit, and a sound that controls sound generation means such as a speaker. A control device, a lamp control device that controls the lamp, and a power supply device that supplies power of various voltages to each control device are provided. Usually, these main control device, prize ball control device, display control device, sound control device, lamp control device, power supply device and the like are often configured as a substrate on which a control circuit and the like are arranged.
The power supply device supplies a plurality of power supplies having different voltages. For example, a power source for operating the control circuit (for example, a 5V power source), a power source for driving a controlled device (for example, a liquid crystal unit or a speaker) controlled by the control circuit (for example, a 12V power source and a 34V power source) Power).
The pachinko machine is constituted by a frame part and a game board (panel) provided detachably on the frame part. Usually, since a power supply board can be used in common, it is provided in a frame part.
In the case of a model change or the like, both the frame portion and the panel are exchanged. However, when the game content is improved, only the game board and the display control device are often exchanged.
[0003]
[Problems to be solved by the invention]
Incidentally, in recent years, there has been a demand for powerful effects and complex effects on a display unit such as a liquid crystal unit. In order to answer such a demand, it is necessary to increase the size of the liquid crystal unit provided in the panel. As the size of the liquid crystal unit increases, the power consumption of the liquid crystal unit increases.
In addition, there is a demand for generating high-level sound and high-quality sound from sound generation means such as a speaker. In order to answer such a demand, it is necessary to increase the power consumption of the power amplifier that drives the speaker.
When the power consumption of the liquid crystal unit and the power amplifier increases, it is necessary to increase the capacity of the power source (for example, 12V power source) supplied from the power circuit (power source device) to the liquid crystal unit and the power amplifier.
In general, in a gaming machine such as a pachinko machine, for example, increasing the capacity of a 12V power supply costs more than increasing the capacity of a 34V power supply.
Specifically, a 5V power source is used as a driving power source for a CPU or the like, and a 12V power source is used as a driving power source for a liquid crystal panel. For this reason, the stability of 5V power supply and 12V power supply is required. Therefore, an expensive stabilized power supply circuit using a switching circuit or the like is used as a power supply circuit for supplying a 5V power supply or a 12V power supply. Since the liquid crystal unit originally consumes a large amount of power, the capacity of the power supplied from the power supply circuit to the liquid crystal unit is set large. In such a situation, further increasing the capacity of the power supplied from the power supply circuit to the liquid crystal unit causes a further increase in cost.
On the other hand, the 34V power source is used as a driving power source for a solenoid, a motor, or the like that drives an opening / closing member that opens and closes the winning opening, and therefore, stability is not required as compared with a 5V or 12V power source. Therefore, as a power supply circuit for supplying a 34V power supply, an inexpensive power supply circuit including a full-wave rectification circuit for full-wave rectification of an AC power supply or a half-wave rectification circuit for half-end rectification and a smoothing capacitor is used. Therefore, even if the capacity of the 34V power supply is increased, the increase in cost is not so great.
On the other hand, there are many pachinko machines that use a conventional type of liquid crystal unit or power amplifier with low power consumption. In such a conventional pachinko machine, it is not necessary to increase the capacity of the 12V power supply of the power supply device (power supply circuit). For this reason, it is difficult to use such a high-cost power supply device for a conventional pachinko machine.
Accordingly, an object of the present invention is to provide a gaming machine that can easily increase the capacity of power supplied to a predetermined controlled device while suppressing an increase in cost of the power supply device.
[0004]
[Means for Solving the Problems]
To solve the above problems The present invention A gaming machine as set forth in claim 1.
The gaming machine according to claim 1,
A frame, a game board detachably provided on the frame, a power supply board provided on the frame, and a plurality of control boards provided on the game board;
The power supply board is provided with a predetermined number of power output terminals, and a power supply circuit that supplies at least a first voltage power source and a second voltage power source to the predetermined number of power output terminals,
The power supply circuit is configured by a switching circuit, and includes a stabilized power supply circuit that supplies power of the first voltage, a full-wave rectifier circuit or a half-wave rectifier circuit, and a smoothing capacitor, and the power supply of the first voltage A gaming machine having a power supply circuit for supplying power of the second voltage having lower stability,
The stabilized power supply circuit that supplies power of the first voltage has a power supply capacity corresponding to power consumption of a controlled device that consumes less power among controlled devices controlled using the power supply of the first voltage. Have
The power supply circuit for supplying the power supply of the second voltage has a power supply capacity larger than the power supply capacity corresponding to the power consumption of the controlled device controlled using the power supply of the second voltage;
The power consumption of the controlled device controlled using the power supply of the first voltage is greater than the power consumption of the controlled device with the low power consumption,
The plurality of control boards are connected in series to the power supply board,
As the most downstream control board of the plurality of control boards, the power supply of the first voltage supplied from the power supply board and the power supply of the second voltage among the power supplies of the second voltage are input. And a conversion circuit that converts the power supply of the second voltage input to the power supply input terminal into the power supply of the first voltage, and the first power supplied from the conversion circuit is provided. With a power supply of 1 voltage Controlled devices with higher power consumption than controlled devices with lower power consumption The control board which controls is used, It is characterized by the above-mentioned.
The “downstream side” refers to a direction in which the distance from the power supply board becomes longer.
Claim 1 In the gaming machine described in (1), since the capacity of the power supply of the second voltage that is inexpensive can be increased and supplied to each control board, an increase in the cost of the power supply device (power supply board) can be suppressed. In addition, when it is necessary to increase the capacity of the power source of the first voltage used on the control board, it is only necessary to replace the corresponding control board, so that the work is easy. In addition, since the control board for increasing the capacity of the first voltage power source used for the control only includes the conversion circuit, the circuit is simple.
[0005]
DETAILED DESCRIPTION OF THE INVENTION
Embodiments of the present invention will be described below with reference to the drawings. Below, the case where this invention is applied to the pachinko machine is demonstrated.
FIG. 1 and FIG. 2 are diagrams for explaining a first embodiment of the present invention. Here, FIG. 1 shows a state in which a display control board that uses the power source of the first voltage input to the power input terminal as it is is connected. Further, FIG. 2 shows a display control board that converts a second voltage power source input to a power input terminal into a first voltage power source by a conversion circuit and uses the first voltage power source converted by the conversion circuit. The connected state is shown.
[0006]
The pachinko machine of the present embodiment includes a power supply device, a prize ball control device, a main control device, a sub control device (sound control device and lamp control device), a display control device, and the like.
The power supply device is usually configured as a power supply substrate 10. The power supply substrate 10 is provided with power output terminals 10a to 10c, a power supply circuit 10d, and the like.
From the power output terminals 10a to 10c, a power source used in each component of the pachinko machine (in this embodiment, a 5V DC power source for operating the control circuit, a controlled device such as a liquid crystal unit and a sound generating means) is operated. 12V and 34V DC power supplies) are output. The 12V DC power supply is used as an operating power supply for a power amplifier that drives a liquid crystal unit or a speaker, for example. The 34V DC power supply is used as a drive power supply for a solenoid, a drive motor, or the like that drives an opening / closing member that makes it easy for a game ball to win a big prize opening and makes it difficult to win a prize.
The power supply circuit 10d converts, for example, an input power supply (AC power supply) into a power supply of a predetermined voltage (DC power supplies of 5V, 12V, and 34V in the present embodiment) and supplies the power supply output terminals 10a, 10b, and 10c, respectively. To do.
As described above, in a pachinko machine, increasing the capacity of a 12V power supply costs more than increasing the capacity of a 34V power supply. Therefore, in the present embodiment, the capacity of the expensive 12V power supply is set small (for example, about the power supply capacity set conventionally), and the capacity of the inexpensive 34V power supply is set large. And when controlling the controlled apparatus with small power consumption, the control board which controls a controlled apparatus using a 12V power supply is used. On the other hand, when controlling a controlled device with high power consumption, a control board that controls the controlled device using a 34V power supply is used.
[0007]
The main control device is usually configured as a main control board 12. The main control board 12 is provided with power input terminals 12a to 12c, power output terminals 12d to 12f, a main control circuit (not shown), and the like. DC power of 5V, 12V, and 34V is supplied to the power input terminals 12a to 12c of the main control board 12, respectively (in FIG. 1, the power output terminals 11d to 11d of the prize ball control board 11 provided on the upstream side). 11f). The power input terminals 12a to 12c are connected to power output terminals 12d to 12f, respectively. Thus, the main control board 12 has a function of relaying 5V, 12V, and 34V power supplies.
The main control circuit (main control device) controls the operation of the entire pachinko machine. For example, when a game ball wins a winning opening and a winning detection signal is input, a payout command signal for instructing the payout of the number of winning balls corresponding to the winning opening where the game ball has won is output to the winning ball control device. Alternatively, when a predetermined start condition is satisfied and a start signal is input, a lottery is performed, and a variation pattern command signal indicating a symbol variation pattern corresponding to the lottery result and a symbol command signal indicating a stop symbol corresponding to the lottery result are displayed. Output to the display controller. Further, when the lottery result is a win, a special gaming state advantageous to the player is generated. For example, a control signal is output to an opening / closing member drive circuit (opening / closing member control circuit) that controls an opening / closing member provided in the prize winning opening, and the opening / closing member is controlled to open / close, so that the game ball becomes a prize winning opening. Make it easy to enter.
[0008]
The prize ball control device is normally configured as a prize ball control board 11. The prize ball control board 11 is provided with power input terminals 11a to 11c, power output terminals 11d to 11f, and a prize ball control circuit (not shown). The power input terminals 11a to 11c of the prize ball control board 11 are respectively supplied with 5V, 12V and 34V DC power (in FIG. 1, the power output terminals 10a to 10c of the power board 10 provided on the upstream side). It is connected to the). The power input terminals 11a to 11c are connected to power output terminals 11d to 11f, respectively. Thereby, the prize ball control board 11 has a function of relaying 5V, 12V, and 34V power supplies.
The prize ball control circuit (prize ball control device) controls the operation related to the payout of the pachinko machine. That is, a prize ball control circuit (prize ball control device) controls a payout device (not shown) as a controlled device, and a prize indicated by a payout command signal output from the main control circuit (main control device). Pay out the number of game balls.
[0009]
The sub-control device is usually configured as a sub-control board 13. The sub-control device is configured as, for example, a sound control device (not shown) that controls sound generation means such as a speaker as a controlled device, and a lamp control device (not shown) that controls a lamp or the like as a controlled device. Can do.
The sub control board 13 is provided with power input terminals 13a to 13c, power output terminals 13d to 13f, and a sub control circuit (sound control circuit, lamp control circuit) (not shown). DC power of 5V, 12V, and 34V is supplied to the power input terminals 13a to 13c of the sub control board 13, respectively (in FIG. 1, power output terminals 12d to 12f of the main control board 12 provided on the upstream side) It is connected to the). The power input terminals 13a to 13c are connected to power output terminals 13d to 13f, respectively. Thereby, the sub-control board 13 has a function of relaying 5V, 12V, and 34V power supplies.
The sub-control circuit (sub-control device) controls the operation related to the operation / stop of the speaker and the lamp provided in the pachinko machine. That is, the sub control circuit (sub control device) controls the speaker and the lamp based on the command signal from the main control circuit (main control device).
[0010]
The display control device is usually configured as a display control board. In the present embodiment, the display control board 14 (see FIG. 1) or 24 (see FIG. 2) is configured.
The display control board 14 is for controlling the liquid crystal unit 15 with low power consumption. The display control board 14 is provided with power input terminals 14a and 14b, a drive terminal 14c, and a display control circuit (not shown).
Here, in the case of controlling the liquid crystal unit 15 with low power consumption, a 12 V power source with small capacity can be used. Therefore, the display control board 14 inputs power of 5V and 12V to the power input terminals 14a and 14b, respectively (in FIG. 1, connected to the 5V and 12V power output terminals 13d and 13e of the upstream side sub-control board 13). The power supply of voltage 34V is not input. The power input terminal 14b is connected to the drive terminal 14c. The connection terminal 15a of the liquid crystal unit 15 is connected to the drive terminal 14c. Thereby, the display control board 14 controls the liquid crystal unit 15 with low power consumption using the 12V power source as it is.
[0011]
On the other hand, when controlling the liquid crystal unit 25 with high power consumption, it is necessary to use a power source with a large capacity. The display control board 24 is for controlling the liquid crystal unit 25 with high power consumption. The display control board 24 is provided with power input terminals 24a and 24b, a drive terminal 24c, a display control circuit (not shown), and the like.
Here, the display control board 24 uses a 34V power source having a large capacity. That is, in the display control board 24, power supplies of 5V and 34V are input to the power supply input terminals 24a and 24b, respectively (in FIG. 2, connected to the 5V and 34V power supply output terminals 13d and 13f of the sub control board 13 on the upstream side. The power of 12V is not input. Then, the conversion circuit 24d converts the 34V power supplied to the power input terminal 24b into 12V power. The 12V power converted by the conversion circuit 24d is supplied to the drive terminal 24c. The connection terminal 25a of the liquid crystal unit 25 is connected to the drive terminal 24c. As a result, the display control board 24 controls the liquid crystal unit 25 using a 12V power supply having a large capacity obtained by converting the 34V power supply.
[0012]
In the present embodiment, the winning ball control board 11, the main control board 12, and the sub control board 13 correspond to the control board of the present invention, and the display control board 14 corresponds to the third control board of the present invention. The circuit 24 corresponds to the fourth control board of the present invention.
[0013]
As described above, in the present embodiment, a predetermined number of power input terminals and power supplies corresponding to the number of power supplies supplied from the power supply board are provided on the control board such as the prize ball control board, the main control board, and the sub control board. An output terminal is provided, and a plurality of control boards are connected in series to the power supply board. Thereby, each control board can select a required power supply easily.
In addition, since a predetermined number of power supplies are relayed to the most downstream control board, the third control board or the fourth control board is used as the most downstream control board according to the power consumption of the controlled device. it can. Thereby, it is possible to easily cope with an increase in power consumption of the controlled device. Moreover, since the capacity | capacitance of an inexpensive power supply can be increased, the cost increase of a power supply device can be suppressed.
[0014]
Although the display control board is used as the most downstream control board in the first embodiment, various control boards other than the display control board can be used as the most downstream control board.
For example, the present invention can also be applied to the case where the power consumption of a power amplifier of a speaker is increased in response to a demand for higher sound quality and higher sound quality. In this case, a sound control board is used as the most downstream control board. When the power consumption of the power amplifier is small, a sound control board having the same configuration as that of the display control board 14 is used. When the power consumption of the power amplifier is large, the sound control having the same structure as that of the display control board 24 is used. A substrate is used.
Moreover, when changing the drive power supplied to drive means, such as a solenoid and a motor which drives an opening-and-closing member, for example, it can apply also when changing the voltage of drive power from 34V to 12V, or vice versa. For example, when the motor that drives the opening / closing member is changed from a motor driven by a 34V power source to a motor driven by a 12V power source, the capacity of the 12V power source is increased in order to increase the output of the motor. There is a need. In such a case, the capacity of the inexpensive 34V power source is increased, the 34V power source is converted into a 12V power source by the conversion circuit, and the motor is driven by the 12V power source converted by the conversion circuit.
[0015]
In the first embodiment, the control board is connected in series to the power supply board, and the third control board or the fourth control board is used as the most downstream control board according to the power consumption of the controlled device. Although used, each control board connected in series can be configured to be replaceable according to the power consumption of the controlled device.
Next, a second embodiment of the present invention is shown in FIGS. Here, FIG. 3 shows a display control board 34 for controlling the liquid crystal unit 15 with low power consumption. FIG. 4 shows a display control board 44 that controls the liquid crystal unit 25 with high power consumption.
The display control board 34 shown in FIG. 3 includes power input terminals 34a, 34b, and 34c that can be connected to the power output terminal of the previous board, and power output terminals 34d, 34e, and 34f that can be connected to the power input terminal of the subsequent board. A drive terminal 34g that can be connected to the connection terminal 15a of the liquid crystal unit and a display control circuit (not shown) are provided. The display control board 34 does not use a power supply with a voltage of 34 V, but only relays it to the subsequent board.
On the other hand, the display control board 44 shown in FIG. 4 is provided with a conversion circuit 44h that converts the 34V power input to the power input terminal 44c into a 12V power. The 12V power converted by the conversion circuit 44h is supplied to the drive terminal 44g.
The display control board 44 does not use a power supply with a voltage of 12 V, but only relays it to the subsequent board.
[0016]
In the present embodiment, the display control board 34 corresponds to the first control board of the present invention, and the display control board 44 corresponds to the second control board of the present invention.
[0017]
This embodiment has the same effect as that of the first embodiment.
In addition to the control board on the most downstream side as in the first embodiment, any control board among the control boards connected in series to the power supply output terminal of the power supply board is independent of other control boards. Since it can be exchanged, it is possible to easily cope with a change in power consumption of the controlled device.
Note that the modification example described in the first embodiment can also be applied to the second embodiment.
[0018]
Although the case where the control board is connected in series to the power supply board has been described in the above embodiment, the control board can also be connected in parallel to the power supply board.
Next, a third embodiment is shown in FIGS. Here, FIG. 5 shows a state in which a display control board for controlling a liquid crystal unit with low power consumption and a sound control board using a power amplifier with low power consumption are connected to a power supply board.
The pachinko machine according to the present embodiment includes a power supply device, a main control device, a prize ball control device, a display control device, a sound control device, a lamp control device, and the like. The power supply device, main control device, prize ball control device, display control device, sound control device, and lamp control device are the power supply board 50, main control board 51, prize ball control board 52, display control board 53, and sound control board 55, respectively. The lamp control board 57 is disposed.
On the power supply substrate 50, power output terminals 50a, 50b, 50c and a power supply circuit 50d are arranged. The power output terminals 50a, 50b, and 50c are supplied with power of different voltages, for example, 5V, 12V, and 34V. Also in this case, the capacity of the 12V power source output from the power output terminal 50b is small, and the capacity of the inexpensive 34V power source is set large.
The main control board 51 uses 5V, 12V, and 34V power input to the power input terminals 51a to 51c (connected to the power output terminals 50a, 50b, and 50c of the power supply board 50).
The prize ball control board 52 uses power supplies of 5V, 12V, and 34V input to the power input terminals 52a to 52c.
The lamp control board 57 uses 5V, 12V, and 34V power supplies input to the power input terminals 57a to 57c.
[0019]
The display control board 53 controls the liquid crystal unit 54 with low power consumption. The display control board 53 is provided with power input terminals 53a and 53b, a drive terminal 53c, and a display control circuit (not shown).
Here, since the power consumption of the liquid crystal unit 54 is small, 5V and 12V power is input to the power input terminals 53a and 53b of the display control board 53 (connected to the power output terminals 50a and 50b of the power board 50). Have been). Then, the display control board 53 controls the liquid crystal unit 54 using the 12V power source inputted to the power input terminal 53b as it is.
The sound control board 55 is provided with power input terminals 55a and 55b, a drive terminal 55c, a power amplifier 55d for supplying power to the speaker 56, and a sound control circuit (not shown).
Here, the sound control board 55 uses a power amplifier 55d with low power consumption. For this reason, the power input terminals 55a and 55b of the sound control board 55 are supplied with 5V and 12V power, respectively (connected to the power output terminals 50a and 50b of the power board 50).
[0020]
On the other hand, when the liquid crystal unit 64 with high power consumption is used as the liquid crystal unit, as shown in FIG. 6, the power input terminals 63a and 63b of the display control board 63 for controlling the liquid crystal unit 64 have 5V and 34V, respectively. Power is input (connected to the power output terminals 50a and 50c of the power supply board 50).
Further, the display control board 63 is provided with a conversion circuit 63d that converts the 34V power input to the power input terminal 63b into a 12V power. As a result, the 12V power converted by the conversion circuit 63d is supplied to the liquid crystal unit 64 via the drive terminal 63c and the connection terminal 64a.
When a power amplifier 65d with high power consumption is used as the power amplifier, 5V and 34V power is input to the power input terminals 65a and 65b of the sound control board 65 (the power output terminal of the power board 50). 50a, 50c).
Further, the sound control board 65 is provided with a conversion circuit 65e for converting the 34V power input to the power input terminal 65b into a 12V power. As a result, the 12V power converted by the conversion circuit 65e is supplied to the speaker 66 via the power amplifier 65d and the drive terminal 65c.
[0021]
In the third embodiment, since each control board is connected in parallel to the power output terminal of the power board, the control board can be easily replaced according to the power consumption of the controlled device.
Further, the power supply input terminal for inputting the 34V power supply is omitted in the display control board 53 and the sound control board 55, and the power supply input terminal for inputting the 12V power supply is omitted in the display control board 63 and the sound control board 65. Can do. Thereby, the configuration of the display control board and the sound control board can be simplified.
Note that the modifications described in the first embodiment and the second embodiment can also be applied to the third embodiment.
[0022]
In the first embodiment, power supplies (for example, 5V, 12V, etc.) of all voltages are supplied to control boards (for example, control boards 11 to 13) other than at least the most downstream control board (for example, display control board 14 or 24). Each control board is connected in series to the power supply board with a function of relaying a 34V power supply), but the configuration of the control boards connected in series is not limited to this.
7 and 8 show a fourth embodiment in which the configuration of the control boards connected in series is changed. In the present embodiment, the control boards are grouped and each control board is connected in series for each group. As a method of grouping, for example, controlled devices that use a power source of a predetermined voltage (for example, a high-cost power source of 12V in a pachinko machine) are controlled, and controlled devices having different power consumption are used. Control boards that may be controlled are set as a first group of control boards, and other control boards are set as a second group of control boards. In the embodiment shown in FIGS. 7 and 8, the lamp control board and the display control board are set as the first group of control boards, and the prize ball control board (not shown) and the main control board are controlled in the second group. Set on the board.
Then, the control board of the second group (in this case, the prize ball control board and the main control board) is connected in series to the power supply board (the connection order can be arbitrarily set).
Next, the control board (lamp control board and display control board) of the first group is connected in series to the control board (main control board 111 in FIG. 7) on the most downstream side of the control board of the second group. (The connection order can be set arbitrarily.)
[0023]
In the present embodiment, the control board of the second group has a function of relaying a predetermined number of voltage power supplies output from the power supply board. That is, the control board of the second group includes a power input terminal to which power of a predetermined number of voltages output from the power board is input, and a predetermined number of power output terminals connected to the predetermined number of power input terminals. Is provided.
On the other hand, the control board of the first group has a function of outputting at least a power supply of a predetermined voltage downstream (a function of inputting a power supply of a predetermined voltage and outputting a power supply of a predetermined voltage downstream, or a predetermined Power supply of a voltage different from that of the input voltage is input, converted to a power supply of a predetermined voltage and output downstream (hereinafter, these are collectively referred to as “relay function of a power supply of a predetermined voltage”) However, it does not have a function of relaying all power sources having a predetermined number of voltages.
[0024]
At least the most upstream control board of the first group of control boards is replaced according to the power consumption of the controlled device controlled by the first group of control boards.
For example, when the lamp unit 113 with low power consumption and the liquid crystal unit 115 with low power consumption are used, the lamp control board shown in FIG. 7 is used as the lamp control board that is the control board on the most upstream side of the first group. 112 is used. A display control board 114 shown in FIG. 7 is used as the display control board.
Here, the power input terminals 112a and 112b of the lamp control board 112 are connected to the power output terminals 111d and 111e of the main control board 111 which is the control board on the most downstream side of the second group, and power supplies of 5V and 12V, respectively. Is entered. The power output terminals 112c and 112d of the lamp control board 112 are connected to the power input terminals 112a and 112b, and output 5V and 12V power, respectively. In the lamp control board 112, the lamp unit 113 is controlled using the power source of a predetermined voltage (in this case, 12V power source) inputted from the power input terminal 112b as it is.
The power input terminals 114a and 114b of the display control board 114 are connected to the power output terminals 112c and 112d of the lamp control board 112, and 5V and 12V power is input thereto, respectively. In the display control board 114, the liquid crystal unit 115 is controlled by using the power source of a predetermined voltage (in this case, 12V power source) inputted from the power input terminal 114b as it is.
[0025]
On the other hand, when at least one of the lamp unit 123 with high power consumption or the liquid crystal unit 125 with high power consumption is used, the control board on the most upstream side of the first group is used as the inexpensive power source for the controlled device with high power consumption. Replace with a control board that can be controlled with. In FIG. 7, a lamp control board 122 is used as the lamp control board. Note that when the liquid crystal unit 125 with high power consumption is used, the display control board 124 capable of controlling the liquid crystal unit 125 is used.
Here, the power input terminals 122a and 122b of the lamp control board 122 are connected to the power output terminals 111d and 111f of the main control board 111 which is the control board on the most downstream side of the second group. Is entered. The power input terminal 122b of the lamp control board 122 has a conversion circuit 122f that converts the power input to the power input terminal 122b (in this case, 34V power) into a power having a predetermined voltage (in this case, 12V power). It is connected. The 12V power converted by the conversion circuit 122f is supplied to the power output terminal 122d and the control terminal 122e. Further, the power output terminal 122c of the lamp control board 122 is connected to the power input terminal 122a.
Thereby, the lamp unit 123 is controlled by the 12V power source converted from the 34V power source by the conversion circuit 122f.
Further, the power input terminals 124a and 124b of the display control board 124 are connected to the power output terminals 122c and 122d of the lamp control board 122, and 5V and 12V power converted by the conversion circuit 122f are input thereto.
The display control board 124 controls the liquid crystal unit 125 using a 12V power source input from the power input terminal 124b.
Control capable of controlling controlled devices with various power consumptions as a control board (display control board in FIG. 7) other than the control board on the most upstream side of the first group (lamp control board in FIG. 7). When a board is used, it can be dealt with by simply replacing the control board on the most upstream side of the first group.
[0026]
As described above, in the present embodiment, a control board that controls a controlled device using the power source of the first voltage and controls controlled devices having different power consumption is included in the first group. The control board is set, and the other control boards are set as the second group of control boards. A second group of control boards and a first group of control boards are connected in series in this order to the power supply board. When any one control board in the first group controls a controlled device with large power consumption, the second input from the power input terminal as the control board on the most upstream side of the first group. A conversion circuit that converts the power supply of the voltage to a power supply of the same voltage as the first voltage, and controls the controlled device using the power supply from the conversion circuit, and supplies the power supply from the conversion circuit to the power supply output terminal A control board is used. As a control board other than the control board on the most upstream side of the first group, a power input terminal to which a first voltage power is input is provided, and the first voltage power input from the power input terminal is used. A control board for controlling the controlled device is used. Alternatively, a power supply input terminal to which a first voltage power supply is input and a power supply output terminal connected to the power supply input terminal are provided, and the controlled device is used by using the first voltage power supply input from the power supply input terminal. A control board for controlling the above is used.
This embodiment also has the effects described above.
[0027]
In the third embodiment, each control board is connected in parallel to the power supply board. However, each control board can be connected to the power supply board using a combination of parallel connection and series connection.
FIG. 9 and FIG. 10 show a fifth embodiment in which a control board is connected to a power supply board by combining parallel connection and series connection.
In the present embodiment, the second group of control boards described in the fourth embodiment (the prize ball control board 131 and the main control board 132 in FIGS. 9 and 10) are arranged in parallel with the power supply output terminals of the power supply board. Connected. Then, the control board of the first group (the lamp control board and the display control board in FIGS. 9 and 10) is placed on one of the control boards (the main control board 132 in FIGS. 9 and 10) in the second group. Connected in series.
FIG. 9 is a diagram illustrating a state in which the lamp unit 134 with low power consumption and the liquid crystal unit 136 with low power consumption are used. FIG. 10 is a diagram illustrating a state where a lamp unit 144 with high power consumption and a liquid crystal unit 146 with high power consumption are used.
The method for selecting the first group of control boards is the same as the method described in the fourth embodiment. That is, at least the control board on the most upstream side of the first group is replaced according to the power consumption of the controlled device controlled by any one of the control boards of the first group.
This embodiment also has the effects described above.
[0028]
The present invention is not limited to the configuration described in the embodiment, and various changes, additions, and deletions are possible.
For example, the control circuit configuring the pachinko machine is not limited to the configuration described in the embodiment, and can be variously changed.
Further, the number of power output terminals provided on the power supply board, and the number of power input terminals and power output terminals provided on each control board can be changed as appropriate.
Further, although a high voltage-low voltage conversion circuit is used as the conversion circuit, various conversion circuits can be used as the conversion circuit depending on the type of the gaming machine, the configuration of the power supply circuit, and the like. For example, a low voltage-high voltage conversion circuit can be used.
The configuration of each control board (control device) can be changed as appropriate according to the controlled device.
Further, as the third and fourth control boards (for example, the display control boards 14, 24 or 53, 63), the first and second control boards (for example, the display control boards 34 and 44) can be used.
Moreover, although the pachinko machine was demonstrated, this invention is applicable to various game machines other than a pachinko machine.
[0029]
Further, the present invention provides a “predetermined number of power supply output terminals, a power supply board provided with a power supply circuit for supplying power of at least first and second voltages to the predetermined number of power supply output terminals, a power supply input terminal, a game A plurality of control boards provided with a control circuit for controlling the controlled equipment constituting the machine, the plurality of control boards controlling the controlled equipment using a power supply of the first voltage, The control board is divided into a first group of control boards for controlling different controlled devices and a second group of control boards, and the power output terminals of the power supply board are connected to the second group of control boards, the first control board. The control board on the most upstream side of the first group controls the controlled device using the power source of the first voltage from the power input terminal as it is, Output the power supply of the first voltage downstream. And a conversion circuit that converts the power supply of the second voltage from the power supply input terminal to the power supply of the same voltage as the first voltage, and the power supply of the first voltage from the conversion circuit. Can be configured as a game machine in which one of the sixth control boards is used to control the controlled device using and to output the power source of the first voltage downstream. Alternatively, “a predetermined number of power supply output terminals, a power supply board provided with a power supply circuit for supplying power of at least first and second voltages to the predetermined number of power supply output terminals, a power supply input terminal, and a gaming machine are configured. A plurality of control boards provided with a control circuit for controlling the non-control equipment, and the plurality of control boards control the controlled equipment using the power supply of the first voltage, and controlled equipment having different power consumption Are divided into a first group of control boards and a second group of other control boards, and the second group of control boards are connected in parallel to the power output terminals of the power board. The control board of the first group is connected in series to one of the control boards of the second group, and the control board on the most upstream side of the first group receives the first voltage from the power input terminal. Controlled equipment using the power supply as is A fifth control board for controlling and outputting a power supply of the first voltage downstream, and a conversion circuit for converting the power supply of the second voltage from the power supply input terminal to a power supply of the same voltage as the first voltage One of the sixth control boards is used, which controls the controlled device using the first voltage power source from the conversion circuit and outputs the first voltage power source to the downstream side. Game machine. "
[0030]
【The invention's effect】
As explained above, Claims 1-3 If the gaming machine described in (1) is used, it is possible to easily increase the capacity of the power supplied to a predetermined controlled device while suppressing an increase in the cost of the power supply circuit (power supply device). Further, it is possible to cope with a change in the power consumption of the controlled device by a minimum change in the control board.
[Brief description of the drawings]
FIG. 1 is a diagram for explaining a first embodiment;
FIG. 2 is a diagram for explaining a first embodiment;
FIG. 3 is a diagram for explaining a second embodiment;
FIG. 4 is a diagram for explaining a second embodiment;
FIG. 5 is a diagram for explaining a third embodiment;
FIG. 6 is a diagram for explaining a third embodiment;
FIG. 7 is a diagram for explaining a fourth embodiment;
FIG. 8 is a diagram for explaining a fourth embodiment;
FIG. 9 is a diagram for explaining a fifth embodiment;
FIG. 10 is a diagram for explaining a fifth embodiment;
[Explanation of symbols]
10, 50 Power supply board
11, 52, 131 Prize ball control board
12, 51, 111, 132 Main control board
13 Sub control board
14, 24, 34, 44, 53, 114, 124, 135, 145 Display control board
15, 25, 54, 115, 125, 136, 146 Liquid crystal unit
55 Sound control board
56 Speaker
57, 112, 122, 133, 143 Lamp control board
113, 123, 134, 144 Lamp unit

Claims (1)

A frame, a game board detachably provided on the frame, a power supply board provided on the frame, and a plurality of control boards provided on the game board;
The power supply board is provided with a predetermined number of power output terminals, and a power supply circuit that supplies at least a first voltage power source and a second voltage power source to the predetermined number of power output terminals,
The power supply circuit is configured by a switching circuit, and includes a stabilized power supply circuit that supplies power of the first voltage, a full-wave rectifier circuit or a half-wave rectifier circuit, and a smoothing capacitor, and the power supply of the first voltage A gaming machine having a power supply circuit for supplying power of the second voltage having lower stability,
The stabilized power supply circuit that supplies power of the first voltage has a power supply capacity corresponding to power consumption of a controlled device that consumes less power among controlled devices controlled using the power supply of the first voltage. Have
The power supply circuit for supplying the power supply of the second voltage has a power supply capacity larger than the power supply capacity corresponding to the power consumption of the controlled device controlled using the power supply of the second voltage;
The power consumption of the controlled device controlled using the power supply of the first voltage is greater than the power consumption of the controlled device with the low power consumption,
The plurality of control boards are connected in series to the power supply board,
As the most downstream control board of the plurality of control boards, the power supply of the first voltage supplied from the power supply board and the power supply of the second voltage among the power supplies of the second voltage are input. And a conversion circuit that converts the power supply of the second voltage input to the power supply input terminal into the power supply of the first voltage, and the first power supplied from the conversion circuit is provided. A gaming machine, wherein a control board is used to control a controlled device having a higher power consumption than a controlled device having a lower power consumption using a power source having a voltage of 1.

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