JP2012045337A - Button device for game machine and game machine with button device for game machine - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a button device for a game machine, which shows a high performance effect.SOLUTION: A chance button device 100 projects the light of an image to be displayed on the screen 511a of a liquid crystal display device 501 by a projection lens 522b toward the screen face 301e of a button operation member 301 and displays an image. The image displayed on the screen face 301e is visually recognized by a player via the transparent operation part 301b of the button operation member 301. A magnetic sensor 525 detects the movement position of the button operation member 301 with respect to a vertical driving frame 307 in eight stages. An image control board 55 performs control to change the image to be displayed on the screen 511a of the liquid crystal display device 501, based on the detection result of the movement position by the magnetic sensor 525. Thus, consistency is ensured between the operation amount of the operation part 301b by the player and the performance content of the image to be displayed on the screen face 301e, thereby the button device for a game machine shows a higher performance effect.

Description

  The present invention relates to a gaming machine button device that includes an operation unit that performs an external operation and performs an effect in the operation unit, and a gaming machine that includes the gaming machine button device.

  Conventionally, a gaming machine called a pachinko machine has a game ball sent out one by one on a launch rail by a ball feeder, and the sent game ball is launched into a hit ball launcher along the outer rail of the guide rail of the game board. The game balls are guided to the game area, and a predetermined number of prize balls are paid out when the game balls guided to the game area win a prize opening.

  As a general pachinko machine that has been put into practical use in recent years, as shown in Patent Document 1, for example, an apparatus having a chance button as a button switch for production is widespread. As a button switch for production, there is a widespread use of a light-emitting lamp inside, which makes the operation surface appear to emit light when the operation is enabled or when the operation is prompted. Yes.

    Japanese Unexamined Patent Publication No. 2009-112212 (paragraph 0011, FIG. 2)

  However, the light emission pattern of the conventional button switch for production has a simple light emission, the light emission color is changed, etc., but all are simple light emission patterns and exhibit a sufficient production effect. I couldn't. Corresponding to this, it is conceivable to apply a complicated decoration to the button switch for production, but this has a problem that the operability of the button switch is impaired.

  In view of the above circumstances, an object of the present invention is to provide a button device for a gaming machine that can exhibit a sufficient effect without impairing operability.

  The invention according to claim 1 is provided in a gaming machine, has an operation part that is transparent and performs an external operation, the surface of the operation part is exposed to the outside of the gaming machine, A button operation member having a screen surface on the back side, an image display means provided on the inner side of the operation unit and displaying an image on the display surface by causing the display surface to emit light, and provided on the inner side of the operation unit A projection lens for projecting light of an image displayed on the display surface of the image display means onto the screen surface of the button operation member and displaying the image on the screen surface; and the button operation member for the gaming machine. A base portion that is movably held in a direction protruding outward and a reverse direction thereof, and is interposed between the base portion and the button operation member, and the button operation member is protruded outward of the gaming machine. Energizing means to energize and A detection result of the movement position detection means of the movement position detection means for detecting the movement position of the button operation member relative to the base portion, at least a part of the optical system of the projection lens and the image display means. And a focus adjustment unit that adjusts the image displayed on the screen surface by the projection lens, and the image display unit displays the image based on the detection result of the movement position by the movement position detection unit. And image control means for performing control to change the image.

  The invention according to claim 2 is the button device for a gaming machine according to claim 1, wherein the button operating member further protrudes outside the gaming machine and any one of the opposite directions. A base part moving means for moving the base part, and a protrusion amount for controlling a protrusion amount of the button operating member protruding outside the gaming machine by controlling the movement of the base part by the base part moving means. And a control means.

  The invention according to claim 3 is the button device for gaming machines according to claim 1 or 2, wherein the image displayed on the screen surface by the projection lens when a predetermined performance condition is satisfied is focused. It further includes an effect control means for controlling the focus adjusting means to generate a shift.

  A fourth aspect of the present invention is a gaming machine comprising the button device for a gaming machine according to any one of the first to third aspects.

  According to the first aspect of the present invention, the movement position detection means detects the movement position of the button operation member with respect to the base portion, and at least part of the optical system of the projection lens and the image display means by the focusing means, The one is moved based on the detection result of the moving position detecting means, and the image displayed on the screen surface is focused by the projection lens, and displayed on the display surface of the image display means by the projection lens. By projecting the image light onto the screen surface and displaying the image on the screen surface, the image displayed on the screen surface is visually recognized by the player through the transparent operation portion of the button operation member. And the image control means changes the image displayed on the image display means based on the detection result of the movement position by the movement position detection means. Therefore, consistency between the amount of operation of the operation unit by the player and the effect content of the image displayed on the screen surface can be achieved, and a sufficient effect can be exhibited without impairing operability. .

  According to the present invention, the moving position detecting means detects the moving position of the button operating member with respect to the base portion, and the focusing means is used to move at least one of the optical system of the projection lens and the image display means to the one of the positions. Light of an image displayed on the display surface of the image display means by the projection lens in a state where the image displayed on the screen surface is moved by the projection lens based on the detection result of the position detection means. Is projected onto the screen surface and an image is displayed on the screen surface, so that the image displayed on the screen surface is visually recognized by the player through the transparent operation portion of the button operation member, and image control is performed. The means performs control to change the image displayed on the image display means based on the detection result of the movement position by the movement position detection means. It can be consistent operation amount of the operating unit by the player and the effect content of an image displayed on the screen surface, without impairing the operability can exhibit a sufficient performance effect.

It is a perspective view which shows the open state of the permeation | transmission member holding frame of the game machine which concerns on one Embodiment of this invention. It is a perspective view which shows the closed state of the permeation | transmission member holding frame of the game machine which concerns on one Embodiment of this invention. It is a front view of the game board concerning one embodiment of the present invention. It is a block diagram which shows the structure of the control means of the game machine which concerns on one Embodiment of this invention. It is a block diagram of an image control board. It is a perspective view of the whole chance button apparatus in the state which protruded slightly. It is a perspective view of the whole chance button apparatus when it exists in the state protruded greatly. It is a disassembled perspective view of a chance button apparatus. It is a disassembled perspective view of an image projection apparatus and its peripheral part. It is a perspective view of an image projection device and its peripheral part. It is sectional drawing of a chance button apparatus when a button part exists in the lowest part. It is sectional drawing of a chance button apparatus when a button part is in the lowest part and pressing force is applied to the button main body. It is sectional drawing of a chance button apparatus when a button part exists in the uppermost part. It is sectional drawing of a chance button apparatus when a button part exists in the uppermost part and pressing force is applied to the button main body. It is sectional drawing of an image projection apparatus and its peripheral part. It is sectional drawing of an image projection apparatus when a pressing force is applied to the button main body, and its peripheral part. It is a perspective view explaining the up-and-down drive frame and cylindrical frame of a chance button device. It is a side view explaining the up-and-down drive frame and cylindrical frame of a chance button device. It is sectional drawing explaining the up-and-down drive frame and cylindrical frame of a chance button apparatus. It is a disassembled perspective view of the drive part of a chance button apparatus. It is a figure explaining the various gears etc. of a drive part. It is a figure explaining the state of the various gears of a drive part when a button part exists in the lowest part. It is a perspective view explaining the state of the various gears shown in FIG. It is a perspective view explaining the state of various gears when a button part starts operation from the lowest part. It is a figure explaining operation | movement of the crank when a drive part act | operates. It is a figure explaining the state of the various gears of a drive part when it exists just before a button part reaches | attains the uppermost part. It is a figure explaining the state of the various gears of a drive part when a button part exists in the uppermost part. It is a figure explaining the state of various gears when a button part starts operation from the uppermost part. It is a figure which shows a mode when it exists in the state (lock state) which the movement lock gear and the gear lock meshed. It is a figure which shows a mode when it exists in the state (non-locking state) where the movement lock gear and the gear lock are not meshing. It is a figure explaining the pressing stroke (pressing allowable distance) when a button part exists in the lowest part. It is a figure explaining the pressing stroke (pressing allowable distance) when a button part exists in the uppermost part. It is a figure explaining the state of a clutch receiver when a button part exists in the uppermost part. It is a figure explaining the state of a clutch receiver when the pressing force which exceeds a pressing stroke acts when a button part exists in the uppermost part. It is a figure which shows the main process in an effect control board. It is a figure which shows the timer interruption process in an effect control board. It is a figure which shows the effect pattern determination table in an effect control board. It is a figure which shows the effect input control process in an effect control board. It is a figure which shows the main process in host CPU. It is a figure which shows the expansion | extension control processing in an expansion | extension circuit. It is a figure which shows the drawing control process in a drawing circuit. It is a figure which shows the display control process in a display circuit. It is the 1st explanatory view showing the picture display of a chance button device. It is the 2nd explanatory view showing the picture display of a chance button device.

Hereinafter, embodiments of the present invention will be specifically described with reference to the drawings.
As shown in FIG. 1, the gaming machine 1 includes a support body 2 and a door body 3 pivotally supported by the support body 2. The support 2 is composed of a frame that forms four sides by an upper plate 2a, a lower plate 2b, and side plates 2c and 2d. Each of the plates 2a to 2d is made of a material such as wood that is not easily deformed or distorted, and is connected by a connecting metal fitting so that an enclosed space is formed in a substantially rectangular shape.
Among these connecting metal fittings, a pair of hinges 4a and 4b project to the front side of the gaming machine 1 in the metal fitting connecting the upper plate 2a and the side plate 2c and the metal fitting connecting the side plate 2c and the lower plate 2b. It is fixed so that it may face at the position.

  The door 3 is pivotally supported by the pair of hinges 4a and 4b. The door body 3 can be opened and closed with respect to the support body 2. In the present embodiment, the door body 3 is constituted by the transmission member holding frame 5 and the game board holding frame 6. FIG. 1 shows a state in which the transmission member holding frame 5 is opened with respect to the support 2 and the game board holding frame 6 is closed with respect to the support 2. The transmission member holding frame 5 and the game board holding frame 6 are partly or entirely brought into contact with the front surface of the support 2 so that the support 2, the transmission member holding frame 5 and the game board holding frame 6 are substantially parallel. From the closed position, the back surface rotates to the open position separated from the front surface of the support 2.

  Like the support body 2, the transmission member holding frame 5 is composed of a frame body in which a substantially rectangular enclosed space is formed by four sides including an upper side 5a, a lower side 5b, and side sides 5c and 5d. A transparent member 7 covering the front surface is fixed in the surrounding space. In the present embodiment, the transparent member 7 is made of a transparent glass plate, but any material or shape can be used as long as a game board 17 (to be described later) can be seen through the transparent member 7. You may comprise with a synthetic resin etc. The material of the transmissive member holding frame 5 is not particularly limited, but is preferably made of a synthetic resin for the purpose of reducing the weight and improving the decorativeness. In this case, in particular, the reinforcing metal fitting 8 is fixed to prevent distortion or deformation. It is good to prevent.

  As shown in FIG. 2, on the front surface of the gaming machine 1, that is, on the front surface of the transmissive member holding frame 5, there is a decorative lamp 9, an operation handle 10 for launching a game ball, and an upper plate for collecting paid-out prize balls. An upper plate unit 11 having a 11a and a decorative member 12 are fixed.

  When there is a remaining number of cards (prepaid cards) inserted in a card unit (CR unit) (not shown) in addition to the upper plate 11a, the upper plate unit 11 pays out a game ball from the card unit to the gaming machine. A payout button 11b that functions as an input means, a return button 11c for returning a card inserted into the card unit, a frequency indicator 11d that displays the remaining frequency of the card inserted into the card unit, and a chance A button device 100 and a chance button storage portion 11e for storing the chance button device 100 are provided.

  Further, the decorative member 12 is fixed so as to completely cover a speaker 18 (not shown) provided therein, but this decorative member 12 has a sound release hole for emitting sound from the speaker 18 to the outside of the gaming machine. Does not have. That is, since the speaker 18 is completely covered with the decorative member 12, the speaker 18 cannot be visually recognized from the outside of the gaming machine. Further, as shown in FIG. 1, a control board 54 (lamp) for controlling the reinforcing metal fitting 8, the supply path 13 for sending a prize ball to the upper plate 11a, a motor for changing the irradiation direction of the decorative lamp 9, and the like. A control board 54) is provided on the back side of the gaming machine 1.

  As is clear from FIGS. 1 and 2, the upper side 5a and the lower side 5b of the transmission member holding frame 5 are equal in length to the upper plate 2a and the lower plate 2b of the support 2, and the transmission member holding frame 5 When the support 2 and the transmissive member holding frame 5 are substantially parallel (when the transmissive member holding frame 5 is in the closed position), the upper side 5a is the upper plate 2a, and the side sides 5c and 5d are the side plates. The outer peripheral surfaces of 2c and 2d overlap with each other. Therefore, when the gaming machine 1 is viewed from the front, the upper plate 2a and the side plates 2c and 2d of the support 2 are covered with the transmissive member holding frame 5 and cannot be seen. However, the side edges 5 c and 5 d are formed shorter than the side plates 2 c and 2 d, and the lower plate 2 b of the support 2 is exposed to the front side of the gaming machine 1. The lower plate 2b of the support 2 is formed thicker than the upper plate 2a and the side plates 2c and 2d, and a decorative member 15 is fixed to the front side thereof.

  The transmitting member holding frame 5 is fixed with a pivot shaft 16a projecting above the side 5c and a pivot shaft 16b projecting below the side 5c. The pivot shaft 16a is fixed to the hinge 4a. The pivot shaft 16b is pivotally supported by the hinge 4b. Thereby, the transmissive member holding frame 5 is supported so as to be openable and closable with respect to the support 2. The structure for pivotally supporting the transmission member holding frame 5 on the support 2 is not limited to the above, and for example, a part of the side 5c of the transmission member holding frame 5 is formed in a convex shape, and this convex portion is formed. May be directly fitted to the hinges 4a, 4b and the support 2 to be pivotally supported.

  Similarly to the transmission member holding frame 5, a game board holding frame 6 is rotatably supported on the hinges 4a and 4b. As shown in FIG. 1, the game board holding frame 6 is composed of a frame in which a substantially rectangular enclosure space is formed by four sides including an upper side 6a, a lower side 6b, a left side 6c, and a right side 6d. Game board stoppers 60a and 60b are provided on the left side 6c of FIG. 6, and game board fixtures 60c and 60d are provided near the right side 6d of the upper side 6a and the lower side 6b, respectively. Then, the game board 17 shown in FIG. 3 is fixed in the surrounding space by the game board stoppers 60a and 60b and the game board fixtures 60c and 60d.

  The front surface of the game board 17 is provided with a plurality of nails, windmills, various winning holes through which game balls can enter, and an effect for production, etc. The liquid crystal display device 30 is fixed. In a state where the transmissive member holding frame 5 and the game board holding frame 6 are closed and the game is possible, the transmissive member 7 faces the game board 17 substantially in parallel with a predetermined interval, and the front surface of the game board 17 is Covered by the transmissive member 7.

  Here, various winning holes, winnings and the like provided on the game board 17 will be described with reference to FIGS. As described above, the operation handle 10 is rotatably provided at a lower position of the game board 17. When the player touches the operation handle 10, the touch sensor 10a (see FIG. 4) in the operation handle 10 detects that the player has touched the operation handle 10, and the firing control board 56 (see FIG. 4) is detected. Send a touch signal. When receiving a touch signal from the touch sensor 10a, the firing control board 56 permits energization of the firing solenoid 10c (see FIG. 4). When the rotation angle of the operation handle 10 is changed, the gear directly connected to the operation handle 10 rotates, and the knob of the firing volume 10b connected to the gear rotates. A voltage corresponding to the detected angle of the firing volume 10b is applied to a launching solenoid 10c provided in the game ball launching mechanism. When a voltage is applied to the firing solenoid 10c, the firing solenoid 10c operates according to the applied voltage, and has a strength according to the rotation angle of the operation handle 10 toward the game area 26. Is fired.

The game ball fired as described above rises between the rails 21 a and 21 b and reaches the upper position of the game board 17, and then falls within the game area 22. At this time, the game ball falls unpredictably by the plurality of nails and the windmill 23 provided in the game area 22.
The game area 22 is provided with a plurality of general winning ports 24. Each of these general winning ports 24 is provided with a general winning port detection switch 24a. When this general winning port detection switch 24a detects the entry of a game ball, a predetermined prize ball (for example, 10 game balls) is provided. Will be paid out. In the present embodiment, the switch is denoted as “SW” as necessary.

  Further, a normal symbol gate 27 is provided in the game area 22 above the special winning opening 28 described later so as to pass the game ball. The normal symbol gate 27 is provided with a gate detection switch 27a for detecting the passage of the game ball. When the gate detection switch 27a detects the passage of the game ball, the normal symbol lottery described later is performed.

  Further, a lower start position of the game area 22 is provided with a first start port 25 through which a game ball can enter, similarly to the general winning port 24. A second start port 26 is provided directly below the first start port 25. As shown in FIG. 3, the second starting port 26 has a pair of movable pieces 26b. The first mode in which the pair of movable pieces 26b is maintained in a closed state, and the pair of movable pieces 26b It is controlled to move to the second mode that is in the open state (FIG. 3 shows a state that is controlled to move to this second mode). When the second start port 26 is controlled in the first mode, the first start port 25 located immediately above the second start port 26 becomes an obstacle and does not accept the game ball. It is possible or difficult. On the other hand, when the second starting port 26 is controlled to the second mode, the pair of movable pieces 26b function as a receiving tray, so that the game ball can easily enter the second starting port 26. That is, when the second start port 26 is in the first mode, there is almost no opportunity for entering a game ball, and when the second start port 26 is in the second mode, the opportunity for entering a game ball is increased.

  The first start port 25 and the second start port 26 are respectively provided with a first start port detection switch 25a and a second start port detection switch 26a for detecting the entrance of a game ball. When the game ball is detected, a lottery for acquiring a right to execute a jackpot game, which will be described later (hereinafter referred to as a “hit lottery”), is performed. Also, when the detection switches 25a and 26a detect the entry of a game ball, a predetermined prize ball (for example, 3 game balls) is paid out.

  As shown in FIG. 2, a special winning opening 28 is provided further below the normal symbol gate 27. The special winning opening 28 is normally kept closed by the special winning opening / closing door 28b, so that it is impossible to enter a game ball. On the other hand, when a special game, which will be described later, is started, the special prize opening / closing door 28b is opened, and the special prize opening / closing door 28b functions as a tray for guiding the game ball into the special winning opening 28, A game ball can enter the big prize opening 28. The big prize opening 28 is provided with a big prize opening detection switch 28a. When the big prize opening detection switch 28a detects the entry of a game ball, preset prize balls (for example, 15 game balls) are provided. To be paid out. The big prize opening 28, the big prize opening detection switch 28a, the big prize opening opening / closing door 28b, and the big prize opening opening / closing solenoid 28c described later are also collectively referred to as a big prize opening opening / closing device.

  The player does not enter any of the general winning port 24, the first starting port 25, the second starting port 26, and the grand winning port 28 further below the grand winning port 28, that is, at the bottom of the game area 22. A discharge port 29 for discharging the game balls is provided.

In addition, the game board 17 is provided with an effect device for performing various effects.
Specifically, a liquid crystal display device 30 made up of a liquid crystal display (LCD) or the like is provided at a substantially central portion of the game area 22. 31 is provided. Further, an effect lighting device 9 (decorative lamp 9) is provided at both the upper position and the lower position of the game board 17.

  The liquid crystal display device 30 displays an image while the game is not being performed or displays an image according to the progress of the game. In particular, when a game ball enters the first start port 25 or the second start port 26, a decorative symbol for notifying the player of the lottery result is variably displayed. The decorative symbol is, for example, that three numbers are scroll-displayed, and the scrolling is stopped after a predetermined time, and a specific symbol (number) is displayed in an array. As a result, while the symbols are being scrolled, the player is given an impression that the lottery is currently being performed, and the player is notified of the lottery result by the symbols displayed when the scrolling is stopped. By displaying various images, characters, and the like during the decorative display of the decorative symbols, the player is given a high expectation that they may win a jackpot.

  The effect accessory device 31 gives the player a sense of expectation depending on the operation mode. In the present embodiment, the effect accessory device 31 simulates a belt provided with a rotatable windmill member 31a at the center. Depending on the performance, the windmill member rotates or the entire belt descends.

  In the present embodiment, a chance button device (button device for gaming machine) 100 that can be pressed by the player is provided in the vicinity of the upper plate unit 11. For example, the chance button device 100 validates an operation pressed when a message for operating the chance button device 100 is displayed on the liquid crystal display device 30 or the operation unit 301b of the chance button device 100. Is. The chance button device 100 is provided with a magnetic sensor 525 as a chance button detection switch, and when the magnetic sensor 525 detects a player's operation, a further effect is executed according to this operation.

  Below the game area 22, the first special symbol display device 40, the second special symbol display device 41, the normal symbol display device 42, the first hold indicator 43, the second hold indicator 44, the normal symbol hold display 45, a high probability state indicator 46, and a short time state indicator 47 are provided.

  The special symbol display devices 40 and 41 are for displaying a lottery result of a jackpot lottery performed on condition that a game ball enters the start ports 25 and 26. In other words, a plurality of special symbols corresponding to the lottery lottery result are set, and the special symbol corresponding to the lottery lottery result is stopped and displayed on these special symbol display devices 40 and 41 so that the lottery result can be played. The person is informed. The special symbol display devices 40 and 41 are each composed of, for example, a plurality of LEDs. When a big win is won, a plurality of specific LEDs are lit, and when it is lost, a specific LED corresponding thereto is displayed. One lights up. The pattern represented by lighting up in this way becomes a special symbol, but this special symbol is displayed in a stopped state after being displayed in a variable manner for a predetermined time. In other words, whenever a special symbol change display is performed, a special symbol stop display is performed, and the lottery result of the jackpot lottery is notified. Moreover, in this embodiment, the display mode of the special symbols in the first special symbol display device 40 and the second special symbol display device 41 is not the same. That is, even if the same type of jackpot, the display mode of the special symbol in the first special symbol display device 40 and the display mode of the special symbol in the second special symbol display device 41 are different. In this case, even if the player learns the display mode of one of the special symbol display devices 40 and 41, the type of jackpot or the like cannot be grasped from the other display mode. The effect that the display mode of a symbol can be obscure is acquired. If a plurality of LEDs are turned on even in the case of a loss, it is also possible to make it difficult to determine whether it is a loss or a big hit.

The normal symbol display device 42 is for notifying the lottery result of the lottery performed when the game ball passes through the normal symbol gate 27 as an opportunity. When the winning lottery is won, the left LED in the figure of the normal symbol display device 42 composed of two left and right LEDs is turned on, and then the second start port 26 is controlled to the second mode for a predetermined time. (In addition, when the right LED in the drawing is lit, it is lost, and the second start port 26 is not controlled to the second mode).
Note that the normal symbol is not notified immediately after the game ball passes through the normal symbol gate 27, and the normal symbol display device 42 blinks until a predetermined time elapses. Is displayed in a variable manner. That is, the normal symbol display device 42 blinks until a predetermined time elapses. The blinking of the normal symbol display device 42 constitutes a normal symbol variation display, and the lighting of the normal symbol display device 42 constitutes a normal symbol stop display corresponding to the lottery result of the winning lottery.

  By the way, during the special symbol variation display or during the special game in which the big prize opening / closing device operates, even if a game ball enters the start opening 25, 26, the special symbol variation display is immediately performed and the special prize lottery is performed. When the lottery result is not notified, the special symbol change display (notification of the lottery result of the special prize lottery) is suspended under certain conditions. More specifically, the right to display the change of the special symbol in which the game ball enters and is retained at the first start opening 25 is retained as the first hold (U1), and the game ball enters the second start opening 26. The right of variable display of the special symbol reserved is reserved as the second reservation (U2).

  For both of these holds, the upper limit reserved number is set to four, and the reserved number is displayed on the first hold indicator 43 and the second hold indicator 44, respectively. When there is one first hold (U1), the LED on the left side of the first hold indicator 43 is lit, and when there are two first holds (U1), the left side of the first hold indicator 43. The two middle LEDs are lit. In addition, when there are three first holds (U1), all three LEDs on the left, middle and right of the first hold indicator 43 are lit, and when there are four first holds (U1), All three LEDs of the 1 hold indicator 43 blink. Further, on the second hold indicator 44, the reserved number of the second hold (U2) is displayed in the same manner as described above.

On the other hand, the upper limit reserved number is similarly set to 4 for the variable symbol display, and the reserved number is the same as that of the first special symbol hold indicator 43 and the second special symbol hold indicator 44. Depending on the mode, it is displayed on the normal symbol hold display 45.
The high-probability state indicator 46 is composed of LEDs, and lights up on the condition that it is in a high-probability state to be described later before the power is turned off during morning (when power is restored). On the other hand, the time-short state indicator 47 is also constituted by an LED, but this is not limited to the time of wake-up but lights up on condition that the time-short state is present if the power is turned on.

  In the game board holding frame 6, below the fixed position of the game board 17, a sound output device 19 (bass speaker 19) and a launch device 20 that launches a game ball into the game area in response to an operation of the operation handle 10. Etc. are fixed. Various control boards for controlling the progress of the game are fixed to the back of the game board 17.

  FIG. 4 is a diagram showing the configuration of the control board (control means) of the gaming machine 1. The gaming machine 1 includes a main control board 51, an effect control board 52, a payout control board 53, a lamp control board 54, an image control board 55, a launch control board 56, and a power supply board 57.

  The main control board 51 controls the basic operation of the game. The main control board 51 includes a main CPU 51a, a main ROM 51b, and a main RAM 51c. The main CPU 51a reads out a program stored in the main ROM 51b based on an input signal from each detection switch or timer, performs arithmetic processing, directly controls each device or display, or outputs the result of the arithmetic processing. In response, a command is transmitted to another board. The main RAM 51c functions as a data work area during the arithmetic processing of the main CPU 51a.

  A general winning opening detection switch 24a, a gate detection switch 27a, a first starting opening detection switch 25a, a second starting opening detection switch 26a, and a big winning opening detection switch 28a are connected to the input side of the main control board 51. The game ball detection signal is input to the main control board 51.

  Further, on the output side of the main control board 51, a start opening / closing solenoid 26c for opening / closing the pair of movable pieces 26b of the second start opening 26 and a large winning opening opening / closing solenoid 28c for opening / closing the large winning opening / closing door 28b. Are connected, and the first special symbol display device 40, the second special symbol display device 41, the normal symbol display device 42 that constitute the symbol display device, the first hold indicator 43 that constitutes the hold display device, and the first The 2 hold display 44, the normal symbol hold display 45, and the high probability state display 46 and the short time state display 47 constituting the state display device are connected, and various signals are output through the output port. .

  The main ROM 51b of the main control board 51 stores a game control program and data and tables necessary for determination for various games. The main RAM 51c of the main control board 51 is provided with a plurality of storage areas.

  Further, the main RAM 51 c constitutes a backup RAM as a nonvolatile storage means that is partly or wholly backed up by a backup power source created in the power supply substrate 57. That is, even if the power supply to the gaming machine is stopped, the data contents of the main RAM 51c are stored for a predetermined period (until the backup power supply cannot be supplied because the capacitor as the backup power supply is discharged). Note that the main RAM 51c may be configured by a flash memory or the like without having a backup power source.

  Further, the main control board 51 is directly mounted with a RAM clear switch 51d for instructing to clear the data contents of the main RAM 51c. The main control board 51 is mounted with an RTC (real time clock) 51e that outputs the current time. The main CPU 51a inputs a date signal indicating the current date and a time signal indicating the current time from the RTC 51e, and executes various processes based on the current date and time. The RTC 51e is normally operated by power from the gaming machine when power is supplied to the gaming machine, and by power supplied from a backup power source mounted on the power supply board 57 when the power of the gaming machine is turned off. Operate. Therefore, the RTC 51e can measure the current date and time even when the gaming machine is turned off.

  Note that the RTC 51e may be provided with a battery on the main control board 51 and operated by the battery. Alternatively, the RTC 51e is not provided, and the time may be measured by counting up a counter provided in the main RAM 51c having a function as a backup RAM every predetermined time (for example, every 4 ms).

  The power supply board 57 manages the power supplied from the power plug 14 and includes a backup power supply composed of a capacitor. The power supply board 57 monitors the power supply voltage supplied to the gaming machine, and when the power supply voltage falls below a predetermined value. The power interruption detection signal is output to the main control board 51 and the effect control board 52. More specifically, when the power interruption detection signal becomes high level, the main CPU 51a and the sub CPU 52a become operable, and when the power interruption detection signal becomes low level, the main CPU 51a and sub CPU 52a become inactive state.

  The effect control board 52 mainly controls each effect such as during a game or standby. The effect control board 52 includes a sub CPU 52a, a sub ROM 52b, and a sub RAM 52c, and is connected to the main control board 51 so as to be able to communicate in one direction from the main control board 51 to the effect control board 52. . Based on the command transmitted from the main control board 51, the input signal from the magnetic sensor 525 of the chance button device 100 via the lamp control board 54, or the input signal from the timer, the sub CPU 52a stores in the sub ROM 52b. The stored program is read to perform arithmetic processing, and corresponding data is transmitted to the lamp control board 54 or the image control board 55 based on the processing. The sub RAM 52c functions as a data work area when the sub CPU 52a performs arithmetic processing.

The sub ROM 52b of the effect control board 52 stores a program for effect control, data necessary for determining various games, and a table.
For example, an effect mode determination table (not shown) for determining an effect mode based on a command received from the main control board 51 is stored in the sub ROM 52b.

  The sub RAM 52c of the effect control board 52 is provided with a plurality of storage areas.

The payout control board 53 performs game ball launch control and prize ball payout control. The payout control board 53 includes a payout CPU 53a, a payout ROM 53b, and a payout RAM 53c, and is connected to the main control board 51 so as to be capable of two-way communication. The payout CPU 53a reads out the program stored in the payout ROM 53b based on the input signal from the payout ball counting switch 32 and the timer that detects whether or not the game ball has been paid out, and performs arithmetic processing. Based on this, the corresponding data is transmitted to the main control board 51. Also, a payout motor 33 (prize ball payout device) for paying out a predetermined number of prize balls from the game ball storage unit to the player is connected to the output side of the payout control board 53. The payout CPU 53a reads out a predetermined program from the payout ROM 53b based on the payout number designation command transmitted from the main control board 51, performs arithmetic processing, and controls the payout motor 33 to give a predetermined prize ball to the player. Pay out. At this time, the payout RAM 53c functions as a data work area during the calculation processing of the payout CPU 53a.
Also, it is confirmed whether a game ball lending device (card unit) (not shown) is connected to the payout control board 53, and if the game ball lending device (card unit) is connected, the game control ball 56 is caused to fire a game ball. Send launch control data to allow that.

When the launch control board 56 receives the launch control data from the payout control board 53, the launch control board 56 permits the launch. Then, the touch signal from the touch sensor 10a and the input signal from the launch volume 10b are read out, the energization of the launch solenoid 10c is controlled, and the game ball is fired.
Here, the number of pulse voltages applied to the firing solenoid 10c is set to about 99.9 (times / minute) based on the frequency based on the output period of the crystal oscillator provided on the firing control board 56. As a result, the number of games played in one minute is about 99.9 (pieces / minute) because one shot is fired each time a pulse voltage is applied to the firing solenoid 10c.
In the present embodiment, the touch sensor signal from the touch sensor 10 a is transmitted from the launch control board 56 to the effect control board 52 via the payout control board 53 and the main control board 51.

  The lamp control board 54 controls the lighting of the effect lighting device 9 (decorative lamp 9) and controls the driving of the motor for changing the light irradiation direction. In addition, energization control is performed on a drive source such as a solenoid or a motor that operates the effect accessory device 31. Further, the lamp control board 54 controls energization of the solenoid 202 and the motor 207 of the chance button device 100. The lamp control board 54 is connected to the effect control board 52, and performs the above-described controls based on data transmitted from the effect control board 52.

  Further, the lamp control board 54 drives and controls the linear actuators 523 and 524 of the chance button device 100 based on the command from the effect control board 52 and the detection results of the magnetic sensors 525 and 526.

  The lamp control board 54 extracts the upper 3 bits (upper three digits) of the 5-bit parallel absolute position data output from the magnetic sensor 525 and transmits the extracted data to the effect control board 52 as 3-bit parallel absolute position data.

  The image control board 55 is connected to the liquid crystal display device 30, the liquid crystal display device 501 of the chance button device 100, and the audio output devices 18 and 19, and based on various commands transmitted from the effect control board 52, the liquid crystal display device 501. Image display control in the display devices 30 and 501 and sound output control in the sound output devices 18 and 19 are performed.

(Block diagram of image control board)
Next, image display control will be described with reference to the block diagram of the image control board 55 in FIG.

  The image control board 55 performs host image display control of the liquid crystal display devices 30 and 501, and includes a host CPU 55a, host RAM 55b, host ROM 55c, CGROM 401, crystal oscillator 402, VRAM 403, VDP (Video Display Processor) 400, sound control circuit 404, It has.

Based on the effect pattern designation command received from the effect control board 52, the host CPU 55a instructs the liquid crystal display devices 30 and 501 to display the image data stored in the CGROM 401 in the VDP 400. Such an instruction is performed by setting data in the control register 411 in the VDP 400 and outputting a display list composed of a drawing control command group.
In addition, when receiving a V blank interrupt signal or a drawing end signal from the VDP 400, the host CPU 55a appropriately performs an interrupt process.

  Further, the host CPU 55 a also instructs the audio control circuit 404 to output predetermined audio data to the audio output devices 18 and 19 based on the effect pattern designation command received from the effect control board 52.

  The host RAM 55b is built in the host CPU 55a, functions as a data work area when the host CPU 55a performs arithmetic processing, and temporarily stores data read from the host ROM 55c. In the storage area of the host RAM 55b, various timer counters such as an effect timer counter are provided. Note that the above-described storage area is merely an example, and many other storage areas are provided.

  The host ROM 55c is composed of a mask ROM, a control processing program for the host CPU 55a, a display list generation program for generating a display list, an animation pattern for displaying an animation of an effect pattern, animation scene information, etc. Is remembered.

  This animation pattern is referred to when displaying the animation of the production pattern, and stores the combination of animation scene information included in the production pattern, the display order of each animation scene information, and the like. The animation scene information stores information such as weight frame (display time), target data (sprite identification number, transfer source address, etc.), parameters (sprite display position, transfer destination address, etc.), drawing method, etc. is doing.

  The CGROM 401 includes a flash memory, an EEPROM, an EPROM, a mask ROM, and the like, and compresses and stores image data (sprite, movie) or the like that is a collection of pixel information in a predetermined range of pixels (for example, 32 × 32 pixels). ing. The pixel information is composed of color number information for designating a color number for each pixel and an α value indicating the transparency of the image.

Further, the CGROM 401 stores palette data in which color number information specifying a color number and display color information for actually displaying colors are associated with each other without being compressed.
Note that the CGROM 401 may have a configuration in which only a part of the image data is compressed without being compressed. As a movie compression method, various known compression methods such as MPEG4 can be used.

  The crystal oscillator 402 outputs a pulse signal to the VDP 400 (clock generation circuit 415), and divides the pulse signal, whereby the clock generation circuit 415 controls the system clock for the VDP 400 to control, the liquid crystal display device 30, A synchronization signal or the like for synchronization with the 501 is generated.

  The VRAM 403 is composed of an SRAM that can write or read image data at high speed.

  The VRAM 403 is expanded by a main display list storage area 403a1 for temporarily storing a display list for the main liquid crystal display device 30 (hereinafter referred to as main) output from the host CPU 55a, and an expansion circuit 416. It has a main development storage area 403b1 for storing main image data, a main first frame buffer 403c1 for drawing or displaying a main image, and a main second frame buffer 403d1. The VRAM 403 also stores palette data.

  The two frame buffers are alternately switched between a “drawing frame buffer” and a “display frame buffer” every time drawing is started.

  The VRAM 403 also includes a chance button display list storage area 403a2 for temporarily storing a display list for the liquid crystal display device 501 (hereinafter referred to as a chance button) of the chance button device 100 output from the host CPU 55a, and an expansion circuit. A chance button expansion storage area 403b2 for storing the image data for the chance button expanded by 416, a first frame buffer for a chance button 403c2 for drawing or displaying an image for the chance button, and a second frame for the chance button And a buffer 403d2.

  The VDP 400 is a so-called image processor, reads image data from one of the frame buffers (display frame buffer) based on an instruction from the host CPU 55a, and outputs a video signal (RGB signal or the like) based on the read image data. Is output to the liquid crystal display devices 30 and 501.

  The VDP 400 also includes a control register 411, a CG bus I / F 412, a CPU I / F 413, a clock generation circuit 415, a decompression circuit 416, a drawing circuit 417, a display circuit 418, and a memory controller 419. ing.

The control register 411 is a register for the VDP 400 to perform drawing and display control, and drawing control and display control are performed by writing and reading data to and from the control register 411. The host CPU 55a can write and read data to and from the control register 411 via the CPU I / F 413.
The control register 411 includes a system control register that performs basic settings necessary for VDP operation, a data transfer register that performs settings necessary for data transfer, a drawing register that performs settings for controlling drawing, It has multiple types of registers, such as a bus interface register that makes settings necessary for bus access, an expansion register that makes settings necessary for decompressing compressed images, and a display register that makes settings for controlling display .

The CG bus I / F 412 is an interface circuit for communication with the CGROM 401, and image data from the CGROM 401 is input to the VDP 400 via the CG bus I / F 412.
The CPU I / F 413 is an interface circuit for communication with the host CPU 55a, and the host CPU 55a outputs a display list to the VDP 400, accesses a control register, and accesses from the VDP 400 via the CPU I / F 413. The host CPU 55a inputs various interrupt signals.

The data transfer circuit 414 performs data transfer between various devices.
Specifically, data transfer between the host CPU 55a and the VRAM 403, data transfer between the CGROM 401 and the VRAM 403, and data transfer between various storage areas (including the frame buffer) of the VRAM 403 are performed.

  The clock generation circuit 415 receives a pulse signal from the crystal oscillator 402 and generates a system clock that determines the calculation processing speed of the VDP 400. Also, a main signal and a chance button synchronization signal generation clock is generated, and a main signal and a chance button synchronization signal are output to the liquid crystal display devices 30 and 501 via the display circuit, respectively.

  The decompression circuit 416 is a circuit for decompressing the image data compressed in the CGROM 401, and stores the decompressed image data in the main development storage area 403b1 or the chance button development storage area 403b2.

  The drawing circuit 417 is a circuit that performs sequence control based on a display list including drawing control command groups.

The display circuit 418 generates RGB signals (analog signals) indicating image color data as video signals for main and chance buttons from the image data (digital signals) stored in the “display frame buffer” in the VRAM 403. The main and chance button video signals (RGB signals) are output to the liquid crystal display devices 30 and 501, respectively. Further, the display circuit 418 also outputs main and chance button synchronization signals (vertical synchronization signal, horizontal synchronization signal, etc.) for synchronization with the liquid crystal display devices 30 and 501 to the liquid crystal display devices 30 and 501.
In the present embodiment, an RGB signal obtained by converting a digital signal into an analog signal is output to the liquid crystal display devices 30 and 501 as the video signal. However, the video signal may be output as the digital signal.

  The memory controller 419 performs control to switch between the “drawing frame buffer” and the “display frame buffer” when the host CPU 55a instructs to switch the frame buffer.

  The sound control circuit 404 is provided with an audio ROM that stores a large number of audio data. The sound control circuit 404 reads out a predetermined program based on a command transmitted from the effect control board 52 and outputs an audio signal. Audio output control is performed in the devices 18 and 19.

  Hereinafter, the structure of the chance button device 100 (the gaming machine button device), which is a characteristic part of the present embodiment, will be described with reference to FIGS.

6 and 7 are perspective views showing the chance button device 100 removed from the upper plate unit 11.
In the chance button device 100, an upper case 101 and a lower case 102 accommodate a drive unit 200 and a button unit 300 described later. In addition, the chance button device 100 allows the button unit 300 to move up and down by a predetermined trigger. The predetermined opportunity refers to, for example, when a specific lottery result is obtained in the jackpot lottery or when a specific effect is performed on the liquid crystal display device 30. At these times, the button unit 300 is raised / lowered. By moving, the production effect can be further improved.

  FIG. 6 shows a state in which the button unit 300 is slightly protruded. Normally, the button unit 300 is slightly protruded as shown in the figure. For this reason, the player is given only the impression that the button unit 300 is a general push button (the button unit 300 itself does not rise or fall).

Note that the “state in which the button part 300 slightly protrudes” shown in FIG. 6 corresponds to the “position where the button unit 300 is pulled in from the gaming machine 1”.
That is, as shown in FIG. 6, “the state in which the button portion 300 slightly protrudes” means that the top portion (“SU” in the drawing) which is the front end surface portion of the button portion 300 slightly protrudes outward from the upper case 101. In other words, it means a state in which most of the button part 300 is housed in the upper case 101, and this slight protrusion allows the operator to perform a pressing operation.

  FIG. 7 shows a state in which the button unit 300 is moved upward and the button unit 300 protrudes greatly. This state is a state in which the button unit 300 protrudes largely upward as compared to the state shown in FIG. 6 (projects upward by a distance S as shown). Thus, by making the button part 300 protrude greatly, a player can be sufficiently appealed in terms of performance.

Note that the “state in which the button part 300 protrudes greatly” shown in FIG. 7 corresponds to the “position where the button part 300 protrudes from the gaming machine 1”.
Further, the above-mentioned “distance S” is not limited to a specific distance, and the position of the top “SU” in a state in which the button part 300 protrudes greatly is shown in FIG. As long as the state is moved to the outside of the position of the top “SU” in the “state”, it may be changed each time in conjunction with the contents of the effects.

FIG. 8 is an exploded perspective view of the chance button device 100.
In FIG. 8, a button unit 300 (see FIGS. 6 and 7) includes a button operation member 301 made of a light-transmitting material such as plastic, an inner mounting member 302 housed in the button operation member 301, and a liquid crystal display. An apparatus 501 and a projection unit 502, a cylindrical pressing frame 304 having a top portion 304a, an inner cylindrical frame 305 to which the cylindrical pressing frame 304 is fixed, and a vertical driving frame 307 that moves the button unit 300 up and down by power from the driving unit 200. A push holder 311 that pushes up the vertical drive frame and the like by receiving the elastic force of the center spring 308, shafts 309 and 310, and the assist spring 315 inserted into the cylindrical portion 307A of the vertical drive frame 307, and is housed in the push holder 311. Guy of shaft 316 A long shaft bush 312 that functions as a shaft, a short shaft bush 313 that is housed in the push holder 311 and functions as a guide for the shaft 317, an assist spring 315 that applies an urging force when the button unit 300 is moved upward, and shafts 316 and 317 And a shaft fixing plate 318 for fixing the shafts 316 and 317. Note that these members are appropriately fixed by screws, screws, etc., but description of the screws, screws, etc. will be omitted.

  Hereinafter, the button operation member 301, the inner attachment member 302, the liquid crystal display device 501, and the projection unit 502 are referred to as a button body 303.

  The button operation member 301 includes a cylindrical portion 301a, a planar operation portion 301b that closes the upper end of the cylindrical portion 301a, and a flange portion 301c formed on the outer periphery of the lower end of the cylindrical portion 301a. Resin). The outer surface of the operation unit 301b is an operation surface 301d pressed by the player's finger, and the inner surface of the operation unit 301b is a screen surface 301e on which a plurality of microlenses are formed. On the inner surface of the cylindrical portion 301a of the button operation member 301, a magnetic scale 301f detected by a magnetic sensor 525 described later is provided by adhesion.

  The inner mounting member 302 is made of resin (transparent or opaque) made of a cylindrical portion 302a, a planar partition wall portion 302b that closes the upper end of the cylindrical portion 302a, and a flange portion 302c formed on the outer periphery of the lower end of the cylindrical portion 302a. A pair is formed. Openings 302d and 302e and a harness insertion hole 302f are formed in the partition wall 302b.

  The shafts 309 and 310 are inserted into the opening portions 302d and 302e of the partition wall portion 302b. A liquid crystal display device 501 and a projection unit 502 are stacked on top and bottom of the shafts 309 and 310 and screwed together. The harness insertion hole 302f of the partition wall 302b has a harness 513 of the liquid crystal display device 501, harnesses 523e and 524e (see FIG. 9) of the piezoelectric linear actuators 523 and 524, and a harness 525a of the magnetic sensors 525 and 526 (see FIG. 9). , 526a is inserted.

  Furthermore, the harnesses 513, 523e, 524e, 525a, and 526a are provided on the chance button device 100 via the harness insertion hole 305f of the inner cylindrical frame 305, the harness insertion hole 307f of the vertical drive frame 307, and the harness insertion hole 102f of the lower case 102. It extends to the outside. The harness 513 of the liquid crystal display device 501 extending to the outside of the chance button device 100 is connected to the image control board 55 shown in FIG. The harnesses 523e and 524e (see FIG. 9) of the piezoelectric linear actuators 523 and 524 extended to the outside of the chance button device 100 and the harnesses 525a and 526a of the magnetic sensors 525 and 526 (see FIG. 9) are shown in FIG. Connected to the control board 54.

  In FIG. 8, the cylindrical portion 302 a of the inner mounting member 302 has an outer diameter that is the same as the inner diameter of the cylindrical portion 301 a of the button operation member 301, and the total length is about 40% of the cylindrical portion 301 a of the button operation member 301. Yes.

  In the inner mounting member 302, the shafts 309 and 310 are inserted into the opening portions 302d and 302e of the partition wall portion 302b, and the liquid crystal display device 501 and the projection unit 502 are screwed to the upper end surfaces of the shafts 309 and 310. The flange portion 302c is inserted into the lower open portion of the cylindrical portion 302a of the button operation member 301 from the side, and is fixed by screwing the flange portion 301c of the button operation member 301.

Opening portions 305d and 305e into which the shafts 309 and 310 are inserted are formed in the inner cylindrical frame 305. The inner cylindrical frame 305 has a flange portion 302c of the inner mounting member 302 in a state where the shafts 309 and 310 are inserted into the opening portions 305d and 305e.
Fixed with screws.

  The lower end surfaces of the shafts 309 and 310 are screwed and fixed to the upper surface of the vertical drive frame 307 with screws 319 and 320 (see FIG. 11) with the cylindrical portion 307A interposed therebetween at a predetermined interval.

  FIG. 9 is an exploded perspective view of the image projection device 501 of the chance button device 100 and its peripheral portion. FIG. 10 is an exploded perspective view of the image projection apparatus 501 of FIG. 9 and its peripheral part in an assembled state.

  In FIG. 9, the liquid crystal display device 501 includes a liquid crystal display panel 511 and a backlight 512. The liquid crystal display panel 511 and the backlight 512 are connected to and driven by the image control board 55 (see FIG. 5) via the harness 513.

  The projection unit 502 includes a light shielding member 521, a projection lens unit 522, piezoelectric linear actuators 523 and 524, magnetic sensors 525 and 526 for reading the magnetic scales 301f and 522n, shaft screws 527 and 528, and screws 529 and 530. ing.

  Screw insertion holes 511d and 511e for screwing to the upper end surfaces of the shafts 309 and 310 (see FIG. 10) by screws 504 and 504 are formed in the frame portion 511b of the liquid crystal display panel 511. In the frame portion 512c of the backlight 512, screw insertion holes 512d and 512e (see FIG. 11) for screwing to the upper end surfaces of the shafts 309 and 310 by screws 504 and 504 are formed.

The light shielding member 521 includes an expanded shape portion 531a formed in an expanded shape downward, screw mounting portions 531d and 531e for screwing to the upper end surfaces of the shafts 309 and 310 by screws 504 and 504, a shaft The screw fixing portions 531f and 531g to which the screws 527 and 528 are fixed, and screw fixing portions 531h and 531i for screwing the magnetic encoder magnetic sensors 525 and 526 are configured.
Fixing members 523a and 524a of the piezoelectric linear actuators 523 and 524 are attached to the screw attachment portions 531d and 531e by screws 504 and 504, respectively.

  An open portion 531j into which the insertion lower portion 522d of the projection lens unit 522 is inserted is formed on the upper surface of the expanded shape portion 531a.

  The projection lens unit 522 has a projection lens 522b in which a plurality of lenses are combined inside the lens barrel 522a. The lens barrel 522a is formed by forming an insertion lower portion 522d having a rectangular outer periphery on the lower side of the cylindrical portion 522c.

  On the lower outer periphery of the cylindrical portion 522c, projecting pieces 522e and 522f are provided so as to project in the left front direction and the right rear direction. The protruding pieces 522e and 522f are formed with insertion holes through which the cylindrical portions 527c and 528c of the shaft screws 527 and 528 are inserted, respectively.

  Front and rear projections 522g and 522h are provided on the outer periphery of the cylindrical portion 522c of the projection lens unit 522. Notches 522i and 522j are formed in the protrusions 522g and 522h, and the vibration shafts 523b and 524b of the piezoelectric linear actuators 523 and 524 are inserted into the notches 522i and 522j. Plate springs 522k and 522l that press the vibration shafts 523b and 524b of the piezoelectric linear actuators 523 and 524 are provided outside the notches 522i and 522j. The piezoelectric linear actuators 523 and 524 move the projection lens unit 522 by vibrating the vibration shafts 523b and 524b with a steep acceleration and a slow acceleration opposite to the acceleration.

  A magnetic scale 522m is attached and fixed to the right side of the outer periphery of the cylindrical portion 522c by bonding.

  The piezoelectric linear actuators 523 and 524 accommodate the piezoelectric elements 523c and 524c (see FIG. 11) in the fixed portions 523a and 524a, respectively. The piezoelectric elements 523c and 524c have vibration shafts 523b and 524b attached thereto, respectively. Screw insertion holes 523d and 524d into which screws 504 and 504 are inserted are formed in the fixing portions 523a and 524a, respectively. Harnesses 523e and 524e connected to the piezoelectric elements 523c and 524c extend from the fixing portions 523a and 524a, respectively.

Hereinafter, the operation principle of the piezoelectric linear actuators 523 and 524 will be described in detail.
The vibration shaft 523b of the piezoelectric linear actuator 523 is fitted between the notch 522i of the projection lens unit 522 and the leaf spring 522k. The vibration shaft 524b of the piezoelectric linear actuator 524 is fitted between the notch 522j of the projection lens unit 522 and the leaf spring 522l.

  The notches 522i and 522j and the leaf springs 522k and 522l of the projection lens unit 522 are slidable with respect to the inserted vibration shafts 523b and 524b, and have sufficient friction in a pressure contact state. In this manner, a sawtooth wave pulse is applied to the electrodes of the piezoelectric elements 523d and 524d of the piezoelectric linear actuators 523 and 524 in a state where the relationship between the inertia of the projection lens unit 522 and the friction between the vibration shafts 523b and 524b is appropriately set. When a signal is given, the vibration shafts 523b and 524b are swung up and down with slow acceleration and steep acceleration. In response to this, the projection lens unit 522 is also shaken. The projection lens unit 522 moves by a displacement Δx1 along with the shaft by a frictional force when the acceleration is slow, and the inertial force of the moving body 12 when the acceleration is steep. Therefore, if the vibration cycle is repeated n times, the vibration shaft 11 is moved in one direction along the vibration shafts 523b and 524b by a distance of nΔx1. I can do it.

  On the other hand, the magnetic scales 301f and 522m shown in FIGS. 8 and 9 are obtained by magnetizing a magnetic medium formed by resin containing a magnetic material with a 5-bit absolute cord to form five magnetic pole rows. The magnetic sensors 525 and 526 for the magnetic encoder shown in FIG. 9 include five magnetic detectors individually corresponding to the five magnetic pole rows, and the five magnetic detectors are respectively used for the magnetic field strength of the magnetic scales 301f and 522m. Is converted into a voltage of H level and L level and output, thereby outputting 5-bit parallel absolute position data from the harnesses 525a and 526b, respectively.

  In FIG. 9, screws 504 and 504 are inserted into screw insertion holes 523d and 524d of the piezoelectric linear actuators 523 and 524, respectively, and are inserted into screw insertion holes 531d and 531e of the light shielding member 521, respectively. Inserted into the screw insertion holes 511d and 511e of the panel 511, and inserted into the screw insertion holes 512d and 512e (see FIG. 11) of the backlight 512, respectively, and formed on the upper end surfaces of the shafts 309 and 310 (see FIG. 10). The piezoelectric linear actuators 523 and 524, the light shielding member 521, the liquid crystal display panel 511, and the backlight 512 are connected to the shafts 309 and 310 (FIG. 10)).

  In the shaft screws 527 and 528, cylindrical portions 527c and 528c are formed between the screw heads 527a and 528a and the screw portions 527b and 528b, respectively. Here, the cylindrical portions 527c and 528c are for reducing friction caused by the projecting pieces 522e and 522f of the projection lens unit 522 as compared with the screw portion.

  As for the shaft screws 527 and 528, the cylindrical portions 527c and 528c are inserted into the projecting pieces 522e and 522f of the projection lens unit 522, and the screw portions 527b and 528b are screwed into the screw screw holes of the screw fixing portions 531f and 531g of the light shielding member 521. As shown in FIG. 10, the projection lens unit 522 is attached to the light shielding member 521 so as to be slidable up and down. The screw heads 527a and 528a of the shaft screws 527 and 528 are arranged so that the edges of the screw insertion holes of the projecting pieces 522e and 522f (see FIG. 9) of the projection lens unit 522 are viewed from above in a state where the projection lens unit 522 is slid upward. Lock. Thereby, the projection lens unit 522 is attached to the light shielding member 521 in a state in which it can slide up and down within a predetermined range.

Hereinafter, the internal structure and operation of the chance button device 100 will be described in more detail.
FIG. 11 is a cross-sectional view of the chance button device 100 when the button portion 300 is at the bottom and no pressing force is applied to the button operation member 301 of the button body 303. FIG. 12 is a cross-sectional view of the chance button device 100 when the button unit 300 is at the bottom and a pressing force is applied to the button operation member 301. FIG. 13 is a cross-sectional view of the chance button device 100 when the button unit 300 is at the top. FIG. 14 is a cross-sectional view of the chance button device 100 when the button unit 300 is at the top and a pressing force is applied to the button operation member 301. FIG. 15 is a side view of the image projection apparatus 501 and its peripheral part when no pressing force is applied to the button operation member 301. FIG. 16 is a side view of the image projection apparatus 501 and its peripheral part when a pressing force is applied to the button operation member 301. FIGS. 11 to 16 show the operation when the out-of-focus effect execution command is not transmitted to the lamp control board 54, that is, when the out-of-focus effect is not performed.

In FIG. 11 to FIG. 14, a control mechanism for vertically moving the button unit 300 such as the driving unit 200 is not shown.
In FIG. 11, the backlight 512 of the liquid crystal display device 501 has a plurality of white light emitting diodes 512a inside, a diffusion plate 512b on the upper surface, and diffuses light from the white light emitting diodes 512a by the diffusion plate 512b. The liquid crystal display panel 511 is led to the back side of the screen 511a. The screen 511a of the liquid crystal display panel 511 transmits light from the backlight 512 with a transmittance controlled for each pixel, so that the screen 511a emits light and displays an image. Various terminals and wirings for driving the liquid crystal are housed in the frame portion 511b disposed on the outer periphery of the screen 511a of the liquid crystal display panel 511.

The liquid crystal display panel 511 and the backlight 512 are connected to and driven by the image control board 55 (see FIG. 5) via a harness 513 (see FIG. 8).
The expanded shape portion 531 a is inserted between the projection lens unit 522 and the liquid crystal display device 501, prevents light from leaking between the projection lens unit 522 and the liquid crystal display device 501, and projects on the liquid crystal display device 501. The angle of the lens unit 522 is made constant.

  The cylindrical pressing frame 304 is fitted with the inner cylindrical frame 305 to form a cylindrical frame 306. The vertical drive frame 307 has a long hole 350 into which the slider 205 (see FIG. 20) is slidably inserted (details will be described later).

  Here, in a state where no pressing force is applied to the operation portion 301b of the button operation member 301 of the button body 303 shown in FIG. 11, the projection lens unit 522 shown in FIGS. 11 and 15 outputs the magnetic sensors 525 and 526. The linear actuators 523 and 524 are driven and controlled by the lamp control board 54 based on the absolute position data, so that the liquid crystal display panel 511 is disposed at the closest position. That is, the image on the screen 511a of the liquid crystal display panel 511 is focused on the farthest position in the structure by the projection lens unit 522b. The focal position is set to coincide with the screen surface 301e of the button operation member 301.

  In this state, the projection lens 522b of the projection lens unit 522 projects the light of the image displayed on the display surface (screen 511a) of the liquid crystal display device 501 as the projection light L1 on the screen surface 301e of the button operation member 301. Then, an image is displayed on the screen surface 301e.

  Next, FIGS. 11 to 16 show the operation and positional relationship of the button operation member 301 and the inner attachment member 302 when the movement force for movement control of the button unit 300 is transmitted from the drive unit 200. It explains using.

  Here, FIG. 11 shows the “state in which the button part 300 protrudes slightly” shown in FIG.

As shown in FIG. 11, a downward movement force is transmitted from a drive source (not shown) to the vertical drive frame 307 of the button unit 300, so that the button unit 300 is moved downward. In this state, no pressing force is applied to the operation portion 301 b of the button operation member 301 of the button body 303, and the button operation member 301, the inner attachment member 302, and the cylindrical frame 306 are driven up and down by the urging force of the center spring 308. It is at a position moved most upward with respect to the frame 307. In this state, the absolute code of the magnetic scale 301f of the magnetic sensor 525 becomes 5-bit parallel absolute position data (00000) corresponding to the pushing amount of the operation unit 301b of 0 mm, and the effect control board 52 has the upper 3 bits of parallel. Absolute position data (000) is transmitted.
The effect control board 52 determines that the operation unit 301b is not operated by receiving the absolute position data (000).

As shown in FIG. 12 from the state of FIG. 11, when the player applies a pressing force to the operation unit 301 b with the finger 600, the button operation member 301, the inner attachment member 302, and the cylindrical frame 306 are biased by the center spring 308. On the other hand, it moves to the position moved to the lowest position with respect to the vertical drive frame 307.
In this state, the liquid crystal display device 501 and the light shielding member 521 are fixed to the vertical drive frame 307 via the shafts 309 and 310, and the button operation member 301, the inner mounting member 302, and the cylindrical frame 306 are attached to the vertical drive frame 307. Even if it moves, the positions of the liquid crystal display device 501, the light shielding member 521, the piezoelectric linear actuators 523 and 524, the shafts 532 and 533, and the magnetic sensors 525 and 526 do not change.

  When the button operation member 301 moves downward with respect to the light shielding member 521, the magnetic scale 301f moves downward with respect to the light shielding member 521, and the absolute code of the magnetic scale 301f to be detected changes in the magnetic sensor 525, and the output The absolute position data to be changed changes. Here, the lamp control board 54 drives and controls the piezoelectric linear actuators 523 and 524 to move the projection lens unit 522, and the absolute position data of the magnetic scale 552 m detected by the magnetic sensor 526 is the absolute position data of the magnetic sensor 525. The data is controlled so as to correspond to. Thereby, the projection lens unit 522 is controlled so that the focus surface of the image of the screen 511a of the liquid crystal display panel 511 coincides with the screen surface 301e. Thereafter, the button operation member 301 moves to the lowermost position with respect to the light shielding member 521, and the projection lens unit 522 shown in FIGS. 12 and 16 is disposed at a position farthest from the liquid crystal display panel 511. Thereby, the projection lens unit 522 focuses the image on the screen 511a of the liquid crystal display panel 511 at a position closest in structure. This focal position is set so as to coincide with the screen surface 301e of the button operation member 301 most depressed by the player's operation.

  On the other hand, the absolute code read by the magnetic sensor 525 from the magnetic scale 301f becomes 5-bit parallel absolute position data (00100) to (11111) corresponding to the pushing amount of the operation unit 301b of 1 mm or more, and the effect control board 52 3 bit absolute position data (001) to (111) in parallel is transmitted.

  The effect control board 52 determines that the operation unit 301b is operated by receiving absolute position data (001) to (111) indicating that the push-in amount is 1 mm or more, for example, as shown in FIGS. The control of the effect shown is performed.

  In such a state, the projection lens 522b of the projection lens unit 522 uses the light of the image displayed on the display surface (screen 511a) of the liquid crystal display device 501 as the projection light L2 on the screen surface 301e of the button operation member 301. Projecting and displaying an image on the screen surface 301e.

  Next, the upward movement force from the drive source 200 is transmitted to the vertical drive frame 307 of the button unit 300, so that the button unit 300 is moved upward, and the button unit 300 is at the uppermost position. 13 is reached, the state shown in FIG. 13 is obtained. In the state of FIG. 13, the “button part 300 protrudes greatly” shown in FIG. 7 is obtained. In the state of FIG. 13, no pressing force is applied to the operation portion 301 b of the button operation member 301 of the button body 303, and the button operation member 301, the inner attachment member 302, and the cylindrical frame 306 are attached with the center spring 308. It is in a position that has been moved upward relative to the vertical drive frame 307 by the force. In this state, the positional relationship among the projection lens unit 522, the liquid crystal display panel 511, and the screen surface 301e is controlled by the piezoelectric linear actuators 523 and 524 based on the detection results of the magnetic sensors 525 and 526 by the lamp control board 54. 11 and the state shown in FIG. In this state, the absolute code of the magnetic sensor 525 of the magnetic scale 301f is the 5-bit parallel absolute position data (00000) similar to the state of FIG. 11, and the effect control board 52 has the upper 3-bit parallel absolute position data. (000) is transmitted.

  The effect control board 52 determines that the operation unit 301b is not operated by receiving the absolute position data (000).

  As shown in FIG. 14 from the state of FIG. 13, when the player applies a pressing force to the operation unit 301b with the finger 600, the vertical drive frame 307 does not move, but the button operation member 301, the inner mounting member 302, and the cylindrical frame 306 moves to the position moved downward relative to the vertical drive frame 307 against the urging force of the center spring 308.

  Thereby, the positional relationship among the projection lens unit 522, the liquid crystal display panel 511, and the screen surface 301e is controlled by the piezoelectric linear actuators 523 and 524 based on the detection results of the magnetic sensors 525 and 526 by the lamp control board 54. This is the same as the state shown in FIGS. In this state, the absolute code of the magnetic scale 301f detected by the magnetic sensor 525 becomes the 5-bit parallel absolute position data similar to the state of FIG. 12, and the 3-bit parallel absolute position data ( 000) is similar to the state of FIG. The effect control board 52 determines that the operation unit 301b is operated by receiving absolute position data (001) to (111) indicating that the pushing amount of the operation unit 301b is 1 mm or more, for example, FIG. And the production control shown in FIG. 44 is performed.

  With this operation, in this embodiment, even when the position of the button operation member 301 with respect to the liquid crystal display panel 511 changes, the image on the screen 511a of the liquid crystal display panel 511 is always focused on the screen surface 301e. Will be displayed in the state. The effect control board 52 performs effect control according to the pressing amount of the operation unit 301b.

  17 and 18 are a perspective view and a side view for explaining members that mainly operate when a pressing force is applied to the button operation member 301 (when the button operation member 301 is pressed by a player or the like). . FIG. 19 is a cross-sectional view of the member.

  As shown in FIGS. 17 and 18, the cylindrical pressing frame 304 is fitted with the inner cylindrical frame 305 to form a cylindrical frame 306. The vertical drive frame 307 has a long hole 350 into which the slider 205 (see FIG. 20) is slidably inserted (details will be described later).

  As shown in FIG. 8, the central portion of the inner cylindrical frame 305 is provided with a cavity 305a into which the cylindrical portion 307A of the vertical drive frame 307 is loosely inserted when the cylindrical frame 306 and the vertical drive frame 307 are engaged. It has been. In FIG. 19, a center spring 308 is inserted into the cylindrical portion 307A from a cylindrical opening 307Am, and a shaft cylinder 304b (described later) formed inside the cylindrical pressing frame 304 is also provided so as to be insertable. The cylindrical portion 307A has a cylindrical bottom 307Ab, and the center spring 308 inserted from the cylindrical port 307Am is locked by the cylindrical bottom 307Ab. In other words, the cylindrical bottom 307Ab is provided so that the center spring 308 inserted from the cylindrical port 307Am does not fall off from the cylinder 307Ab side.

  The cylindrical pressing frame 304 has one cylindrical shape closed by a top portion 304a, and a shaft tube 304b is provided on the back side (that is, inside the cylinder) of the top portion 304a. When the cylindrical frame 306 is engaged with the vertical drive frame 307, the shaft tube 304b is slidably engaged within the cylindrical portion 307A of the vertical drive frame 307. Further, the diameter of the shaft tube 304b is larger than the diameter of the center spring 308. When the shaft tube 304b slides in the cylindrical portion 307A in the direction of the cylinder bottom 307Ab, the center spring 308 is caused to move by the shaft tube 304b. It will be pressed. At this time, the pushing force from the center spring 308 acts on the shaft tube 304b by the elastic force of the pressed center spring 308. That is, when the button operation member 301 is pressed, the pressing force is transmitted to the center spring 308 from the inner mounting member 302 and the top 304a and the shaft tube 304b of the cylindrical frame 306. The pressed button operation member 301 is subjected to an urging force (force caused by the reaction of the pressing force) from the center spring 308 trying to return to the state before the pressing.

  The inner cylindrical frame 305 is engaged with the vertical drive frame 307 at an interval indicated by ST1 (for example, 8 mm) in FIG. Specifically, the inner cylindrical frame 305 and the vertical drive frame 307 are engaged with each other so as to keep the distance ST1 between the flange surface UX of the inner cylindrical frame 305 and the flange surface DX of the vertical drive frame 307. That is, the cylindrical frame 306 (inner cylindrical frame 305) is engaged with the vertical drive frame 307 so as to be able to move downward by a distance of ST1. The distance ST1 in which the cylindrical frame 306 can move downward is referred to as an allowable pressing distance (details will be described later). The inner cylindrical frame 305 has a plurality of boss-like protrusions 305c.

  FIG. 20 is an exploded perspective view of the drive unit 200. The drive unit 200 includes a front gear frame 201, a rear gear frame 206, various gears and the like (see FIG. 21) housed in the gear frames 201 and 206, a solenoid 202, a crank arm 203, and the tip of the crank arm 203. A crank bushing 204 fitted to the protrusion 203a, a motor 207 connected to one of various gears (motor gear 210) housed in the gear frames 201 and 206, and a motor cover 208 protecting (housing) the motor 207 It consists of and. The tip protrusion 203a and the crank bushing 204 constitute a slider 205.

  FIG. 21 is an enlarged view for explaining various gears and the like housed in the gear frames 201 and 206. A motor gear 210 is coupled (directly coupled) to the motor 207, and rotational power generated by driving the motor 207 is transmitted from the motor gear 210 to the relay gear 211 and the crank gear 212. The crank gear 212 is inserted into a clutch shaft 222 fixed to the crank arm 203, but is not fixed in the rotational direction of the shaft 222, and therefore is not driven as the shaft 222 rotates. It has become a thing.

  A clutch receiver 220 is also inserted in the clutch shaft 222. The clutch receiver 220 is fixed in the rotational direction of the clutch shaft 222, and is driven by the rotation of the shaft 222. Rotate. Further, the clutch receiver 220 is slidable in the axial direction of the shaft 222 (the direction back and forth with respect to the shaft), and is always urged by the clutch spring 221 to press the crank gear 212. It has become.

  The crank gear 212 is formed with a tooth-shaped portion 212 </ b> A having a saw-tooth shape that is jagged in the axial direction of the clutch shaft 222. The clutch receiver 220 is formed with a tooth mold part 220A having a sawtooth shape that can mesh with the tooth mold part 212A. The tooth mold part 220A of the clutch receiver 220 urged by the clutch spring 221 The state where the tooth mold portion 212A is engaged is always maintained. By maintaining the engaged state in this way, the crank gear 212, the clutch receiver 220, the clutch shaft 222, and the crank arm 203 rotate in synchronization. The tooth mold part 220A and the tooth mold part 212A will be described later with reference to FIGS.

  Photo sensors (a lower position photo sensor 213 and an upper position photo sensor 214) capable of detecting the rotation angle of the crank arm 203 are provided in the vicinity of the crank gear 212. The photosensors 213 and 214 are transmissive photosensors, and are arranged at positions where the light receiving and light emitting elements can be shielded by the shielding protrusions 203b formed on the crank arm 203. Although details will be described later, each of the photosensors 213 and 214 is a position where the button unit 300 is in the lowest position (the button unit 300 is slightly protruded) when the shielding projection 203b is detected by the lower position photosensor 213. In addition, when the shielding protrusion 203b is detected by the upper position photosensor 214, the button part 300 is arranged at the uppermost position (the position where the button part 300 is greatly protruded). ing.

  The rotational power generated by driving the motor 207 is also transmitted from the motor gear 210 to the movement lock gear 215. The movement lock gear 215 has a rotary shaft that can move substantially vertically (details will be described later). . When the rotary shaft 215A of the movement lock gear 215 moves downward (that is, when the movement lock gear 215 moves downward), the gear lock 216 is moved to a position where it can mesh with the teeth of the movement lock gear 215. Is arranged. The gear lock 216 is connected to the solenoid 202 by a plunger 202a, and the plunger 202a is attracted to the solenoid 202 main body by the operation of the solenoid 202 (the solenoid 202 is energized). The gear lock 216 is also attracted to the solenoid 212 main body side.

  The gear lock 216 is disposed so as to mesh with the movement lock gear 215 that has moved downward when the solenoid 202 is not operated (non-energized state). Therefore, when the solenoid 202 is not operated (non-energized state), the rotational power of the movement lock gear 215 is restricted by the gear lock 216 (this is referred to as “lock state”).

On the other hand, when the solenoid 202 is activated (energized state), as described above, the gear lock 216 is attracted to the solenoid 202 main body side, so that it is disengaged from the position where it is engaged with the movable lock gear 215 moved downward. Become. Therefore, when the solenoid 202 is actuated (energized state), the rotational power of the movement lock gear 215 is not restricted by the gear lock 216 (this is referred to as “unlocked state”).
Note that the movement lock gear 215 in the locked state is brought into the unlocked state by the operation of the solenoid 202 is particularly referred to as “the locked state is released”.

  Next, the operation of the chance button device 100 will be described with reference to FIGS.

  The operation when the upward movement is started from the state where the button unit 300 is at the lowest position will be described with reference to FIGS.

  As shown in FIG. 22, the rotation shaft 215A of the movement lock gear 215 can move substantially vertically between the rotation shaft 215Ad and the rotation shaft 215Au by the rotation of the motor gear 210 (in the direction of the arrow indicated by A in the drawing). .

  FIG. 23 shows a state where the button unit 300 is stationary at the lowest position. As shown in the drawing, the movement lock gear 215 moves downward due to its own weight. At this time, the rotation shaft 215A of the movement lock gear 215 is in the lower position (the rotation shaft at this time is referred to as a rotation shaft 215Ad). That is, the movement lock gear 215 having the rotation shaft 215Ad is locked with the gear lock 216.

  FIG. 24 shows a state in which the upward movement is started from the state where the button unit 300 is at the lowest position. As illustrated, with the rotation of the motor gear 210 (A direction in the figure), the movement lock gear 215 moves upward in the X direction in the figure. At this time, the rotation shaft 215A of the movement lock gear 215 is in the upper position (the rotation shaft at this time is referred to as a rotation shaft 215Au). Further, the movement lock gear 215 having the rotation shaft 215Au is in an unlocked state with the gear lock 216.

  Next, the crank arm 203 and the long hole 350 when the button unit 300 moves from the lowermost position to the uppermost position will be described with reference to FIG.

FIG. 25A shows the positional relationship between the crank arm 203 and the long hole 350 when the button unit 300 starts to move upward from the lowest position. When the button unit 300 starts to move upward from the lowest position, the crank gear 212 rotates in the M direction and the crank arm 203 also rotates in the M direction. At this time, the slider 205 slides in the R1 direction in the long hole 350, and the vertical drive frame 307 moves upward in the arrow direction indicated by U in the drawing.
The point where the slider 205 is located in the long hole 350 when it is at the lowest position is referred to as the lowest descending point (D).

FIG. 25B shows a state where the slider 205 further slides in the long hole 350 in the R1 direction and reaches the right end 350a of the long hole 350. FIG. At this time, since the crank arm 203 continues to rotate in the M direction, the slider 205 that has reached the right end 350a then slides in the direction L1 in the drawing toward the left end 350b in the long hole 350. (FIG. 25 (c)).
Then, the slider 205 slid and moved in the L1 direction in the long hole 350 stops when it moves to the position shown in FIG. 25D (that is, the shielding protrusion 203b reaches the position detected by the upper position photosensor 214). ).
The point where the slider 205 is located in the long hole 350 when it is at the uppermost position is referred to as the highest rising point (H).

  Next, the operation of the movement lock gear 215 when the button unit 300 reaches the uppermost position and when the downward movement is started from the uppermost position will be described with reference to FIGS.

  FIG. 26 shows a state of the driving unit 200 immediately before the button unit 300 reaches the uppermost position. That is, the motor gear 210 continues to rotate in the A direction, and at this time, the movement lock gear 215 is kept in the state of being moved upward (in the X direction in the drawing) to the position where the rotation shaft becomes the rotation shaft 215Au. Therefore, the unlocked state of the gear lock 216 and the movement lock gear 215 is maintained.

  FIG. 27 shows a state of the driving unit 200 when the button unit 300 reaches the uppermost position. That is, the rotation of the motor gear 210 is stopped, and the movement lock gear 215 is in a state where the rotation shaft 215A is moved downward due to its own weight (in the Y direction in the figure) where the rotation shaft 215A becomes the rotation shaft 215Ad. As a result, the movement lock gear 215 is locked with the gear lock 216.

FIG. 28 shows a state of the driving unit 200 when the button unit 300 starts to move downward from the uppermost position. At this time, since the motor gear 210 rotates in the B direction opposite to the upward movement, the crank gear 212 and the crank arm 203 also rotate in the N direction in the figure opposite to the M direction during the upward movement (see FIG. 25). Will be. Then, the movement lock gear 215 rotates in the W direction in the figure. Since the rotation axis of the movement lock gear at this time is the rotation axis 215Ad, the movement lock gear 215 is locked with the gear lock 216. (See FIG. 29). Therefore, in order to release the locked state shown in FIG. 29, the solenoid 202 is energized and the gear lock 216 and the movement lock gear 215 are unlocked (see FIG. 30).
In the present embodiment, the solenoid 202 is energized while the button unit 300 described in FIG. 26 continues to move upward from the lowest position. Thereby, for example, even if a heavy gear is used as the movement lock gear 215, the gear 215 is moved to the lower position due to its own weight (the weight of the movement lock gear 215) during the upward movement (the rotation shaft 215A rotates). It is possible to avoid being locked with the gear lock 216 even when the shaft is 215Ad.

  Next, a pressing allowable distance (hereinafter referred to as “pressing stroke”) when the button unit 300 is pressed will be described with reference to FIGS. 31 and 32.

FIG. 31 shows the positional relationship among the lower case 102 (indicated by a dotted line), the cylindrical frame 306, and the vertical drive frame 307 when the button unit 300 is at the lowermost position.
That is, the distance indicated by ST1 is maintained between the cylindrical frame 306 and the vertical drive frame 307 as described in FIG. That is, the cylindrical frame 306 can be moved downward toward the vertical drive frame 307 by ST1, but the lower case 102 is engaged with the button portion 300 (particularly, the cylindrical frame 306). In addition, a plurality of receiving holes 102 a that can receive the plurality of boss-like protrusions 305 c of the cylindrical frame 306 are provided. As shown in the figure, the receiving hole 102a is formed between the tip surface BX of the boss-like protrusion 305c and the bottom surface TX of the receiving hole 102a when the lower case 102 is engaged with the button portion 300 (particularly the cylindrical frame 306). The hole is drilled so that the distance indicated by ST2 is maintained.

  The distance indicated by ST2 (for example, 10 mm) is set to be larger than the distance indicated by ST1 (for example, 8 mm). As a result, even if the cylindrical frame 306 moves downward by ST1, the tip surface BX of the boss-shaped protrusion 305c does not come into contact with the bottom surface TX of the receiving hole 102a. That is, the pressing stroke when the button unit 300 is at the lowest position is ST1.

On the other hand, FIG. 32 shows a positional relationship between the lower case 102 (shown by a dotted line), the cylindrical frame 306, and the vertical drive frame 307 when the button unit 300 is at the uppermost position.
That is, since the plurality of boss-like protrusions 305c are located away from the receiving hole 102a that can receive them, the relationship [ST2 <ST1] is not established. Therefore, only the distance indicated by ST1 is maintained between the cylindrical frame 306 and the vertical drive frame 307, as described with reference to FIG. Therefore, the cylindrical frame 306 can move downward by ST1. That is, the pressing stroke when the button unit 300 is at the uppermost position is ST1.

  Next, the operation of the drive unit 200 when a pressing force exceeding the pressing stroke is applied when the button unit 300 is at the uppermost position will be described with reference to FIGS. 33 and 34.

  FIG. 33 shows a state of the crank gear 212 and the clutch receiver 220 when the button unit 300 is at the uppermost position. As shown in the drawing, the urging force from the clutch spring 221 acts on the clutch receiver 220, so that the tooth mold part 220 </ b> A of the clutch receiver 220 is in mesh with the tooth mold part 212 </ b> A of the crank gear 212. .

  However, as shown in FIG. 34, when a pressing force F exceeding the pressing stroke ST1 (indicated by a white arrow in the figure) is applied, the button section 300 has no more room for the pressing stroke to move further downward. Therefore, rotational power (force in the direction of the arrow indicated by I in the figure) due to this pressing force F acts on the crank gear 212 via the crank arm 203. In other words, power is applied to rotate the crank gear 212 in the direction I in the drawing although the drive unit 200 is not operating. However, at this time, the movement lock gear 215 is in a locked state with the gear lock 216, and the relay gear 211 and the motor gear 210 are also not rotatable. For this reason, when rotational power in the direction I in the drawing is applied to the crank gear 212, the rotational power is transmitted to the other gears 211 to 215 following this. That is, an unreasonable force (overload) is applied to the gears 211 to 215, and there is a possibility that the gears 212 to 215 may be damaged (the teeth are broken or the gear shaft is displaced). is there.

In order to avoid such a situation, in the present embodiment, the crank gear 212 is provided with the tooth mold portion 212A, and the clutch receiver 220 having the tooth mold portion 220A meshing with the tooth mold portion 212A is provided. As shown in the figure, the tooth mold portions 212A and 220A have a jagged shape (a notch like a saw tooth), and are in mesh with each other.
Therefore, as shown in FIG. 33, since the clutch receiver 220 is normally urged in the P direction from the clutch spring 221, the tooth mold portion 220A of the urged clutch receiver 220 becomes the tooth mold portion of the crank gear 212. It will mesh with 212A.

  On the other hand, when a pressing force F as shown in FIG. 34 is applied, rotational power in the direction I in the figure is applied to the crank arm 203 and the clutch receiver 220. At this time, the crank gear 212 is applied to the crank gear 212. Since the other gears 210, 211, and 215 are in a locked state, a force in the direction of the arrow indicated by K in the figure is generated. Then, the tooth mold part 220A of the clutch receiver 220 is moved in the I direction while being shifted from the position where the tooth mold part 212A is engaged with the tooth mold part 212A along the toothed surface of the tooth mold part 212A of the crank gear 212A. Will be rotated. Therefore, as shown in the figure, the engaged state of the clutch receiver 220 and the crank gear 212 is temporarily released (hereinafter, this released state is referred to as “non-engaged state”). That is, in this non-engaged state, the urging force in the arrow direction indicated by L in the drawing acts on the clutch receiver 220 from the crank gear 212 (and the tooth mold portion 212A).

  In this non-engaged state, when the crank arm 203 and the clutch receiver 220 are slightly rotated in the I direction, the clutch receiver 220 urged by the clutch spring 221 is pushed out in the P direction, and the tooth mold portion 220A is again moved. It will mesh with the tooth mold 212A.

  Here, “slightly rotated” means that if the clutch receiver 220 is rotated and moved by one pitch of the tooth mold portion 212A, the tooth mold portions 212A and 220A are in positions where they can be engaged next. Therefore, the clutch receiver 220 that is always urged in the P direction is engaged again at a position where the engagement is possible.

That is, when the pressing force F is applied for a short period of time (when a strong force is applied for a moment), the gears 210 to 215 due to the pressing force F are simply shifted by one pitch as described above. Can reduce the overload.
Further, when the pressing force F is continuously applied for a long time (when the pressing force F is continuously pressed with a strong force), the gear by the pressing force F is repeated while repeating the one-pitch deviation as described above. The overload to 210-215 can be reduced.

  The main process of the effect control board 52 will be described with reference to FIG.

  In step S1000, the sub CPU 52a performs an initialization process. In this process, the sub CPU 52a reads the main processing program from the sub ROM 52b and initializes and sets a flag stored in the sub RAM 52c in response to power-on. If this process ends, the process moves to a step S1100.

  In step S1100, the sub CPU 52a performs an effect random number update process. In this process, the sub CPU 52a performs a process of updating random numbers (the effect random number value 1, the effect random number value 2, the effect design determining random value, the effect mode determining random value, etc.) stored in the sub RAM 52c. Thereafter, the process of step S1100 is repeated until a predetermined interrupt process is performed.

(Timer interrupt processing of production control board)
The timer interrupt process of the effect control board 52 will be described with reference to FIG.
Although not shown in the figure, a clock pulse is generated every predetermined period (2 milliseconds) by a reset clock pulse generation circuit provided on the effect control board 52, a timer interrupt processing program is read, and a timer of the effect control board is read. Interrupt processing is executed.

  First, in step S1400, the sub CPU 52a saves the information stored in the register of the sub CPU 52a to the stack area.

  In step S1500, the sub CPU 52a performs update processing of various timer counters used in the effect control board 52.

  In step S1600, the sub CPU 52a performs command analysis processing. In this process, the sub CPU 52a performs a process of analyzing a command stored in the reception buffer of the sub RAM 52c. A specific description of the command analysis processing will be described later with reference to FIG. When the effect control board 52 receives a command transmitted from the main control board 110, a command reception interrupt process of the effect control board 52 (not shown) occurs, and the received command is stored in the reception buffer. Thereafter, the received command is analyzed in step S1600.

  In step S <b> 1700, the sub CPU 52 a checks input data from the magnetic sensor 525 via the substrate 54 that is an effect button detection switch, and performs an effect input control process related to the chance button device 100.

  In step S1800, the sub CPU 52a performs data output processing for transmitting various commands set in the transmission buffer of the sub RAM 52c to the lamp control board 54 and the image control board 55.

  In step S1900, the sub CPU 52a restores the information saved in step S1810 to the register of the sub CPU 52a.

Next, the variation effect pattern determination table will be described with reference to FIG.
FIG. 37 is a diagram showing an example of a variation effect pattern determination table corresponding to a case where a long winning game is won and a loss.

  As shown in this figure, the variation effect pattern determination table is classified for each variation pattern designation command received by the effect control board 52.

  For example, when the effect control board 52 receives the variation pattern designation command “E6H-01H”, command analysis processing is performed, and a table corresponding to “E6H-01H” is selected from the variation effect pattern determination table. As described above, the ROM 102b of the effect control board 52 is provided with as many change effect pattern determination tables as the number of change pattern designation commands that can be received.

  In the present embodiment, the MODE of the variation pattern designation command corresponds to a jackpot lottery result performed on condition that a game ball has entered the first start port 25 or the second start port 26. “E6H” indicates a loss, and “E7H” indicates a winning game per jackpot. Further, DATA of the variation pattern designation command indicates the effect time of one game performed by the lottery. In this embodiment, in addition to the jackpot long hit and the loss, there are fluctuation pattern designating commands corresponding to the jackpot short hit and small hit and corresponding variation effect patterns, which are omitted in FIG. .

  Then, in the effect control board 52, the effect random number value is extracted when the change pattern designation command is received, and based on the extracted effect random number value and the determined change effect pattern determination table, one is determined. One variation production pattern will be determined.

  The effect control board 52 generates an effect instruction command based on the change effect pattern, and based on the determined change effect pattern, the repeated impact enable flag, the button operation image switching effect flag, the out-of-focus effect flag, etc. of the sub RAM 52c. The production flag is set and reset.

  The sub RAM 52c of the effect control board 52 is provided with various timer counters such as an effect input timer counter. The effect input timer counter can be reset and measures time by counting clock signals from a clock generation circuit provided on the effect control board 52.

The effect input control process will be described with reference to FIG.
First, in step S1701 shown in FIG. 38, the sub CPU 52a determines whether or not the 3-bit absolute position data output from the magnetic sensor 525 (see FIG. 8) is data (000). Here, if the absolute position data output from the magnetic sensor 525 (see FIG. 8) is data (000), the sub CPU 52a ends the current effect input control process, and the absolute position data is not data (000). If it determines with it being data (001)-(111), it will transfer to the process of step S1702.

  In step S1702, the sub CPU 52a determines whether or not the time value of the effect input timer counter of the sub RAM 52c is 0.5 seconds or less. If the time value of the effect input timer counter in the sub RAM 52c is 0.5 seconds or less, the process proceeds to step S1703, and if the time value of the effect input timer counter in the sub RAM 52c exceeds 0.5 seconds, step S1703 is performed. The process proceeds to S1705.

  In step S <b> 1703, the sub CPU 52 a determines whether or not the continuous hit effect flag = 01 is set in the sub RAM 52 c. The sub CPU 52a proceeds to the process of step S1704 if the continuous hit effect flag = 01 is set, and if the continuous hit effect flag = 01 is not set (if the continuous hit effect flag = 00), the step is executed. The process proceeds to S1705.

  In step S1704, the sub CPU 52a sets a continuous strike effect execution command in the transmission buffer. This command is a command for causing the image control board 55 to execute a continuous striking effect. The sub CPU 52a proceeds to the process of step S1705 after the process of step S1704.

  In step S1705, the sub CPU 52a determines whether or not the button operation image switching effect flag = 01 is set in the sub RAM 52c. If the button operation image switching effect flag = 01 is set, the sub CPU 52a proceeds to the process of step S1706, and if the button operation image switching effect flag 01 is not set, the sub CPU 52a proceeds to the process of step S1707.

  In step S1706, the sub CPU 52a sets a button operation image switching effect command in the transmission buffer. This command is a command for causing the image control board 55 to execute a button operation image switching effect. The sub CPU 52a proceeds to the process of step S1707 after the process of step S1706.

  In step S1707, the sub CPU 52a determines whether or not a focus deviation effect flag = 01 is set in the sub RAM 52a. If the out-of-focus effect flag = 01 is not set, the sub CPU 52a proceeds to the process of step S1709. If the out-of-focus effect flag 01 is set, the sub CPU 52a proceeds to the process of step S1708.

  In step S1708, the sub CPU 52a sets a defocusing effect execution command individually corresponding to the absolute position data output from the magnetic sensor 525 (see FIG. 8) in the transmission buffer. This command is a command for causing the lamp control board 54 to execute an out-of-focus effect. The sub CPU 52a proceeds to the process of step S1709 after the process of step S1708.

In step S1709, the CPU 52a resets the effect input timer counter of the sub RAM 52c, resets the time count to 0 seconds, and ends the effect input control process this time.
The main process of the image control board 55 will be described with reference to FIG.
When power is supplied from the power supply board 170, a system reset occurs in the host CPU 55a, and the host CPU 55a performs the following main processing.

In step S2010, the host CPU 55a performs an initialization process. In this processing, the host CPU 55a reads the main processing program from the host ROM 55c and instructs the initial setting of various modules of the host CPU 55a and the VDP (Video Display Processor) 400 in response to power-on.
Here, the host CPU 55a uses the VDP 400 as an initial setting instruction.
(1) To instruct the display circuit 418 to create and output a video signal, instruct the video signal to be created (set 1 to 0 bit of the display register),
(2) The image data frequently used in the decompression circuit 416 (image data of the production symbol 36, image data of the press (see FIG. 43), etc.) is stored in the main expansion storage area 403b1 or the chance button expansion storage area 403b2. In order to expand and expand to a predetermined initial value data in the expansion register,
(3) In order to cause the drawing circuit 417 to draw initial value image data (such as a character image “power-on”), an initial value display list is output.

In step S2020, the host CPU 55a performs a drawing execution start process. In this process, in order to instruct the VDP 400 to execute drawing on the display list that has already been output, drawing execution start data is set in the drawing register.
That is, at the start of power-on, execution of drawing for the initial value display list output in step S2010 is instructed, and during normal routine processing, execution of drawing for the display list output in S2050 described later is instructed. .

In step S2030, the host CPU 55a performs effect instruction command analysis processing for analyzing the effect instruction command (command stored in the reception buffer of the host RAM 55b) transmitted from the effect control board 52.
When the image control board 55 receives a command transmitted from the effect control board 52, a command reception interrupt process of the image control board 55 (not shown) occurs, and the received command is stored in the reception buffer. Thereafter, the received command is analyzed in step S2030.

The effect instruction command analysis process confirms whether or not an effect instruction command (for example, an effect pattern designation command as shown in FIG. 14) is stored in the reception buffer. If an effect instruction command is not stored in the reception buffer, the process proceeds directly to step S2040.
If a production instruction command is stored in the reception buffer, a new production instruction command is read, and one or more animation groups to be executed are determined based on the read production instruction command. Determine the pattern.

  In step S2040, the host CPU 55a performs an animation control process. In this process, based on the “scene switching counter”, the “weight frame”, the “frame counter” updated in step S2210, which will be described later, and the animation pattern determined in step S2030, various animation scenes are displayed. Update the address.

In step S2050, the host CPU 55a determines the display list from the display information (sprite identification number, display position, etc.) of the animation scene at the updated address according to the priority order (drawing order) of the animation group to which the animation scene belongs. Will be generated. When the generation of the display list is completed, the host CPU 55a outputs the display list to the VDP 400.
The display list output here is stored in the main display list storage area 403a1 or the chance button display list storage area 403a2 of the VRAM 403 via the CPU I / F 2030 in the VDP 400.

In step S2060, the host CPU 55a determines whether or not the FB switching flag = 01.
Here, the FB switching flag becomes FB switching flag = 01 if drawing of the previous display list is completed in the V blank interruption every 1/60 seconds (about 16.6 ms). That is, in step S2060, it is determined whether or not the previous drawing has been completed.
If the FB switching flag = 01, the host CPU 55a shifts the process to step S2070. If the FB switching flag = 00, the host CPU 55a waits until the FB switching flag = 01.

In step S2070, the host CPU 55a sets the FB switching flag = 00 (turns the FB switching flag off), and moves the process to step S2020.
Thereafter, the processing from step S2020 to step S2070 is repeated until a predetermined interrupt occurs.

(Expansion circuit expansion control processing)
The extension control process of the extension circuit 416 in the VDP 400 will be described with reference to FIG.

First, in step S2310, the decompression circuit 416 determines whether an instruction to start decompression execution for decompressing image data to be rendered has been issued from the rendering circuit 417. Specifically, the drawing circuit 417 determines whether or not decompression execution start data is set in the decompression register (whether 1 is set in the 0th bit of the decompression register).
When there is an instruction to start decompression execution, the decompression circuit 416 moves the process to step S2320, and when there is no instruction to start decompression execution, the decompression circuit 416 waits until there is an instruction to start decompression execution.

  In step S2320, the decompression circuit 416 clears the decompression start data of the decompression register set by the drawing circuit 417 (sets 0 to the 0th bit of the decompression register).

  In step S2330, the decompression circuit 416 sets the decompression execution data in the decompression register (sets 1 to the 1st bit of the decompression register) in order to inform the drawing circuit 417 that decompression is being performed.

  In step S2340, the decompression circuit 416 reads the compressed image data compressed in the CRROM 401, decompresses the read compressed image data into the original image data, and decompresses the decompressed image data into the main expanded storage area 403b1 of the VRAM 403. Alternatively, it is expanded in the chance button expansion storage area 403b2.

In step S2350, the decompression circuit 416 determines whether decompression of one image has been completed.
In the decompression circuit 416, when decompression of one image is completed, the process proceeds to step S2360, and when decompression of one image is not completed, the process returns to step S2340 and the decompression process is repeated.

  In step S2360, when the decompression circuit 416 completes decompression of one image, the decompression data in the decompression register is cleared (0 is set in the first bit of the decompression register) to notify the drawing circuit 417 that the decompression has been completed. Then, the process returns to step S2310 to repeat the expansion control process.

(Drawing control process in drawing circuit)
The drawing control process of the drawing circuit 417 in the VDP 400 will be described with reference to FIG.

In step S2410, the drawing circuit 417 determines whether there is an instruction to start drawing from the host CPU 55a. Specifically, the host CPU 55a determines whether drawing execution start data is set in the drawing register (whether 1 is set in the 0th bit of the drawing register).
If there is an instruction to start drawing, the drawing circuit 417 moves to step S2420. If there is no instruction to start drawing, the drawing circuit 417 waits until there is an instruction to start drawing.

  In step S2420, the drawing circuit 417 clears the drawing execution start data in the drawing register set by the host CPU 55a (sets 0 to the 0th bit of the drawing register).

In step S2430, the drawing circuit 417 reads the display list stored in the main display list storage area 403a1 or the chance button display list storage area 403a2 of the VRAM 403, and sets the drawing control command for the read display list in advance. The analysis is sequentially performed according to the priority (drawing order).
Here, not all of the plurality of drawing control commands in the display list are analyzed at once. In one display list analysis control process, a predetermined unit (drawing order) is used in accordance with a predetermined priority (drawing order). For example, a drawing control command of one image data) is sequentially analyzed.

  In step S2440, the drawing circuit 417 stores an expansion command for expanding the compressed image in the display list, and the image data to be drawn is stored in the main expansion storage area 403b1 or the chance button expansion storage area 403b2. If not (decompressed), the decompression circuit 416 is instructed to decompress the image data to be drawn. Specifically, the decompression execution start data is set in the decompression register (1 is set to 0 bit of the decompression register).

In step S2450, the drawing circuit 417 determines whether expansion of the image to be drawn has been completed. Specifically, it is determined whether or not the decompression execution data is cleared in the decompression register (whether or not 0 is set in the first bit of the decompression register).
The drawing circuit 417 shifts the processing to step S2460 when the drawing image has been decompressed, and waits until the drawing image has been decompressed when the drawing image has not been decompressed.

  In step S2460, the drawing circuit 417 expands the image expanded to the main development storage area 403b1 or the chance button development storage area 403b2 of the VRAM 403 while appropriately setting necessary data in the drawing register according to the display list drawing control command. Is drawn in the “drawing frame buffer” in the VRAM 403.

In step S2470, the drawing circuit 417 determines whether all drawing control commands in the display list for one frame have been completed (drawing processing for one frame has been completed).
When the drawing process for one frame is completed, the drawing circuit 417 shifts the process to step S2480. When the drawing process for one frame is not completed, the drawing circuit 417 returns the process to step S2430, and the drawing process for one frame is performed. Until the process is completed, the “display list analysis control process” in step S2430, the “decompression instruction process” in step S2440, and the “drawing process” in step S2460 are repeated.
If all the image data is compressed and stored in the CGROM 401 as in the present embodiment, the image is expanded and drawn for each image according to the display list.

  In step S2480, the drawing circuit 417 sets drawing end data in the interrupt register (sets 1 in the first bit of the system control register), returns to the process in step S2410, and repeats the drawing control process.

(Display control processing in display circuit)
A display control process of the display circuit 2080 in the VDP 400 will be described with reference to FIG.

In step S2510, the display circuit 2080 determines whether a video signal creation instruction has been received from the host CPU 55a. Specifically, it is determined whether 1 is set in the 0th bit of the display register.
If there is an instruction to create a video signal, the display circuit 2080 moves to step S2520. If there is no instruction to create a video signal, the display circuit 2080 waits until there is an instruction to create a video signal.
As a general rule, the 0th bit of the display register remains set to “1” from the time of power-on (the video signal creation ON state is maintained from the time of power-on).

  In step S2520, the display circuit 2080 generates an RGB signal (analog signal) indicating image color data as a video signal from the image data (digital signal) stored in the “display frame buffer” in the VRAM 403.

In step S2530, the display circuit 2080 generates the generated video signal (RGB signal) and a synchronization signal (vertical synchronization signal, horizontal synchronization signal, etc.) for synchronizing with the liquid crystal display devices 30 and 501, the liquid crystal display device 30 and Output to 501. Thereafter, the process returns to step S2510 to repeat the display control process.
(Image display)
As shown in FIGS. 11 and 12, the image displayed on the screen 511a of the liquid crystal display device 501 is projected and displayed on the screen surface 301e of the operation unit 301b by the projection lens 522b of the chance button device 100. An image displayed on the operation unit 301b will be described with reference to FIG.

  As shown in FIGS. 11 and 12, the image displayed on the screen 511a of the liquid crystal display device 501 is projected and displayed on the screen surface 301e of the operation unit 301b by the projection lens 522b of the chance button device 100. An image displayed on the operation unit 301b will be described with reference to FIG.

FIG. 43 is an explanatory diagram showing image display of the operation unit 301b.
FIG. 43A is a first example of image display on the operation unit 301b of the chance button device 100, and an image 701a marked with [!!] is displayed on the operation unit 301b.

  FIG. 43B is a second example of the image display of the operation unit 301b of the chance button device 100, and an image 701b of the character “PRESS” of the press request is displayed on the operation unit 301b.

  FIG. 43C is a third example of the image display of the operation unit 301b of the chance button device 100, and the operation unit 301b displays an image 701c of [Win] indicating that the jackpot has been won. The

  FIG. 43D is a fourth example of image display of the operation unit 301b of the chance button device 100, and a character image 701d is displayed on the operation unit 301b. The character image 701d can be displayed as both a moving image and a still image.

  FIG. 43E is a fifth example of the image display of the operation unit 301b of the chance button device 100. The operation unit 301b displays a firework image 701e indicating that there is a high possibility of winning the jackpot. The The image 701e of the fireworks 701e can be displayed as both a moving image and a still image.

  The images shown in FIGS. 43A to 43E are selected by the effect control board 52. The effect control board 52 selects the effect mode determination table based on the command transmitted from the main control board 51 and the input signal from the magnetic sensor 525 of the chance button device 100, and the selected effect mode determination table is selected as a random number generator. The image to be displayed on the operation unit 301b is determined by collating with the random number acquired from, and a command for displaying the determined image is transmitted to the image control board 55 and displayed on the liquid crystal display device 501.

  As an example of an effect using such a display, for example, a relatively simple multi-stage effect in the case of winning a lottery on the main control board 51 will be described.

  In a relatively simple multi-stage effect, the absolute position data output from the magnetic sensor 525 (see FIG. 8) becomes data (000) before pressing the operation unit 301b of the button operation member 301, and the effect input shown in FIG. The control process is a flow of step S1701 → RETURN. The sub CPU 52a does not transmit the multi-stage effect execution command and the out-of-focus effect execution command to the image control board 55 and the lamp control board 54, and sends the operation unit 301b to FIGS. 43 (a), 43 (b), and 43 (d). One of the images shown in Fig. 1 is displayed.

  When the player presses the operation unit 301b, the absolute position data output from the magnetic sensor 525 (see FIG. 8) becomes data (001) to (111), and the effect input control process shown in FIG. 38 is performed in steps S1701 → S1702 → S1705. → S1706 → S1707 → S1709 → RETURN The sub CPU 52a sets a multistage effect execution command individually corresponding to the absolute position data output from the magnetic sensor 525 (see FIG. 8) in the transmission buffer, and the image control board. The image shown in FIG. 43 (c) or (e) is displayed on the operation unit 301b. Further, in this case, the sub CPU 52a does not transmit the out-of-focus effect execution command to the lamp control board 54. Thereby, the lamp control board 54 drives and controls the piezoelectric linear actuators 523 and 524 so that the absolute position data of the magnetic scale 552m detected by the magnetic sensor 526 becomes data corresponding to the absolute position data of the magnetic sensor 525. The image displayed on the operation unit 301b is focused.

  By performing such control, the player operates the operation unit 301b by pressing the operation unit 301b from the state shown in FIGS. 43 (a), (b), and (d) where the jackpot is not fixed on the operation unit 301b. It will be switched to the image shown in any of FIGS. 43 (c) and (e) where the jackpot has been determined for the part 301b, and the gameability can be improved.

An example of another multistage effect will be described with reference to FIG.
FIG. 44 is an explanatory diagram showing a multistage effect corresponding to the operation of the operation unit 301b of the button operation member 301. Here, in the description of FIG. 44, it is assumed that the player does not operate the operation unit 301b within 0.5 seconds after the operation unit 301b returns to the most protruding position, that is, the player does not repeatedly hit. .

  44A to 44F show image display patterns 1 to 6 displayed on the operation unit 301b, respectively. When the effect control board 52 determines any one of the image display patterns 1 to 6 based on the effect pattern determination table shown in FIG. 37 and the acquired random number, the image display patterns 1 to 6 before pressing the operation unit 301b. A command for displaying the determined image display pattern is transmitted to the image control board 55, and the image control board 55 is in a state of displaying the determined image display pattern.

(Image display pattern 1)
When the production control board 52 selects the image display pattern 1 shown in FIG. 44A and displays it on the operation unit 301b, before pressing the operation unit 301b, that is, when the pushing amount of the operation unit 301b is 0 mm, The absolute position data output from the magnetic sensor 525 (see FIG. 8) becomes data (000), and the effect input control process of the sub CPU 52a shown in FIG. 38 becomes the flow of step S1701 → RETURN. The sub CPU 52a does not transmit the multi-stage effect execution command and the out-of-focus effect execution command to the image control board 55 and the lamp control board 54, and the image control board 55 corresponds to the button non-operation of the image display pattern 1. An image 701a marked with [!!] is displayed on the operation unit 301b. The sub CPU 52a of the effect control board 52 maintains the same state as before the operation unit 301b is pressed until the player presses the operation unit 301b until the pressing amount becomes 1 mm.

  When the player presses the operation unit 301b and the push-in amount is 1 mm or more and less than 5 mm, the absolute position data output by the magnetic sensor 525 (see FIG. 8) is data (001) to (100), which is shown in FIG. The input control process is a flow of steps S1701, S1702, S1705, S1706, S1707, S1709, and RETURN. The sub CPU 52a sets a multistage effect execution command individually corresponding to the absolute position data output from the magnetic sensor 525 (see FIG. 8) in the transmission buffer, and transmits it to the image control board 55. Further, in this case, the sub CPU 52a does not transmit the out-of-focus effect execution command to the lamp control board 54. As a result, the image control board 55 displays the image 701a with the mark [!!] corresponding to the data (001) to (100) in the absolute position data of the image display pattern 1 on the operation unit 301b.

  When the player presses the operation unit 301b and the pressing amount becomes 5 mm or more, the absolute position data output from the magnetic sensor 525 (see FIG. 8) becomes data (101) to (111), and the effect input control process shown in FIG. The flow of steps S1701, S1702, S1705, S1706, S1707, S1709, and RETURN is maintained, and the sub CPU 52a individually corresponds to the absolute position data (101) to (111) output from the magnetic sensor 525 (see FIG. 8). A multistage effect execution command is set in the transmission buffer and transmitted to the image control board 55. Further, in this case, the sub CPU 52a does not transmit the out-of-focus effect execution command to the lamp control board 54. As a result, the image control board 55 displays the [right] character 701c corresponding to the absolute position data (101) to (111) of the image display pattern 1 on the operation unit 301b.

  In the image display pattern 1, the lamp control board 54 causes the piezoelectric linear actuators 523 and 524 so that the absolute position data of the magnetic scale 552 m detected by the magnetic sensor 526 becomes data corresponding to the absolute position data of the magnetic sensor 525. Is controlled to focus the image displayed on the operation unit 301b.

(Image display pattern 2)
When the production control board 52 selects the image display pattern 2 shown in FIG. 44B and displays it on the operation unit 301b, before pressing the operation unit 301b, that is, when the pushing amount of the operation unit 301b is 0 mm, The absolute position data output from the magnetic sensor 525 is data (000), and the effect input control process of the sub CPU 52a shown in FIG. 38 is the flow of step S1701 → RETURN. The sub CPU 52a does not transmit the multi-stage effect execution command and the out-of-focus effect execution command to the image control board 55 and the lamp control board 54, and the image control board 55 corresponds to the button non-operation of the image display pattern 2. The image 711a of the devil character is displayed on the operation unit 301b. The sub CPU 52a of the effect control board 52 maintains the same state as before the operation unit 301b is pressed until the player presses the operation unit 301b until the pressing amount becomes 1 mm.

  When the player presses the operation unit 301b and the push-in amount is 1 mm or more and less than 2 mm, the absolute position data output from the magnetic sensor 525 (see FIG. 8) becomes the data (001), and the effect input control process shown in FIG. Step S1701, S1702, S1705, S1706, S1707, S1709, and RETURN. The sub CPU 52a sets a multistage effect execution command individually corresponding to the absolute position data (001) output from the magnetic sensor 525 (see FIG. 8) in the transmission buffer, and transmits it to the image control board 55. Further, in this case, the sub CPU 52a does not transmit the out-of-focus effect execution command to the lamp control board 54. As a result, the image control board 55 displays the image 711a of the devil character corresponding to the absolute position data (001) of the image display pattern 2 on the operation unit 301b.

  When the player presses the operation unit 301b and the push-in amount is 2 mm or more and less than 6 mm, the absolute position data output from the magnetic sensor 525 (see FIG. 8) is data (010) to (101), and the effects shown in FIG. The input control process maintains the flow of steps S1701, S1702, S1705, S1706, S1707, S1709, and RETURN, and the sub CPU 52a transmits multistage effect execution commands individually corresponding to the absolute position data (010) to (101). It is set in the buffer and transmitted to the image control board 55. Further, in this case, the sub CPU 52a does not transmit the out-of-focus effect execution command to the lamp control board 54. Accordingly, the image control board 55 displays the image 711b of the human character corresponding to the absolute position data (010) to (101) of the image display pattern 2 on the operation unit 301b.

When the player presses the operation unit 301b and the pressing amount becomes 6 mm or more, the absolute position data output from the magnetic sensor 525 (see FIG. 8) becomes data (110) to (111), and the effect input control shown in FIG. The process maintains the flow of steps S1701, S1702, S1705, S1706, S1707, S1709, and RETURN, and the sub CPU 52a individually outputs the absolute position data (110) to (111) output from the magnetic sensor 525 (see FIG. 8). A corresponding multistage effect execution command is set in the transmission buffer and transmitted to the image control board 55. Further, in this case, the sub CPU 52a does not transmit the out-of-focus effect execution command to the lamp control board 54. Thereby, the image control board 55 displays the image 711c of the human angel character corresponding to the absolute position data (010) to (101) of the image display pattern 2 on the operation unit 301b.
In the image display pattern 2, the lamp control board 54 focuses the image displayed on the operation unit 301 b as in the image display pattern 1.

(Image display pattern 3)
When the presentation control board 52 selects the image display pattern 3 shown in FIG. 44C and displays it on the operation unit 301b, the absolute position data output by the magnetic sensor 525 is data (000) before pressing the operation unit 301b. Thus, the effect input control process of the sub CPU 52a shown in FIG. 38 becomes a flow of step S1701 → RETURN. The sub CPU 52a does not transmit the multi-stage effect execution command and the out-of-focus effect execution command to the image control board 55 and the lamp control board 54, and the image control board 55 corresponds to the button non-operation of the image display pattern 3. The image 721a of the monster character of the first form is displayed on the operation unit 301b. The sub CPU 52a of the effect control board 52 maintains the same state as before the operation unit 301b is pressed until the player presses the operation unit 301b until the pressing amount becomes 1 mm.

  When the player presses the operation unit 301b and the push-in amount becomes 1 mm or more, the effect input control process shown in FIG. 38 becomes a flow of steps S1701 → S1702 → S1705 → S1706 → S1707 → S1709 → RETURN, and the sub CPU 52a receives the absolute position data. A multi-stage effect execution command corresponding to (001) to (111) is set in the transmission buffer and transmitted to the image control board 55. As a result, the image control board 55 displays the monster character in the second to eighth forms as shown in the images 721b to 721h every time the push-in amount changes by 1 mm corresponding to the absolute position data (001) to (111). Are displayed on the operation unit 301b.

In the image display pattern 3, the lamp control board 54 focuses the image displayed on the operation unit 301 b as in the image display pattern 1.
(Image display pattern 4)
When the presentation control board 52 selects the image display pattern 4 shown in FIG. 44D and displays it on the operation unit 301b, the absolute position data output by the magnetic sensor 525 is data (000) before pressing the operation unit 301b. Thus, the effect input control process of the sub CPU 52a shown in FIG. 38 becomes a flow of step S1701 → RETURN. The sub CPU 52a does not transmit the multi-stage effect execution command and the out-of-focus effect execution command to the image control board 55 and the lamp control board 54, and the image control board 55 corresponds to the button non-operation of the image display pattern 4. A monster character image 731a is displayed on the operation unit 301b. The sub CPU 52a of the effect control board 52 maintains the same state as before the operation unit 301b is pressed until the player presses the operation unit 301b until the pressing amount becomes 1 mm.

When the player presses the operation unit 301b and the push-in amount becomes 1 mm or more, the effect input control process shown in FIG. 38 becomes a flow of steps S1701 → S1702 → S1705 → S1706 → S1707 → S1709 → RETURN, and the sub CPU 52a receives the absolute position data. A multi-stage effect execution command corresponding to (001) to (111) is set in the transmission buffer and transmitted to the image control board 55. As a result, the image control board 55 changes the movement of the monster character as shown in the images 731b to 731h every time the pushing amount changes by 1 mm corresponding to the absolute position data (001) to (111), and as a moving image. It is displayed on the operation unit 301b.
In the image display pattern 4, the lamp control board 54 focuses the image displayed on the operation unit 301 b as in the image display pattern 1.

(Image display pattern 5)
When the effect control board 52 selects the image display pattern 5 shown in FIG. 44 (e) and displays it on the operation unit 301b, the absolute position data output by the magnetic sensor 525 is data (000) before pressing the operation unit 301b. Thus, the effect input control process of the sub CPU 52a shown in FIG. 38 becomes a flow of step S1701 → RETURN. The sub CPU 52a does not transmit the multi-stage effect execution command and the out-of-focus effect execution command to the image control board 55 and the lamp control board 54, and the image control board 55 corresponds to the button non-operation of the image display pattern 5. A monster character image 731a (similar to the case of the image display pattern 4) is displayed on the operation unit 301b. The sub CPU 52a of the effect control board 52 maintains the same state as before the operation unit 301b is pressed until the player presses the operation unit 301b until the pressing amount becomes 1 mm.

  When the player presses the operation unit 301b and the push-in amount becomes 1 mm or more, the effect input control process shown in FIG. A multistage effect execution command corresponding to the absolute position data (001) to (111) is set in the transmission buffer and transmitted to the image control board 55. In this case, the sub CPU 52a transmits to the lamp control board 54 a focus deviation effect execution command corresponding to the absolute position data (001) to (111) of the image display pattern 5.

  The focus position effect execution command corresponding to the absolute position data (001), (010), (011), (100), (101), (110), (111) corresponding to the image display pattern 5 is the projection lens. This is a command for controlling the focus surface of the image on the screen 511a by the unit 522 to be shifted upward by 1 mm, 2 mm, 3 mm, 4 mm, 5 mm, 6 mm, and 7 mm from the screen surface 301e, respectively.

  When the lamp control board 54 receives the defocusing effect execution command corresponding to the absolute position data (001), (010), (011), (100), (101), (110), (111), the magnetic sensor (00100), (01000), (01100), (10000), (10100), (11000), (11100) from the 5-bit absolute position data ((00100) to (11111)) of the magnetic scale 552m detected by 526, respectively. ) Is generated, and control is performed so that the absolute position data of the magnetic scale 552m detected by the magnetic sensor 526 becomes data corresponding to the focus position data.

  Thereby, the projection lens unit 522 is controlled such that the focus surface of the image of the screen 511a of the liquid crystal display panel 511 is shifted upward by a set distance from the screen surface 301e.

  On the other hand, the image control board 55 changes the movement of the monster character every time the pushing amount changes by 1 mm corresponding to the absolute position data (001) to (111).

  As a result, the operation unit 301b has images 731b-L1, 731c-L2, 731d-L3, 731e-L4, 731f-L5, 731g-L6 in which the movement and focus of the character change according to the amount of pressing the operation unit 301b. , 731h-L7 are displayed. In this case, every time the push amount of the operation unit 301b is increased by 1 mm, the shift amount of the focus is also increased, and the resolution of the image is reduced, so that the moving image of the monster character is more blurred and displayed on the operation unit 301b. become.

(Image display pattern 6)
When the effect control board 52 selects the image display pattern 6 shown in FIG. 44 (e) and displays it on the operation unit 301b, the processing is the same as the image display pattern 5 before pressing the operation part 301b. 55 displays the image 731a of the monster character corresponding to the non-operation of the image display pattern 6 (similar to the case of the image display pattern 4) on the operation unit 301b. The sub CPU 52a of the effect control board 52 maintains the same state as before the operation unit 301b is pressed until the player presses the operation unit 301b until the pressing amount becomes 1 mm.

  When the player presses the operation unit 301b and the push-in amount becomes 1 mm or more, the effect input control process shown in FIG. A multistage effect execution command corresponding to the absolute position data (001) to (111) is set in the transmission buffer and transmitted to the image control board 55. In this case, the sub CPU 52a transmits to the lamp control board 54 a focus deviation effect execution command corresponding to the absolute position data (001) to (111) of the image display pattern 6.

  An out-of-focus effect execution command corresponding to the absolute position data (001), (010), (011), (100), (101), (110) of the image display pattern 6 is displayed on the screen by the projection lens unit 522. This is a command for controlling the focus surface of the image 511a to be shifted by 1 mm, 2 mm, 3 mm, 4 mm, 3 mm, and 1 mm above the screen surface 301e. The out-of-focus effect execution command corresponding to the absolute position data (111) is a command for controlling the focus surface of the image on the screen 511a by the projection lens unit 522 so as to coincide with the screen surface 301e. .

  When the lamp control board 54 receives a focus deviation effect execution command corresponding to the absolute position data (001), (010), (011), (100), (101), (110), the magnetic sensor 526 detects the lamp control board 54. Defocus by subtracting (00100), (01000), (01100), (10000), (01100), and (00100) from the 5-bit absolute position data ((00100) to (11011)) of the magnetic scale 552m. Position data is generated, and control is performed so that the absolute position data of the magnetic scale 552m detected by the magnetic sensor 526 becomes data corresponding to the out-of-focus position data. Thereby, the projection lens unit 522 is controlled such that the focus surface of the image of the screen 511a of the liquid crystal display panel 511 is shifted upward by a set distance from the screen surface 301e.

  When the ramp control board 54 receives the defocus effect execution command corresponding to the absolute position data ((111)), the absolute position data of the magnetic scale 552m detected by the magnetic sensor 526 is detected by the magnetic sensor 301f. Control is performed so that the data corresponds to 5-bit absolute position data ((11100) to (11111)).

  On the other hand, the image control board 55 changes the movement of the monster character every time the pushing amount changes by 1 mm corresponding to the absolute position data (001) to (111).

  As a result, the operation unit 301b displays images 731b-L1, 731c-L2, 731d-L3, 731e-L4, 731f-L3, 731g-L1 in which the character's movement and focus change according to the amount of pressing of the operation unit 301b. , 731h are displayed. In this case, in a state where the pushing amount of the operation unit 301b is less than 5 mm, the moving amount of the monster character becomes larger by decreasing the resolution of the image every time the pushing amount is increased by 1 mm and the resolution of the image is reduced. The image is blurred and displayed on the operation unit 301b. When the push amount of the operation unit 301b is 5 mm or more, the defocus amount is reduced every time the push amount is increased by 1 mm, the resolution of the image is improved, and the blur amount of the monster character video is reduced and displayed. The When the push amount of the operation unit 301b is just 8 mm from the 7 mm range, an image 731f with zero focus shift is displayed on the operation unit 301b.

  If the above structure and operation | movement are demonstrated collectively, the chance button apparatus 100 is a button apparatus for game machines.

  The button operation member 301 is provided in the gaming machine 1 and has an operation unit 301b that is transparent and performs an external operation. The surface of the operation unit 301b is exposed to the outside of the gaming machine 1, and the operation unit 301b Is provided with a screen surface 301e.

  The liquid crystal display device 501 is an image display unit that is provided inside the operation unit 301b and displays an image on the screen 511a by causing the screen 511a on the display surface to emit light.

  The projection lens 522b is provided inside the operation unit 301b, and projects the light of the image displayed on the screen 511a of the liquid crystal display device 501 onto the screen surface 301e of the button operation member 301, thereby the screen surface 301e. Display an image.

  The vertical drive frame 307 is a base portion that holds the button operation member 301 so as to be movable in a direction protruding to the outside of the gaming machine 1 and in the opposite direction.

  The center spring 308 is interposed between the vertical drive frame 307 and the button operation member 301, and serves as a biasing means that biases the button operation member 301 in a direction protruding outward from the gaming machine 1. .

The button operation member 301 moves in the reverse direction with respect to the vertical drive frame 307 by the predetermined external operation.
A magnetic scale 301f fixed to the button operation member 301 and a magnetic sensor 525 fixed to the light shielding member 521 (that is, fixed to the vertical drive frame 307) constitute a magnetic encoder, and the button operation member for the vertical drive frame 307 is formed. The moving position detecting means 301 detects the moving position 301 at a predetermined detection stage (eight stages in this embodiment).

The lamp control board 54, the piezoelectric linear actuators 523 and 524, the notches 522i and 522j and the leaf springs 522k and 522l of the projection lens unit 522 move the projection lens 522b based on the detection result of the magnetic sensor 525, and the projection The lens 522b serves as a focusing means for focusing the image displayed on the screen surface 301e.
The effect control board 52 and the image control board 55 are image control means for performing control to change the image displayed on the liquid crystal display device 501 based on the detection result of the moving position by the magnetic sensor 526.
The effect control board 52 and the lamp control board 54 control the focus adjusting unit to cause a deviation in focus of an image displayed on the screen surface 301e by the projection lens 522b when a predetermined effect condition is satisfied. It is an effect control means to be performed. 44. For example, in the case of the pattern 5 shown in FIG. 44, the pressing amount of the operation unit 301b is 1 mm to 8 mm, or in the pattern 6, the pressing amount of the operation unit 301b is less than 1 mm to 7 mm. It shows that.

  The drive unit 200 is a base unit moving unit that moves the vertical drive frame 307 in any one of the direction in which the button operating member 301 further protrudes outside the gaming machine 1 and the opposite direction.

  The effect control board 52 and the lamp control board 54 control the amount of protrusion of the button operation member 301 that protrudes outside the gaming machine 1 by controlling the movement of the vertical drive frame 307 by the drive unit 200. It is a quantity control means.

  According to this embodiment described above, the magnetic sensor 525 detects the movement position of the button operation member 301 with respect to the vertical drive frame 307 in three or more detection stages (eight stages in the case of this embodiment). , The lamp control board 54, the piezoelectric linear actuators 523 and 524, the notches 522i and 522j of the projection lens unit 522, and the leaf springs 522k and 522l, the focusing means adjusts the projection lens 522b based on the detection result of the magnetic sensor 525. The projection lens 522b is used to focus the image displayed on the screen surface 301e, and in this state, the projection lens 522b pushes the light of the image displayed on the screen 511a of the liquid crystal display device 501 with a button. The screen is projected onto the screen surface 301e of the operation member 301 and the script is Image is displayed on the emission surface 301e, the image displayed on the screen surface 301e is, because it is visible to the player through the transparency of the operating portion 301b of the button operation member 301 can exhibit higher performance effects. Further, since the image control board 55 performs control to change the image displayed on the screen 511a of the liquid crystal display device 501 based on the detection result of the moving position by the magnetic sensor 525, the player operates the operation unit 301b. It is possible to achieve consistency between the amount and the effect contents of the image displayed on the screen surface 301e, and a higher effect can be exhibited. Here, the operation of the projection lens 522b for focusing is performed by electrical driving by the focusing means, and the button operating member 301 and the projection lens 522b are not mechanically interlocked with each other. Compared to moving all of the display device 501 and the projection unit 502 in accordance with the position of the screen surface 301e of the button operation member 301, the load on the player's finger is small, and the operability of the button operation member 301 is impaired. Can be prevented.

Further, in this embodiment, a moving image such as a character can be displayed as an image to be displayed on the operation unit 301b of the button operation member 301, and a remarkably high production effect as compared with a change in the light emission pattern of a conventional production button switch. Is obtained.
In the present embodiment, the effect control board 52 and the lamp control board 54 cause a deviation in focusing of the image displayed on the screen surface 301e by the projection lens 522b when a predetermined effect condition is satisfied. This is an effect control means for controlling the focus adjusting means, and this also provides a high effect.

  Further, in this embodiment, a moving image such as a character can be displayed as an image to be displayed on the operation unit 301b of the button operation member 301, and a remarkably high production effect as compared with a change in the light emission pattern of a conventional production button switch. Is obtained.

  In addition, when the player hits the button operation member 301 repeatedly, for example, the image shown in FIG. 44 can be displayed in a complicated manner as an image to be displayed on the operation unit 301b of the button operation member 301. Is obtained. As such an effect, for example, an image in which the focus of FIG. 44 (e) is greatly shifted is displayed from the first to fifth shots, and the focus of FIG. 44 (f) is displayed from the sixth to the tenth shots. A method of displaying an image that is shifted during the operation of the button operation member 301 and displaying an image in which the focus of FIG.

  Further, according to the present embodiment, the chance button device 100 is provided between the position where the button operation member 301 protrudes greatly and the position where it slightly protrudes from the surface of the gaming machine 1 (specifically, the upper plate unit 11). Can be controlled to move up and down, and can be pressed by the player at any position between the projecting position and the slightly projecting position, and is durable against excessive pressing force. By providing, the button device for gaming machines corresponding to various gaming states and effects can be provided.

  For example, the progress of the game in the gaming machine is not given a special game value and a first game state (a so-called high probability game state represented by a probability variation state) in which a special game value is given to the player. In a gaming machine that is advanced by switching to the second gaming state (a so-called low-probability gaming state represented by a normal gaming state), the button unit 300 is set to the “uppermost position” in the first gaming state. The button unit 300 is moved to the “lowermost position” in the second gaming state. In this way, when the button operation member 301 is in the “largely protruding state” in the chance button device 100, it can be notified that the current gaming state is the first gaming state.

  Further, when the progress of the game is the first gaming state and the button operation member 301 is in the “largely protruding state”, the button operation member 301 is continuously pressed to the liquid crystal display device 30 and the liquid crystal display device 501. A message “continuous hit” prompting an action to be performed (hereinafter referred to as “continuous hit”) may be displayed to prompt the player to hit consecutively. Thus, the chance button device 100 according to the present embodiment has an excessive pressing force (pressing force) at any position between the “largely protruding position” and the “slightly protruding position” of the button operation member 301. Since it has durability against this, it is possible to prompt this “continuous hit”.

  As another example, when a specific effect content is executed according to the effect content of the liquid crystal display device 30 or the like in the gaming machine 1, the button operation member 301 is moved to a “largely protruding position” When the execution of the specific effect content is finished, the player may be moved to a “slightly protruding position” to enhance the player's preference. In this case as well, when the button operating member 301 is moved to the “largely protruding position”, the message “continuous hit” is displayed on the liquid crystal display device 30 or the like, and the chance button is displayed to the player. The device 100 may be prompted to “continuously hit”.

  Furthermore, the chance button device 100 according to the present embodiment enables vertical movement control between a position where the button part 300 protrudes greatly and a position where the button part 300 protrudes slightly, and slightly protrudes from a position where the button part 300 protrudes greatly. Since the player can perform a pressing operation at any position between the positions, the “continuous hit” can be performed at any position between the “largely protruding position” and the “slightly protruding position”. It becomes possible. From this, the combination of the production content in the production for prompting “continuous hitting” and the production content based on the height position of the button unit 300 becomes diverse, and it is possible to improve the interest of the player.

  In the present embodiment, the entire projection lens 522b is moved by the focusing unit, and the image displayed on the screen surface 301e is focused by the projection lens 522b. However, the focusing unit By moving only a part of the optical system of the lens 522b or only the liquid crystal display device 501, the image displayed on the screen surface 301e may be focused by the projection lens 522b.

  Further, the button operating member moving position detecting means for detecting the moving position of the button operating member 301 with respect to the vertical drive frame 307 is not limited to the magnetic encoder, and various applications such as an optical encoder can be applied.

  Further, in the present embodiment, it is possible to control the vertical movement between the position where the button part 300 is largely protruded and the position where it slightly protrudes, and any of the position between the position where the button part 300 protrudes slightly and the position where it slightly protrudes is possible. Although the player can perform the pressing operation at the position, the position at which the player can perform the pressing operation is not limited to the “largely protruding position” and the “slightly protruding position”. That is, the drive control of the vertical movement of the button unit 300 is stopped at any position between the “largely protruding position” and the “slightly protruding position”, and the pressing operation can be accepted at the stopped position. Good. Furthermore, according to the gaming state in the gaming machine 1 described above and the contents of the performance of the liquid crystal display device 30 or the like, the drive control of the vertical movement of the button unit 300 is “a position that protrudes greatly” and “a position that protrudes slightly”. The drive control of the vertical movement may be stopped at any position between. Further, “pressing operation” and “continuous hitting” may be prompted at any position.

  In this embodiment, the screen surface 301e of the image on which the image light is projected by the projection lens 522b is directly formed on the back surface of the operation unit 301b. However, the screen surface is formed on a transparent plate separate from the operation unit 301b. The transparent plate may be attached to the back side of the operation unit 301b.

1 gaming machine 11 upper plate unit 17 gaming board 30 liquid crystal display device 51 main control board 52 presentation control board 100 chance button device 101 upper case 102 lower case 102a receiving hole 200 driving part 202 solenoid 203 crank arm 205 slider 210 motor gear 212 crank gear 212A Tooth part 213 Lower position photo sensor 214 Upper position photo sensor 215 Movement lock gear 216 Gear lock 220 Clutch receiver 300 Button part 301 Button operation member 301b Operation part 301e Screen surface 301f Magnetic scale 302 Inner attachment member 303 Button body 304 Cylindrical pressing Frame 305 Inner cylindrical frame 305b Projection 306 Cylindrical frame 307 Vertical drive frame 308 Center spring 309 Shaft 310 Shaft 311 Shoe holder 312 Long shaft bush 313 Short shaft bush 315 Assist spring 316 Shaft 317 Shaft 318 Shaft fixing plate 350 Long hole 501 Liquid crystal display device 502 Projection unit 511a Screen 521 Shading member 522 Projection lens unit 522b Projection lens 522m Magnetic scale 522i Notch 522j Notch Notch 522k Leaf spring 522l Leaf spring 523 Piezoelectric linear actuator 524 Piezoelectric linear actuator 525 Magnetic sensor 526 Magnetic sensor

Claims (4)

Provided in a gaming machine, having a transparent operation unit for external operation, the surface of the operation unit is exposed to the outside of the gaming machine, and a screen surface is provided on the back side of the operation unit A button operation member;
An image display means provided inside the operation unit and displaying an image on the display surface by causing the display surface to emit light;
A projection lens that is provided inside the operation unit and projects the light of an image displayed on the display surface of the image display means onto the screen surface of the button operation member, and displays an image on the screen surface;
A base portion that holds the button operation member so as to be movable in a direction protruding to the outside of the gaming machine and in the opposite direction;
An urging means interposed between the base portion and the button operation member, and urging the button operation member in a direction protruding to the outside of the gaming machine;
A moving position detecting means for detecting a moving position of the button operation member relative to the base portion;
Focusing of an image displayed on the screen surface by the projection lens by moving at least one of the optical system of the projection lens and the image display unit based on a detection result of the movement position detection unit. A focusing means for performing the alignment;
Image control means for performing control to change the image displayed on the image display means based on the detection result of the movement position by the movement position detection means;
A button device for gaming machines, comprising: A base part moving means for moving the base part in any one of the direction in which the button operating member further protrudes outside the gaming machine and the opposite direction;
The apparatus further comprises: a protrusion amount control means for controlling the protrusion amount of the button operation member protruding outside the gaming machine by controlling the movement of the base portion by the base portion moving means. The button device for gaming machines according to 1.   The image processing apparatus further includes an effect control unit that controls the focus adjusting unit to cause a shift in focusing of an image displayed on the screen surface by the projection lens when a predetermined effect condition is satisfied. The button device for gaming machines according to claim 1 or 2. A gaming machine comprising the gaming machine button device according to any one of claims 1 to 3.

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