JP5427470B2 - Game machine - Google Patents

Description

  The present invention relates to a gaming machine capable of saving power.

  In recent years, game machines tend to be flashy with a display effect by a symbol display device, a light effect by a light emitting means such as various lamps, and a sound effect by a speaker in order to improve the interest. There is a tendency. On the other hand, since the problem of power saving (that is, energy saving) of gaming machines has been highlighted from the viewpoint of environmental problems, various gaming machines capable of power saving are being proposed (for example, Patent Document 1). reference). In the prior art described in Patent Document 1, when a game is not being performed, more specifically, when a predetermined period of time has elapsed when the gaming machine has not been operated, power saving to the light-emitting means is stopped or suppressed. Is supposed to do.

JP-A-2003-135684 (Claim 1, [0020], [0021], [0023], FIG. 4, etc.)

  However, in the gaming machine described in Patent Document 1, since the target of power saving is only the light emitting means, the contribution to power saving is low. Moreover, since power saving is performed only when the game is not in progress, there is a problem that power cannot be effectively saved.

  The present invention has been made in view of the above problems, and its purpose is to enable power saving regardless of whether or not a game is in progress, and to save power to a plurality of devices controlled by the sub-control means. Accordingly, an object of the present invention is to provide a gaming machine that can effectively save power.

Means for solving the above problems include main control means for controlling the entire gaming machine, and overall control means for overall control of a plurality of sub-control means based on control commands from the main control means. Display control means for performing control for executing display effects by the display means, light emission control means for performing control for executing light emission effects by the light emitting means, and voice control means for performing control for executing sound effects by the sound generating means. The plurality of sub-control means, and the overall control means and the display control means are electrically connected to generate a power supply voltage necessary for the operation of the overall control means and the display control means, and the generated power supply voltage is A gaming machine comprising a general control means and a power supply board to be supplied to the display control means, wherein the general control means has a power supply supplied from the power supply board. A power generation circuit that generates a drive voltage necessary for the operation of the light emission control unit and the sound control unit, and the power generation circuit includes a normal power generation resistor whose resistance value is set to a normal set value. And a power saving power generation resistor set to a power saving setting value whose resistance value is larger than the normal setting value, and the overall control means includes the normal power generation resistor or the power saving power source. When a generation resistor is selected and the power saving power generation resistor is selected, the drive voltage generated by the power generation circuit is reduced to reduce the light amount of the light emitting means and the volume of the sound generation means. A power saving command indicating that the power saving mode is in effect is output to the display control means, and the display control means is supplied from the power supply board when the power saving command is input. By reducing the supply voltage, the gaming machine characterized by reducing the brightness of the display unit and its gist.

Therefore, in the invention described in the above means, when the power saving power generation resistor is selected by the overall control means, power saving is performed by reducing the drive voltage and the power supply voltage. That is, since power saving is performed regardless of whether or not the game is in progress, the power saving effect is enhanced. In addition, when the power-saving power generation resistor is selected by the overall control means, not only power is saved by reducing the light amount of the light emitting means, but also by reducing the volume of the sound generating means and the brightness of the display means. Even power saving is done. From the above, effective power saving can be performed.

  Suitable display means in the present invention include an electric display means such as a liquid crystal type, a dot matrix type, an electroluminescence element type, and a 7 segment type, and a mechanical display means such as a drum type and a belt type. In particular, it is preferable to use an electric display unit, and it is particularly preferable to use a liquid crystal type among the electric display units. In this way, it becomes easy to execute a complicated display effect. Note that these display means may be a symbol display device capable of displaying a plurality of symbols.

  As the light emitting means, any conventionally known light emitting means can be used, but a light emitting diode (LED) having advantages of small size, long life and power saving is preferably used.

The invention according to claim 2, in claim 1, the first selecting means that having a function for switching to the normal power mode or the power saving mode, are provided on the machine back side of the gaming machine and the It is electrically connected to the integrated control unit Rutotomoni, wherein the normal power mode or the second selection means that having a function for switching to the power saving mode, is arranged on the machine front side of the gaming machine and the supervising Electrically connected to the control means, the overall control means determines whether or not to lower the drive voltage according to the selection results by the first selection means and the second selection means, the display control means The gist of the present invention is to determine whether or not to lower the power supply voltage according to the selection results by the first selection means and the second selection means.

  Therefore, according to the second aspect of the present invention, it is determined whether or not the power saving power generation resistor is selected by the first selection unit and the second selection unit (that is, whether the drive voltage or the power supply voltage is reduced). Therefore, it is possible to select whether or not to save power according to the needs of the game store or the player, not the setting at the time of designing the gaming machine. In addition, not only can a store clerk at a gaming store determine power saving by operating the first selection means on the back side of the machine, but also by operating the second selection means on the machine surface side by the player, It can be determined whether or not to save power. For this reason, the selection of whether or not to save power can be made in a more detailed manner according to the needs of the game shop and the player.

  As the first selection means, a mechanical switch (mechanism switch) that outputs a signal only while operating the first selection means, for example, an electromagnetic that outputs a signal when a store clerk's hand approaches. Examples include a type switch (proximity switch), for example, a touch sensor that outputs a signal when a store clerk's hand comes into contact. Further, when the first selection means is operated by a store clerk of the game store, the place where the first selection means is provided is on a control board (for example, on the overall control board) in the gaming machine.

  Similarly, as the second selection means, a mechanical switch (mechanical switch) that outputs a signal only while operating the second selection means, for example, an electromagnetic type that outputs a signal when the player's hand approaches. For example, a switch (proximity switch), for example, a touch sensor that outputs a signal when a player's hand comes into contact therewith can be used. Further, when the second selection means is operated by the player, the place where the second selection means is provided is preferably on the machine surface side of the gaming machine that can be reached by the player, specifically, an outer frame, Examples include an inner frame, a front frame, an upper ball tray, a lower ball tray, an operation handle used for launching a game ball, and the back side of an ashtray.

  According to a third aspect of the present invention, in the second aspect, the operation of the second selection unit is effective when the first selection unit causes the overall control unit to select the power saving power generation resistor. It becomes the gist.

  For example, when the power saving mode is set, the voltage supplied to various devices (display means, light emission means, sound generation means) decreases, and the player may feel unsatisfactory in the performance. Therefore, in the invention described in claim 3, when the first selection unit selects the power-saving power generation resistor, that is, when the power-saving mode is set, the operation of the second selection unit is made effective. . Thereby, even if the game store side sets the power saving mode, the player can cancel the power saving mode by operating the second selection means, so that it is not necessary to impair the interest of the game by the power saving mode.

The invention according to claim 4, in claim 2 or 3, wherein the second selection means, also serves as an operating means for directing execution to be operated to perform a predetermined effect in said symbol variation games, The period during which the symbol variation game is not being executed is set as an effective period in which the operation of causing the overall control unit to select the normal power generation resistor or the power saving power generation resistor is performed by the second selection unit. This is the gist.

  Therefore, according to the fourth aspect of the invention, the effect execution operation means used during the symbol variation game functions as the second selection means when the symbol variation game is not being executed. The operating means can be used effectively. In addition, since the second selection unit need not be provided separately from the effect execution operation unit, it is possible to avoid an increase in cost due to the provision of the second selection unit.

  Here, as the effect execution operation means, a mechanical switch (mechanical switch) that outputs a signal only while operating the effect execution operation means, for example, a signal is output when a player's hand approaches. Examples thereof include an electromagnetic switch (proximity switch), such as a touch sensor that outputs a signal when a player's hand touches. Furthermore, the place where the operation means for effect execution is provided is preferably on the machine surface side of the gaming machine that can be reached by the player. Specifically, the outer frame, the middle frame, the front frame, the upper ball tray, the lower ball Examples include dishes, operation handles used for launching game balls, and the back side of ashtrays.

The invention according to claim 1 is a main control means for controlling the entire gaming machine, a general control means for controlling a plurality of sub-control means based on a control command from the main control means, and a display means. A plurality of display control means for performing control to execute a display effect by the light emission control means for performing control to execute the light emission effect by the light emitting means, and voice control means for performing control to execute the sound effect by the sound generating means. Sub-control means, electrically connected to the overall control means and the display control means, generates a power supply voltage necessary for the operation of the overall control means and the display control means, and the generated power supply voltage is used as the overall control means And a power supply board to be supplied to the display control means, wherein the overall control means is based on a power supply voltage supplied from the power supply board. A power generation circuit that generates a drive voltage necessary for the operation of the light emission control unit and the sound control unit, and the power generation circuit includes a normal power generation resistor whose resistance value is set to a normal setting value, and a resistance value A power-saving power generation resistor set to a power-saving setting value that is larger than the normal setting value, and reduces the drive voltage generated by the power generation circuit for power saving while maintaining energization Switching to the power mode is possible during a period when the symbol variation game that varies a plurality of types of symbols is not executed, and the overall control means selects the normal power generation resistor or the power saving power generation resistor and, when the power-saving power generating resistor is selected and switched to the power saving mode it has been performed, the volume of the light intensity and the sound generating means of the light emitting means to lower the driving voltage The gaming machine for causing Do as its gist.

Therefore, according to the first aspect of the present invention, when the power saving power generation resistor is selected by the overall control means, power saving is performed by reducing the drive voltage. That is, since power saving is performed regardless of whether or not the game is in progress, the power saving effect is enhanced. In addition, when the power saving power generation resistor is selected by the overall control means, not only power is saved by reducing the light amount of the light emitting means, but also power saving is achieved by reducing the volume of the sound generating means. Is called. From the above, effective power saving can be performed.

As described above in detail, according to the first to fourth aspects of the invention, it is possible to save power regardless of whether or not a game is in progress and to save power to a plurality of devices controlled by the sub-control means. Thus, it is possible to provide a gaming machine that can effectively save power. In particular, according to the invention described in claim 2, it is possible to select whether or not to save power according to the needs of a game store or a player.

The schematic front view which shows the pachinko machine in this invention. The schematic back view which shows the pachinko machine in this invention. The block diagram for demonstrating the connection relation of a main control board and another board | substrate. The block diagram for demonstrating electrical structures, such as a power supply board in 1st Embodiment, a comprehensive control board, a display control board, and an audio | voice / lamp control board. The block diagram for demonstrating electrical structures, such as a power supply board in 2nd Embodiment, a comprehensive control board, a display control board, and an audio | voice / lamp control board. (A) is a time chart for explaining the duty ratio in the normal power mode in the second embodiment, and (b) is a time chart for explaining the duty ratio in the power saving mode in the second embodiment. (A) is a time chart for demonstrating the duty ratio in the normal power mode in other embodiment, (b) is a time chart for demonstrating the duty ratio in the power saving mode in other embodiment.

[First Embodiment]
Hereinafter, a first embodiment in which a gaming machine of the present invention is embodied in a pachinko machine 10 will be described with reference to the drawings.

(1) Schematic configuration on the machine surface side of the pachinko machine 10 FIG. 1 schematically shows the machine surface side of the pachinko machine 10. The pachinko machine 10 includes a vertical rectangular outer frame 11 that forms an outer shell of the machine body. On the front side of the opening of the outer frame 11, a vertical rectangular middle frame 12 constituting the airframe is assembled so as to be openable and detachable. Further, a front frame 14 is assembled on the front side of the middle frame 12 so as to be opened and closed in a laterally open state. The front frame 14 has a structure in which an upper ball tray 15 is integrally assembled below the window 14a while having a window 14a at the center. A glass frame (not shown) for seeing through and protecting the game board 13 disposed inside the machine is assembled on the back side of the front frame 14. Further, an upper frame lamp 16a, a left frame lamp 16b, and a right frame lamp 16c are provided on the front surface of the front frame 14. Each of the frame lamps 16a to 16c includes a light emitter (not shown) (not shown), and is configured by covering the light emitter with a lens member. In these frame lamps 16a to 16c, light emission effects such as lighting (flashing) and light extinction are executed according to various game performance modes (big hit, reach, etc.) of the pachinko machine 10. That is, the frame lamps 16a to 16c have a function as "light emitting means".

  Further, as shown in FIG. 1, a left speaker 17 a is disposed at the upper left portion of the front frame 14, and a right speaker 17 b is disposed at the upper right portion of the front frame 14. The left speaker 17a and the right speaker 17b are for executing sound effects for outputting various sounds. That is, the left speaker 17a and the right speaker 17b have a function as “sound generation means”. The left speaker 17a and the right speaker 17b are mounted on the back side of the front frame 14, and a plurality of sound emitting holes are formed at locations corresponding to the left speaker 17a and the right speaker 17b on the front side of the front frame 14.

  Further, a lower ball tray 18 is assembled to be openable and closable below the front frame 14 on the front side of the middle frame 12. On the right side of the lower ball tray 18 is mounted an operation handle 19 that is turned by the player when the game ball is launched. Further, on the left side of the lower ball tray 18, an ashtray 20, a woofer speaker 17c for executing sound effects for outputting various sounds, and the like are disposed. That is, the woofer speaker 17c has a function as “sound generation means”. The woofer speaker 17c is attached to the middle frame 12.

  As shown in FIG. 1, a frame-shaped center accessory 60 having a symbol display device 61 is mounted at a substantially central portion of the game board surface 13 a of the game board 13. In addition, although the symbol display device 61 of this embodiment is a liquid crystal type, a dot matrix type, an electroluminescence element type, and a 7 segment type symbol display device may be used. In the symbol display device 61, a game effect (display effect) based on a varying image (or image display) is executed. That is, the symbol display device 61 has a function as “display means”. Then, the symbol display device 61 displays a symbol combination game in which a plurality of types of effect symbols are varied in three columns and a symbol combination is derived in relation to the display effect.

  A start winning device 21 in which a start winning port 21a is formed is disposed below the center combination 60 on the game board surface 13a. The start winning device 21 is integrally configured with an ordinary electric accessory comprising a pair of blade members 21b. The pair of blade members 21b are configured to open and close by the excitation action of the ordinary electric accessory solenoid SOL1 (see FIG. 3). In addition, a start opening switch SE1 (see FIG. 3) for detecting a game ball that has entered the start winning opening 21a is provided behind the start winning apparatus 21. The start port switch SE1 is turned on when a game ball won in the start winning device 21 is detected, and outputs a winning signal. On the other hand, the start port switch SE1 is turned off when no game ball is detected, and no winning signal is output. When a winning signal is output, a symbol variation game is performed by the special symbol display device 51 described later, and a symbol combination game is performed by the symbol display device 61 in relation to the symbol variation game, and a prize ball Is paid out.

  As shown in FIG. 1, a big winning device 23 is arranged below the start winning device 21. A count switch SE3 (see FIG. 3) for detecting a winning game ball is provided in the back of the big winning device 23. In addition, the big prize opening door 23a of the big prize winning device 23 can be switched between a closed state in which no hit ball is received and an open state in which the hit ball is easily received by the exciting action of the big prize port solenoid SOL2 (see FIG. 3). Yes. In the present embodiment, the “closed state” of the grand prize opening door 23a means a state in which the big prize opening door 23a is completely closed, and the “open state” of the big prize opening door 23a means the grand prize opening door. 23a is in a fully open state. When a game ball is detected by the count switch SE3, a prize ball is paid out.

  A gate 25 having a function of detecting the passage of a game ball is provided on the left side of the center accessory 60. Behind the gate 25 is provided a gate switch SE5 (see FIG. 3) for detecting a game ball that has passed. It should be noted that when the game ball is detected by the gate switch SE5, a random number is acquired, and based on the result of determining whether or not the acquired random number is a predetermined random value, the ordinary electric accessory solenoid SOL1 is driven. The Since the pair of blade members 21b are opened by such determination (hit determination), it is easy for the game ball to win the start winning opening 21a.

  As shown in FIG. 1, a special symbol display device 51 having a visible display unit is disposed on the lower left side of the center accessory 60. In the special symbol display device 51, a symbol variation game for changing a plurality of types of special symbols is displayed in response to the winning of the game ball in the start winning device 21, and as a result of the symbol variation game, display of a big hit and a loss The result is displayed. For example, when the result of the symbol variation game is a big hit, at the end of the symbol variation game, symbols indicating eight numbers “1” to “8” are displayed as special symbols. Further, when the result of the symbol variation game is lost, at the end of the symbol variation game, a symbol “-” indicating a loss is displayed as a special symbol.

  Further, in the present embodiment, the symbol combination game by the symbol display device 61 is performed in accordance with the symbol variation game on the special symbol display device 51. Specifically, the symbol combination game is started almost simultaneously with the start of the symbol variation game, and the result of the symbol combination game is displayed almost simultaneously with the end of the symbol variation game (the display result of jackpot or lose) is displayed. ing. In the present embodiment, the symbol combination game performed on the symbol display device 61 and the symbol variation game performed on the special symbol display device 51 are referred to as “variable game”.

  As shown in FIG. 1, a special symbol hold display device C is disposed below the special symbol display device 51. The special symbol hold display device C is composed of a plurality of (four) light-emitting units each including a first special hold lamp, a second special hold lamp, a third special hold lamp, and a fourth special hold lamp. The special holding lamp is turned on when there is a game ball (special symbol holding ball) stored in response to the winning of the start winning device 21, and is turned off when there is no special symbol holding ball. Each special holding lamp is for indicating the number of special symbol holding balls (the number of special symbol holding balls). For example, when there are three special symbol holding balls, three special holding lamps are lit.

  Here, the “number of special symbol reserved balls” is a range of a predetermined maximum value (4 in the present embodiment) that is the number of game balls won in the start winning device 21 during the fluctuation of the special symbol (the effect symbol). This is the value stored in. The number of special symbol reserved balls is “+1” by winning a game ball to the start winning device 21 and “−1” by starting the variable game.

  As shown in FIG. 1, a normal symbol display device 53 having a visible display unit is disposed on the lower right side of the center accessory 60. In the normal symbol display device 53, a normal symbol variation game for changing the normal symbol is executed in response to the passing of the game ball to the gate 25 (see FIG. 1). As a result of the normal symbol variation game, a random number lottery is performed. The normal symbol indicating the result is stopped and displayed. Note that there are two types of normal symbols in the present embodiment: a winning symbol “◯” or a lost symbol “X”. When the winning symbol is derived (when the normal symbol variation game is won), the normal electric accessory solenoid SOL1 is driven for a predetermined time, and the pair of blade members 21b are opened. .

  A normal symbol holding display device F is disposed below the normal symbol display device 53. The normal symbol hold display device F is composed of a plurality of (four) light-emitting units including a first normal hold lamp, a second normal hold lamp, a third normal hold lamp, and a fourth normal hold lamp. The normal holding lamp is turned on when there is a game ball (ordinary symbol holding ball) stored with the passage of the gate 25 as an opportunity, and is turned off when there is no normal symbol holding ball. Each normal holding lamp is for indicating the number of normal symbol holding balls (the number of normal symbol holding balls). For example, when there are two normal symbol holding balls, two normal holding lamps are lit.

  Here, the “ordinary symbol reserved ball count” is a value stored in the range of a predetermined maximum value (4 in the present embodiment) of the number of game balls that have passed through the gate 25. The number of normal symbol reserved balls is “+1” when the game ball passes through the gate 25 and is “−1” when the normal symbol variation game is started.

  On the upper surface of the upper ball tray 15 shown in FIG. 1, an effect button 15a as a “second selection means” is provided. In other words, the effect button 15a is arranged on the surface side of the pachinko machine 10 that can be reached by the player. The effect button 15a is operated by the player in order to switch to a power saving mode in which power saving is performed or a normal power mode in which power saving is not performed. The effect button 15a also functions as an “effect execution operation means” that is operated to execute a predetermined effect during the symbol variation game. The effect button 15a is turned on when operated by the player, and outputs a second operation signal to the overall control CPU 32a (see FIGS. 3 and 4) of the overall control board 32. Further, the effect button 15a is turned off when not being operated by the player, and does not output the second operation signal. The effect button 15 a may be provided on the back side of the ashtray 20 and other places such as the operation handle 19.

(2) Schematic configuration of the back side of the pachinko machine 10 FIG. 2 schematically shows the back side of the pachinko machine 10. A mechanism set board 3 for assembling back parts is disposed on the back side of the middle frame 12. A ball tank 4 for storing game balls is provided on the entire upper portion of the mechanism set board 3 on the back side. Below the ball tank 4, a tank rail 5 is provided for allowing the game balls flowing out therefrom to flow down in an aligned state. A ball supply path 6 is connected to the lower end (right end) of the tank rail 5 that extends obliquely in the lower right direction, and a ball payout device 7 is connected to the lower end of the ball supply path 6. In addition, a frame external terminal plate 8 for connecting a hall computer (not shown) and the pachinko machine 10 is disposed in the vicinity of the connecting portion between the tank rail 5 and the ball supply path 6. The frame external terminal board 8 is configured to transmit prize ball information, ball rental information, and ball break information to the hall computer.

  As shown in FIGS. 2 to 4, the pachinko machine 10 according to the present embodiment has various boards (main control board 31, overall control board 32, display control board 33, audio on the back side of the mechanism set board 3. A lamp control board 34, a payout control board 35, a launch control board 36, a power supply board 37, and the like. The payout control board 35 is electrically connected to the main control board 31 and controls the payout of game balls by the ball payout device 7 based on a payout instruction from the main control board 31. Further, the launch control board 36 is electrically connected to the payout control board 35, and detects the operation state of the operation handle 19 constituting the hitting ball launching device, and controls the launch intensity of the game ball based on it. Plays. Further, the power supply board 37 plays a role of generating a plurality of power supply voltages (34V or 5V DC voltage in this embodiment) necessary for the operation of each of the boards 31 to 36. The power supply board 37 is electrically connected to the overall control board 32 and the display control board 33, and supplies the generated power supply voltage to the overall control board 32 and the display control board 33.

  As shown in FIG. 2, the main control board 31, the overall control board 32, the display control board 33, the payout control board 35, and the power supply board 37 are accommodated in a dedicated board case 30. These substrate cases 30 are openable and closable flat boxes made of a transparent or translucent synthetic resin material, and are sealed with screws with the substrates 31 to 33, 35, and 37 arranged in parallel on the bottom thereof. Yes. A large number of through holes (not shown) for releasing heat generated from the substrates 31 to 33, 35, and 37 are formed in the substrate case 30.

  A volume control knob 71 for steplessly changing the volume of sound output from the speakers 17a to 17c is provided on the left side (exposed portion not covered by the board case 30) on the overall control board 32. Is provided. When the volume control knob 71 is turned by a store clerk, the resistance value of a variable resistor (not shown) provided in the electrical path connecting the overall control CPU 32a and the speakers 17a to 17c changes. The voltage of the current flowing through the electrical path changes. For example, when the volume control knob 71 is rotated in the clockwise direction, the resistance value of the variable resistor decreases and the voltage of the current flowing through the electrical path increases, so that the sound output from the speakers 17a to 17c increases. . On the other hand, when the volume control knob 71 is rotated counterclockwise, the resistance value of the variable resistor is increased and the voltage of the current flowing through the electrical path is decreased, so that the sound output from the speakers 17a to 17c is small. Become.

  As shown in FIGS. 2 to 4, a power saving switch SW as a “first selection means” is provided in the lower right portion (exposed portion not covered by the substrate case 30) on the overall control board 32. Yes. That is, the power saving switch SW is arranged on the back side of the pachinko machine 10 that is out of reach of the player. The power saving switch SW is operated by a store clerk of the game store in order to switch to the power saving mode or the normal power mode. The power saving switch SW is turned on when operated by a store clerk in the amusement store, and outputs a first operation signal to the overall control CPU 32a. Further, the power saving switch SW is turned off when it is not operated by a store clerk of the amusement store, and does not output the first operation signal.

  A power switch (not shown) is provided on the power board 37. When this power switch is operated to the on position by a store clerk at the amusement store, power supply to the pachinko machine 10 is started. Further, when the power switch is operated to the off position, the power supply to the pachinko machine 10 is cut off.

  Further, as shown in FIG. 2, a RAM clear switch 38 is provided at a lower end portion (exposed portion not covered with the substrate case 30) on the power supply substrate 37. That is, the RAM clear switch 38 is arranged in a state of being separated from the volume control knob 71 and the power saving switch SW. The RAM clear switch 38 outputs a RAM clear signal to the main control board 31. The main RAM of the main control board 31 normally has a backup function for storing the gaming state at the time of a power failure and the number of unpaid prize balls remaining. Therefore, when the RAM clear switch 38 is operated when the power switch is operated to the ON position (when power supply to the pachinko machine 10 is started), a RAM clear signal is output and the gaming state stored in the main RAM In addition, all data on the remaining number of unpaid prize balls is erased.

(3) Electrical Configuration of Pachinko Machine 10 As shown in FIG. 3, the pachinko machine 10 includes a main control board 31, the overall control board 32, the display control board 33, and the sound / lamp control board 34. ing. An overall control board 32 is electrically connected to the main control board 31, and a display control board 33 and an audio / lamp control board 34 are electrically connected to the overall control board 32.

(3-1) Electrical Configuration of Main Control Board 31 The main control board 31 includes a main CPU 31a that is a “main control means” that controls the entire pachinko machine 10. The main CPU 31a is connected to the start port switch SE1, the count switch SE3, and the gate switch SE5. Further, the special symbol display device 51, the special symbol hold display device C, the normal symbol display device 53, and the normal symbol hold display device F are connected to the main CPU 31a. In addition, the main CPU 31a is connected to the ordinary electric accessory solenoid SOL1 and the special prize opening solenoid SOL2.

  Further, a main ROM (not shown) and the main RAM (not shown) are electrically connected to the main CPU 31a shown in FIG. The main CPU 31a updates the values of various random numbers such as a jackpot determination random number, a jackpot design random number, a reach determination random number, a variation pattern distribution random number, etc., used for various lotteries relating to the variation game at predetermined intervals. Then, the main CPU 31a rewrites the value before update by setting the updated value in the random number storage area of the main RAM. In the timer storage area of the main RAM, various timers that are appropriately rewritten during the operation of the pachinko machine 10 are stored (set).

  The big hit determination random number is a random number used when determining whether or not the variable game is a big hit (when determining the big hit). The jackpot symbol random number is a random number used in determining the special symbol when the result of the variable game is a jackpot. The reach determination random number is a random number used when determining whether or not to execute the reach effect when the result of the floating game is lost (during reach determination). The variation pattern distribution random number is a random number used when determining the variation pattern for specifying the contents of the effect of the game effect in the variation game.

  The main ROM stores a variation pattern distribution table in which variation patterns for symbol combination games are distributed. In each variation pattern, the symbols in all the columns displayed on the symbol display device 61 (the effect symbols) start to vary (the symbol combination game starts), and then the symbols in all the columns stop (the symbol combination game ends). This is for specifying the time and contents of the game effect (display effect, light emission effect, sound effect) until the game is performed. Each variation pattern is assigned a variation pattern distribution random number value. In addition, the variation pattern distribution table is allocated with a variation pattern for a big hit effect, a variation pattern for a loss reach effect, and a variation pattern for a loss effect. The variation pattern for the jackpot effect shows the pattern that becomes the base of the jackpot effect that displays the symbol combination (the jackpot symbol combination) in which the middle symbol stops at the same symbol as the left symbol and the right symbol after reaching the reach effect. Yes. The variation pattern for the lost reach production is the pattern that becomes the base of the lost reach production that displays the symbol combination (the combination of the lost symbols) that the middle symbol stops at a different symbol from the left symbol and the right symbol after reaching the reach effect. Show. The variation pattern for losing effect indicates a pattern serving as a base of losing effect for deriving a symbol combination of losing symbols (a symbol combination from which a symbol combination that is a big hit or reach is not derived). Note that the effect time (variation time) of the big hit effect, the lose reach effect, and the lose effect differs for each variation pattern.

  Next, various processes related to the symbol variation game executed by the main CPU 31a shown in FIG. 3 (such as jackpot determination, reach determination, jackpot symbol, lost symbol, variation pattern determination, etc.) will be described.

  The main CPU 31a uses the value of the jackpot determination random number and the value of the jackpot symbol random number updated every predetermined period as a trigger when the start winning condition is satisfied (the detection of the game ball by the start winning device 21). Obtained from the main RAM, and stores (stores) these values in the random number storage area of the main RAM. The main CPU 31a determines whether or not the result of the symbol variation game is a big hit. More specifically, the main CPU 31a compares the jackpot determination random number stored in the random number storage area of the main RAM with the jackpot determination value stored in the main ROM immediately before the start of the symbol variation game. Then, a big hit determination (big hit lottery) for determining whether or not the symbol variation game is successful is performed. In the present embodiment, the numbers that can be taken by the jackpot determination random numbers are 0 to 946 (total of 947 different integers). Then, the main CPU 31a uses the three jackpot determination values determined in advance from the values that can be taken by the jackpot determination random number, and determines the jackpot lottery probability as 3/947 (= 315.7) as a jackpot determination. I do.

  When the determination result of the big hit determination is negative (the value of the big hit determination random number and the big hit determination value do not match), the main CPU 31a shown in FIG. 3 determines the symbol “-” which is a lost symbol as the special symbol. . Further, the main CPU 31a stores the data corresponding to the determined special symbol in the main RAM until the process related to the next symbol variation game is performed.

  Then, the main CPU 31a compares the reach determination random number value read from the main RAM with the reach determination value stored in the main ROM, and determines whether or not to execute the lose reach. In the present embodiment, the numerical values that can be taken by the random numbers for reach determination are 0 to 180 (a total of 181 types of integers). The reach determination value is a value determined in advance from numerical values that can be taken by the reach determination random number.

  If the determination result of reach determination is affirmative (the value of the reach determination random number and the reach determination value match), the main CPU 31a shown in FIG. 3 determines the loss reach. If the determination result of reach determination is negative (the reach determination random number value and the reach determination value do not match), the main CPU 31a determines a loss (a loss without a reach).

  On the other hand, if the determination result of the jackpot determination is affirmative (the value of the jackpot determination random number matches the jackpot determination value), the main CPU 31a determines the jackpot. When the jackpot determination is made, the main CPU 31a displays a symbol indicating any one of “1” to “8” based on the value of the jackpot symbol random number stored in the random number storage area of the main RAM. The special symbol is determined. Then, the main CPU 31a stores data corresponding to the determined special symbol in the main RAM until a process related to the next symbol variation game is performed.

  Then, the main CPU 31a shown in FIG. 3 determines the variation pattern based on the determination results of the jackpot determination and the reach determination. More specifically, when the big hit is determined in the big hit determination, the main CPU 31a reads the value of the random variation pattern distribution random number from the main RAM, and based on the value, for the big hit effect from the variable pattern distribution table Determine the variation pattern. Further, when losing reach is determined in the reach determination, the main CPU 31a reads the value of the variation pattern distribution random number from the main RAM, and based on the value, the variation pattern for losing reach production from the variation pattern distribution table. decide. Further, when the loss is determined in the reach determination, the main CPU 31a reads the variation pattern distribution random number value from the main RAM, and determines the variation pattern for the loss effect from the variation pattern distribution table based on the value. .

  When the main CPU 31a shown in FIG. 3 determines the special symbol and the variation pattern, the main CPU 31a sets (stores) the variation time associated with each variation pattern in the timer storage area of the main RAM as a variation timer. The special symbol display device 51 is caused to start changing the special symbol.

  When the main CPU 31a instructs the overall control CPU 32a of the overall control board 32 to perform control, a control command or the like is used as a control signal (8-bit signal), and the signal is output to an output port (not shown) and an output buffer (not shown). (Not shown) at a predetermined timing. Specifically, the main CPU 31a first generates a variation pattern designation command for designating a variation pattern and instructing the start of symbol variation, and sets it as a control command (stored in the main RAM). The control command set here is output in the next command output process. Next, the main CPU 31a sets (stores in the main RAM) a special symbol designation command for designating a special symbol as a control command. The control command set here is output in the next command output process. Further, the main CPU 31a subtracts the variation timer set at the beginning of the variation every interrupt (4 ms). When the variation time associated with the variation pattern elapses (when the variation timer reaches 0 ms), the main CPU 31a sets (outputs) a special symbol and a symbol stop command that instructs the stop of the effect symbol as a control command. To do.

  The main CPU 31a shown in FIG. 3 reads a read signal (INT signal or strobe signal) for instructing the overall control CPU 32a to read a control command constituting the control signal in accordance with the output timing of the control signal. Are output via an output port and an output buffer.

(3-2) Electrical Configuration of Overall Control Board 32 The overall control board 32 shown in FIGS. 3 and 4 includes an overall control CPU 32a that is an “overall control means”. The overall control CPU 32a operates based on a power supply voltage supplied from the power supply board 37 (in this embodiment, a DC voltage of 5V). The general control CPU 32a is electrically connected to an input buffer (not shown) for inputting control signals and read signals output from the main CPU 31a. Further, an input port (not shown) is electrically connected to the input buffer, and a control signal and a read signal are input to the overall control CPU 32a via the input port.

  Further, the effect button 15a and the power saving switch SW are electrically connected to the overall control CPU 32a. Further, a general ROM (not shown) and a general RAM (not shown) are connected to the general control CPU 32a. The overall control CPU 32a updates the values of various random numbers used for determining the game effect at predetermined intervals. Then, the overall control CPU 32a rewrites the value before update by setting the updated value in the setting area of the overall RAM. For example, in the random number storage area of the general RAM, a random number for a left symbol, a random number for a middle symbol, a random number for a right symbol, and the like are stored.

  As shown in FIG. 4, the overall control board 32 includes a power generation circuit 41, a lamp drive circuit 44, and a sound generation circuit 45 (amplifier). The power generation circuit 41 includes a normal power generation resistor 42 and a power saving power generation resistor 43. Here, the resistance value of the normal power generation resistor 42 is set to a normal set value. On the other hand, the resistance value of the power saving power generation resistor 43 is set to a power saving set value that is a value larger than the normal set value (for example, a value that is twice the normal set value). The power generation circuit 41 is based on the power supply voltage (34V DC voltage in this embodiment) supplied from the power supply board 37, and the sound / lamp control CPU 34a of the sound / lamp control board 34 (see FIG. 3). The drive voltage necessary for the operation is generated. Specifically, the power generation circuit 41 generates a drive voltage of 12V when the normal power generation resistor 42 is used, and generates a drive voltage of 6V when the power saving power generation resistor 43 is used. It has become. The lamp driving circuit 44 is configured to dynamically drive the frame lamps 16 a to 16 c based on the driving voltage supplied from the power generation circuit 41. In the present embodiment, the duty (DUTY) ratio when driving the frame lamps 16a to 16c is constant regardless of the magnitude of the drive voltage. Note that the duty ratio of the present embodiment is 25% (1: 4). Furthermore, the sound generation circuit 45 amplifies the volume adjusted by the volume adjustment knob 71 based on the drive voltage supplied from the power supply generation circuit 41 and outputs the amplified volume to the speakers 17a to 17c.

  By the way, when the variation pattern designation command is input from the main CPU 31a, the overall control CPU 32a shown in FIGS. 3 and 4 stores the variation pattern designated by the variation pattern designation command in the overall RAM. It has become. When the special symbol designation command is input, the overall control CPU 32a stores the special symbol designated by the special symbol designation command in the overall RAM.

  Furthermore, the overall control CPU 32a generates the effect symbols that are stopped and displayed on the symbol display device 61 at the end of the symbol combination game, based on the special symbols stored in the overall RAM. For example, when the special symbol stored in the overall RAM is any one of “1” to “8”, the variation pattern stored in the overall RAM is the variation pattern for the big hit effect. In this case, the overall control CPU 32a generates an effect symbol (effect symbol left, middle, right) that is finally stopped by the symbol display device 61 so that all columns are of the same type. Specifically, the overall control CPU 32a generates the effect symbol left, the effect symbol in the effect symbol, and the effect symbol right (each effect symbol is the same type) based on the special symbol. The generated effect symbols (effect symbol left, middle, and right) are derived to the symbol display device 61 as a final symbol combination. Then, the overall control CPU 32a stores data corresponding to the produced effect symbol left, the effect symbol, and the effect symbol right in the overall RAM.

  When the special symbol stored in the overall RAM is “−” and the variation pattern stored in the overall RAM is the variation pattern for the lost reach production, the overall control CPU 32a shown in FIGS. Decides to lose. In this case, the overall control CPU 32a determines the effect symbols left, middle, and right so that the left column and the right column are the same type of symbols, and the middle column is a different type of symbols from the left and right columns. Specifically, the effect symbol left and the effect symbol right (both effect symbols are the same type) are generated based on the value of the random number for the lost left symbol. Then, based on the value of the random symbol for the losing symbol, the effect symbol is generated. If the value of the random symbol for losing and the value of the random number for the left of the losing symbol (or the value of the random number for losing the right symbol) match, the overall control CPU 32a determines that the symbol in the effect symbol and the effect symbol left (or effect symbol) The production pattern is generated so that (right) does not match. Then, the overall control CPU 32a stores data corresponding to the produced effect symbol left, the effect symbol, and the effect symbol right in the overall RAM. In the present embodiment, the numbers that can be taken by random numbers for the left symbol for lost, the random number for right for lost, and the random number for lost symbol are 10 integers from 0 to 9, and one numerical value corresponds to each type of symbol. It is attached.

  When the special symbol stored in the overall RAM is “−” and the variation pattern stored in the overall RAM is the variation pattern for the loss effect, the overall control CPU 32a shown in FIGS. Determine the loss. In this case, the overall control CPU 32a generates effect symbols left, middle, and right so that all columns do not become the same type of symbols. Specifically, the production symbol left is generated based on the value of the random symbol for the loss left symbol, the production symbol is generated based on the value of the random number for the middle symbol of the loss, and the production is produced based on the value of the random number for the loss right symbol. Generate the symbol right. If the value of the lost symbol random number and the value of the lost right symbol random match, the overall control CPU 32a generates the effect symbol right so that the effect symbol left does not match the effect symbol right. Then, the overall control CPU 32a stores data corresponding to the produced effect symbol left, the effect symbol, and the effect symbol right in the overall RAM.

  Then, the overall control CPU 32a uses, as control commands, a change pattern designation command for designating a change pattern stored in the overall RAM, the display control CPU 33a of the display control board 33, and the voice / lamp control board 34. This is output to the lamp control CPU 34a. As a result, the specific contents of the game effects executed by the display control board 33 and the sound / lamp control board 34 are comprehensively controlled by the overall control board 32 based on the control command from the main CPU 31a.

  Further, the overall control CPU 32a shown in FIGS. 3 and 4 outputs an effect symbol left designation command for designating the effect symbol left of the effect symbol to the display control CPU 33a as a control command. Similarly, the overall control CPU 32a outputs to the display control CPU 33a, as control commands, an effect symbol right designation command for designating the effect symbol right of the effect symbol and an effect symbol middle designation command for designating the effect symbol of the effect symbol. .

  Thereafter, when the symbol stop command is input from the main CPU 31a, the overall control CPU 32a outputs the input symbol stop command as a control command to the display control CPU 33a and the sound / lamp control CPU 34a.

  Further, the overall control CPU 32a counts the time after the symbol stop command is input. When the predetermined pattern (for example, 1 second) has elapsed after the symbol stop command is input (the symbol combination game is ended), but the variation pattern designation command is not input from the main CPU 31a (next symbol) Combination game does not start). In this case, the overall control CPU 32 a outputs a demonstration effect designation command to the display control board 33 and the sound / lamp control board 34. The demonstration effect designation command is output to display the initial symbol on the symbol display device 61 and cause the frame lamps 16a to 16c and the speakers 17a to 17c to execute a demonstration effect (demonstration effect). It has become.

  Note that the overall control CPU 32a shown in FIGS. 3 and 4 sets (stores in the overall RAM) an effective period for validating the input of the second operation signal from the effect button 15a. The effective period is set to a period in which the symbol variation game is not executed, that is, a period in which the demonstration effect is executed.

  Further, the overall control CPU 32a determines whether or not to reduce the drive voltage necessary for the operation of the sound / lamp control CPU 34a according to the selection result by the power saving switch SW and the effect button 15a. ing. More specifically, the overall control CPU 32a determines whether or not the first operation signal from the power saving switch SW or the second operation signal from the effect button 15a has been input. When it is determined that the first operation signal is input from the power saving switch SW, the overall control CPU 32a selects the power saving power generation resistor 43 if the normal power generation resistor 42 is already selected. If the power saving power generation resistor 43 has already been selected, the normal power generation resistor 42 is selected. That is, the overall control CPU 32a alternately selects the normal power generation resistor 42 and the power saving power generation resistor 43 every time the first operation signal is input. On the other hand, if it is determined that the second operation signal has been input from the effect button 15a within the effective period, the overall control CPU 32a has already received the normal power generation resistor 42 in response to the input of the first operation signal or the second operation signal. If it is selected, the normal power generation resistor 42 is continuously selected. On the other hand, if the power saving power generation resistor 43 is already selected in response to the input of the first operation signal, the normal power generation resistor 42 is selected. It has become. If it is determined that the second operation signal is input from the effect button 15a outside the effective period, the overall control CPU 32a continues to select the normal power generation resistor 42 if the normal power generation resistor 42 has already been selected. If the power saving power generation resistor 43 has already been selected, the power saving power generation resistor 43 is continuously selected. In other words, the operation of the effect button 15a is effective only within the effective period and when the power saving switch SW causes the overall control CPU 32a to select the power saving power generation resistor 43. If it is determined that neither the first operation signal nor the second operation signal is input, the overall control CPU 32a continues to select the normal power generation resistor 42 if the normal power generation resistor 42 has already been selected. If the power saving power generation resistor 43 is already selected, the power saving power generation resistor 43 is continuously selected.

  When the normal power generation resistor 42 is selected (that is, when the normal power mode is selected), the current supplied from the power supply substrate 37 passes through the normal power generation resistor 42. In this case, the drive voltage generated by the power supply generation circuit 41 (drive voltage of the lamp drive circuit 44 and the sound generation circuit 45) is 12V, and the light amounts of the frame lamps 16a to 16c and the sound volumes of the speakers 17a to 17c are normal. It becomes a state. On the other hand, when the power saving power generation resistor 43 is selected (that is, when the power saving mode is selected), the current supplied from the power supply substrate 37 passes through the power saving power generation resistor 43. In this case, since the resistance value of the power supply generation circuit 41 is larger than when the normal power supply generation resistor 42 is selected, the drive voltage generated by the power supply generation circuit 41 decreases to 6 V, and the frame lamps 16a to 16c The amount of light and the volume of the speakers 17a to 17c are reduced. When the power saving power generation resistor 43 is selected, the overall control CPU 32a outputs a power saving command indicating that it is in the power saving mode to the display control board 33.

  The overall control CPU 32a shown in FIG. 3 and FIG. 4 uses the above control commands and the like as control signals (8-bit signals), and the signals are predetermined via an output port (not shown) and an output buffer (not shown). Output at the timing. Further, the overall control CPU 32a, in accordance with the output timing of the control signal, instructs the display control board 33 and the sound / lamp control board 34 to read a control command constituting the control signal (INT signal or , A strobe signal) is output via an output port and an output buffer.

(3-3) Electrical Configuration of Display Control Board 33 As shown in FIGS. 3 and 4, the display control board 33 includes the display control CPU 33a, which is a “sub control means” and a “display control means”, and an inverter. And a substrate 46. The display control CPU 33a generates a drive voltage (12V DC voltage in this embodiment) necessary for the operation of the inverter board 46 based on the power supply voltage (34V DC voltage in this embodiment) supplied from the power supply board 37. It is designed to generate. The inverter board 46 supplies the drive voltage supplied from the display control CPU 33 a to the backlight of the symbol display device 61. Further, a display ROM (not shown) and a display RAM (not shown) are connected to the display control CPU 33a. The display RAM temporarily stores (sets) various information that can be appropriately rewritten during the operation of the pachinko machine 10.

  The display ROM stores a plurality of types of display effect data used when the symbol combination game is performed, and demonstration effect display effect data used when the demonstration effect is performed. The display effect data and the display effect data for demonstration effect are information for the display control CPU 33a to control the display content (symbol variation etc.) of the symbol display device 61, that is, the symbol display device 61 executes the display effect. This is information for instructing.

  When the change pattern designation command is input from the overall control CPU 32a shown in FIGS. 3 and 4, the display control CPU 33a stores the change pattern designated by the change pattern designation command in the display RAM. It has become.

  In addition, when the effect symbol left designation command is input from the overall control CPU 32a, the display control CPU 33a stores the effect symbol left designated by the command in the display RAM. Similarly, when the presentation design right designation command is input from the overall control CPU 32a, the display control CPU 33a stores the production design right designated by the command in the display RAM, and when the production design middle designation command is inputted. The effect symbols designated by the command are stored in the display RAM.

  Thereafter, when the symbol stop command is input from the overall control CPU 32a shown in FIG. 3 and FIG. 4, the display control CPU 33a is based on the effect symbol left, right, and center stored in the display RAM input at the start of variation. Thus, the symbol display device 61 is instructed to stop the effect symbol. Thereby, the designated effect symbol is stopped and displayed on the symbol display device 61.

  When the variation pattern designation command is input, the display control CPU 33a sets (generates) any one of the plurality of types of display effect data stored in the display ROM, and sets the display effect. Data is stored in a storage area of the display RAM. Thereby, the display control CPU 33a performs display control based on the variation pattern designation command and the display effect data. More specifically, the display control CPU 33a converts display effect data stored in the display RAM into a symbol signal and outputs the symbol signal to the symbol display device 61. As a result, the symbol display device 61 can perform a predetermined display (such as a symbol combination game) based on the symbol signal.

  When the demonstration effect designation command is input from the overall control CPU 32a shown in FIGS. 3 and 4, the display control CPU 33a sets (generates) the demonstration effect display effect data stored in the display ROM. The set demonstration effect display effect data is stored in the storage area of the display RAM. Thereby, the effect by the symbol display device 61 is switched to the demonstration effect. More specifically, the display control CPU 33a converts the demonstration effect display effect data stored in the display RAM into a symbol signal and outputs the symbol signal to the symbol display device 61. As a result, the symbol display device 61 can perform a demonstration effect based on the symbol signal. In the demonstration effect of the present embodiment, an effect that is performed based on the variation pattern for the jackpot effect is introduced.

  Further, when the power saving command is input from the overall control CPU 32a, the display control CPU 33a outputs the input power saving command to the inverter board 46. And the inverter board | substrate 46 reduces the drive voltage (12V) supplied from the display control CPU33a to 6V based on the input power saving command. As a result, the luminance of the backlight of the symbol display device 61 is lowered.

(3-4) Electrical Configuration of Audio / Lamp Control Board 34 As shown in FIG. 3, the audio / lamp control board 34 is “sub-control means”, “light emission control means”, and “audio control means”. The voice / lamp control CPU 34a is provided. A voice / lamp ROM (not shown) and a voice / lamp RAM (not shown) are connected to the voice / lamp control CPU 34a. In the sound / lamp RAM, various types of information that are appropriately rewritten during the operation of the pachinko machine 10 are temporarily stored (set).

  The sound / lamp ROM stores a plurality of types of light effect data and a plurality of types of sound effect data used when the symbol combination game is performed. The light emission effect data is information for the sound / lamp control CPU 34a to control the light emission output mode of the frame lamps 16a to 16c. The voice effect data is information for the voice / lamp control CPU 34a to control the voice output mode (sound effect type, language voice type, voice output time, etc.) of the speakers 17a to 17c.

  Furthermore, the demonstration data for demonstration effect used when the demonstration effect is performed is stored in the voice / lamp ROM. The demonstration effect production data is information for the voice / lamp control CPU 34a to instruct the execution of the production also to the frame lamps 16a to 16c and the speakers 17a to 17c.

  When the change pattern designation command is input from the overall control CPU 32a shown in FIGS. 3 and 4, the voice / lamp control CPU 34a displays the change pattern designated by the change pattern designation command in the voice / lamp RAM. To come to remember.

  Thereafter, when the symbol stop command is input from the overall control CPU 32a, the sound / lamp control CPU 34a instructs the frame lamps 16a to 16c to stop the light emission and also instructs the speakers 17a to 17c to stop the sound output. It is like that.

  When the variation pattern designation command is input, the sound / lamp control CPU 34a sets (generates) any one of the plurality of types of light emission effect data stored in the sound / lamp ROM, The set light effect data is stored in the storage area of the sound / lamp RAM. Thus, the sound / lamp control CPU 34a performs light emission control (light emission effect) based on the light emission effect data corresponding to the variation pattern designation command. More specifically, the sound / lamp control CPU 34a converts the light emission effect data stored in the sound / lamp RAM into a light emission control signal and outputs it to the frame lamps 16a to 16c. As a result, the frame lamps 16a to 16c can perform a predetermined light emission operation (lighting, blinking, etc.) based on the light emission control signal.

  When a change pattern designation command is input, the voice / lamp control CPU 34a shown in FIG. 3 sets (generates) any one of a plurality of types of voice effect data stored in the voice / lamp ROM. The set sound production data is stored in the storage area of the sound / lamp RAM. Thus, the voice / lamp control CPU 34a performs voice control (voice production) based on the voice production data corresponding to the variation pattern designation command. More specifically, the sound / lamp control CPU 34a converts sound effect data stored in the sound / lamp RAM into sound signals and outputs the sound signals to the speakers 17a to 17c. As a result, the speakers 17a to 17c can perform a predetermined output operation (sound output) based on the audio signal.

  When the demonstration effect designation command is input from the overall control CPU 32a, the sound / lamp control CPU 34a shown in FIG. 3 sets (generates) demonstration effect effect data stored in the sound / lamp ROM, The set demonstration effect data is stored in the storage area of the voice / lamp RAM. Thereby, the effects by the frame lamps 16a to 16c and the speakers 17a to 17c are switched to the demonstration effects. More specifically, the sound / lamp control CPU 34a converts demonstration effect effect data stored in the sound / lamp RAM into a light emission control signal and outputs it to the frame lamps 16a to 16c. As a result, the frame lamps 16a to 16c can perform a demonstration effect based on the light emission control signal. The sound / lamp control CPU 34a converts the demonstration effect effect data stored in the sound / lamp RAM into a sound signal and outputs the sound signal to the speakers 17a to 17c. As a result, the speakers 17a to 17c can perform a demonstration effect based on the audio signal.

  Next, a method for switching the normal power mode to the power saving mode by operating the power saving switch SW on the back side of the game shop clerk will be described.

  (A-1) When a store clerk in the amusement shop operates the power saving switch SW during the normal power mode, the overall control CPU 32a determines that the first operation signal from the power saving switch SW is in the on state, and the power saving power supply The generating resistor 43 is selected. As a result, the normal power mode is switched to the power saving mode. In this case, the drive voltage generated by the power supply generation circuit 41 is reduced from 12V to 6V, and the light amount of the frame lamps 16a to 16c and the volume of the speakers 17a to 17c are reduced, thereby saving power.

  (A-2) At the same time, the overall control CPU 32a outputs a power saving command indicating that it is in the power saving mode to the display control CPU 33a, and the display control CPU 33a receives the power saving command input from the overall control CPU 32a as an inverter. Output to the substrate 46. And the inverter board | substrate 46 reduces the drive voltage (12V) supplied from the display control CPU33a to 6V based on the input power saving command. As a result, the luminance of the backlight of the symbol display device 61 is reduced, and power is saved.

  Next, a method of switching the power saving mode to the normal power mode by operating the effect button 15a on the machine surface side by the player will be described.

  (B-1) In this embodiment, when the mode is switched to the power saving mode by the power saving switch SW, power saving is performed regardless of whether the game is being played or the demonstration effect is being played. As a result, the voltage supplied to the various devices (the symbol display device 61, the frame lamps 16a to 16c, and the speakers 17a to 17c) is reduced even during the game. May feel unsatisfactory in games).

  (B-2) Therefore, when the player operates the effect button 15a during the demonstration effect in which the symbol variation game is not executed, the overall control CPU 32a determines that the second operation signal from the effect button 15a is in the on state. Thus, the normal power generation resistor 42 is selected. As a result, the power saving mode is canceled and switched to the normal power mode. In this case, the drive voltage generated by the power supply generation circuit 41 increases from 6V to 12V, and the amount of light of the frame lamps 16a to 16c and the volume of the speakers 17a to 17c increase. .

  (B-3) At the same time, the overall control CPU 32a terminates the output of the power saving command, so that the inverter board 46 turns on the backlight of the symbol display device 61 by the drive voltage (12V) supplied from the display control CPU 33a. Make it work. As a result, the luminance of the backlight of the symbol display device 61 is increased, and the effect during the game is gorgeous.

  Therefore, according to the present embodiment, the following effects can be obtained.

  (1) In the pachinko machine 10 of the present embodiment, power saving is performed when the power saving power generation resistor 43 is selected by operating the power saving switch SW. That is, since power saving is performed regardless of whether or not the game is in progress, the power saving effect is enhanced. In addition, when the power saving power generation resistor 43 is selected, not only power is saved by reducing the light amount of the frame lamps 16a to 16c, but also the volume of the speakers 17a to 17c and the brightness of the symbol display device 61 are reduced. Power saving is also performed by lowering. From the above, since power saving of various devices can be performed simultaneously, effective power saving can be performed. Therefore, since the necessary expenses on the game store side are reduced, it is possible to return the game to the player accordingly.

  (2) In the present embodiment, not only the power saving mode is set during the execution of the symbol variation game, but also the power saving mode is set in a demonstration effect that originally consumes less power than the symbol variation game. For this reason, when the power saving mode is set in the demonstration effect, the power consumption can be greatly reduced.

  (3) In this embodiment, the resistance value (power saving setting value) of the power saving power generation resistor 43 is set to a well-balanced value (a value that is neither too large nor too small). For this reason, when the power saving power generation resistor 43 is selected, the drive voltage can be reliably reduced, and effective power saving can be performed. In addition, even if the power saving power generation resistor 43 is selected, the driving voltage does not drop significantly, so that the light amount of the frame lamps 16a to 16c and the sound volume of the speakers 17a to 17c can be prevented from being reduced too much. Can prevent a decline in interest.

  (4) In this embodiment, the power saving mode can be set without changing the programs stored in the main ROM, the general ROM, the display ROM, and the sound / lamp ROM. That is, since the program development period is not different from the conventional one, the pachinko machine 10 can be realized at low cost.

[Second Embodiment]
Hereinafter, a second embodiment of the present invention will be described with reference to the drawings. Here, the description will focus on the parts that are different from the first embodiment, and the common parts will not be described in place of the same member numbers.

  In the present embodiment, a method for saving electricity is different from that in the first embodiment. As shown in FIG. 5, the power supply generation circuit 41 of this embodiment includes only the normal power generation resistor 42 and does not include the power saving power generation resistor 43 of the first embodiment. Therefore, the power supply generation circuit 41 always generates a drive voltage of 12V using the normal power supply generation resistor 42. Further, the lamp drive circuit 44 dynamically drives the frame lamps 16a to 16c based on the drive voltage (12V) supplied from the power generation circuit 41 and the drive load signal output from the overall control CPU 32a. It has become.

  The overall control CPU 32a determines whether to set the power saving mode or the normal power mode according to the selection result by the power saving switch SW and the effect button 15a. When it is determined to switch to the normal power mode, the overall control CPU 32a sets the duty ratio of the drive load signal to 25% (1: 4) (see commons 1 to 4 in FIG. 6A). As a result, since the output time of the drive load signal is normal, the light amounts of the frame lamps 16a to 16c are in the normal state. On the other hand, when it is determined to enter the power saving mode, the overall control CPU 32a reduces the duty ratio of the drive load signal to 12.5% (1: 8) (see commons 1 to 4 in FIG. 6B). ). More specifically, the overall control CPU 32a halves the length of the output period t1 per time that the drive load signal is turned on. As a result, the output time of the drive load signal is halved in the normal power mode, so that the light amounts of the frame lamps 16a to 16c are reduced. In the present embodiment, the volume of the speakers 17a to 17c does not decrease even in the power saving mode.

  Therefore, according to the present embodiment, the setting of the power saving mode can be realized relatively easily without changing the hardware configuration (for example, adding the power saving power generation resistor 43).

  In addition, you may change each said embodiment as follows.

  In the first embodiment, during the power saving mode, the light intensity of the frame lamps 16a to 16c and the volume of the speakers 17a to 17c are reduced, and the luminance of the backlight of the symbol display device 61 is reduced. However, the luminance of the backlight need not be reduced.

  In the first embodiment, a plurality of power saving modes may be provided. More specifically, a plurality of power saving power generation resistors having different power saving setting values are provided, and the light amounts of the frame lamps 16a to 16c and the speakers 17a to 17c are determined according to the selected power saving power generation resistors. And the degree to which the luminance of the backlight of the symbol display device 61 decreases may be varied.

  In the second embodiment, during the power saving mode, the light intensity of the frame lamps 16a to 16c is reduced and the luminance of the backlight of the symbol display device 61 is reduced. The volume of the speakers 17a to 17c may be lowered. In this case, the sound generation circuit 45 drives the speakers 17a to 17c based on the drive voltage (12V) supplied from the power supply generation circuit 41 and the drive load signal output from the overall control CPU 32a. Then, the overall control CPU 32a reduces the volume of the speakers 17a to 17c by reducing the duty ratio of the drive load signal when it is determined to enter the power saving mode.

  In each of the above embodiments, the frame lamps 16a to 16c are dynamically driven. However, the frame lamps 16a to 16c may be statically driven. In the second embodiment, the frame lamps 16a to 16c are statically driven as follows. That is, when it is determined to switch to the normal power mode, the overall control CPU 32a sets the duty ratio of the drive load signal to 25% (1: 4) (see SEG1 to SEG4 in FIG. 7A). As a result, since the output time of the drive load signal is normal, the light amounts of the frame lamps 16a to 16c are in the normal state. On the other hand, when it is determined to enter the power saving mode, the overall control CPU 32a reduces the duty ratio of the drive load signal to 12.5% (1: 8) (see SEG1 to SEG4 in FIG. 7B). . Specifically, the overall control CPU 32a sets the length of the output period t2 per turn when the drive load signal is turned on to the same length as the output period t2 in the normal power mode. The driving load signal is alternately switched between the on state and the off state within the output period t2 per round. As a result, the output time of the drive load signal is halved in the normal power mode, so that the light amounts of the frame lamps 16a to 16c are reduced.

  In each of the above embodiments, switching to the power saving mode or the normal power mode is performed with the operation of the power saving switch SW and the effect button 15a as an opportunity, but the power mode is switched with another opportunity. May be. For example, when the game ball wins the start winning device 21 and the determination result of the big hit determination becomes affirmative (big hit), the switch to the normal power mode is performed, and the determination result of the big hit determination is negative. Switching to the power saving mode may be performed when triggered by (losing). In addition, switching to the power saving mode is triggered by the operation of the power saving switch SW or the production button 15a, and the normal power mode is entered when the power saving timer set at the start of the power saving mode becomes 0 ms. Switching may be performed.

  In the above embodiments, the power saving switch SW is provided on the overall control board 32. However, for example, the power saving switch SW may be provided in a hall computer. In this case, by operating the power saving switch SW, a plurality of pachinko machines 10 managed by the hall computer can be simultaneously switched to the power saving mode. As a result, the store clerk at the amusement store does not bother to switch to the power saving mode, and thus actively saves power.

  In each of the above embodiments, the operation of the effect button 15a is effective when the power saving switch SW causes the overall control CPU 32a to select the power saving power generation resistor 43, but the operation of the power saving switch SW Regardless of the operation, the operation of the effect button 15a may be validated. That is, even if the player operates the effect button 15a, the normal power mode is not switched to the power saving mode. However, the operation button 15a can be switched to the normal power mode or the power saving mode. May be. In this way, when the player thinks that “the power saving mode is acceptable”, the effect button 15a can be operated to save power. In the power saving mode, the light amount of the frame lamps 16a to 16c, the volume of the speakers 17a to 17c, and the luminance of the backlight of the symbol display device 61 are reduced. Therefore, if the player feels that the lights of the frame lamps 16a to 16c and the light of the backlight are dazzling or feels noisy sound of the speakers 17a to 17c, the player can operate the effect button 15a to obtain light or sound. It can be connected to the improvement of interest.

  Next, the technical ideas grasped by the embodiment described above are listed below.

  (1) Main control means for controlling the entire gaming machine, overall control means for overall control of a plurality of sub-control means based on control commands from the main control means, and display effect by the display means are executed. A plurality of sub-control means including a display control means for performing control, a light emission control means for performing control for executing a light emission effect by the light emission means, and a sound control means for performing control for executing a sound effect by the sound generation means; Electrically connected to the overall control means and the display control means, and generates a power supply voltage necessary for the operation of the overall control means and the display control means, and the generated power supply voltage is supplied to the overall control means and the display control means. A power supply board to supply, wherein the overall control means is based on a power supply voltage supplied from the power supply board, and the light emission control means and The light emission means based on a power generation circuit that generates a drive voltage necessary for the operation of the voice control means, a drive voltage supplied from the power generation circuit, and a drive load signal output from the overall control means A light emission means drive circuit that emits light, and by reducing the duty ratio of the drive load signal, the light intensity of the light emission means is reduced and the power saving command indicating that the power saving mode is in effect is displayed in the display control. The display control means reduces the brightness of the display means by reducing the power supply voltage supplied from the power supply board when the power saving command is input. A gaming machine.

DESCRIPTION OF SYMBOLS 10 ... Pachinko machine 15a as a game machine ... Effect button 16a as second selection means and operation execution operation means ... Upper frame lamp 16b as light emission means ... Left frame lamp 16c as light emission means ... As light emission means Right frame lamp 17a ... Left speaker 17b as sound generating means ... Right speaker 17c as sound generating means ... Woofer speaker 31a as sound generating means ... Main CPU as main control means
32a ... Overall control CPU as overall control means
33a ... Display control CPU as sub-control means and display control means
34a ... Voice / lamp control CPU as sub-control means, light emission control means and voice control means
37 ... Power supply board 41 ... Power generation circuit 42 ... Normal power generation resistor 43 ... Power saving power generation resistor 61 ... Symbol display device SW as display means ... Power saving switch as first selection means

Claims (4)

Main control means for controlling the entire gaming machine;
Based on a control command from the main control means, an overall control means for overall control of a plurality of sub-control means;
The display control means for performing control for executing a display effect by the display means, the light emission control means for performing control for executing the light emission effect by the light emitting means, and the sound control means for performing control for executing the sound effect by the sound generating means. A plurality of sub-control means;
Electrically connected to the overall control means and the display control means, generates a power supply voltage necessary for the operation of the overall control means and the display control means, and uses the generated power supply voltage as the overall control means and the display control means. A gaming machine comprising a power supply board to be supplied to
The overall control unit includes a power generation circuit that generates a driving voltage necessary for the operation of the light emission control unit and the sound control unit based on a power supply voltage supplied from the power supply board,
The power generation circuit includes a normal power generation resistor whose resistance value is set to a normal setting value, and a power saving power generation resistor whose resistance value is set to a power saving setting value that is larger than the normal setting value. And
Switching to the power saving mode for reducing the drive voltage generated by the power generation circuit for power saving while maintaining energization is possible during a period in which the symbol variation game that varies a plurality of types of symbols is not executed,
The integrated control unit, when the normal select power generating resistor or the power-saving power generating resistor, a switch to the power saving mode has been performed the power-saving power generating resistor is selected, the A gaming machine, characterized in that a driving voltage is lowered to reduce the light amount of the light emitting means and the volume of the sound generating means. First selection means that having a function for switching to the normal power mode or the power saving mode, are electrically connected to be arranged on the machine back side of the gaming machine and the integrated control unit Rutotomoni,
It said second selecting means normally that having a function for switching to the power mode or the power saving mode, are electrically connected to be arranged on the machine front side of the gaming machine and the integrated control unit,
The overall control means determines whether to reduce the drive voltage according to the selection results by the first selection means and the second selection means,
2. The gaming machine according to claim 1, wherein the display control unit determines whether or not to lower the power supply voltage according to a selection result by the first selection unit and the second selection unit.   The gaming machine according to claim 2, wherein the operation of the second selection unit is effective when the first selection unit causes the overall control unit to select the power-saving power generation resistor. . It said second selecting means also serves as an operating means for directing execution to be operated to perform a predetermined effect in said symbol variation games,
The period during which the symbol variation game is not being executed is set as an effective period in which the operation of causing the overall control unit to select the normal power generation resistor or the power saving power generation resistor is performed by the second selection unit. The gaming machine according to claim 2 or 3, characterized in that.

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