JP2021164892A - Game machine - Google Patents

Abstract

To provide a game machine whose operation device exerts excellent motion.SOLUTION: Depending on whether a tilting device 310 is disposed at a first position or disposed at a second position due to operation of a player, whether or not a weight member 5412 comes into contact with a housing member 5430 changes. Therefore, even if in the case where the weight member 5412 is caused to vibrate continuously, vibration can be felt by the player for the first time due to operation of the tilting device 310 by the player.SELECTED DRAWING: Figure 60

Description

The present invention relates to a gaming machine such as a pachinko machine.

In a gaming machine such as a pachinko machine, there is a gaming machine including an operating member that moves between a first position and a second position by being manually operated by a player (Patent Document 1).

Japanese Unexamined Patent Publication No. 2014-014571

However, the above-mentioned conventional gaming machine has a problem that there is room for improvement in the operation of the operating member. The present invention has been made to solve the above-exemplified problems and the like, and an object of the present invention is to provide a gaming machine having good durability of operating members.

In order to achieve this object, the gaming machine according to claim 1 is an operating device having an operating means operated by a player, and the operating device is such that the operating means is from a first position and the first position. A vibrating means having a vibrating portion that is configured to be movable between a second position reached by the operating means by a player's operation and a receiving means that is arranged so as to be in contact with the vibrating portion. When the operating means is arranged in the first position, the vibrating portion is in a separated state in which it cannot come into contact with the receiving means, while the operating means is placed in the second position. When arranged, the vibrating portion is in a contact state where it can come into contact with the receiving means.

The gaming machine according to claim 2 is the gaming machine according to claim 1, wherein the vibrating means is arranged so as to project over an occupied area occupied when the operating means is arranged at the second position in the separated state. When the operating means moves to the second position, the vibrating means is taken out of the occupied area, and the contact state is changed.

The gaming machine according to claim 3 is the gaming machine according to claim 1 or 2, wherein the vibrating means is supported by the receiving means via a supporting means having spring elasticity.

According to the gaming machine according to claim 1, the operation of the operating device can be improved.

According to the gaming machine according to claim 2, in addition to the effect of the gaming machine according to claim 1, the operation of the operating device can be improved by the relationship between the operating means and the vibrating means.

According to the gaming machine according to claim 3, in addition to the effect of the gaming machine according to claim 1 or 2, the operation of the operating device can be improved by devising a method of supporting the vibrating means.

It is a front view of the pachinko machine in 1st Embodiment. It is a front view of the game board of a pachinko machine. It is a rear view of a pachinko machine. It is a block diagram which shows the electric structure of a pachinko machine. It is a front perspective view of the operation device. (A) is a partial front view of the pachinko machine, and (b) is a partial cross-sectional view of the pachinko machine on the VIb-VIb line of FIG. 6 (a). (A) is a partial front view of the pachinko machine, and (b) is a partial cross-sectional view of the pachinko machine in line VIIb-VIIb of FIG. 7 (a). It is a front perspective view of the operation device in the direction view of arrow VIII of FIG. FIG. 7 is a front perspective view of the operating device in the direction of arrow IX in FIG. 7. It is a front perspective view of the operation device. It is a rear perspective view of the operation device. It is a front view exploded perspective view of an operation device. It is a rear view exploded perspective view of an operation device. (A) is a front view of the tilting device, (b) is a side view of the tilting device in the direction of arrow XIVb of FIG. 14 (a), and (c) is a side view of the tilting device of FIG. 14 (a). It is sectional drawing of the tilting device in line XIVc. It is a front view exploded perspective view of a tilting device. It is a rear view exploded perspective view of the lid of a tilting device. (A) is a front view of the drive device, and (b) is a side view of the drive device in the direction of arrow XVIIb of FIG. 17 (a). It is a front view exploded perspective view of a drive device. It is a front view exploded perspective view of a transmission shaft rod. (A) is a side view of the left disk cam in the direction of arrow XXa of FIG. 18, and (b) is a side view of the left disk cam in the direction of arrow XXb of FIG. (A) and (b) are front views of the release member and the rotary claw member. It is sectional drawing of the operation device in line XXII-XXII of FIG. 6A. It is sectional drawing of the operation device in line XXII-XXII of FIG. 6A. It is sectional drawing of the operation device in line XXII-XXII of FIG. 6A. It is sectional drawing of the operation device in line XXII-XXII of FIG. 6A. It is sectional drawing of the operation device in line XXII-XXII of FIG. 6A. It is sectional drawing of the operation device in line XXII-XXII of FIG. 6A. It is sectional drawing of the operation device in line XXII-XXII of FIG. 6A. It is sectional drawing of the operation device in line XXII-XXII of FIG. 6A. It is sectional drawing of the operation device in line XXII-XXII of FIG. 6A. It is sectional drawing of the operation device in line XXII-XXII of FIG. 6A. It is sectional drawing of the operation device in line XXII-XXII of FIG. 6A. It is sectional drawing of the operation device in line XXII-XXII of FIG. 6A. It is sectional drawing of the operation device in line XXII-XXII of FIG. 6A. It is sectional drawing of the operation device in line XXII-XXII of FIG. 6A. It is sectional drawing of the operation device in line XXII-XXII of FIG. 6A. It is sectional drawing of the operation device in line XXII-XXII of FIG. 6A. It is sectional drawing of the operation device in line XXII-XXII of FIG. 6A. It is a partial cross-sectional view of the operation device in the XXXIX-XXXIX line of FIG. 38. It is sectional drawing of the operation device in line XXII-XXII of FIG. 6A. It is sectional drawing of the operation device in line XXII-XXII of FIG. 6A. It is sectional drawing of the operation device in line XXII-XXII of FIG. 6A. It is sectional drawing of the operation device in line XXII-XXII of FIG. 6A. It is sectional drawing of the operation device in line XXII-XXII of FIG. 6A. (A) is a side view of the slide claw member in the second embodiment, (b) is a side view of the rotating plate member, and (c) is a side view of the release member. (A) and (b) are side views of a release member, a rotating plate member, and a slide claw member. 6 is a cross-sectional view of the operating device in the line corresponding to the XXII-XXII line of FIG. 6A. 6 is a cross-sectional view of the operating device in the line corresponding to the XXII-XXII line of FIG. 6A. 6 is a cross-sectional view of the operating device in the line corresponding to the XXII-XXII line of FIG. 6A. It is a side view of the tilting device in 3rd Embodiment. (A) and (b) are side views of the operation device. (A) and (b) are side views of the operation device. It is a side view of the tilting device in 4th Embodiment. (A) and (b) are side views of the operation device. (A) and (b) are side views of the operation device. It is an exploded front perspective view of the operation device in 5th Embodiment. It is an exploded rear perspective view of an operation device. It is an exploded front perspective view of a lower frame member and a vibrating device. (A) is a side view of the lower frame member, (b) is a partial cross-sectional view of the lower frame member in the LIXb-LIXb line of FIG. 59 (a), and (c) is a partial cross-sectional view of FIG. 59 (a). It is a partial top view of the lower frame member in the direction view of the arrow LIXc. (A) and (b) are sectional views of the vibrating apparatus in the line LXa-LXa of FIG. 59 (a). (A) and (b) are sectional views of the transmission device 5410 and the accommodating member 5430 in the LIXb-LIXb line of FIG. 59 (a). It is an exploded front perspective view of a drive device. (A) is a front perspective view of the right disk cam, and (b) is a rear perspective view of the right disk cam. It is a front view exploded perspective view of a transmission shaft rod. (A) is a front view of the right disk cam in the direction of the arrow LXVa of FIG. 62, and (b) is a cross-sectional view of the right disk cam in the LXVb-LXVb line of FIG. 65 (a). c) is a cross-sectional view of the right disk cam in the LXVc-LXVc line of FIG. 65 (a). (A) is a front view of the right disk cam in the direction of arrow LXVa of FIG. 62, and (b) is a cross-sectional view of the right disk cam in the LXVIb-LXVIb line of FIG. 66 (a). (A) is a cross-sectional view of the operation device in the line corresponding to the line corresponding to the line XXII-XXII of FIG. 6 (a), and FIG. Is. (A) is a cross-sectional view of the operating device in the line corresponding to the line XXII-XXII of FIG. 6A, and FIG. 68B is a partial rear view of the operating device in the direction of arrow LXVIIIb of FIG. Is. It is an exploded front perspective view of the drive device in 6th Embodiment. It is a front view exploded perspective view of the disk member, the ring member, and the second transmission member of the left disk cam. 6 is a cross-sectional view of the operating device in the line corresponding to the XXII-XXII line of FIG. 6A. 6 is a cross-sectional view of the operating device in the line corresponding to the XXII-XXII line of FIG. 6A. 6 is a cross-sectional view of the operating device in the line corresponding to the XXII-XXII line of FIG. 6A. (A) is a front view of the right disk cam according to the seventh embodiment, and (b) is a rear view of the right disk cam. (A) is a cross-sectional view of the right disk cam in the LXXVa-LXXVa line of FIG. 74 (a), and (b) is a partial side view of the right disk cam in the direction of arrow LXXVb of FIG. Is. (A) is a front view of the ring member, (b) is a rear view of the ring member, and (c) is a side view of the ring member in the direction of arrow LXXVIc of FIG. 76 (a). (A) is a front view of the engaging member, and (b) is a side view of the engaging member in the direction of arrow LXXVIIb of FIG. 77 (a). (A) is a front view of the right disk cam, (b) is a side view of the right disk cam in the direction of arrow LXXVIIIb of FIG. 78 (a), and (c) is a right disk cam. (D) is a side view of the right disk cam in the direction of arrow LXXVIIId in FIG. 78 (c), (e) is a front view of the right disk cam, and (f). Is a side view of the right disk cam in the direction of arrow LXXVIIIf in FIG. 78 (e). (A) and (b) are partial cross-sectional views of the operation device in the line corresponding to the XXII-XXII line of FIG. (A) and (b) are partial cross-sectional views of the operation device in the line corresponding to the XXII-XXII line of FIG. 6 is a partial cross-sectional view of the operating device in the line corresponding to the XXII-XXII line of FIG. (A) and (b) are partial cross-sectional views of the operation device in the line corresponding to the XXII-XXII line of FIG. (A) and (b) are partial cross-sectional views of the operation device in the line corresponding to the XXII-XXII line of FIG. It is sectional drawing of the operation device in the line corresponding to line XXII-XXII of FIG. It is sectional drawing of the operation device in the line corresponding to line XXII-XXII of FIG.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings. First, with reference to FIGS. 1 to 44, as a first embodiment, an embodiment when the present invention is applied to a pachinko gaming machine (hereinafter, simply referred to as “pachinko machine”) 10 will be described. FIG. 1 is a front view of the pachinko machine 10 according to the first embodiment, FIG. 2 is a front view of the game board 13 of the pachinko machine 10, and FIG. 3 is a rear view of the pachinko machine 10.

As shown in FIG. 1, the pachinko machine 10 has an outer frame 11 in which an outer shell is formed by a wooden frame combined in a substantially rectangular shape, and an outer frame 11 formed in substantially the same outer shape as the outer frame 11. It is provided with an inner frame 12 that is supported so as to be openable and closable. Metal hinges 18 are attached to the outer frame 11 at two upper and lower positions on the left side of the front view (see FIG. 1) in order to support the inner frame 12, and the side on which the hinge 18 is provided is used as an opening / closing axis. The frame 12 is supported so as to be openable and closable toward the front side of the front surface.

A game board 13 (see FIG. 2) having a large number of nails, winning openings 63, 64, etc. is detachably attached to the inner frame 12 from the back surface side. A ball game is performed by a ball (game ball) flowing down in front of the game board 13. The inner frame 12 includes a ball launching unit 112a (see FIG. 4) that launches a ball into the front region of the game board 13 and a launch that guides the ball launched from the ball launching unit 112a to the front region of the game board 13. Rails (not shown) etc. are attached.

On the front side of the inner frame 12, a front frame 14 that covers the upper side of the front surface and a lower plate unit 15 that covers the lower side thereof are provided. In order to support the front frame 14 and the lower plate unit 15, metal hinges 19 are attached to the upper and lower two places on the left side of the front view (see FIG. 1), and the side on which the hinges 19 are provided is used as an opening / closing axis for the front frame. The 14 and the lower plate unit 15 are supported so as to be openable and closable toward the front side of the front surface. The lock of the inner frame 12 and the lock of the front frame 14 are released by inserting a dedicated key into the key hole 21 of the cylinder lock 20 and performing a predetermined operation.

The front frame 14 is formed by assembling decorative resin parts, electric parts, and the like, and a window portion 14c having a substantially elliptical opening is provided at a substantially central portion thereof. A glass unit 16 having two flat glass sheets is arranged on the back surface side of the front frame 14, and the front surface of the game board 13 can be visually recognized on the front side of the pachinko machine 10 through the glass unit 16.

In the front frame 14, an upper plate 17 for storing balls is formed in a substantially box shape with the upper surface open so as to project toward the front side, and prize balls, rented balls, and the like are discharged to the upper plate 17. The bottom surface of the upper plate 17 is formed so as to be inclined downward to the right side when viewed from the front (see FIG. 1), and the ball thrown into the upper plate 17 is guided to the ball launching unit 112a (see FIG. 4) by the inclination. Further, a frame button 22 is provided on the upper surface of the upper plate 17. The frame button 22 is operated by the player, for example, when changing the stage of the effect displayed on the third symbol display device 81 (see FIG. 2) or changing the effect content of the super reach. NS.

The front frame 14 is provided with light emitting means such as various lamps around the front frame 14 (for example, a corner portion). These light emitting means change and control the light emitting mode by lighting or blinking according to a change in the gaming state at the time of a big hit or a predetermined reach, and play a role of enhancing the effect during the game. Illuminations 29 to 33 having a light emitting means such as an LED are provided on the peripheral edge of the window portion 14c. In the pachinko machine 10, these illumination units 29 to 33 function as effect lamps such as jackpot lamps, and each illumination unit 29 to 33 lights up by lighting or blinking the built-in LED at the time of jackpot or reach production. Or, it blinks to notify that the jackpot is in progress or that the reach is one step before the jackpot. Further, in the upper left portion of the front frame 14 when viewed from the front (see FIG. 1), a light emitting means such as an LED is built in, and a display lamp 34 capable of displaying when the prize ball is being paid out and when an error occurs is provided.

Further, on the lower side of the illuminated portion 32 on the right side, a small window 35 is formed by attaching a transparent resin from the back side so that the back side of the front frame 14 can be visually recognized, and a sticking space K1 on the front of the game board 13 (FIG. The certificate stamp or the like attached to (see 2) can be visually recognized from the front of the pachinko machine 10. Further, in the pachinko machine 10, in order to bring out more glitter, a plating member 36 made of ABS resin having chrome plating is attached to the area around the illumination portions 29 to 33.

A ball lending operation unit 40 is arranged below the window unit 14c. The ball lending operation unit 40 is provided with a frequency display unit 41, a ball lending button 42, and a return button 43. When the ball lending operation unit 40 is operated with bills, cards, etc. inserted into the card unit (ball lending unit) (not shown) arranged on the side of the pachinko machine 10, the ball is operated according to the operation. Lending is done. Specifically, the frequency display unit 41 is an area in which the remaining amount information such as a card is displayed, and the built-in LED lights up and the remaining amount is displayed as a numerical value as the remaining amount information. The ball lending button 42 is operated to obtain a lending ball based on the information recorded on the card or the like (recording medium), and the lending ball is supplied to the upper plate 17 as long as the remaining amount is present on the card or the like. Will be done. The return button 43 is operated when requesting the return of the card or the like inserted in the card unit. A pachinko machine in which balls are lent directly to the upper plate 17 from a ball lending device or the like without going through a card unit, a so-called cash machine, does not require a ball lending operation unit 40. In this case, the ball lending operation unit 40 is not required. A decorative sticker or the like may be added to the installation portion of the above to make the component configuration common. It is possible to standardize pachinko machines and cash machines that use card units.

In the lower plate unit 15 located on the lower side of the upper plate 17, a lower plate 50 for storing balls that could not be stored in the upper plate 17 is formed on the left side thereof in a substantially box shape with an open upper surface. There is. On the right side of the lower plate 50, an operation handle 51 and an operation device 300 operated by the player to drive the ball into the front of the game board 13 are arranged. The operation device 300 will be described later.

Inside the operation handle 51, there is a touch sensor 51a for permitting the driving of the ball launch unit 112a, a launch stop switch 51b for stopping the launch of the ball during the pressing operation period, and a rotation of the operation handle 51. It has a built-in variable resistor (not shown) that detects the amount of dynamic operation (rotation position) by the change in electrical resistance. When the operation handle 51 is rotated clockwise by the player, the touch sensor 51a is turned on and the resistance value of the variable resistor changes according to the amount of rotation operation, and the resistance value of the variable resistor is changed. The ball is launched with a strength corresponding to (launch intensity), whereby the ball is driven into the front of the game board 13 with a flying amount corresponding to the operation of the player. Further, when the operation handle 51 is not operated by the player, the touch sensor 51a and the firing stop switch 51b are turned off.

A ball pulling lever 52 for operating the ball stored in the lower plate 50 when the ball stored in the lower plate 50 is discharged downward is provided in the lower portion of the front surface of the lower plate 50. The ball pulling lever 52 is always urged to the right, and by sliding it to the left against the urging, the bottom opening formed on the bottom surface of the lower plate 50 is opened, and the bottom opening is opened. The ball naturally falls from the bottom opening and is discharged. The operation of the ball removing lever 52 is usually performed in a state where a box (generally referred to as "Senryobako") for receiving the balls discharged from the lower plate 50 is placed below the lower plate 50. An operation handle 51 is arranged on the right side of the lower plate 50 as described above, and an ashtray (not shown) is attached to the left side of the lower plate 50.

As shown in FIG. 2, the game board 13 has a base plate 60 machined into a substantially square shape in front view, a large number of nails (not shown) and windmills (not shown) for ball guidance, and a rail 61. , 62, general winning opening 63, first winning opening 64, second winning opening 640, variable winning device 330, through gate 67, variable display device unit 80, etc. are assembled, and the peripheral portion thereof is an inner frame 12 (FIG. 1) is attached to the back side. The base plate 60 is made of a light-transmitting resin material, and is formed so that the player can visually recognize various structures arranged on the back side of the base plate 60 from the front side thereof. The general winning opening 63, the first winning opening 64, the second winning opening 640, and the variable display device unit 80 are arranged in through holes formed in the base plate 60 by router processing, and tapping screws are provided from the front side of the game board 13. It is fixed by etc.

The front central portion of the game board 13 can be visually recognized from the front side of the inner frame 12 through the window portion 14c (see FIG. 1) of the front frame 14. Hereinafter, the configuration of the game board 13 will be described mainly with reference to FIG. 2.

An outer rail 62 formed by bending a strip-shaped metal plate into a substantially arc shape is planted on the front surface of the game board 13, and a strip-shaped metal plate is placed inside the outer rail 62 in the same manner as the outer rail 62. The arc-shaped inner rail 61 formed in 1 is planted. The inner rail 61 and the outer rail 62 surround the front outer periphery of the game board 13, and the game board 13 and the glass unit 16 (see FIG. 1) surround the front and back, so that the front of the game board 13 has a ball. A game area in which the game is played is formed by the behavior of. The game area is the area in front of the game board 13 that is partitioned by the two rails 61 and 62 and the resin outer edge member 73 that connects the rails (a winning opening or the like is arranged and fired). This is the area where the sphere flows down).

The two rails 61 and 62 are provided to guide the ball launched from the ball launching unit 112a (see FIG. 4) to the upper part of the game board 13. A return ball prevention member 68 is attached to the tip of the inner rail 61 (upper left portion in FIG. 2) to prevent the ball once guided to the upper part of the game board 13 from returning to the ball guide passage. Will be done. A return rubber 69 is attached to the tip of the outer rail 62 (upper right part in FIG. 2) at a position corresponding to the maximum flight portion of the ball. Is dampened and bounced back toward the center.

In the lower left side of the front view (lower left side of FIG. 2) of the game area, first symbol display devices 37A and 37B including a plurality of LEDs as light emitting means and a 7-segment display are arranged. The first symbol display devices 37A and 37B display according to each control performed by the main control device 110 (see FIG. 4), and mainly display the gaming state of the pachinko machine 10. In the present embodiment, the first symbol display devices 37A and 37B are configured to be used properly depending on whether the ball has won the first winning opening 64 or the second winning opening 640. Specifically, when the ball wins the first winning opening 64, the first symbol display device 37A operates, while when the ball wins the second winning opening 640, the first The symbol display device 37B is configured to operate.

Further, the first symbol display devices 37A and 37B use LEDs to indicate whether the pachinko machine 10 is in the probabilistic change, the time reduction, or the normal state by the lighting state, or indicate whether the pachinko machine 10 is in the changing state or not by the lighting state. , Whether the stop symbol is a symbol corresponding to a probabilistic jackpot, a symbol corresponding to a normal jackpot, or a missed symbol is indicated by the lighting state, the number of reserved balls is indicated by the lighting state, and the round during the jackpot is indicated by the 7-segment display device. Display the number and error. It should be noted that the plurality of LEDs are configured so that the emission colors (for example, red, green, blue) of the respective LEDs are different, and the combination of the emission colors may suggest various gaming states of the pachinko machine 10 with a small number of LEDs. can.

In the pachinko machine 10, a lottery is performed when the first winning opening 64 and the second winning opening 640 have won a prize. In the lottery, the pachinko machine 10 determines whether or not it is a big hit (big hit lottery), and if it is determined to be a big hit, it also determines the type of the big hit. As the jackpot type determined here, 15R probability variation jackpot, 4R probability variation jackpot, and 15R normal jackpot are prepared. The first symbol display devices 37A and 37B not only indicate whether or not the lottery result is a big hit as a stop symbol after the end of the fluctuation, and if it is a big hit, a symbol corresponding to the jackpot type is shown. ..

Here, the "15R probability variation jackpot" is a probability variation jackpot in which the maximum number of rounds shifts to a high probability state after the jackpot of 15 rounds, and the "4R probability variation jackpot" is a jackpot with a maximum number of rounds of 4 rounds. It is a probabilistic jackpot that shifts to a high probability state after. Further, "15R normal jackpot" is a jackpot in which the maximum number of rounds is 15 rounds, and then the probability shifts to a low probability state, and the time is shortened during a predetermined number of fluctuations (for example, 100 fluctuations). be.

In addition, the "high probability state" refers to a state in which the probability of a jackpot is increased as an added value after the end of the jackpot, that is, during a so-called probability fluctuation (probability change), in other words, a game in which it is easy to shift to a special gaming state. It is the state of. The high-probability state (during probabilistic change) in the present embodiment includes a game state in which the winning probability of the second symbol, which will be described later, is increased and the ball is likely to win the second winning opening 640. The "low probability state" refers to a state in which the probability change is not in progress, and a state in which the jackpot probability is normal, that is, a state in which the jackpot probability is lower than that in the probability change state. In addition, in the "low probability state", the time saving state (time saving medium) is a state in which the jackpot probability is a normal state, and the jackpot probability remains the same and only the hit probability of the second symbol is increased to increase the second winning opening 640. It refers to the state of the game in which the ball is easy to win. On the other hand, when the pachinko machine 10 is in the normal state, it is a state of the game in which neither the probability change nor the time reduction is performed (the jackpot probability and the hit probability of the second symbol are not increased).

During the probability change and the time reduction, not only the probability of hitting the second symbol increases, but also the time when the electric accessory 640a attached to the second winning opening 640 is opened is changed, which is a longer time than during normal times. Set. When the electric accessory 640a is in the open state (open state), the ball wins the second winning opening 640 as compared with the case where the electric accessory 640a is in the closed state (closed state). It will be easy. Therefore, during the probability change or the time reduction, it becomes easy for the ball to win the second winning opening 640, and the number of times the big hit lottery is performed can be increased.

In addition, during the probability change or the time reduction, the opening time of the electric accessory 640a attached to the second winning opening 640 is not changed, or in addition to changing the opening time, electric motors are applied once. The change may be made so that the number of times that the accessory 640a is opened is increased from the normal time. Further, during the probability change or the time reduction, the hit probability of the second symbol is not changed, and the electric accessory 640a is opened at the time when the electric accessory 640a attached to the second winning opening 640 is opened and at one hit. At least one of the times may be changed. In addition, during the probability change or the time reduction, the time when the electric accessory 640a attached to the second winning opening 640 is opened and the number of times when the electric accessory 640a is opened per hit is not performed, and the second symbol is hit. Only the probability may be changed so as to be higher than the normal one.

In the game area, a plurality of general winning openings 63 are arranged in which 5 to 15 balls are paid out as prize balls when the balls are won. Further, a variable display device unit 80 is arranged in the central portion of the game area. The variable display device unit 80 is triggered by winning a prize (starting prize) in the first winning opening 64 and the second winning opening 640, and synchronizes with the variable display in the first symbol display devices 37A and 37B, while synchronizing with the variable display of the third symbol. It is composed of a third symbol display device 81 composed of a liquid crystal display (hereinafter simply abbreviated as "display device") that performs variable display, and an LED that variablely displays the second symbol triggered by the passage of a sphere of a through gate 67. A second symbol display device (not shown) is provided. Further, in the variable display device unit 80, a center frame 86 is arranged so as to surround the outer periphery of the third symbol display device 81.

The third symbol display device 81 is composed of a large 9-inch size liquid crystal display, and by controlling the display contents by the display control device 114 (see FIG. 4), for example, the upper, middle, and lower 3 Two symbol columns are displayed. Each symbol row is composed of a plurality of symbols (third symbol), and these third symbols are horizontally scrolled for each symbol row, and the third symbol is variably displayed on the display screen of the third symbol display device 81. It has become like. In the third symbol display device 81 of the present embodiment, the game state displayed by the control of the main control device 110 (see FIG. 4) is displayed by the first symbol display devices 37A and 37B, whereas the first of the third symbol display devices 81 is A decorative display is performed according to the display of the symbol display devices 37A and 37B. In addition, instead of the display device, for example, a reel or the like may be used to configure the third symbol display device 81.

The second symbol display device alternately lights the “○” symbol and the “×” symbol as the display symbol (second symbol (not shown)) each time the sphere passes through the through gate 67 for a predetermined time. It is a variable display. When the pachinko machine 10 detects that the ball has passed through the through gate 67, a winning lottery is performed. As a result of the winning lottery, if it is a winning, the symbol "○" is stopped and displayed on the second symbol display device after the variation display of the second symbol. Further, if the result of the winning lottery is a failure, the symbol "x" is stopped and displayed on the second symbol display device after the variation display of the third symbol.

In the pachinko machine 10, when the variation display in the second symbol display device is stopped at a predetermined symbol (in the present embodiment, the symbol “○”), the electric accessory 640a attached to the second winning opening 640 is used for a predetermined time. It is configured to be activated (opened) only.

The time required for the variation display of the second symbol is set to be shorter during the probability change or the time reduction than when the game state is normal. As a result, during the probability change and the time reduction, the variation display of the second symbol is performed in a short time, so that the winning lottery can be performed more than during the normal time. Therefore, since the chances of winning in the winning lottery increase, it is possible to give the player many opportunities to open the electric accessory 640a of the second winning opening 640. Therefore, it is possible to make it easy for the ball to win the second winning opening 640 during the probability change and the time saving.

In addition, during the probability change or the time reduction, the second winning opening 640 can be reached during the probability change or the time reduction by other methods such as increasing the opening time and the number of times of opening the electric accessory 640a per hit. When the ball is in a state where it is easy to win a prize, the time required for the variable display of the second symbol may be constant regardless of the gaming state. On the other hand, when the time required for the variation display of the second symbol is set to be shorter than the normal time during the probability change or the time reduction, the hit probability may be constant regardless of the gaming state, or one hit. The opening time and the number of times of opening of the electric accessory 640a may be made constant regardless of the gaming state.

The through gate 67 is assembled to the game board 13 in the left and right regions of the variable display device unit 80, and is configured so that a part of the balls launched on the game board 13 can pass through. When the ball passes through the through gate 67, a winning lottery for the second symbol is performed. After the winning lottery, variable display is performed on the second symbol display device, and if the winning lottery result is a winning symbol, a symbol "○" is displayed as a stop symbol of the variable display, and if the winning lottery result is incorrect. For example, a symbol of "x" is displayed as a stop symbol of the variable display.

The number of times the ball has passed through the through gate 67 is held up to a total of four times, and the number of held balls is displayed by the above-mentioned first symbol display devices 37A and 37B and on the second symbol holding lamp (not shown). Is also lit and displayed. Four second symbol holding lamps are provided for the maximum number of holding lamps, and are symmetrically arranged below the third symbol display device 81.

The variation display of the second symbol is performed by switching the lighting and non-lighting of a plurality of lamps in the second symbol display device as in the present embodiment, as well as the first symbol display devices 37A, 37B and the third. It may be performed by using a part of the symbol display device 81. Similarly, the second symbol holding lamp may be turned on by a part of the third symbol display device 81. Further, the maximum number of reserved balls for the passage of the balls of the through gate 67 is not limited to 4, but may be set to 3 times or less, or 5 times or more (for example, 8 times). Further, the number of through gates 67 assembled is not limited to two, and may be one, for example. Further, the assembly position of the through gate 67 is not limited to the left and right sides of the variable display device unit 80, and may be, for example, below the variable display device unit 80. Further, since the number of reserved balls is indicated by the first symbol display devices 37A and 37B, the lighting display may not be performed by the second symbol holding lamp.

Below the variable display device unit 80, a first winning opening 64 in which a ball can win a prize is arranged. When the ball wins the first winning opening 64, the first winning opening switch (not shown) provided on the back side of the game board 13 is turned on, and the main control device 110 is caused by the turning on of the first winning opening switch. A big hit lottery is made in (see FIG. 4), and the display according to the lottery result is shown by the first symbol display device 37A.

On the other hand, below the front view of the first winning opening 64, a second winning opening 640 in which the ball can win is arranged. When the ball wins the second winning opening 640, the second winning opening switch (not shown) provided on the back side of the game board 13 is turned on, and the main control device 110 is caused by the turning on of the second winning opening switch. A big hit lottery is made in (see FIG. 4), and the display according to the lottery result is shown on the first symbol display device 37B.

In addition, the first winning opening 64 and the second winning opening 640 are also one of the winning openings in which five balls are paid out as prize balls when the balls are won. In the present embodiment, the number of prize balls paid out when a ball wins in the first winning opening 64 and the number of prize balls paid out when a ball wins in the second winning opening 640 are configured to be the same. , The number of prize balls paid out when a ball wins in the first winning opening 64 and the number of prize balls paid out when a ball wins in the second winning opening 640, for example, a ball to the first winning opening 64 The number of prize balls paid out when a prize is won may be three, and the number of prize balls paid out when a ball is won in the second winning opening 640 may be configured as five.

An electric accessory 640a is attached to the second winning opening 640. The electric accessory 640a is configured to be openable and closable, and normally the electric accessory 640a is in a closed state (reduced state), making it difficult for the ball to win a prize in the second winning opening 640. On the other hand, when the symbol "○" is displayed on the second symbol display device as a result of the variation display of the second symbol performed when the ball passes through the through gate 67, the electric accessory 640a is in the open state (enlarged). State), and the ball is in a state where it is easy to win a prize in the second winning opening 640.

As described above, during the probabilistic change and the time reduction, the probability of hitting the second symbol is higher than during the normal time, and the time required for the variation display of the second symbol is short. ”Is easy to display, and the number of times that the electric accessory 640a is in the open state (enlarged state) increases. Further, during the probability change and the time reduction, the time during which the electric accessory 640a is released is also longer than during the normal operation. Therefore, during the probability change and the time reduction, it is possible to create a state in which the ball is more likely to win the second winning opening 640 as compared with the normal time.

Here, the probability of winning a jackpot is the same in both the low probability state and the high probability state when the ball wins in the first winning opening 64 and when the ball wins in the second winning opening 640. However, the probability of becoming a 15R probability variation jackpot as the type of jackpot selected in the case of a jackpot is higher when the ball wins the second winning opening 640 than when the ball wins the first winning opening 64. It is set. On the other hand, the first winning opening 64 does not have an electric accessory as in the second winning opening 640, and the ball is in a state where it can always win a prize.

Therefore, in normal times, the electric accessory attached to the second winning opening 640 is often in a closed state, and it is difficult to win the second winning opening 640. Then, the ball is fired so that the ball passes to the left side of the variable display device unit 80 (so-called "left-handed"), and by winning the first winning opening 64, many chances of a big hit lottery are obtained and the big hit is obtained. It is advantageous for the player to aim at that.

On the other hand, during the probability change or the time reduction, by passing the ball through the through gate 67, the electric accessory 640a attached to the second winning opening 640 is likely to be opened, and the second winning opening 640 is likely to be won. Therefore, the ball is launched toward the second winning opening 640 so that the ball passes to the right of the variable display device 80 (so-called "right-handed"), and the electric accessory is opened by passing through the through gate 67. At the same time, it is advantageous for the player to aim for a 15R probability variation jackpot by winning the second winning opening 640.

Since the pachinko machine 10 in the present embodiment has a symmetrical configuration of the game board 13, it is possible to aim at the first winning opening 64 by "right-handed" or to aim at the second winning opening 640 by "left-handing". You can also aim. Therefore, the pachinko machine 10 of the present embodiment is a method of firing a ball to the player according to the gaming state of the pachinko machine 10 (whether it is in the probabilistic change, in the time saving, or in the normal state). Can be eliminated from changing to "left-handed" and "right-handed". Therefore, it is possible to eliminate the hassle of changing the way the ball is hit.

A variable winning device 330 (see FIG. 11) is arranged below the first winning opening 64, and a specific winning opening 65a is provided in a substantially central portion thereof. In the pachinko machine 10, when the jackpot lottery performed due to the winning of the first winning opening 64 or the second winning opening 640 becomes a jackpot, after a predetermined time (variable time) has elapsed, the jackpot stop symbol is displayed. The first symbol display device 37A or the first symbol display device 37B is turned on so that the stop symbol corresponding to the jackpot is displayed on the third symbol display device 81 to indicate the occurrence of the jackpot. After that, the game state shifts to a special game state (big hit) in which the ball is easy to win. As this special game state, the specific winning opening 65a, which is normally closed, is opened for a predetermined time (for example, until 30 seconds have passed or until 10 balls are won).

The specific winning opening 65a is closed after a lapse of a predetermined time, and after the closing, the specific winning opening 65a is opened again for a predetermined time. The opening / closing operation of the specific winning opening 65a can be repeated up to 15 times (15 rounds), for example. The state in which this opening / closing operation is performed is a form of a special gaming state that is advantageous to the player, and a larger amount of prize balls than usual is paid out to the player as a game value (game value). Is done.

The special gaming state is not limited to the above-described form. A large opening that opens and closes separately from the specific winning opening 65a is provided in the game area, and when the LED corresponding to the big hit is turned on in the first symbol display devices 37A and 37B, the specific winning opening 65a is opened for a predetermined time. A special game in which a large opening provided separately from the specific winning opening 65a is opened a predetermined number of times for a predetermined time when the ball wins a prize in the specific winning opening 65a while the specific winning opening 65a is open. It may be formed as a state. Further, the specific winning opening 65a is not limited to one, and one or two or more (for example, three) may be arranged, and the arrangement position is also the lower right side of the first winning opening 64 or the first. Not limited to the lower left side of the winning opening 64, for example, the left side of the variable display device unit 80 may be used.

In the right corner on the lower side of the game board 13, a sticking space K1 for sticking a certificate stamp or an identification label is provided, and the certificate stamp or the like stuck on the sticking space K1 is a small window of the front frame 14. It can be visually recognized through 35 (see FIG. 1).

The game board 13 is provided with an out port 71. Balls that flow down the game area and do not win any of the winning openings 63, 64, 65a, 640 are guided to a ball discharge path (not shown) through the out opening 71. The out openings 71 are arranged in pairs on the left and right sides of the specific winning opening 65a.

A large number of nails are planted on the game board 13 in order to appropriately disperse and adjust the falling direction of the ball, and various members (accessories) such as a windmill are arranged.

As shown in FIG. 3, the control board units 90 and 91 and the back pack unit 94 are mainly provided on the back side of the pachinko machine 10. The control board unit 90 is unitized by mounting a main board (main control device 110), a voice lamp control board (voice lamp control device 113), and a display control board (display control device 114). The control board unit 91 is unitized by mounting a payout control board (payout control device 111), a launch control board (launch control device 112), a power supply board (power supply device 115), and a card unit connection board 116.

In the back pack unit 94, the back pack 92 forming the protective cover portion and the payout unit 93 are unitized. In addition, each control board is used for MPU as a one-chip microcomputer that controls each control, a port for contacting various devices, a random number generator used for various lottery, and for time counting and synchronization. A clock pulse generation circuit, etc. is installed as needed.

The main control device 110, the voice lamp control device 113 and the display control device 114, the payout control device 111 and the launch control device 112, the power supply device 115, and the card unit connection board 116 are housed in the board boxes 100 to 104, respectively. .. The board boxes 100 to 104 include a box base and a box cover that covers an opening of the box base, and the box base and the box cover are connected to each other to house each control device and each board.

Further, in the board box 100 (main control device 110) and the board box 102 (payout control device 111 and launch control device 112), the box base and the box cover are connected by a sealing unit (not shown) so as not to be opened (caulking structure). (Consolidated by). Further, a sealing sticker (not shown) is attached to the connecting portion between the box base and the box cover over the box base and the box cover. This sealing seal is made of a brittle material, and if the sealing seal is to be peeled off in order to open the board boxes 100 and 102, or if the board boxes 100 and 102 are forcibly opened, the box base side and the box cover are used. Cut to the side. Therefore, by checking the sealing unit or the sealing seal, it is possible to know whether or not the substrate boxes 100 and 102 have been opened.

The payout unit 93 includes a tank 130 located at the uppermost portion of the back pack unit 94 and opened upward, a tank rail 131 connected below the tank 130 and gently inclined toward the downstream side, and a downstream of the tank rail 131. A case rail 132 vertically connected to the side and a payout device 133 provided at the most downstream portion of the case rail 132 and paying out balls by a predetermined electrical configuration of a payout motor 216 (see FIG. 4) are provided. ing. The tank 130 is sequentially replenished with balls supplied from the island equipment of the game hall, and the required number of balls is appropriately paid out by the payout device 133. A vibrator 134 for adding vibration to the tank rail 131 is attached to the tank rail 131.

Further, the payout control device 111 is provided with a state return switch 120, the launch control device 112 is provided with a variable resistor operation knob 121, and the power supply device 115 is provided with a RAM erase switch 122. The state return switch 120 is operated to clear the ball clogging (return to the normal state) when a payout error occurs, such as a ball clogging of the payout motor 216 (see FIG. 4). The operation knob 121 is operated to adjust the firing force of the firing solenoid. The RAM erase switch 122 is operated when the power is turned on when it is desired to return the pachinko machine 10 to the initial state.

Next, the electrical configuration of the pachinko machine 10 will be described with reference to FIG. FIG. 4 is a block diagram showing an electrical configuration of the pachinko machine 10.

The main control device 110 is equipped with an MPU 201 as a one-chip microcomputer which is an arithmetic unit. The MPU 201 is a ROM 202 that stores various control programs and fixed value data executed by the MPU 201, and a memory for temporarily storing various data and the like when the control program stored in the ROM 202 is executed. A certain RAM 203 and various other circuits such as an interrupt circuit, a timer circuit, and a data transmission / reception circuit are built in. In the main control device 110, the MPU 201 is used to perform main processing of the pachinko machine 10 such as a jackpot lottery, display settings in the first symbol display devices 37A and 37B and the third symbol display device 81, and a lottery of display results in the second symbol display device. To execute.

In order to instruct the operation of the sub control device such as the payout control device 111 and the voice lamp control device 113, various commands are transmitted from the main control device 110 to the sub control device by the data transmission / reception circuit. Such a command is transmitted from the main control device 110 to the sub control device in only one direction.

The RAM 203 includes various areas, counters, flags, a stack area in which the contents of the internal registers of the MPU 201 and the return address of the control program executed by the MPU 201 are stored, various flags, counters, I / O, and the like. It has a work area (work area) in which values are stored. The RAM 203 has a configuration in which a backup voltage is supplied from the power supply device 115 to hold (back up) data even after the power supply of the pachinko machine 10 is cut off, and all the data stored in the RAM 203 is backed up. ..

When the power supply is cut off due to the occurrence of a power failure or the like, the stack pointer at the time of the power failure (including the time when a power failure occurs; the same applies hereinafter) and the value of each register are stored in the RAM 203. On the other hand, when the power is turned on (including power on due to power failure elimination; the same applies hereinafter), the state of the pachinko machine 10 is restored to the state before the power was cut off based on the information stored in the RAM 203. Writing to the RAM 203 is executed by the main process (not shown) when the power is cut off, and restoration of each value written in the RAM 203 is executed in the start-up process (not shown) at the time of turning on the power. The NMI terminal (non-maskable interrupt terminal) of the MPU 201 is configured so that a power failure signal SG1 from the power failure monitoring circuit 252 is input when the power is cut off due to a power failure or the like, and the power failure signal SG1 is the MPU201. When input to, the NMI interrupt process (not shown) as the power failure process is immediately executed.

An input / output port 205 is connected to the MPU 201 of the main control device 110 via a bus line 204 composed of an address bus and a data bus. The input / output port 205 is centered on the lower side of the payout control device 111, the voice lamp control device 113, the first symbol display devices 37A and 37B, the second symbol display device, the second symbol hold lamp, and the opening / closing plate of the specific winning opening 65a. A solenoid 209 consisting of a large opening solenoid for driving the opening and closing and a solenoid for driving an electric accessory is connected to the front side, and the MPU 201 sends various commands and control signals to these via the input / output port 205. To send.

Further, the input / output port 205 includes various switches 208 including a switch group (not shown), a sensor group including a slide position detection sensor S and a rotation position detection sensor R, and a RAM erasing switch circuit 253 provided in the power supply device 115, which will be described later. Is connected, and the MPU 201 executes various processes based on the signals output from the various switches 208 and the RAM erase signal SG2 output from the RAM erase switch circuit 253.

The payout control device 111 drives the payout motor 216 to control the payout of prize balls and rented balls. The MPU 211, which is an arithmetic unit, has a ROM 212 that stores a control program and fixed value data executed by the MPU 211, and a RAM 213 that is used as a work memory or the like.

The RAM 213 of the payout control device 111, like the RAM 203 of the main control device 110, has a stack area in which the contents of the internal registers of the MPU 211 and the return address of the control program executed by the MPU 211 are stored, and various flags and counters. It has a work area (work area) in which values such as, I / O, etc. are stored. The RAM 213 has a configuration in which a backup voltage is supplied from the power supply device 115 to hold (back up) data even after the power supply of the pachinko machine 10 is cut off, and all the data stored in the RAM 213 is backed up. Similar to the MPU 201 of the main control device 110, the NMI terminal of the MPU 211 is also configured so that the power failure signal SG1 is input from the power failure monitoring circuit 252 when the power is cut off due to the occurrence of a power failure or the like. When input to the MPU211, an NMI interrupt process (not shown) as a power failure process is immediately executed.

An input / output port 215 is connected to the MPU 211 of the payout control device 111 via a bus line 214 composed of an address bus and a data bus. A main control device 110, a payout motor 216, a launch control device 112, and the like are connected to the input / output port 215, respectively. Further, although not shown, the payout control device 111 is connected to a prize ball detection switch for detecting the paid out prize balls. The prize ball detection switch is connected to the payout control device 111, but is not connected to the main control device 110.

The launch control device 112 controls the ball launch unit 112a so that when the main control device 110 gives an instruction to launch the ball, the launch strength of the ball corresponds to the amount of rotation of the operation handle 51. .. The ball launching unit 112a includes a firing solenoid and an electromagnet (not shown), and the firing solenoid and the electromagnet are allowed to be driven when predetermined conditions are met. Specifically, the touch sensor 51a detects that the player is touching the operation handle 51, and the operation is performed on condition that the launch stop switch 51b for stopping the launch of the ball is off (not operated). The firing solenoid is excited in response to the rotation operation amount (rotation position) of the handle 51, and the ball is launched with a strength corresponding to the operation amount of the operation handle 51.

The audio lamp control device 113 is an audio output in an audio output device (speaker, etc. not shown) 226, an output of lighting and extinguishing in a lamp display device (illumination units 29 to 33, indicator lamp 34, etc.) 227, and a variation effect (variation). It controls the setting of the display mode of the third symbol display device 81 performed by the display control device 114 such as the display) and the advance notice effect. The arithmetic unit MPU 221 has a ROM 222 that stores a control program and fixed value data executed by the MPU 221 and a RAM 223 that is used as a work memory or the like.

An input / output port 225 is connected to the MPU 221 of the voice lamp control device 113 via a bus line 224 composed of an address bus and a data bus. A main control device 110, a display control device 114, an audio output device 226, a lamp display device 227, other devices 228, a frame button 22, and the like are connected to the input / output port 225, respectively. Other devices 228 include a drive motor 342 and a voice coil motor 352.

The voice lamp control device 113 determines the display mode of the third symbol display device 81 based on various commands (variation pattern command, stop type command, etc.) received from the main control device 110, and commands the determined display mode. The display control device 114 is notified by (display fluctuation pattern command, display stop type command, etc.). Further, the voice lamp control device 113 monitors the input from the frame button 22, and when the frame button 22 is operated by the player, the stage displayed on the third symbol display device 81 can be changed or the super reach can be changed. The display control device 114 is instructed to change the effect content of the time. When the stage is changed, a rear image change command including information about the changed stage is transmitted to the display control device 114 in order to display the rear image corresponding to the changed stage on the third symbol display device 81. .. Here, the back image is an image displayed on the back side of the third symbol, which is a main image to be displayed on the third symbol display device 81. The display control device 114 displays various images on the third symbol display device 81 according to a command transmitted from the voice lamp control device 113.

Further, the voice lamp control device 113 receives a command (display command) indicating the display content of the third symbol display device 81 from the display control device 114. Based on the display command received from the display control device 114, the voice lamp control device 113 outputs the voice corresponding to the display content according to the display content of the third symbol display device 81 from the voice output device 226, and also outputs the voice corresponding to the display content. The lighting and extinguishing of the lamp display device 227 are controlled according to the display content.

In the display control device 114, the voice lamp control device 113 and the third symbol display device 81 are connected, and based on the command received from the voice lamp control device 113, the third symbol variation effect of the third symbol display device 81 and the like are performed. It controls the display. Further, the display control device 114 appropriately transmits a display command for notifying the display content of the third symbol display device 81 to the voice lamp control device 113. The voice lamp control device 113 outputs voice from the voice output device 226 according to the display content indicated by this display command, thereby matching the display of the third symbol display device 81 with the voice output from the voice output device 226. be able to.

The power supply device 115 is provided with a power supply unit 251 for supplying power to each part of the pachinko machine 10, a power failure monitoring circuit 252 for monitoring power failure due to a power failure, and a RAM erasing switch 122 (see FIG. 3). It has an erasing switch circuit 253. The power supply unit 251 is a device that supplies the required operating voltage to each of the control devices 110 to 114 and the like through a power supply path (not shown). As an outline, the power supply unit 251 takes in a voltage of 24 volt AC supplied from the outside, and has a voltage of 12 volt for driving various switches such as various switches 208, a solenoid such as a solenoid 209, and a motor. A 5 volt voltage for logic, a backup voltage for RAM backup, and the like are generated, and these 12 volt voltage, 5 volt voltage, and backup voltage are supplied to each control device 110 to 114 and the like.

The power failure monitoring circuit 252 is a circuit for outputting a power failure signal SG1 to each NMI terminal of the MPU 201 of the main control device 110 and the MPU 211 of the payout control device 111 when the power is cut off due to the occurrence of a power failure or the like. The power failure monitoring circuit 252 monitors the DC stable 24 volt voltage, which is the maximum voltage output from the power supply unit 251 and determines that a power failure (power cutoff, power cutoff) has occurred when this voltage becomes less than 22 volt. Then, the power failure signal SG1 is output to the main control device 110 and the payout control device 111. By the output of the power failure signal SG1, the main control device 110 and the payout control device 111 recognize the occurrence of the power failure and execute the NMI interrupt process. The power supply unit 251 outputs a voltage of 5 volts, which is the drive voltage of the control system, for a sufficient time for executing the NMI interrupt process even after the voltage of DC stable 24 volts becomes less than 22 volts. Is configured to maintain a normal value. Therefore, the main control device 110 and the payout control device 111 can normally execute and complete the NMI interrupt process (not shown).

The RAM erase switch circuit 253 is a circuit for outputting the RAM erase signal SG2 for clearing the backup data to the main control device 110 when the RAM erase switch 122 (see FIG. 3) is pressed. When the RAM erase signal SG2 is input when the power of the pachinko machine 10 is turned on, the main control device 110 clears the backup data, and the payout control device 111 issues a payout initialization command for clearing the backup data. It transmits to the device 111.

FIG. 5 is a front perspective view of the operation device 300. As shown in FIG. 5, the operation device 300 is arranged at the center portion in the left-right direction of the inner frame 12 in the front view (that is, the center portion in the left-right direction of the pachinko machine 10).

The operation device 300 includes a tilting device 310 that is configured to be tilted by being pushed by a player, and is located in an area composed of a housing recess 17a recessed in the front-rear direction along the outer frame of the upper plate 17. Arranged. When the player tilts (rotates) the tilting device 310, a signal is input to the pachinko machine 10 (see FIG. 1).

There is a gap between the tilting device 310 and the accommodating recess 17a so that at least the fingers of the hand can be comfortably inserted. As a result, the player can prepare to operate the tilting device 310 by arranging the fingertips on the back side of the upper surface of the tilting device 310 (see FIG. 7).

Since the player holds the operation handle 51 with his right hand, the tilting device 310 is often operated with his left hand. Therefore, in the following description, the description will be made on the assumption that the player operates the tilting device 310 with the left hand.

6 (a) is a partial front view of the pachinko machine 10, and FIG. 6 (b) is a partial cross-sectional view of the pachinko machine 10 in the VIb-VIb line of FIG. 6 (a). Is a partial front view of the pachinko machine 10, and FIG. 7 (b) is a partial cross-sectional view of the pachinko machine 10 in line VIIb-VIIb of FIG. 7 (a).

In FIGS. 6 and 7, the vicinity of the operating device 300 of the pachinko machine 10 is partially illustrated. Note that FIG. 6 shows a state in which the tilting device 310 is arranged in the first state (initial state in the present embodiment) in which the operation surface 312a1 faces in the vertical direction, and FIG. 7 shows the tilting device 310 from the first state. The state in which the operation surface 312a1 is arranged in the second state facing upward and rearward by rising around the shaft portion 314 is shown. In FIG. 7, an example of a player's hand operating the tilting device 310 is illustrated by an imaginary line.

The tilting device 310 is configured to be able to automatically operate between the first state and the second state by the driving force of the driving device 340. The details of the drive device 340 will be described later.

An example of the operation of the tilting device 310 will be described. The operation of the tilting device 310 is performed by the player, for example, when a specific display (for example, a display of "press a button") appears on the third symbol display device 81 (see FIG. 2).

Here, for example, when the tilting device 310 is pushed in by a method of dropping the hand vigorously downward, as in the case of pushing a button that moves up and down, the position of the operation surface 312a1 moves toward the front side depending on the degree of tilting. The palm and the operation surface 312a1 are easily rubbed against each other. Therefore, it is possible to give a sense of discomfort to the player, and it is possible to suppress the player from performing the pushing operation by dropping his / her hand downward vigorously.

In the present embodiment, as shown in FIG. 7, the fingertip is placed near the shaft portion 314 of the tilting device 310, and the palm is lowered downward with the fingertip as a fulcrum, so that the palm is integrated with the operation surface 312a1. The tilting device 310 can be comfortably pushed in and operated.

Therefore, the player can be guided to operate by lowering the palm with the fingertip as a fulcrum so as not to forcefully drop the hand downward. As a result, the degree of impact applied to the tilting device 310 by the operation of the player can be reduced, and the possibility of damage to the tilting device 310 can be reduced.

The difference in the appearance of the tilting device 310 from the player's viewpoint will be described with reference to FIGS. 8 and 9. FIG. 8 is a front perspective view of the operation device 300 in the direction of arrow VIII of FIG. 6, and FIG. 9 is a front perspective view of the operation device 300 in the direction of arrow IX of FIG. In addition, in FIGS. 8 and 9, the shape of the pachinko machine 10 is partially illustrated by an imaginary line. Further, in FIG. 9, an example of a player's hand for pushing and operating the tilting device 310 is illustrated by an imaginary line.

As shown in FIGS. 8 and 9, the operation surface 312a1 of the tilting device 310 is visible from the player's point of view in the first state, while the area is reduced to the extent that it is invisible in the second state. (The operation surface 312a1 is directed to the outside of the player's viewpoint). As a result, the appearance of the tilting device 310 can be significantly changed between the first state and the second state.

In the present embodiment, the area of the protective lens member 311i is gradually increased in the process of changing from the first state to the second state, and the LED device 341f arranged inside the operation device 300 accordingly (FIG. FIG. Since the amount of light in (see 12) is gradually increased, the difference in the amount of light (degree of brightness) that the player can see between the first state and the second state becomes large, and the first state and the second state are displayed. Can greatly change the appearance of the tilting device 310.

An example of the operation of the tilting device 310 will be described. In the present embodiment, as shown in FIG. 9, the outer side surface of the little finger is placed near the shaft portion 314 (see FIG. 7) of the tilting device 310, and the palm is lowered downward with the outer side surface portion of the little finger as a fulcrum. (By rotating the wrist as an axis), the tilting device 310 can be comfortably pushed in while the palm is integrated with the operation surface 312a1.

Therefore, the player can be guided to perform the operation by lowering the palm downward with the outer side surface portion of the little finger as a fulcrum so as not to force the hand to drop downward. As a result, the degree of impact applied to the tilting device 310 by the operation of the player can be reduced, and the possibility of damage to the tilting device 310 can be reduced.

Next, the operation device 300 will be described with reference to FIGS. 10 and 11. FIG. 10 is a front perspective view of the operation device 300, and FIG. 11 is a rear perspective view of the operation device 300. As shown in FIG. 10, the operation device 300 is rotatably supported around a shaft portion 314 in which the tilting device 310 is arranged at the rear end portion.

Further, as shown in FIG. 11, a voice coil motor 352 that gives an impact in the straight direction to the tilting device 310 and detection sensors 324L and 324R that detect a pushing operation from the first state lower the tilting device 310. It is arranged outside the lower frame member 320 that surrounds it from the side.

In this way, by arranging the sensor that detects the position of the tilting device 310, the voice coil motor that gives the driving force, and the like outside the lower frame member 320, the region inside the lower frame member 320 is largely used and the tilting device 320 is tilted. The device 310 can be housed in the lower frame member 320. As a result, a large amount of movable amount of the tilting device 310 can be secured.

FIG. 12 is a front exploded perspective view of the operating device 300, and FIG. 13 is a rear exploded perspective view of the operating device 300. As shown in FIGS. 12 and 13, the operation device 300 includes a tilting device 310 having ring members BR1 arranged at the left and right end portions at the rear side end portion (the back end portion on the paper surface of FIG. 12), and a tilting device 310 thereof. A lower frame member 320 having a lower bearing portion 323 that supports the ring member BR1 of the device 310 from below and determining the push-in end of the tilting device 310, and a lower frame member 320 that supports the ring member BR1 of the tilting device 310 from above. It is a member having a recessed portion arranged opposite to the lower frame member 320 and having a large opening in the central portion, and is fastened and fixed to the lower frame member 320 in a manner in which the tilting member 310 is arranged between the lower frame member 320 and the lower frame member 320. To the tilting device 310 via the upper frame member 330 that determines the arrangement of the tilting device 310 in the second state, and the arm member 345 that is fastened and fixed to the lower side of the lower frame member 320 and constitutes the tilting device 310 and the link mechanism. It mainly includes a drive device 340 that transmits a driving force, and a protective cover device 350 that is fastened and fixed to the drive device 340 and protects the drive device 340 by covering the drive device 340 from three sides in the left-right direction and the rear direction.

The lower frame member 320 is a cup-shaped member that is configured such that the left and right portions of the bottom surface are inclined downward toward the front side, and the bottom plate portion 321 that is inclined downward toward the front side and the bottom plate portion 321 thereof. A horizontal portion 322 composed of a plate-shaped member arranged horizontally at the upper end portion on the back side of the above, and a semicircular receiving portion open upward near the rear end portion of the horizontal portion 322, which is a tilting device 310. The lower bearing portion 323 that receives the shaft portion 314 from the lower side, the left side detection sensor 324L arranged in pairs on the lower side of the bottom plate portion 321 and the right side detection sensor 324R, and the bottom plate portion 321 horizontally at the center position in the left-right direction. It mainly includes an opening 325, which is an opening that is opened by scraping a portion arranged on the lower side of the portion 322.

The bottom plate portion 321 defines the moving end of the tilting device 310 by abutting with the tilting device 310, and has a plurality of openings so that the portion of the tilting device 310 can pass through the bottom plate portion 321. NS.

The bottom plate portion 321 has a transmission hole 321a drilled in the central portion on the front side, a detection hole 321b drilled along the detection grooves of the left and right detection sensors 324L and 324R, and left and right on the left and right of the opening 325. It mainly includes an insertion hole 321c which is formed symmetrically.

The transmission hole 321a is arranged at a front position of the voice coil motor 352 of the protective cover device 350, and is formed in a size that allows the overhanging convex portion 311j of the tilting device 310 to pass through. By driving the voice coil motor 352 in a state where the overhanging convex portion 311j of the tilting device 310 projects below the bottom plate portion 321, a driving force in the linear motion direction can be applied to the tilting device 310.

The detection hole 321b is a through hole through which detection pieces 311 gL and 311 gR projecting from the lower surface of the tilting device 310 can be inserted. By arranging the detection pieces 311 gL and 311 gR protruding from the detection hole 321b in the detection grooves of the detection sensors 324L and 324R, the posture of the tilting device 310 can be detected.

The insertion hole 321c is sized so that the shaft portion 311c arranged on the flange of the tilting device 310 and the arm member 345 of the drive device 340 can be inserted, and the arm member is formed when the drive device 340 is operated. A through hole is formed to a position where interference with the 345 can be avoided.

The horizontal portion 322 constitutes a flat surface for fastening and fixing the lower frame member 320 and the drive device 340, and is formed of a U-shape having an open portion on the front side while extending upward from the upper surface thereof. A locking portion 322a is provided.

The locking portion 322a is a portion that locks one end of the torsion spring 315 of the tilting device 310 so as not to move backward. When the locking portion 322a locks the torsion spring 315, the urging force of the torsion spring 322a acts in the direction of moving the tilting device 310 to the second state.

The detection sensors 324L and 324R are photocoupler type sensors that detect the position of the tilting device 310. The detection sensors 324L and 324R are arranged at positions where the distances (positions of the detection grooves) from the bottom plate portion 321 of the lower frame member 320 are the same on the left and right sides.

Further, the photocoupler type sensor includes a light projecting unit that emits light and a light receiving unit that receives light from the light emitting unit, and a gap (slit, detection groove) into which a detection portion can be inserted. Means a sensor that is arranged in a substantially U-shape.

The opening 325 is a through hole for allowing the LED device 341f of the drive device 340, the rotary claw member 347, and the like to enter the inside of the lower frame member 320. Therefore, the left-right width thereof is made larger than the left-right width of the pair of rotating claw members 347.

On the other hand, regarding the vertical width, since the drive device 340 is configured to project the LED device 341f toward the upper front side (see FIG. 17B), the drive device 341f passes through the opening 325 and then the drive device. By pushing the 340 upward, the LED device 341f can be arranged above the opening 325, and the opening 325 is compared with the vertical width including the LED device 341f to the rotary claw member 347. The vertical width can be shortened.

The upper frame member 330 is arranged so as to face the opening 331, which is an opening sized to catch the extension portion 311h extending from the lower end surface of the tilting device 310 to the front side, and the lower bearing portion 323 of the lower frame member 320. It is mainly provided with an upper bearing portion 332 which is formed of a semicircular shape whose lower side is open and supports the ring member BR1 of the tilting device 310.

The protective cover device 350 is configured so that it can be divided in the vertical direction and covers three directions except the front side, and the main body cover 351 and the main body cover 351 which are fastened and fixed to the lower end of the drive device 340. A voice coil motor 352 that is supported by the bottom plate and is arranged on the front side and whose vibration surface is directed diagonally forward and upward, a left side detection sensor 353L that is a detection sensor having a detection groove on the upper side of the bottom plate of the main body cover 351 and a right side. It mainly includes a detection sensor 353R.

Note that FIG. 12 shows a state in which the main body cover 351 is partially broken so that the right side detection sensor 353R arranged on the opposite side of the left side detection sensor 353L with respect to the left and right center can be visually recognized.

The voice coil motor 352 is arranged in a posture in which the vibration surface is substantially parallel to the bottom plate portion 321 of the lower frame member 320 in the assembled state (see FIG. 10). As a result, the voice coil motor 352 is driven when the tilting device 310 projects the overhanging convex portion 311j downward through the transmission hole 321a, so that the driving force can be efficiently transmitted to the tilting device 310.

The detection sensors 353L and 353R are photocoupler type sensors that detect the phase of the disk cams 344L and 344R of the drive device 340. The disc cams 344L and 344R of the drive device 340 are arranged in such a manner that they are arranged inside the detection groove of the detection sensors 353L and 353R. Detecting whether or not the detection holes 344eL and 344eR of the disc cams 344L and 344R are arranged in the detection grooves of the detection sensors 353L and 353R, and detecting that the disc cams 344L and 344R are arranged in a specific phase. Can be done.

In the present embodiment, since the left and right disk cams 344L and 344R of the drive device 340 include the detection holes 344eL and 344eR in different phases, the specific phase that can be detected by the detection sensors 353L and 353R is 2. It becomes a kind.

Next, the tilting device 310 will be described with reference to FIGS. 14 to 16. 14 (a) is a front view of the tilting device 310, FIG. 14 (b) is a side view of the tilting device 310 in the direction of arrow XIVb of FIG. 14 (a), and FIG. 14 (c) is a side view of the tilting device 310. It is sectional drawing of the tilting apparatus 310 in the XIVc-XIVc line of FIG. 14A. FIG. 15 is a front exploded perspective view of the tilting device 310, and FIG. 16 is a rear exploded perspective view of the lid 312 of the tilting device 310.

As shown in FIGS. 14 to 16, the tilting device 310 has a mode in which a case main body 311 formed of a box-shaped body having side fan-shaped openings at the top and bottom and an upper opening of the case main body 311 are covered with a lid. A mode in which the lid 312 fastened and fixed to the case body 311, the spherical lens member 313 fastened and fixed to the front end of the lid 312 and hung downward, and the rear end of the case body 311 and the lid 312 are sandwiched between them. In a ring shape, the shaft portion 314 arranged in the above, the torsion spring 315 wound around the shaft portion 314, and the case body 311 and the lid 312 are indivisiblely fixed at the rear ends of the case body 311 and the lid 312. Mainly includes a ring member BR1.

The case body 311 has a bottom plate portion 311a that is tilted downward from the back side to the front side in the first state, an opening 311b opened in the center of the bottom plate portion 311a, and left and right of the opening 311b. A cylindrical shaft portion 311c extending downward from a flange extending downward along the edge of the spring and a recessed portion 311d which is a semicircular concave portion supporting the shaft portion 314 at the rear end portion. The insertion groove 311e, which is a groove in which both arm portions 315a of the torsion spring 315 can be inserted, and the hook-shaped portion 311f, which is formed in a hook shape and locks the central portion 315b of the torsion spring 315. A pair of left and right detection pieces 311 gL extending below the bottom plate portion 311a, a right side detection piece 311 gR (see FIG. 15), and a extension extending from the front end portion of the bottom plate portion 311a to the front side by a predetermined amount. A protective lens member 311i, which is arranged above the front end of the bottom plate 311h, has a shape along an arc centered on the shaft 314, and is formed of a light-transmitting material, and a bottom plate. Mainly includes an overhanging convex portion 311j which is projected downward from the central portion in the left-right direction at the front end portion of the 311a.

The bottom plate portion 311a is a portion that comes into contact with the bottom plate portion 321 of the lower frame member 320 on a surface when the tilting device 310 is pushed downward by the player.

The opening 311b is configured as an opening through which the LED device 341f of the drive device 340 and the arm member 345 of the drive device 340 can be inserted.

The shaft portion 311c is a cylindrical member inserted into the guide hole 345b of the arm member 345 (see FIG. 17B) of the drive device 340, and serves as a portion for transmitting a driving force to and from the drive device 340. To be equipped.

The left side detection piece 311 gL and the right side detection piece 311 gR are portions inserted into the detection grooves of the left side detection sensor 324L and the right side detection sensor 324R (see FIG. 15) of the lower frame member 320, respectively, and the left side detection piece 311 gL However, the overhang length is longer than that of the right side detection piece 311 gR.

In the present embodiment, the angle from the tip of the right side detection piece 311 gR to the tip of the left side detection piece 311 gL with respect to the shaft portion 314 is about 3 ° (from the first state (see FIG. 22) to the push-in end (FIG. 22). The left side detection piece 311 gL is projected as compared with the right side detection piece 311 gR so that the tilting device 310 rotates up to (see 23).

The extension portion 311h is a portion that projects from the lower end portion of the protective lens member 311i to the front side, and extends to a position where it is locked to the opening 331 of the upper frame member 330 in the assembled state (see FIG. 10). Consists of aspects.

The protective lens member 311i has a curved shape in the top view (see FIG. 14 (a)) and a curved shape in the left-right direction view (see FIG. 14 (c)), so that the player can use it. The configuration is such that the load when pushing the tilting device 310 is easily released (easy to flow). Thereby, the durability of the tilting device 310 can be improved.

The overhanging convex portion 311j is projected at a right angle from the lower surface of the bottom plate portion 311a and has a cross-sectional shape smaller than that of the transmission hole 321a of the lower frame member 320, and the player pushes the tilting device 310 into operation. In the state (see FIG. 29), it is inserted into the transmission hole 321a and its tip is projected below the lower frame member 320.

As shown in FIG. 16, the lid 312 has a top plate member 312a having an operation surface 312a1, an intermediate plate member 312b fastened and fixed to the lower surface of the top plate member 312a, and the intermediate plate member 312b attached to the top plate member 312a. It is mainly provided with a cylindrical member 312c having a cylindrical shape having a size surrounding the LED device 341f in the first state (see FIG. 6).

The cylindrical member 312c improves the strength of the lid 312 by the rigidity in the axial direction, and in the first state (see FIG. 6), the light emitted from the LED device 341f toward the tilting device 310 is cylindrical due to its positional relationship. While it is fastened to the inside of the member 312c, in the second state (see FIG. 7), it is arranged in such a manner that such limitation is released and the light from the LED device 341f can be irradiated over a wide range.

The lens member 313 is formed of a light-transmitting material, and the upper and lower end portions are extended forward in a flange shape, and the extended end portion is formed in a shape that matches the curved shape of the protective lens member 311i. A spherical shell portion 313a formed from a spherical shell shape is provided in the central portion.

The torsion spring 315 is wound around the shaft portion 314 with a pair of left and right twisted portions, and has both arm portions 315a extending rearward from the left and right outer ends of the twisted portion and a central portion 315b connecting the pair of twisted portions. , Equipped with.

Next, the drive device 340 will be described with reference to FIGS. 17 and 18. 17 (a) is a front view of the drive device 340, FIG. 17 (b) is a side view of the drive device 340 in the direction of arrow XVIIb of FIG. 17 (a), and FIG. 18 is a side view of the drive device 340. It is a front view exploded perspective view of.

As shown in FIGS. 17 and 18, the drive device 340 is a drive motor that is fastened and fixed to a main body member 341 that constitutes a frame by bending a plate-shaped sheet metal member and a driving force that generates a driving force. A pair of disc cams 344 (left disc cam 344L, right disc cam) fixed to both ends of the transmission shaft rod 343 that transmits the driving force of the 342 and its drive motor 342 and the transmission shaft rod 343 so as not to rotate. 344R), the arm member 345 pivotally supported by the connecting pin 344d of the disc cam 344, and the first overhanging portion 344c1 and the second of the disc cam 344 while being pivotally supported by the shaft portion 341c of the main body member 341. The release member 346 that comes into contact with the overhanging portion 344c3 in the rotational direction, the rotary claw member 347 that is pivotally supported by the release member 346 and operates relative to the release member 346, and the rotary claw member 347 are tilted down. A torsion spring-like first spring SP1 which is a coil spring-like spring member that generates an urging force in the direction of causing the force, and a torsion spring-like spring member that generates an urging force in the direction of separating the release member 346 and the rotary claw member 347 from each other. It mainly includes a second spring SP2, which is a spring member.

The main body member 341 is bored at the same position of the motor accommodating portion 341a which is bent rearward on the left and right to form a U-shape in the top view and the plate portion of the motor accommodating portion 341a which is arranged to face each other, and is a disk. A shaft support hole 341b that pivotally supports the cam 344, and a shaft portion 341c that is convex in the left-right direction at a position deviated from the shaft support hole 341b to the front side in a manner having a shaft parallel to the shaft of the shaft support hole 341b. , An extension portion 341d extending from the motor accommodating portion 341a below the shaft portion 341c, an illumination support portion 341e extending forward and upward from the motor accommodating portion 341a, and the illumination support portion 341e thereof. It mainly includes an LED device 341f which is arranged at the upper end and has an LED light source inside.

The LED device 341f has a triangular member on the upper surface thereof, and includes a portion that refracts light (a portion that refracts light). As a result, the light of the LED device 341f can be evenly irradiated upward and forward.

The drive motor 342 includes a fixing member 342a that is fastened and fixed to the motor housing portion 341a inside the U-shape of the motor housing portion 341a.

The fixing member 342a pivotally supports the rotary gear of the drive motor 342 and supports the transmission shaft rod 343 in such a manner that the transmission gear 343b meshes with the rotary gear.

The arm member 345 is bored at one end in a perfect circular shape, and at the shaft support hole 345a axially supported by the connecting pin 344d of the disc cam 344, and at the other end in a rectangular shape. Along with this, a guide hole 345b through which the shaft portion 311c (see FIG. 15) of the tilting device 310 is inserted is mainly provided.

The guide hole 345b is formed at a position where the end on the opposite side of the shaft support hole 345a comes into contact with the shaft portion 311c in the first state of the tilting device 310, and the disc cam 344 makes one or more rotations on the opposite end. It is formed in a position sufficient to be rotatable.

The transmission shaft rod 343 will be described with reference to FIG. FIG. 19 is a front exploded perspective view of the transmission shaft rod 343. The transmission shaft rod 343 has a cylindrical member 343a to which a disc cam 344 (see FIG. 18) is fixed at both ends, and a transmission gear 343b that is pivotally supported by the cylindrical member 343a and meshes with the rotary gear of the drive motor 342. A movable clutch 343c that can switch whether or not to transmit a driving force between the transmission gear 343b and the cylindrical member 343a by axial movement, a coil spring 343d that presses the movable clutch 343c against the transmission gear 343b, and the like. Mainly prepared.

The cylindrical member 343a includes fixing portions 343a1 and 343a2 having a D-shaped cross section for fixing the disc cam 344 at both ends thereof, and the fixing portion 343a2 on the right side is formed longer toward the center side than the fixing portion 343a1 on the left side. NS. Here, in detail, the fixed portion 343a2 is formed with a length capable of moving to a position where the movable clutch 343c does not interfere with the transmission gear 343b when the movable clutch 343c moves against the urging force of the coil spring 343d.

The transmission gear 343b is a clutch in which a perfect circular insertion hole 343b1 through which a cylindrical member 343a is inserted and an unevenness along the axial direction are formed at a circumferential position of the axial center from a surface arranged facing the movable clutch 343c. A unit 343b2 is provided.

Since the insertion hole 343b1 has a perfect circular shape, the transmission gear 343b can rotate (idle) with respect to the cylindrical member 343a even when the cylindrical member 343a is fixed.

The movable clutch 343c has an angle fixing hole 343c1 having a D-shaped cross section through which the cylindrical member 343a is inserted, and irregularities along the axial direction at the circumferential position of the axial center from the surface arranged opposite to the transmission gear 343b. It also includes a clutch portion 343c2 that is configured to be engageable with the clutch portion 343b2.

In the present embodiment, the clutch portions 343b2 and 343c2 are composed of a mountain-shaped convex portion and a concave portion having a top angle of about 100 °.

Since the angle fixing hole 343c1 has a D-shaped cross section, the movable clutch 343c cannot rotate relative to the cylindrical member 343a. Therefore, the clutch portion 343b2 of the transmission gear 343b and the clutch portion 343c2 of the movable clutch 343c are engaged with each other. Therefore, the driving force transmitted from the drive motor 342 to the transmission gear 343b is transmitted to the cylindrical member 343a via the movable clutch 343c. This makes it possible to rotate the disc cam 344 (see FIG. 18) by rotating the drive motor 342.

The movable clutch 343c is usually arranged at a position close to the transmission gear 343b by the urging force of the coil spring 343d, and the engagement relationship between the clutch portions 343b2 and 343c2 is maintained. On the other hand, by applying an axial load to the movable clutch 343c, the movable clutch 343c is configured to be movable along the fixed portion 343a2 so as to be separated from the transmission gear 343b.

The disk cam 344 will be described with reference to FIG. As for the disc cam 344, the left disc cam 344L and the right disc cam 344R have a substantially mirrored shape, and the only difference is the positions of the detection holes 344eL and 344eR, so only the left disc cam 344L. The description of the right disk cam 344R will be omitted.

20 (a) is a side view of the left disk cam 344L in the direction of arrow XXa of FIG. 18, and FIG. 20 (b) is a side view of the left disk cam 344L in the direction of arrow XXb of FIG. be. In addition, in FIG. 20A and FIG. 20B, the state in which the drive device 340 is set to the first initial state is shown as shown in FIG.

As shown in FIGS. 20 (a) and 20 (b), the left disk cam 344L is a member having a portion protruding from both sides of a perfect circular disk, and is at the center position of the disk. A central shaft portion 344a projecting inwardly in a cylindrical shape, a circular rib 344b projecting inwardly as a ring-shaped rib centered on the central shaft portion 344a, and a circular rib 344b outside the circular rib 344b. The engaging rib 344c, which is projected inward as a rib having a height lower than that of the circular rib 344b and has a portion protruding outward in the radial direction at two points, and the outer side between the circular rib 344b and the engaging rib 344c. It mainly includes a connecting pin 344d which is projected in a cylindrical shape in the direction and is connected to an arm member 345 (see FIG. 18), and a detection hole 344eL which is formed in the vicinity of the outer periphery.

The right disk cam 344R differs only in that the detection hole 344eR is arranged at an angle of 60 ° with the detection hole 344eL, and the other components are a mirror image of the shape of the left disk cam 344L. ..

The central shaft portion 344a has a D-shaped cross section in which the inner circumference engages with both ends of the cylindrical member 343a (see FIG. 19), and the outer circumference is fitted into the shaft support hole 341b (see FIG. 18). It is composed. That is, the disk cam 344 is rotatably supported in the shaft support hole 341b.

The circular rib 344b is projected to a position where it can come into contact with the left and right wall surfaces of the motor accommodating portion 341a (see FIG. 18) in a state where the disc cam 344 is pivotally supported by the shaft support hole 341b. As a result, misalignment of the disc cam 344 can be suppressed.

In the first initial state, the engaging rib 344c protrudes outward in the radial direction at a position deviated by 80 ° in the backward rotation direction (clockwise in FIG. 20A) from the position where the detection hole 344eL is arranged. From the overhanging portion 344c1 and the first retracting portion 344c2 and the first overhanging portion 344c1 that retract inward in the radial direction at a position deviated from the first overhanging portion 344c1 by an angle θ1 (angle θ1 = 50 ° in this embodiment). At a position deviated by an angle θ2 (angle θ2 = 150 ° in this embodiment), a second overhanging portion 344c3 that overhangs outward again in the radial direction and an angle θ3 (angle in this embodiment) from the second overhanging portion 344c3. θ3 = 20 °) Mainly provided with a second retractable portion 344c4 that retracts inward in the radial direction at a displaced position.

In the first initial state of the drive device 340, the connecting pin 344d is arranged at a position having the longest separation distance from the shaft portion 311e of the tilting device 310 in the first state (see FIG. 22). That is, the connecting pin 344d is arranged on the opposite side of the shaft portion 311e of the tilting device 310 in the first state with respect to the central shaft portion 344a.

The release member 346 and the rotary claw member 347 will be described with reference to FIG. Since the release member 346 and the rotary claw member 347 are arranged in pairs on the left and right, and their configurations are the same on the left and right, only one of them will be described.

21 (a) and 21 (b) are front views of the release member 346 and the rotary claw member 347. Note that FIG. 21 (a) shows a large angle state in which the rotary claw member 347 rotates to the end position in the urging direction of the second spring SP2 with respect to the release member 346, and FIG. 21 (b) shows the release member 346. On the other hand, a small angle state in which the rotary claw member 347 rotates to the terminal position against the urging force of the second spring SP2 is shown.

The state in which the release member 346 is rotated by being brought into contact with the disk cam 344 is a state between a large angle state and a small angle state (the convex pin 346b is arranged at an intermediate position of the guide slot 347b). (See FIG. 35).

As shown in FIGS. 21 (a) and 21 (b), the release member 346 is formed of a substantially rectangular plate member and is pivotally supported by a shaft portion 341c (see FIG. 18) with a shaft support hole 346a. From the convex pin 346b which is formed in an arc shape centered on the central axis of the shaft support hole 346a in the plate thickness direction, the insertion hole 346c into which the end of the second spring SP2 is inserted, and the shaft support hole 346a. It mainly includes an engaging portion 346d formed as a portion overhanging with the maximum diameter.

The engaging portion 346d is a portion configured to be in contact with the engaging rib 344c (see FIG. 20) of the disk cam 344 in the assembled state (see FIG. 10). In the present embodiment, since the outer circumference of the engaging portion 346d is formed to be curved, the contact with the engaging rib 344 can be smoothly performed.

The rotary claw member 347 is formed of a substantially rectangular plate member, and has a shaft support hole 347a pivotally supported by a shaft portion 341c (see FIG. 18) and an arc shape centered on the central axis of the shaft support hole 347a. A guide elongated hole 347b (drilled with a size that includes the movement locus of the convex pin 346b inside) and an end of the second spring SP2 are bored along the convex pin 346b of the release member 346 so as to be guideable. It is possible to insert the insertion hole 347c through which the portion is inserted, the hook-shaped portion 347d which is projected downward in a hook shape at the opposite end of the shaft support hole 347a, and the end of the first spring (see FIG. 18). It is mainly provided with a pull-down hole 347e drilled in the.

In the present embodiment, the release member 346 is arranged at the terminal position in the backflip direction (clockwise direction in FIG. 21A) with respect to the rotary claw member 347 in the large angle state shown in FIG. 21A. Therefore, when a load in the pushing-down direction is applied to the engaging portion 346d in the large angle state, the release member 346 and the rotary claw member 347 are integrally rotated in the backward rotation direction, while the engaging portion is in the large angle state. When a load in the push-up direction is applied to the 346d, only the release member 346 can be rotated to maintain the posture of the rotary claw member 347 until the angle is small as shown in FIG. 21B.

Next, an operation example of the operation device will be described. First, with reference to FIGS. 22 to 24, an operation example in which the player pushes in the tilting device 310 in the first state will be described. In the following description of the operation example, the illustration of the lid 312 is simplified for easy understanding.

22 to 24 are cross-sectional views of the operating device 300 in line XXII-XXII of FIG. 6A. Note that FIG. 22 shows a state in which the tilting device 310 is in the first state, and FIG. 23 shows a state in which the player pushes the tilting device 310 to the terminal position from the state shown in FIG. 22. FIG. 24 Then, the state after the tilting device 310 returns from the state of FIG. 23 to the first state is shown. Further, in FIGS. 22 to 24, an example of a player's hand that repeatedly strikes the tilting device 310 is shown.

As shown in FIG. 22, the tilting device 310 receives an urging force in the backward rotation direction (clockwise in FIG. 22) by the torsion spring 315, and the bottom plate portion 311a is hooked on the hook-shaped portion 347d of the rotary claw member 347. As a result, the tilting device 310 is maintained in the posture in the first state. That is, in the first state, an urging force in the backflip direction (clockwise in FIG. 22) is constantly acting on the tilting device 310.

In the state shown in FIG. 22, the left side detection piece 311 gL is inserted into the detection groove of the left side detection sensor 324L (ON state), while the right side detection piece 311 gR is arranged in front of the detection groove of the right side detection sensor 324R. (OFF state, see FIG. 11).

As shown in FIG. 23, when the player pushes the tilting device 310, the tilting device 310 rotates about 3 ° in the forward rotation direction (counterclockwise in FIG. 23). In this state, the left side detection piece 311 gL is inserted into the detection groove of the left side detection sensor 324L (ON state), and similarly, the right side detection piece 311 gR is inserted into the detection groove of the right side detection sensor 324R (ON state).

Therefore, by determining the change in the detection state of the left side detection sensor 324L and the right side detection sensor 324R, it can be determined that the tilting device 310 has been pushed by the player from the first state.

Here, when the tilting device 310 is repeatedly hit, the state shown in FIG. 22 and the state shown in FIG. 23 are alternately repeated, but depending on the time interval in which the player repeatedly hits, the tilting device 310 by the torsion spring 315 is used. The return of the spring is not in time, and the pushing operation is performed at a halfway position, which may cause the player to feel a sense of discomfort.

Conventionally, it was possible to deal with this by increasing the spring constant of the torsion spring 315, but in the present embodiment, when the spring constant of the torsion spring 315 is increased, the tilting device 310 resists the urging force of the torsion spring 315. It is necessary to increase the driving force of the driving motor 342 that pushes down (see FIG. 18), and it is necessary to increase the size of the driving motor 342. Therefore, there are problems that the product cost rises and the space cannot be saved.

On the other hand, in the present embodiment, in the state where the tilting device 310 is pushed in, a voice coil motor 352 capable of producing an effect by vibration operation is arranged at a position facing the overhanging convex portion 311j of the tilting device 310. NS.

As shown in FIG. 24, by driving the voice coil motor 352 in the extension direction from the state shown in FIG. 23, the tilting device 310 can be quickly returned without increasing the spring constant of the torsion spring 315. can.

Here, when the voice coil motor 352 is always driven when the tilting device 310 is pushed in, for example, when the player presses and holds the tilting device 310 for a long time, the voice coil motor 352 is driven, and the player is informed. Since it gives an unnecessary load, the player may feel uncomfortable.

On the other hand, in the present embodiment, when the left side detection sensor 324L is in the ON state, the number of times the right side detection sensor 324R is switched between the ON state and the OFF state is calculated in a predetermined period, and when the number of times is equal to or greater than the threshold value, the voice coil is used. By driving the motor 352, it is possible to improve the load for returning the tilting device 310 only when the player repeatedly strikes. As a result, the player can comfortably operate the tilting device 310.

Next, a case (first operation mode) in which the tilting device 310 starts a reciprocating operation (fanning operation) up and down from the first state will be described with reference to FIGS. 25 to 30. 25 to 30 are cross-sectional views of the operating device 300 in line XXII-XXII of FIG. 6A.

Note that FIG. 25 shows a state in which the tilting device 310 is in the first state, and FIG. 26 shows that the disk cam 344 rotates in the forward rotation direction by a predetermined amount from the state shown in FIG. 25, and the rotary claw member 347 rotates. The state in which the posture has changed is shown, and FIG. 27 shows a state in which the disc cam 344 rotates in the forward rotation direction by a predetermined amount from the state shown in FIG. 26 and the posture of the rotary claw member 347 returns. A state in which the tilting device 310 reciprocates and rotates is shown. FIG. 29 shows a state in which the player pushes the tilting device 310 to the terminal position from the state shown in FIG. 28, and FIG. 30 shows a circle from the state shown in FIG. 29. A state in which the plate cam 344 rotates in the forward rotation direction by a predetermined amount to reach the second initial state in which the second overhanging portion 344c3 of the engaging rib 344c comes into contact with the engaging portion 346d of the release member 346. Is illustrated. Further, in FIG. 28, the position of the tilting device 310 in the state of FIG. 27 is illustrated by an imaginary line, and in FIG. 29, an example of a player's hand pushing and operating the tilting device 310 is illustrated by an imaginary line.

As shown in FIG. 25, when the tilting device 310 is in the first state, the upper end portion (prism portion) of the LED device 341f is housed inside the cylindrical member 312c of the lid 312. Therefore, while the amount of light emitted in the radial direction of the cylindrical member 312c is suppressed by the thickness of the cylindrical member 312c, the amount of light emitted in the axial direction can be largely secured. As a result, the cylindrical member 312c can have the effect of improving the intensity as a rib of the lid 312 and the effect of adjusting the light irradiation intensity of the LED device 341f in the first state of the tilting device 310.

As shown in FIG. 26, from the state shown in FIG. 25 in which the tilting device 310 is in the first state and the driving device 340 is in the first initial state, the disk cam 344 is rotated forward (counterclockwise in FIG. 26). When rotated in the direction), the first overhanging portion 344c1 of the disk cam 344 pushes down the engaging portion 346d of the releasing member 346, so that the releasing member 346 rotates in the backward rotation direction (clockwise in FIG. 26). Along with this, the rotary claw member 347 rotates in the backward rotation direction to a position where the tilting device 310 is disengaged from the bottom plate portion 311a.

The posture change of the release member 346 is continued until the disc cam 344 is rotated until the first retractable portion 344c2 of the engaging rib 344c and the engaging portion 346d face each other, so that the tilting device 310 twists during that time. It rises due to the urging force of the spring 315 (rotates clockwise in FIG. 26).

At this time, in the states of FIGS. 25 and 26, the shaft portion 311c of the tilting device 310 is arranged at one end position of the guide hole 345b of the arm member 345 (the end position on the side far from the rotation axis of the disk cam 344). Since the movement of the tilting device 310 in the ascending direction is regulated by the arm member 345, the ascending operation of the tilting device 310 becomes an operation mode corresponding to the rotation angle of the disk cam 344.

As shown in FIG. 27, when the disc cam 344 rotates in the forward rotation direction (counterclockwise direction in FIG. 27) and the first retractable portion 344c2 of the disc cam 344 passes through the engaging portion 346d of the release member 346, Due to the urging force of the first spring SP1, the release member 346 and the rotary claw member 347 rotate in the forward rotation direction (counterclockwise direction in FIG. 27), and the rotary claw member 347 can engage with the tilting device 310 (FIG. 27). Return to the state shown in 25). At this time, since the urging force of the second spring SP2 acts in the direction of increasing the angle between the release member 346 and the rotary claw member 347 (the upper angle in FIG. 27), the release member 346 and the rotary claw member The 347 rotates while maintaining the state shown in FIG. 26 (large angle state).

In this state, the lid 312 retracts above the LED device 341f, and the area in which the protective lens member 311i can be seen from the player's point of view increases as compared with the tilting device 310 in the first state. , The light of the LED device 341f can be irradiated in the front direction (direction toward the player) as well. Therefore, by changing the posture of the tilting device 310, the traveling direction of the light emitted from the LED device 341f can be changed, and the effect of producing the light can be improved.

In this state, the right side detection sensor 353R of the protective cover device 350 is turned on, and the start point of the vertical reciprocating operation can be detected.

As shown in FIG. 28, the disk cam 344 is rotated in the forward rotation direction (counterclockwise in FIG. 28) by a predetermined amount from the state shown in FIG. 27, and then the disk cam 344 is rotated by the same amount in the backward rotation direction (counterclockwise in FIG. 28). By repeating the operation of rotating clockwise (FIG. 28), the tilting device 310 can be repeatedly operated up and down within the range of the angle D1 shown in FIG. 28. As a result, the appearance of the tilting device 310 to the player can be changed, and the player's attention to the operating device 300 can be improved.

Further, the area of the portion protruding above the upper frame member 331 of the protective lens member 313 changes in response to the operation of the tilting device 310 repeatedly operating up and down within the range of the angle D1. Therefore, among the light emitted from the LED device 341f, the amount of light that can be visually recognized through the protective lens member 313 can be changed according to the operation of the tilting device 310. Therefore, the brightness of the tilting device 310 can be changed, and the player's attention to the operating device 300 can be improved.

In the state shown in FIG. 28, since the spherical shell portion 313a of the lens member 313 is arranged on the front side (left side of FIG. 28) of the LED device 341f, the irradiation range of the light emitted from the LED device 341f is set in the front-rear direction. It can be expanded not only in the vertical direction but also in the horizontal direction (vertical direction on the paper in FIG. 28).

According to the present embodiment, as described above, when the tilting device 310 is arranged in the first state, the light of the LED device 341f travels upward, and the irradiation range thereof is narrowed by the cylindrical member 312c. (See FIG. 25). On the other hand, when the tilting device 310 ascends from the first state, the light of the LED device 341f is also irradiated in the direction toward the player (front direction), and the irradiation range is expanded by the lens member 313.

That is, according to the present embodiment, not only the light irradiation direction can be changed but also the light irradiation range can be changed at the same time as the posture of the tilting device 310 is changed. Thereby, the degree of attention of the tilting device 310 can be improved.

As shown in FIG. 29, in the state where the tilting device 310 is moving up and down in FIG. 28, the player can push the tilting device 310 into operation. In the state of FIG. 28, the load given from the arm member 345 to the tilting device 310 is only the load in the direction of lowering the tilting device 310 (even if the arm member 345 moves in the ascending direction, the shaft portion 311c Only moves through the guide hole 345b of the arm member 345, and no load is generated).

Therefore, when the player pushes the tilting device 310 in the state of FIG. 28, it is possible to prevent the player from being subjected to a load due to the driving force of the drive motor 342 (see FIG. 18). At this time, the player is given only the load due to the urging force of the torsion spring 315. As a result, when the player pushes the tilting device 310 into operation, it is possible to prevent a large load from being generated on the player, so that the player can comfortably operate the operation device 300.

As shown in FIG. 29, in the process from the state shown in FIG. 28 to the pushing end of the tilting device 310, the bottom plate portion 311a of the tilting device 310 pushes the hook-shaped portion 347d of the rotary claw member 347 to push the rotary claw. When the member 347 rotates in the backward rotation direction (clockwise in FIG. 29) and the bottom plate portion 311a passes through the hook-shaped portion 347d by subsequently pushing the tilting device 310, the rotating claw member 347 becomes the tilting device 310. Return to the engageable position (rotate in the forward rotation direction). Therefore, the tilting device 310 is restricted from moving in the ascending direction by the rotating claw member 347.

Therefore, the tilting device 310 can be maintained in the first state when the player releases the tilting device 310 after the player pushes down the tilting device 310 from the state in which the tilting device 310 is moved up and down as shown in FIG. 28. ..

In the state shown in FIG. 29, the voice coil motor 352 performs a vibration operation (an operation of repeating movement in the extension direction and movement in the contraction direction). As a result, it is possible to perform an effect of transmitting vibration to the player who keeps his / her hand on the tilting device 310 after pushing the tilting device 310 to the end.

That is, the purpose of the voice coil motor 352 is to generate a driving force that assists the tilting device 310 to rise (see FIG. 24), and the purpose of vibrating the tilting device 310 arranged at the push-in end position to produce a vibration effect. Can be used for.

As shown in FIG. 30, when the player releases the tilting device 310 and the tilting device 310 returns to the first state, the overhanging convex portion 311j of the tilting device 310 is attached to the lower frame member 320. It is buried in the lower surface and the contact with the voice coil motor 352 is released. Therefore, the vibration effect is effective only when the player pushes the tilting device 310 toward the end.

Therefore, as compared with a gaming machine in which the operation buttons simply vibrate, the player who pushes the tilting device 310 to determine whether or not vibration is generated by the voice coil motor 352 at the pushing end when the tilting device 310 is pushed in. Can only be grasped.

Here, whether or not the lottery is a big hit does not depend on the pushing operation of the tilting device 310. Therefore, depending on the player, there is a possibility that the tilting device 310 is not operated at all, and in that case, the value of the tilting device 310 as an operating means is lowered.

On the other hand, in the present embodiment, the player can feel the vibration of the voice coil motor 352 for the first time by pushing the tilting device 310.

Here, for example, by controlling the voice coil motor 352 to vibrate when the jackpot is confirmed, it is possible to improve the expectation when the player pushes the tilting device 310 and operates the tilting device 310. It is possible to improve the value as a look-ahead means. As a result, the player can easily operate the tilting device 310, and the value of the tilting device 310 as an operating means can be increased.

As shown in FIG. 30, from the state shown in FIG. 29, the disc cam 344 is rotated forward in the forward rotation direction until the second overhanging portion 344c1 abuts on the engaging portion 346d of the disengaging member 346 (FIG. 29). By rotating the drive device 340 by a predetermined amount in the clockwise direction), the drive device 340 can be brought into the second initial state.

The second initial state is a state in which the engaging rib 344c and the release member 346 come into contact with each other in the rotational direction, as in the first initial state. In the first initial state, the first overhanging portion 344c1 comes into contact with the engaging rib 344c, while in the second initial state, the second overhanging portion 344c3 and the engaging rib 344c come into contact with each other.

From the state of FIG. 29, the disk cam 344 is rotated in the backward rotation direction (clockwise direction in FIG. 29), and after the first overhanging portion 344c1 of the engaging rib 344c passes through the engaging portion 346d, it rotates in the reverse direction. The drive device 340 can be returned from the state shown in FIG. 29 to the first initial state shown in FIG. In this case, a load in the direction of pushing up the release member 346 is applied to the release member 346, and only the release member 346 can be rotated in the forward rotation direction (counterclockwise direction in FIG. 29) while maintaining the posture of the rotary claw member 347. can.

Next, referring to FIGS. 31 to 34, when the tilting device 310 is moved up and down (fanning operation) from the state where the tilting device 310 is in the first state and the driving device 340 is in the second initial state ( The second operation mode) will be described. In this case, the tilting device 310 starts a motion of reciprocating up and down (fanning motion) through the second state.

31 to 34 are cross-sectional views of the operating device 300 in line XXII-XXII of FIG. 6A. In FIG. 31, the disc cam 344 is rotated in the forward rotation direction (counterclockwise in FIG. 31) from the state shown in FIG. 30, and the release member 346 and the rotary claw member 347 are rotated in the backward rotation direction (clockwise in FIG. 31). In FIG. 32, the state in which the disk cam 344 is rotated by a predetermined amount and the tilting device 310 reaches the second state from the state shown in FIG. 31 is shown, and in FIG. 33, the state shown in FIG. 32 is shown. A state in which the disk cam 344 reciprocates and rotates is shown, and FIG. 34 shows a state in which the player pushes the tilting device 310 to the terminal position from the state shown in FIG. 33. Further, in FIG. 33, the position of the tilting device 310 in the state of FIG. 32 is illustrated by an imaginary line, and in FIG. 34, an example of a player's hand for pushing and operating the tilting device 310 is illustrated by an imaginary line.

As shown in FIG. 31, when the disk cam 344 is rotated in the forward rotation direction (counterclockwise in FIG. 31) from the state shown in FIG. 30, the engagement between the rotary claw member 347 and the tilting device 310 is released, and the disc cam 344 is tilted. The device 310 operates in the ascending direction.

At this time, since the guide hole 345b of the arm member 345 extends (has a space) in the direction in which the shaft portion 311c of the tilting device 310 moves, the tilting device 310 passes through the arm member 345 to the disk cam 344. The tilting device 310 can be raised with low resistance without being pulled by the tilting device 310, and the tilting device 310 can be changed from the first state to the second state in a short time.

As shown in FIG. 32, the posture of the disc cam 344 is tilted by rotating the disc cam 344 by about 10 degrees from the state shown in FIG. 31 (the state in which the tilting device 310 and the rotary claw member 347 are disengaged). The posture of the 310 can be arranged in the second state (the posture in which the disk cam 344 is rotated by 180 ° from the first initial state). Therefore, when the tilting device 310 rises at a high speed and the tilting device 310 tries to reach the second state from the state of FIG. 30 in a short period of time, the disk cam 344 interferes with the state change (disk). It is possible to prevent the cam 344 from rotating slowly by a predetermined angle and taking a long time until the tilting device 310 is in the second state).

As shown in FIG. 33, the disk cam 344 is rotated in the forward rotation direction (counterclockwise in FIG. 32) by a predetermined amount from the state shown in FIG. 32, and then the disk cam 344 is rotated by the same amount in the backward rotation direction (counterclockwise direction in FIG. 32). By repeating the operation of rotating clockwise (FIG. 32), the tilting device 310 can be repeatedly operated up and down within the range of the angle D2 shown in FIG. 33. As a result, the appearance of the tilting device 310 to the player can be changed, and the player's attention to the operating device 300 can be improved.

Further, the area of the portion protruding above the upper frame member 331 of the protective lens member 313 changes in response to the operation of the tilting device 310 repeatedly operating up and down within the range of the angle D2. Therefore, among the light emitted from the LED device 341f, the amount of light that can be visually recognized through the protective lens member 313 can be changed according to the operation of the tilting device 310. Therefore, the brightness of the tilting device 310 can be changed, and the player's attention to the operating device 300 can be improved.

In the state shown in FIG. 33, since the spherical shell portion 313a of the lens member 313 is arranged on the front side (left side of FIG. 33) of the LED device 341f, the irradiation range of the light emitted from the LED device 341f is set in the front-rear direction. It can be expanded not only in the vertical direction but also in the horizontal direction (vertical direction on the paper in FIG. 33).

That is, according to the present embodiment, not only the light irradiation direction can be changed but also the light irradiation range can be changed at the same time as the posture of the tilting device 310 is changed. Thereby, the degree of attention of the tilting device 310 can be improved.

The range of the angle D2 shown in FIG. 33 is different from the range of the angle D1 shown in FIG. 28. That is, in the present embodiment, as an aspect of the vertical movement of the tilting device 310, two types of vertical movements (fanning movements), that is, the vertical movement shown in FIG. 28 and the vertical movement shown in FIG. 33, are tilted by the rotating claw member 347. This can be done immediately after the restriction on the ascending movement of the device 310 is lifted. Therefore, it is possible to create two types of modes in which the tilting device 310 in the first state is operated by the driving force of the driving motor 342.

As a result, the operating member 310 can have a different meaning (for example, a difference in the expectation of the jackpot) in the operation mode as compared with the case where the operating member 310 performs the same operation each time, and the player pays attention to the tilting device 310. The degree can be improved.

As shown in FIG. 33, in the state where the tilting device 310 is moving up and down in FIG. 32, the player can push the tilting device 310 into operation. In the state of FIG. 33, the load given from the arm member 345 to the tilting device 310 is only the load in the direction of pulling down the tilting device 310 (even if the arm member 345 moves in the upward direction, the shaft portion The 311c only moves through the guide hole 345b of the arm member 345, and there is no load for lifting the shaft portion 311c from the arm member 345).

Therefore, when the player pushes the tilting device 310 in the state of FIG. 33, it is possible to prevent the player from being subjected to a load due to the driving force of the drive motor 342 (see FIG. 18). At this time, the player is given only the load due to the urging force of the torsion spring 315. As a result, when the player pushes the tilting device 310 into operation, it is possible to prevent a large load from being generated on the player, so that the player can comfortably operate the operation device 300.

As shown in FIG. 34, in the process of pushing the tilting device 310 into operation, the bottom plate portion 311a of the tilting device 310 pushes the hook-shaped portion 347d of the rotary claw member 347, so that the rotary claw member 347 rotates backward. When the bottom plate portion 311a passes through the hook-shaped portion 347d by rotating in the direction (clockwise in FIG. 34) and subsequently pushing the tilting device 310. The rotary claw member 347 returns to a position where it can engage with the tilting device 310 (rotates in the forward rotation direction). Therefore, the tilting device 310 is restricted from moving in the ascending direction by the rotating claw member 347.

Therefore, when the player releases the tilting device 310 after the player pushes down the tilting device 310 from the state in which the tilting device 310 shown in FIG. 33 is moved up and down (see FIG. 34), the tilting device 310 is put into the first state. Can be maintained.

Next, with reference to FIGS. 35 to 37, the operation of setting the disc cam 344 to the second initial state after the player push-in operation without releasing the regulation of the tilting device 310 by the rotating claw member 347 will be described. do. By this method, it is possible to alternately perform two types of vertical movements (fanning movements) of the tilting device 310, or to continuously perform one of them.

35 to 37 are cross-sectional views of the operating device 300 in line XXII-XXII of FIG. 6A. In FIG. 35, a state in which the disk cam 344 is rotated in the backward rotation direction (clockwise in FIG. 35) and the release member 346 is rotated in the forward rotation direction (counterclockwise in FIG. 35) from the state shown in FIG. 34 is shown. In FIG. 36, after the rotary cam 344 rotates in the backward rotation direction (clockwise in FIG. 35) more than the state shown in FIG. 35, the forward rotation direction is reached until the disc cam 344 comes into contact with the engaging portion 346d of the release member 346. The state of rotation (counterclockwise in FIG. 35) is shown, and in FIG. 37, the disk cam 344 rotates in the forward rotation direction (counterclockwise in FIG. 36) from the state shown in FIG. 36 to detect the left side of the protective cover device 350. The state in which the sensor 353L is turned on is illustrated. In addition, in FIGS. 35 to 37, an example of a player's hand swinging from above on the tilting device 310 is illustrated by an imaginary line.

As shown in FIG. 35, when the disk cam 344 is rotated in the backflip direction (clockwise in FIG. 34) from the state shown in FIG. 34, the second retractable portion 344c4 of the engaging rib 344c becomes the engaging portion of the releasing member 346. It comes into contact with 346d. In this case, the posture of the release member 346 is changed by the engaging rib 344c pushing up the release member 346, but the convex pin 346b of the release member 346 moves in the space portion of the guide slot 347b of the rotary claw member 347. The rotating claw member 347 stays and is maintained in the posture shown in FIG. 35.

That is, in the process of further rotating the disk cam 344 in the backward rotation direction (clockwise in FIG. 35) from the state shown in FIG. 35 to disengage the engaging rib 344c and the disengaging member 346, the rotating claw member 347 is used. The regulation of the rise of the tilting device 310 can be maintained.

From the state shown in FIG. 35, the disc cam 344 is further rotated in the backward rotation direction (clockwise in FIG. 35), and then the rotary cam 344 is continuously rotated in the forward rotation direction (counterclockwise in FIG. 35). As shown in, the drive device 340 can be in the second initial state.

In the present embodiment, since there is no sensor for detecting the second initial state, it is difficult to accurately stop the disk cam 344 in the state shown in FIG. 36, but the disk cam 344 passes through the second initial state shown in FIG. It is possible. Therefore, by operating the disk cam 344 from the state shown in FIG. 36, it is possible to perform the vertical movement (fanning operation) from the second initial state in the range of the angle D2 as described above.

Here, the player who pushes the tilting device 310 may perform an operation of keeping his / her hand on the tilting device 310 after the pushing operation even if a special display such as "long press" is not displayed. be.

This is an operation that occurs, for example, by pushing the tilting device 310 too much to concentrate on the effect and forgetting to release the operated hand. In this case, the tilting device 310 rises even if the regulation by the rotating claw member 347 is released. Therefore, even if the disk cam 344 performs a reciprocating operation (forward / reverse switching operation) for moving the tilting device 310 up and down (fanning operation) within the range of the angle D2, the posture of the tilting device 310 can be changed. Can not. In this case, the rotation of the drive motor 342 is wasted, and if the rotation can be omitted, the life of the drive motor 342 can be extended.

Therefore, in the present embodiment, the left side detection sensor 324L (see FIG. 15) of the lower frame member 320 is turned on in the state where the disk cam 344 is rotated in the forward rotation direction (counterclockwise in FIG. 36) from the state shown in FIG. While the state is maintained (while the tilting device 310 tilts to the first state or lower), the disk cam 344 is not rotated in the reverse direction, and as shown in FIG. 37, the left side detection sensor 353L of the protective cover device 350 (See FIG. 14) is controlled in a mode in which the rotation of the disk cam 344 is stopped (the drive of the drive motor 342 is stopped) in the first initial state of the drive device 340 in which the drive device 340 is turned on.

In the states shown in FIGS. 36 and 37, the tilting device 310 does not rise due to the player's hand being placed on the upper side of the tilting device 310. In this case, the state shown in FIG. 36 to the state shown in FIG. 37 The change occurs by rotating the drive motor 342 in one direction.

Therefore, as shown in FIGS. 35 to 37, the drive motor 342 is reciprocated (forward / reverse switching) until the player's hand is continuously placed on the upper side of the tilting device 310 and the tilting device 310 cannot be moved up and down. Operation) can be avoided, the load on the drive motor 342 can be reduced, and the motor life can be extended.

When the left side detection sensor 324L (see FIG. 15) is maintained in the ON state when the disk cam 344 is rotated by a predetermined amount (to the state shown in FIG. 31) from the state shown in FIG. 36, it is a circle as it is. Instead of rotating the plate cam 344, it may be controlled to immediately reversely rotate the plate cam 344 to return to the state shown in FIG. As a result, the drive device 340 can be returned to the second initial state at an early stage, and an unnecessary load is not applied to the drive device 340, so that the motor life of the drive motor 342 (see FIG. 18) can be extended.

A device for preventing the destruction of the drive device 340 will be described with reference to FIGS. 38 and 39. FIG. 38 is a cross-sectional view of the operating device 300 on the XXII-XXII line of FIG. 6A, and FIG. 39 is a partial cross-sectional view of the operating device 300 on the XXXIX-XXXIX line of FIG. 38. In FIG. 38, the player's hand that grips and fixes the tilting device 310 in the state where the tilting device 310 is in the second state is illustrated by an imaginary line, and in FIG. 39, the upper member of the main body cover 351 is illustrated. Omitted.

As shown in FIG. 38, when the player grabs and fixes the tilting device 310, the movement of the arm member 345 is restricted, so that the disk cam 344 cannot be rotated from the state of FIG. 38. Therefore, when the drive motor 342 (see FIG. 39) starts to rotate, a high load is generated between the drive motor 342 and the transmission gear 343b, and if left unattended, the drive motor 342 (see FIG. 18) may break down. be.

On the other hand, in the present embodiment, since the transmission gear 343b is configured to be idle with respect to the transmission shaft rod 343a fixing the disk cam 344, it is possible to prevent the drive motor 342 from failing.

That is, as shown in FIG. 39, the drive motor 342 starts driving with the disk cam 344 fixed, and the transmission gear 343b is urged in the rotational direction, so that the clutch portions 343b2 and 343c2 are used. Power is transmitted, and the movable clutch 343c moves in a direction away from the transmission gear 343b. As a result, the engagement between the transmission gear 343b and the movable clutch 343c can be released, and the transmission gear 343b can be idled. This makes it possible to prevent the drive motor 342 from failing.

If the player does not grasp the tilting device 310, the tilting device 310 goes through the first state if the disk cam 344 is rotated once due to the configuration of the operating device 300. Therefore, in the present embodiment, when the left side detection sensor 324L of the lower frame member 320 is not turned on while the drive motor 342 is rotated by a predetermined angle (for example, 360 °) (when the tilting device 310 is not in the first state). In addition, it is determined that the player intentionally performs an unnecessary operation of gripping and fixing the tilting device 310, and the third symbol display device 81 is notified to stop the gripping operation, for example. While doing so, the rotation of the drive motor 342 is stopped.

As a result, it is possible to select a case where the player intentionally performs an erroneous operation and notify that the erroneous operation is stopped only at that time, and stop the drive motor 342 at an early stage to prevent a failure. be able to.

When the transmission gear 343b and the movable clutch 343c are separated from each other to cause a phase shift, the initial phase of the drive motor and the initial phase of the disk cam 344 having the same phase as the movable clutch 343c are shifted. Therefore, if the drive motor 342 is continuously controlled (by the number of steps or the like) from the state before the phase shift occurs, the disk cam 344 cannot be operated accurately (the phase shift cannot be corrected).

On the other hand, in the present embodiment, it is possible to identify that the drive device 340 is in the first initial state by detecting that the left side detection sensor 353L of the protective cover member 350 is in the ON state. By restarting the control of the drive motor 352 (resetting the initial phase of the drive motor 342) with that state as the initial position, even after the phase shift occurs between the transmission gear 343b and the movable clutch 343c. The control can be performed in a state where the phase of the drive motor 342 and the phase of the disk cam 344 are realigned.

As a result, when the effect is produced by operating the tilting device 310, there is a discrepancy between the operation of the tilting device 310 due to the rotation control of the drive motor 342 and the operation actually performed by the tilting device 310. It is prevented from occurring. Therefore, even after the phase shift occurs between the transmission gear 343b and the movable clutch 343c, the tilting device 310 can be properly operated to produce an effect.

Here, as shown in FIG. 39, the movable clutch 343c is configured to idle with respect to the transmission gear 343b regardless of the rotation direction of the transmission gear 343b. The necessity will be described below.

40, 41, 42 and 43 are cross-sectional views of the operating device 300 in line XXII-XXII of FIG. 6 (a). Note that FIG. 40 shows a state in which the disk cam 344 is rotated 180 degrees in the forward rotation direction (arrow CCW direction) from the state shown in FIG. 38, and FIG. 41 shows a state in which the disk cam is further rotated from the state shown in FIG. 40. The state in which 344 is rotated in the direction of the arrow CCW is shown. Further, FIG. 42 shows a state in which the disk cam 344 is rotated 180 degrees in the backward rotation direction (arrow CW direction) from the state shown in FIG. 38, and FIG. 43 shows a state in which the disk cam is further rotated from the state shown in FIG. 42. The state in which 344 is rotated in the direction of arrow CW is shown.

As shown in FIG. 41, when the disk cam 344 rotates in the direction of the arrow CCW, the tilting device 310 moves upright toward the second state via the first state shown in FIG. 40. On the other hand, as shown in FIG. 43, when the disk cam 344 rotates in the direction of the arrow CW, the tilting device 310 is configured to maintain the first state shown in FIG. 42.

This is not only due to the fact that the engaging rib 344c operates in a manner of separating from the release member 346 as the state shown in FIG. 42 shifts to the state shown in FIG. 43, but the disk cam 344 rotates in the direction of the arrow CW. In this case, even if the engaging rib 344c comes into contact with the release member 346, the fixing by the rotary claw member 347 is not released. That is, when the disk cam 344 rotates in the direction of the arrow CW, the engaging rib 344c abuts on the disengaging member 346 from below, but in this case, the disengaging member 346 is lifted by the engaging rib 344c, and the rotating claw No load is generated in the direction of pushing up the member 347. Therefore, the fixing by the rotating claw member 347 is not released.

Here, when the operation of the tilting device 310 is viewed from the player's point of view, both of the first states shown in FIGS. 38 to 40 and 42 appear to be the same operation, and the subsequent movements after the first state is reached. Is a different operation of either FIG. 41 or FIG. 43.

For example, a difference in operation after the tilting device 310 reaches the first state may be generated by controlling the drive motor 342 (see FIG. 39), but the drive noise due to the change in the rotation speed of the drive motor 342 may be generated. Due to the difference in the change, the player may notice the mode of control being performed, and the player may be aware of the effect to be executed in the future, which may discourage the player's interest. Further, when the operation of suddenly stopping the tilting device 310 is performed by suddenly stopping the drive motor 342, the load applied to the drive motor 342 becomes large, and the durability of the drive motor 342 may decrease.

On the other hand, according to the present embodiment, when the tilting device 310 moves from the state shown in FIG. 38 toward the first state and the subsequent operation of the tilting device 310 is changed, the rotation of the drive motor 342 is changed. Since the directions are different only, it is possible to make it difficult for the player to grasp the rotation direction depending on the driving mode (vibration, sound, etc.). Therefore, for example, when the expectation of the effect changes depending on whether the tilting device 310 rises from the first state or the tilting device 310 is maintained in the first state, the tilting device 310 is operating toward the first state. In addition, it is possible to prevent the player from grasping the change in the degree of expectation. As a result, it is possible to improve the attention to the operation of the tilting device 310.

On the other hand, when the tilting device 310 reaches the first state and the drive motor 342 further rotates, the player confirms whether the tilting device 310 rises or maintains the first state, so that the player can produce the effect. Since the change in the degree of expectation can be grasped, the movement of the tilting device 310 when the tilting device 310 is in the second state (see FIG. 38) and is moved toward the first state by the drive motor 342 for the player. You can make them watch over.

That is, when the tilting device 310 is in the second state, it is possible to prevent the player from gripping the tilting device 310. Therefore, when the drive motor 342 is driven, the player erroneously operates the tilting device 310 and the drive. It is possible to prevent the device 340 from being overloaded.

Further, since it is not necessary to suddenly stop the drive motor 342 (see FIG. 39) in order to perform the effect of suddenly stopping the tilting device 310, the burden given to the drive motor 342 when the drive motor 342 is suddenly stopped is eliminated. This makes it possible to improve the durability of the drive motor 342.

Next, with reference to FIG. 44, even when the player pushes down the tilting device 310, the tilting device 310 moves up and down without being restricted by the rotating claw member 347 (third operation mode). explain.

FIG. 44 is a cross-sectional view of the operating device 300 in line XXII-XXII of FIG. 6A. In addition, in FIG. 44, a state in which the disk cam 344 is rotated in a predetermined amount forward rotation direction (counterclockwise in FIG. 44) from the first initial state (see FIG. 25) of the drive device 340 is shown, and the first state is shown. The outer shape of the tilting device 310 after rotating the disk cam 344 in the backward rotation direction (clockwise in FIG. 44) at an angle at which the overhanging portion 344c1 does not pass through the engaging portion 346d of the release member 346 is illustrated by an imaginary line. ..

As shown in FIG. 44, in a state where the release member 346 is pushed down by the first overhanging portion 344c1 of the disk cam 344, the first overhanging portion 344c1 and the first retracting portion 344c2 are engaged with the releasing member 346. By reciprocating the disk cam 344 while maintaining the positional relationship that does not pass through the 346d, the tilting device 310 can be reciprocated up and down while maintaining the posture of the release member 346.

In this case, the posture of the rotary claw member 347 is maintained in a state of being rotated in the backward rotation direction (clockwise in FIG. 44) as the posture of the release member 346 changes. When the player moves up and down, even if the tilting device 310 is pushed in and operated, the tilting device 310 and the rotary claw member 347 do not engage with each other, and the tilting device 310 is in the first state (rotation) when the player releases the hand. When the claw member 347 engages with the tilting device 310, it is possible to carry out an operation mode in which the tilting device 310 moves upward from the position (position where the ascending is restricted) and continues the vertical movement.

Therefore, for example, as the operation mode of the tilting device 310, the operation is performed by providing a difference in effect between the above-mentioned first operation mode and the second operation mode and the third operation mode shown in FIG. The operation of the device 300 can have a meaning different from the conventional one. That is, according to the present embodiment, the tilting device 310 moves up and down in the first operation mode or the second operation mode only when the player pushes in the tilting device 310 and then releases the tilting device 310. It is possible to know whether the movement was performed or the movement was performed up and down in the third operation mode.

As a difference in production, when the tilting device 310 moves up and down in the first operation mode and the second operation mode (when the tilting device 310 is pushed in and then released, the tilting device 310 is maintained in the first state. Compared to the case where the tilting device 310 moves up and down in the third operation mode (when the tilting device 310 continues to move up and down even if the tilting device 310 is pushed in and then released). Assuming that the difference is that the expectation of the jackpot is high, the player recognizes the expectation of whether or not to hit the jackpot not only when the player pushes the tilting device 310 but also when the player releases the tilting device 310. Since the opportunity can be obtained, it is possible to provide many timings for the player to pay attention to the operation device 300. Thereby, the degree of attention of the operation device 300 can be improved.

Next, the second embodiment will be described with reference to FIGS. 45 to 49. In the first embodiment, the case where the state of the rotary claw member 347 is maintained when the release member 346 is pushed up has been described, but in the operation device 2300 in the second embodiment, the drive device 2340 has the slide claw member 2348. The slide claw member 2348 slides when the release member 2346 is pushed up. The same parts as those in the above-described embodiments are designated by the same reference numerals, and the description thereof will be omitted. First, the difference from the first embodiment will be described with reference to FIGS. 45 and 46.

45 (a) is a side view of the slide claw member 2348 according to the second embodiment, FIG. 45 (b) is a side view of the rotating plate member 2347, and FIG. 45 (c) is a side view of the release member 2346. It is a side view.

46 (a) and 46 (b) are side views of the release member 2346, the rotary plate member 2347, and the slide claw member 2348 showing the interlocking of the release member 2346, the rotary plate member 2347, and the slide claw member 2348. ..

FIG. 46 (a) shows a large angle state in which the rotary plate member 2347 rotates with respect to the release member 2346 to the end position in the urging direction of the second spring SP2, and FIG. 46 (b) shows the release member 2346. The small angle state in which the rotary plate member 2347 is rotated to the terminal position against the urging force of the second spring SP2 is shown. The state in which the release member 2346 is rotated by being brought into contact with the disk cam 344 is a state between a large angle state and a small angle state (the convex pin 346b is arranged at an intermediate position of the guide slot 347b). (See FIG. 48).

As shown in FIGS. 45 and 46, the drive device 2340 (see FIG. 47) includes a release member 2346, a rotating plate member 2347, and their rotation as functional members pivotally supported by the shaft portion 341c (see FIG. 47). With the slide claw member 2348, which is arranged on the opposite side of the release member 2346 with the plate member 2347 in between and is configured to be slidable along an arc trajectory centered on the rotation axis of the tilting device 2310 (see FIG. 47). , Is mainly provided. The release member 2346, the rotary plate member 2347, and the slide claw member 2348 have the same reference numerals as those of the first embodiment, and the description thereof will be omitted.

As shown in FIG. 45 (a), the slide claw member 2348 has a curved portion 2348a formed from a curved shape in which the slide claw member 2348 is slidably fitted in the rail portion 2347f, and the front end portion of the curved portion 2348a. The hook-shaped portion 2348b is projected in a hook shape toward the left side of FIG. 45, and the curved portion 2348a and the hook-shaped portion 2348b are arranged so as to be overlapped with each other in the thickness direction (FIG. 47 (a) perpendicular to the paper surface). Mainly, a reinforcing portion 2348c formed from a curved plate shape wider than the curved portion 2348a, and a convex pin 2348d projecting in a columnar shape toward the release member 2346 at the lower end portion of the reinforcing portion 2348c. Be prepared.

The length of the curved portion 2348a is set to be slightly shorter than the separation width of the rail portion 2347f. Therefore, the curved portion 2348a of the slide claw member 2348 is configured to be slidable with respect to the rotating plate member 2347 in a state of being internally fitted in the rail portion 2347f.

The hook-shaped portion 2348b has the same shape as the hook-shaped portion 347d of the first embodiment, and a magnetic material is arranged on the lower side surface thereof. This magnetic material is a magnetic material for generating a magnetic force that is attracted to the bottom plate portion 2311a of the tilting device 2310, which will be described later.

The reinforcing portion 2348c is a portion facing the surface of the rotating plate member 2347 facing the slide claw member 2348 in the assembled state (see FIG. 46), and is formed wider than the curved portion 2348a. , A portion that reinforces the slide claw member 2348.

The convex pin 2348d is a cylindrical member that is inserted into the functional elongated hole 2346e of the release member 2346, and is composed of a metal rod that is inserted and fixed in the main body plate portion 2348e. When the release member 2346 rotates relative to the rotating plate member 2347, the convex pin 2348d is pushed to the side surface of the functional elongated hole 2346e, and the slide claw member 2348 slides and moves.

The rotating plate member 2347 includes a shaft support hole 347a, a guide elongated hole 347b, an insertion hole 347c, a pull-down hole 347e, a rail portion 2347f for guiding the sliding operation of the slide claw member 2348, and a slide. The support elongated hole 2347g through which the convex pin 2348d of the claw member 2348 is inserted is provided.

The rail portion 2347f is formed of a pair of plate-shaped portions extending from the upper end portion of the rotating plate member 2347, and the rotating plate member 2347 is forward-rotating on the side surfaces of the pair of plate-shaped portions arranged to face each other (FIG. It is formed from a curved shape along an arc centered on a shaft portion 314 (see FIG. 47) in a state of being arranged at a terminal position (46 counterclockwise).

Like the rail portion 2347f, the support elongated hole 2347g is formed from a curved shape along an arc centered on the shaft portion 314 (see FIG. 47). When the slide claw member 2348 is slid and moved with the convex pin 2348d inserted through the support elongated hole 2347g, the slide claw member 2348 can be supported by the rail portion 2347f and the support elongated hole 2347g, and the slide claw member 2348 can be supported. It is possible to suppress wobbling.

The release member 2346 includes a shaft support hole 346a, a convex pin 346b, an insertion hole 346c, an engaging portion 346d, and a functional elongated hole 2346e which is an elongated hole drilled in the thickness direction. ..

The functional elongated hole 2346e is configured as an elongated hole slightly wider than the diameter of the convex pin 2348d of the slide claw member 2348, and has a first length formed of a curved shape along an arc centered on the shaft support hole 346a. It mainly includes a hole portion 2346e1 and a second elongated hole portion 2346e2 extending in a direction inclined from one end of the first elongated hole portion 2346e toward the opposite direction of the shaft support hole 346a.

As shown in FIG. 46, when the release member 2346 rotates with respect to the rotating plate member 2347 and the state changes between the large angle state and the small angle state, the slide claw member 2348 follows the curved shape of the rail portion 2347f. Slide to move.

Since the functional elongated hole 2346e is configured as an elongated hole slightly wider than the diameter of the convex pin 2348d, the movement speed of the release member 2346 remains unchanged from the movement of the convex pin 2348d without a time delay with respect to the movement of the release member 2346. It is reflected in the speed.

That is, if the release member 2346 is rotated quickly, the slide claw member 2348 slides quickly, while if the speed at which the release member 2346 is rotated is reduced, the operation speed of the slide claw member 2348 also decreases.

As shown in FIG. 46A, in a large angle state, even if the slide claw member 2348 is pulled in the slide direction, the first arc portion 2346e1 has a shape along an arc centered on the shaft support hole 346a. Therefore, the load applied from the convex pin 2348d to the functional elongated hole 2346e is directed in the linear direction passing through the shaft support hole 346a. Therefore, the force for rotating the release member 2346 is not generated, and the slide claw member 2348 can be prevented from sliding and moving.

That is, in the present embodiment, although the slide claw member 2347 may slide and move due to the rotational operation of the release member 2346, the slide claw member 2347 slides when the slide claw member 2347 is pulled when the angle is large. It doesn't move. Therefore, as in the first embodiment, when the tilting device 2310 is arranged in the first state, the tilting device 2310 can be restricted from rising by engaging the slide claw member 2348 with the tilting device 2310.

47 to 49 are drawings showing changes in the posture of the tilting device 2310 in chronological order, and are cross-sectional views of the operation device 2300 in the line corresponding to the XXII-XXII line of FIG. 6A. Note that FIG. 47 shows a state in which the second retractable portion 344c4 of the disc cam 344 is arranged below the engaging portion 346d of the release member 2346, and FIG. 48 shows the disc cam 344 from the state shown in FIG. 47. Is rotated in the backward rotation direction (clockwise in FIG. 47) and the engaging portion 346d of the release member 2346 is pushed up. A state in which the release member 2346 is rotated clockwise) and returned by the urging force of the second spring SP2 is shown in the figure.

In the present embodiment, the bottom plate portion 2311a of the tilting device 2310 is fixed to the upper side surface in the vicinity of the lower edge portion of the opening 311b and includes a magnet portion 2311a1 made of a magnetic material.

In the state shown in FIG. 47, the magnet portion 2311a1 and the hook-shaped portion 2348b are attracted by magnetic force. When the player pushes the tilting device 2310 from this state, the tilting device 2310 disengages the attraction between the magnet portion 2311a1 and the hook-shaped portion 2348b due to the posture change of the tilting device 2310, so that a large load is applied from the tilting device 2310 to the slide claw member 2348. It will not be done.

As shown in FIG. 48, when the release member 2346 is pushed up, the slide claw member 2348 slides in the ascending direction in conjunction with the operation. At this time, since the magnet portion 2311a1 and the hook-shaped portion 2348b are attracted by a magnetic force, if the release member 2346 operates quickly, the tilting device 2310 also operates quickly.

Therefore, by sliding the slide claw member 2348 at a speed different from the speed at which the tilting device 2310 rotates in the ascending direction due to the urging force of the torsion spring 315, the slide claw member 2348 is moved backward (clockwise in FIG. 48). The tilting device 2310 can be moved ascending at a speed different from the ascending movement when the restriction on the ascending movement of the tilting device 2310 is lifted (fourth operation mode). That is, the speed at which the tilting device 2310 moves in the ascending direction can be changed.

As shown in FIG. 49, when the disc cam 344 and the release member 2346 are disengaged, the release member 2346 rotates in the backflip direction (clockwise in FIG. 48) due to the urging force of the second spring SP2. As a result, the slide claw member 2348 is returned to the first state.

By enabling the operation modes shown in FIGS. 47 to 49, the tilting device 2310 can be operated in four operation modes in addition to the first to third operation modes described in the first embodiment. .. As the number of operation modes increases, by associating the operation mode with the expected degree of jackpot, it becomes easier for the player to use the operation device 2300 as a means of pre-reading, so that the operation device 2300 for the player can be used. The degree of attention can be improved.

Further, according to the present embodiment, as shown in FIG. 48, when the tilting device 2310 is raised by raising the slide claw member 2348, the hook-shaped portion 2348b of the slide claw member 2348 and the magnet portion 2311a1 of the tilting device 2310 are used. Since the tilting device 2310 is raised by the magnetic force attraction between the tilting device 2310 and the tilting device 2310, the tilting device 2310 can be applied to the tilting device 2310 by securing a large magnetic force as compared with the case where the tilting device 2310 is raised by the urging force of the torsion spring 315. The load can be increased.

That is, normally, when the player puts his / her hand on the upper part of the tilting device 2310, when the restriction by the slide claw member 2348 is released, the tilting device 2310 is prevented from being raised by the weight of the hand. (Even if the urging force of the torsion spring 315 is not large enough to lift the weight of the hand), if the magnetic force is large enough to lift the weight of the hand, lift the player's hand in the state shown in FIG. The tilting device 2310 can be raised in an embodiment.

Thereby, when raising the tilting device 2310, it is possible to provide a difference in the load in the ascending direction (force for maintaining the posture of the tilting device 2310 with respect to the downward load). Therefore, the player who plays the game by placing his / her hand on the upper part of the tilting device 2310 before pushing the tilting device 2310 can feel the difference in the load.

For example, by associating the difference in load with the expected degree of jackpot, the player can easily use the operation device 2300 as a means of pre-reading, so that the degree of attention of the operation device 2300 to the player can be determined. Can be improved.

Next, a third embodiment will be described with reference to FIGS. 50 to 52. In the first embodiment, the case where the detection sensors 324L and 324R can detect whether the tilting device 310 is in the first state or in the state of being pushed by the player has been described, but the operation device 3300 in the third embodiment has been described. Is configured in such a manner that the detection sensors 324L and 324R can detect whether the tilting device 3310 is in the middle of the first state and the state of being pushed by the player or the state of being pushed by the player. NS. The same parts as those in the above-described embodiments are designated by the same reference numerals, and the description thereof will be omitted.

FIG. 50 is a side view of the tilting device 3310 according to the third embodiment. As shown in FIG. 50, the tilting device 3310 has the same position as the right side detection piece 311 gR extending downward from the bottom plate portion 311a of the case body 3311 and the left side detection piece 311 gL in the first embodiment (rotation of the tilt device 3310). It is provided with a left side detection piece 3311 gL extending at a surface perpendicular to the axis and located at a position opposite to the right side detection piece 311 gR with respect to the surface arranged at the center position in the rotation axis direction. The left side detection piece 3311 gL has a longer extension length than the right side detection piece 311 gR, and its extension length is shorter than that of the left side detection piece 311 gL in the first embodiment.

51 (a) and 51 (b) are side views of the operating device 3300. Note that FIG. 51 (a) shows the tilting device 3310 in the first state, and FIG. 51 (b) shows a state in which the tilting device 3310 is being pushed in. Further, in FIGS. 51 (a) and 51 (b), in order to facilitate understanding, the outer shapes of the lower frame member 320, the upper frame member 330, and the protective cover device 350 are illustrated by imaginary lines, while each of them is shown by an imaginary line. The detection sensors 324L and 324R and the voice coil motor 352 are shown by solid lines, and the portion where the detection sensors 324L and 324R and the detection pieces 3311gL and 311gR overlap is schematically shown.

As shown in FIG. 51 (a), when the tilting device 3310 is in the first state, the left side detection piece 3311 gL is not inserted through the left side detection sensor 324L and the right side detection piece 311 gR is inserted through the right side detection sensor 324R. None (the left side detection sensor 324L is in the OFF state and the right side detection sensor 324R is in the OFF state).

As shown in FIG. 51 (b), when the tilting device 3310 is in the process of being pushed from the first state to the pushing end, the left side detection piece 3311gL is inserted through the left side detection sensor 324L, while the right side is inserted. The detection piece 311gR is not inserted through the right side detection sensor 324R (the left side detection sensor 324L is in the ON state and the right side detection sensor 324R is in the OFF state).

By detecting the change in the state of each of these detection sensors 324L and 324R, when the tilting device 3310 is in the middle of the first state and the state of being pushed to the end of pushing, it is in the middle of pushing. It is possible to detect whether it is in the process of returning or not.

That is, if the left side detection sensor 324L is ON and the right side detection sensor 324R is OFF, the tilting device 3310 is in the middle of the first state and the state of being pushed to the end of pushing. By detecting that the left side detection sensor 324L is in the OFF state and the right side detection sensor 324R is in the state of being changed from the OFF state, it can be determined that the tilting device 3310 is in the middle of the pushing operation.

52 (a) and 52 (b) are side views of the operating device 3300. Note that FIG. 52 (a) shows a state in which the tilting device 3310 is pushed to the pushing end, and FIG. 52 (b) shows a state in which the tilting device 3310 is in the process of moving from the pushing end to the first state. .. Further, in FIGS. 51 (a) and 51 (b), in order to facilitate understanding, the outer shapes of the lower frame member 320, the upper frame member 330, and the protective cover device 350 are illustrated by imaginary lines, while each of them is shown by an imaginary line. The detection sensors 324L and 324R and the voice coil motor 352 are shown by solid lines, and the portion where the detection sensors 324L and 324R and the detection pieces 3311gL and 311gR overlap is schematically shown.

As shown in FIG. 52A, when the tilting device 3310 is pushed to the end of pushing, the left side detection piece 3311 gL is inserted through the left side detection sensor 324L and the right side detection piece 311 gR is inserted through the right side detection sensor 324R. (The left side detection sensor 324L is ON and the right side detection sensor 324R is ON).

As shown in FIG. 52 (b), when the tilting device 3310 is between the first state and the state arranged at the push-in end, the left side detection piece 3311 gL is inserted through the left side detection sensor 324 L. The right side detection piece 311gR is not inserted through the right side detection sensor 324R (the left side detection sensor 324L is in the ON state and the right side detection sensor 324R is in the OFF state).

If the left side detection sensor 324L is ON and the right side detection sensor 324R is OFF, the tilting device 3310 is in the middle of the first state and the state of being pushed to the end of pushing, which is the left side detection. By detecting that the sensor 324L is in the ON state and the right side detection sensor 324R is in the state of being changed from the ON state, it can be determined that the tilting device 3310 is in the process of returning to the first state.

Here, when the driving force of the voice coil motor 352 is transmitted to the tilting device 3310 to give an auxiliary load for raising the tilting device 3310, the voice coil motor 352 is moved to the tilting device 3310 while the tilting device 3310 is descending. It is possible to effectively give a load for raising the tilting device 3310 by colliding the voice coil motor 352 with the tilting device 3310 while the tilting device 3310 is operating ascending rather than colliding with the tilting device 3310.

Therefore, as shown in FIG. 52B, the operating direction of the tilting device 3310 is determined from the detection history of each of the detection sensors 324L and 324R, and the tilting device 3310 is in the process of ascending and reaches the first state. By driving the voice coil motor 352 when not in use, the driving force of the voice coil motor 352 can be effectively transmitted to the tilting device 3310, and the ascending speed of the tilting device 3310 can be improved.

Here, when the urging force of the torsion spring 315 is suppressed in order to suppress the driving force of the drive motor 342 (see FIG. 18), the ascending speed of the tilting device 3310 after the tilting device 3310 is pushed in from the first state is slow. Become. In this case, even if the player repeatedly hits the tilting device 3310, the ascending operation of the tilting device 3310 does not follow the movement of the player's hand, and the continuous hitting operation cannot be performed comfortably.

On the other hand, according to the present embodiment, by effectively using the driving force of the voice coil motor 352, the tilting device 3310 moves up as compared with the case where the tilting device 3310 is raised only by the urging force of the torsion spring 315. Since the ascending speed can be improved, the continuous striking operation of the tilting device 3310 can be comfortably performed.

Next, a fourth embodiment will be described with reference to FIGS. 53 to 55. In the first embodiment, the case where the detection sensors 324L and 324R can detect whether the tilting device 310 is in the first state or in the state of being pushed by the player has been described, but the operation device 4300 in the fourth embodiment has been described. Is an embodiment in which the tilting device 4310 detects the operating speed during the change from the second state to the first state, and changes the driving method of the voice coil motor 352 according to the detection result. The same parts as those in the above-described embodiments are designated by the same reference numerals, and the description thereof will be omitted.

FIG. 53 is a side view of the tilting device 4310 according to the fourth embodiment. As shown in FIG. 53, the tilting device 4310 includes a front detection piece 4311k that is projected in a plate shape from the front side of the overhanging convex portion 311j of the case body 4311.

The front detection piece 4311k is configured to be able to pass through the detection grooves (slits) of the upper detection sensor 4321d and the lower detection sensor 4321e (see FIG. 54) arranged in the bottom plate portion 4321 of the lower frame member 4320, and each detection is performed. This is a part for determining the operating speed of the tilting device 4310 based on the detection timing of the sensors 4321d and 4321e.

54 (a) and 54 (b) are side views of the operation device 4300 showing the pressing operation of the operation device 4300 in chronological order. In FIG. 54 (a), the tilting device 4310 is in the second state, and in FIG. 54 (b), the tilting device 4310 is pushed in from the state shown in FIG. 54 (a) and the front detection piece 4311k is detected on the lower side. The state in which the sensor 4321e has passed downward is shown. Further, in FIGS. 54 (a) and 54 (b), in order to facilitate understanding, the outer shapes of the lower frame member 4320, the upper frame member 330, and the protective cover device 350 are illustrated by imaginary lines, while each of them. The detection sensors 324L, 324R, 4321d, 4321e and the voice coil motor 352 are shown by solid lines.

As shown in FIGS. 54 (a) and 54 (b), the lower frame member 4320 includes an upper detection sensor 4321d and a lower detection sensor 4321e in a portion on the front side of the bottom plate portion 4321. The upper detection sensor 4321d and the lower detection sensor 4321e are photocoupler type sensors, and are arranged in a posture in which the detection groove is oriented so that the front detection piece 4311k can pass through. In the present embodiment, the upper detection sensor 4321d and the lower detection sensor 4321e are arranged at intervals of 20 ° on an arc orbit centered on the rotation axis of the tilting device 4310.

When the player changes from the state shown in FIG. 54 (a) to the state shown in FIG. 54 (b) by pushing the tilting device 4310, the front detection piece 4311k has the upper detection sensor 4321d and the lower detection sensor. It passes through 4321e in order. By detecting the interval of the passing timing, it is possible to determine the magnitude of the operating speed of the tilting device 4310, and it is selected whether or not to drive the voice coil motor 352 by the determination.

Here, when the tilting device 4310 is pushed in from the second position, the pushing length is long (because the period during which acceleration can be applied is long), so that the tilting device is compared with the operation button having a short pushing length. The upper limit of the operating speed of 4310 is increased. Therefore, if there is no means for deceleration, it is necessary to make the tilting device 4310 strong as a safety measure for the player to push in with full force, and the tilting device 4310 tends to be heavy. Challenges arise.

Further, it is also possible to incorporate an elastic spring that applies an urging force to the tilting device 4310 only when the tilting device 4310 is arranged near the end of pushing, and to decelerate the tilting device 4310 by the urging force of the elastic spring. However, in this case, for a player with a weak force or a player who has decided to perform a gentle pushing operation, the fact that the reaction force is always large near the pushing position becomes a burden on the pushing operation, and it becomes easy to feel fatigue. Therefore, there is a risk that the tilting device 4310 cannot be pushed in comfortably.

On the other hand, in the present embodiment, it is determined whether or not the upper detection sensor 4321d and the lower detection sensor 4321e drive the voice coil motor 352 by the timing interval at which the upper detection sensor 4321d and the lower detection sensor 4321e are switched between the ON state and the OFF state, respectively. Therefore, it is possible to prevent a strong reaction force from being applied to the tilting device 4310 even when it is not necessary.

That is, for example, when the timing interval at which the upper detection sensor 4321d and the lower detection sensor 4321e are switched between the ON state and the OFF state is longer than a predetermined period (for example, 1 second), the voice coil motor 352 is used. On the other hand, when the above-mentioned timing interval is shorter than a predetermined period, the voice coil motor 352 is driven.

As a result, when the operation speed of the pushing operation of the tilting device 4310 is slow, the reaction force felt by the player from the tilting device 4310 is only the urging force generated by the torsion spring 315, and the tilting device 4310 can be easily operated even with a weak force. It can be pushed in.

Further, when the operation speed of the pushing operation of the tilting device 4310 is high, not only the urging force generated by the torsion spring 315 but also the driving force generated by the voice coil motor 352 at the pushing end is used as the reaction force against the tilting device 4310. Can be added. Therefore, the operating speed of the tilting device 4310 can be suppressed.

In the present embodiment, as shown in FIG. 54B, the voice coil motor 352 is driven before the overhanging convex portion 311j of the tilting device 4310 projects below the lower frame member 4320. It is controlled in such a manner that the movable member of the voice coil motor 352 is extruded in advance to the side close to the tilting device 4310.

As a result, the impact applied to the tilting device 4310 can be suppressed as compared with the case where the tilting device 4310 and the voice coil motor 352 collide with each other during the extrusion of the movable member of the voice coil motor 352.

55 (a) and 55 (b) are side views of the operating device 4300. Note that FIG. 55 (a) shows a state in which the tilting device 4310 is being pushed from the first state to the pushing end, and FIG. 55 (b) shows a state in which the tilting device 4310 reaches the pushing end. ..

Further, in FIGS. 55 (a) and 55 (b), in order to facilitate understanding, the outer shapes of the lower frame member 4320, the upper frame member 330, and the protective cover device 350 are illustrated by imaginary lines, while each of them. The detection sensors 324L, 324R, 4321d, 4321e and the voice coil motor 352 are shown by solid lines.

As shown in FIG. 55 (a), when the tilting device 4310 is pushed in at high speed from the second state, the tilting device 4310 is in the process of reaching the pushing end from the first state, and the tilting device 4310 is projected. The setting portion 311j and the voice coil motor 352 are brought into contact with each other.

By pushing the tilting device 4310, the overhanging convex portion 311j moves the voice coil motor 352 in the direction along the extension direction D41 of the voice coil motor 352, so that the voice coil motor 352 is reduced. The force of the push operation can be consumed to move to. Therefore, while the tilting device 4310 continues to move, the driving force of the voice coil motor 352 can apply a load in the direction of pushing up the tilting device 4310, and the tilting device 4310 can be decelerated.

At this time, since the voice coil motor 352 does not have a structure in which a load is applied by friction like a disc brake, but a structure in which a load is applied by an electromagnetic force, damage to members can be suppressed and durability can be ensured.

In the state shown in FIG. 55 (a), the overhanging convex portion 311j of the tilting device 4310 and the voice coil motor 352 are already in contact with each other, so that the state shown in FIG. 55 (a) (the left side detection sensor 324L is By gradually increasing the current flowing through the voice coil motor 352 from the ON state), the reaction force applied to the tilting device 4310 from the voice coil motor 352 can be gradually increased.

Therefore, while suppressing the reaction force felt by the player at the timing when the overhanging convex portion 311j of the tilting device 4310 and the voice coil motor 352 come into contact with each other, the tilting device 4310 decelerates on the way from the first state to the pushing end. The effect can be improved.

As shown in FIG. 55 (b), when the tilting device 4310 is arranged at the push-in end position, the right side detection sensor 324R is turned on. In this state, the tilting device 4310 abuts on the lower frame member 4320 in the rotational direction and stops descending. Therefore, it is not necessary to decelerate the tilting device 4310 by the voice coil motor 352.

In the present embodiment, in the state shown in FIG. 55 (b), the voice coil motor 352 performs a vibration operation (an operation of repeating movement in the extension direction and movement in the contraction direction). As a result, it is possible to perform an effect of transmitting vibration to the player who keeps his / her hand on the tilting device 4310 after pushing the tilting device 4310 to the end.

That is, the voice coil motor 352 can be used for the purpose of reducing the speed of the pushing operation of the tilting device 4310 and for the purpose of vibrating the tilting device 4310 arranged at the pushing end position to produce a vibration effect.

Next, the operation device 5300 according to the fifth embodiment will be described with reference to FIGS. 56 to 68.

In the first embodiment, the case where the vibration is transmitted to the player who pushes and operates the tilting device 310 by vibrating the voice coil motor 352 has been described, but the operation device 5300 in the fifth embodiment is attached to the lower frame member 5320. The drive motor 5411 for rotating the weight member 5412 whose center of gravity is eccentric is provided, and the vibration is transmitted to the player who touches the lower frame member 5320 based on the rotation of the drive motor 5411. The same parts as those in the above-described embodiments are designated by the same reference numerals, and the description thereof will be omitted. First, the difference in configuration from the first embodiment will be described with reference to FIGS. 56 and 57.

FIG. 56 is an exploded front perspective view of the operating device 5300 according to the fifth embodiment, and FIG. 57 is an exploded rear perspective view of the operating device 5300.

As shown in FIGS. 56 and 57, in the operation device 5300, the lower frame member 320 is the lower frame member 5320 and the drive device 340 is the drive device 5340, as compared with the operation device 300 in the first embodiment. At the same time, the voice coil motor 352 is omitted from the protective cover member 350. The tilting device 310 and the upper frame member 330 have the same configuration as that of the first embodiment.

The lower frame member 5320 is provided with a vibration device 5400 including a drive motor 5411, and the drive device 5340 is provided with a disk cam 5344 fixed to the transmission shaft rod 5343 with one touch. First, the vibrating device 5400 will be described with reference to FIGS. 58 to 61, and then the disk cam 5344 will be described.

FIG. 58 is an exploded front perspective view of the lower frame member 5320 and the vibrating device 5400. As shown in FIG. 58, the vibrating device 5400 includes a transmission device 5410 that rotationally drives a fan-shaped weight member 5412, a transmission device 5410, and a drive motor 5411 of the transmission device 5410, and is composed of a flexible material. The flexible member 5420 and the flexible member 5420 are formed in a bottomed dish shape with an open upper surface, and the weight member 5412 and the flexible member 5420 are separately accommodated and are fastened and fixed to the bottom plate portion 5321 of the lower frame member 5320. Mainly equipped with 5430.

The transmission device 5410 includes a drive motor 5411 formed of a rotary drive electric motor, and a weight member 5412 whose outer shape is fan-shaped and whose rotating shaft of the drive motor 5411 is pivotally supported by a portion corresponding to the main part of the fan. And mainly prepare.

The drive motor 5411 includes a fixed portion 5411a which is arranged in pairs on the left and right and is formed in a flange shape from a metal material on the side surface on the side where the shaft projects.

The weight member 5412 has a radius Ra and is eccentrically supported with the rotation axis of the drive motor 5411. Therefore, when the drive motor 5411 is rotationally driven, the position of the center of gravity of the weight member 5412 fluctuates, and the drive motor 5411 can vibrate together with the drive motor 5411.

The flexible member 5420 has a main body 5421 formed of a cylindrical container shape in which the drive motor 5411 is inserted along the axial direction and has a bottom on the opposite side of the insertion side, and the main body 5421 in the assembled state. The rib-shaped legs 5422, which are projected in a pair of ribs on the left, right, left and right and downward in the radial direction, and the rib-shaped legs 5422, which are convex on the left and right on the open portion side of the main body 5421, are connected to each other. It mainly includes a posture maintaining portion 5423 in which the fixing portion 5411a is embedded, and a convex leg portion 5424 projecting upward from the upper surface of the main body portion 5421 in a pair of columns.

The main body portion 5421 has a container-shaped depth formed at the same depth as the axial length of the drive motor 5411. Therefore, in a state where the drive motor 5411 is completely inserted into the main body portion 5421, the end face on the shaft side of the drive motor 5411 and the end face on the opening side of the main body portion 5421 are formed on the same surface. Further, in this state, the fixing portion 5411a is embedded in the posture maintaining portion 5423.

The rib-shaped leg portion 5422 is formed on the left and right sides and the lower side of the main body portion 5421, but the rib-shaped leg portion 5422 on the left and right sides is larger than the rib-shaped leg portion 5422 on the left and right sides because the posture maintaining portion 5423 is arranged on the left and right sides. Deformation resistance is larger than that of the lower ribbed leg portion 5422.

Since the convex leg portion 5424 is projected in a columnar shape, it is possible to easily concentrate the load on one point in contact with the tilting device 310 described later. Therefore, when the flexible member 5420 is deformed by tilting the tilting device 310, the resolution of the degree of deformation of the flexible member 5420 with respect to the tilting angle of the tilting device 310 can be made finer.

In the assembled state, the accommodating member 5430 is provided next to the first accommodating portion 5431 in which the drive motor 5411 and the flexible member 5420 are accommodated, and the second accommodating portion 5412 in which the weight member 5412 is accommodated. 5432 and a concave groove 5433 that is recessed downward from the upper surface on the connecting surface of the first accommodating portion 5431 and the second accommodating portion 5432 are mainly provided.

The depth of the first accommodating portion 5431 is adjusted from the upper surface when the flexible member 5420 is inserted until the lower rib-shaped leg portion 5422 touches the bottom and the load applied during the insertion is released (assembly load release state). The depth is such that the convex leg portion 5424 overhangs.

The depth of the second accommodating portion 5432 is a depth that is recessed to the outside of the rotation locus of the weight member 5412 in the assembled load release state, while the player applies a load to the convex leg portion 5424 to provide a flexible member. When the 5420 is deformed (assembled load state), the depth is set to interfere with the rotation locus of the weight member 5412.

The concave groove 5433 has a width dimension that is slightly wider than the diameter of the rotation shaft of the drive motor 5411, and a depth dimension that extends slightly downward from the rotation shaft of the drive motor 5411 under the assembled load state. NS.

59 (a) is a side view of the lower frame member 5320, and FIG. 59 (b) is a partial cross-sectional view of the lower frame member 5320 in the LIXb-LIXb line of FIG. 59 (a). ) Is a partial top view of the lower frame member 5320 in the direction of arrow LIXc in FIG. 59 (a). In FIG. 59 (a), the portion corresponding to the vibrating device 5400 is partially cross-sectionally viewed. Further, in FIG. 59 (a), when the tilting device 310 is in the first state, the first region S51, which is the area occupied by the tilting device 310, and the first region are pushed into the player by three degrees. The end area S52, which is the area occupied by the tilting device 310 when arranged at the end position of the push-in, is illustrated by an imaginary line.

As shown in FIG. 59 (a), the convex leg portion 5424 is convexly provided in the direction along the circular orbit formed with the central axis of the arc of the lower bearing portion 323 as the rotation axis. Therefore, the amount of deformation of the convex leg portion 5424 with respect to the angle change of the tilting device 310 (see FIG. 56) can be secured to the maximum.

As shown in FIG. 59 (b), the weight member 5412 is separated from the second accommodating portion 5432 in the assembled load release state in which the convex leg portion 5424 is not loaded.

As shown in FIG. 59 (c), the convex leg portions 5424 are arranged symmetrically with respect to the left and right center lines of the lower frame member 5320 in the extension direction view. Therefore, since the convex leg portion 5424 can be pushed evenly to the left and right on the bottom surface of the tilting device 310, it is possible to prevent the flexible member 5420 from tilting to the left or right (tilting to the left or right on the paper surface in FIG. 59 (b)). The convex leg portion 5424 can be pushed in while maintaining the posture shown in FIG. 59 (b).

As shown in FIG. 59 (c), the bottom plate portion 5321 of the lower frame member 5320 includes a pair of through holes 5321d into which the convex leg portion 5424 can be inserted. Since the width dimension of the through hole 5321d in the left-right direction is slightly larger than the diameter dimension of the convex leg portion 5424, the tilting device 310 is pushed by the player and the lower side surface of the tilting device 310 is convex. When pressed against the leg portion 5424, deformation of the convex leg portion 5424 in the left-right direction can be suppressed. Therefore, the deformation of the shape of the convex leg portion 5424 can be suppressed, and the main body portion 5421 together with the convex leg portion 5424 can be easily translated downward (downward in FIG. 59B).

60 (a) and 60 (b) are cross-sectional views of the vibrating device 5400 in the LXa-LXa line of FIG. 59 (a). Note that FIG. 60 (a) shows an assembly load release state, and FIG. 60 (b) shows the convex leg portion 5424 in a state where the tilting device 310 occupies the terminal region S52 (see FIG. 59 (a)). The assembly load state after being pushed inward of the first accommodating portion 5431 is shown. The outer shapes of the second accommodating portion 5432 and the weight member 5412 are illustrated by imaginary lines.

As shown in FIGS. 60A and 60B, when a load is applied to the vibrating device 5400 from the assembly load release state and the assembly load state is reached, the convex leg portion 5424 and the lower ribbed leg portion As the 5422 is deformed, the drive motor 5411 and the weight member 5412 are displaced downward.

In the assembled load state, as shown in FIG. 60 (b), the flexible member 5420 is elastically deformed by being pushed by the tilting device 310 (see FIG. 57). The elastic recovery force of this deformation acts as a force to push back the tilting device 310, and the force increases as the tilting device 310 approaches the flexible member 5420. Therefore, when the tilting device 310 is pushed to the terminal position, the tilting device 310 is pushed back. The impact when the 310 collides with the lower frame member 5320 (see FIG. 57) can be mitigated. Further, since the load is due to the elastic recovery force, the load can be generated without a time delay even when the tilting device 310 moves at high speed.

Here, when the urging force of the torsion spring 315 is suppressed in order to suppress the driving force of the drive motor 342 (see FIG. 57), from the first state (the state in which the tilting device 310 is arranged at the rising end, see FIG. 38). The ascending speed of the tilting device 310 after the tilting device 310 is pushed in is slowed down. In this case, even if the player repeatedly hits the tilting device 310, the ascending operation of the tilting device 310 does not follow the movement of the player's hand, and the continuous hitting operation cannot be performed comfortably.

On the other hand, according to the present embodiment, by effectively using the elastic recovery force of the flexible member 5420, the tilting device 310 is compared with the case where the tilting device 310 is ascended only by the urging force of the torsion spring 315. Since the ascending speed can be improved, the continuous striking operation of the tilting device 310 can be comfortably performed.

As shown in FIG. 60A, the weight member 5412 does not come into contact with the inner wall of the second accommodating portion 5432 regardless of its posture in the assembled load release state. Therefore, even if the drive motor 5411 is started to be driven in the assembled load release state, the vibration due to the contact between the weight member 5412 and the second accommodating portion 5432 does not occur.

Further, the vibration of the drive motor 5411 itself and the slight vibration generated in the drive motor 5411 due to the movement of the center of gravity of the weight member 5412 are absorbed by the flexibility of the flexible member 5420, and transmission to the accommodating member 5430 is prevented. This makes it difficult for the player to grasp the drive start timing of the drive motor 5411.

As shown in FIG. 60B, the main body portion 5421 of the flexible member 5420 is displaced vertically due to deformation of the upper convex leg portion 5424 and the lower rib-shaped leg portion 5422 under the assembly load state. Consists of acceptable aspects.

When the flexible member 5420 moves downward, the state of the rib-shaped leg portion 5422 arranged under the main body portion 5421 changes to a state of being compressed more vertically, and the rib-shaped leg portion 5422 is slightly hardened. Therefore, the damping effect of the vibration by the rib-shaped leg portion 5422 can be weakened, and the vibration generated by the vibration device 5400 can be easily transmitted to the player.

Further, the main body portion 5421 of the flexible member 5420 is formed in a cylindrical shape, and the lower rib-shaped leg portion 5422 is extended along the axial direction of the cylinder of the main body portion 5421 and at uniform intervals to the left and right from the central axis. Since the flexible members 5420 are arranged in pairs on the left and right, the radial outer ends of the rib-shaped leg 5422 move outward on the left and right (at the connection position between the main body 5421 and the rib-leg 5422) as the flexible members 5420 move downward. It deforms in a manner of moving to (the one with the smaller resistance) (see FIG. 60 (b)). In this case, since the convex direction of the rib-shaped leg portion 5422 arranged on the lower side of the main body portion 5421 has a left-right direction component, the elastic force of the rib-shaped leg portion 5422 can be applied in the left-right direction. .. Therefore, in the assembled load state, the load in the left-right direction that may occur when the weight member 5421 and the second accommodating portion 5432 collide is partially applied by the elastic force of the rib-shaped leg portion 5422 on the lower side of the main body portion 5421. Can be absorbed. As a result, the displacement of the drive motor 5411 in the left-right direction can be suppressed.

61 (a) and 61 (b) are cross-sectional views of the transmission device 5410 and the accommodating member 5430 in the LIXb-LIXb line of FIG. 59 (a).

61 (a) and 61 (b) show an assembly load state, and FIG. 61 (a) shows a state in which the position of the center of gravity of the weight member 5412 is arranged above the rotation axis. In b), a state in which the position of the center of gravity of the weight member 5412 is arranged below the rotation axis is illustrated. Note that FIGS. 61 (a) and 61 (b) show a state of the vibrating device 5400 in a state where the tilting device 310 is pushed by the player and occupies the terminal region S52.

The operation of the transmission device 5410 based on the rotation of the weight member 5412 will be described. First, in the present embodiment, when the center of gravity of the weight member 5412 is arranged on the upper side in the assembled load state, the drive motor 5411 rotates at a position where the distance from the lower bottom portion of the second accommodating portion 5432 is the distance Q1. The axis is placed. In the present embodiment, the distance Q1 is equal to the radius Ra of the weight member 5412 (Q1 = Ra).

That is, when the weight member 5412 rotates in the assembled load state, the outer peripheral side surface thereof comes into contact with (rubs) the second accommodating portion 5432. Therefore, the vibration generated by the rotation of the weight member 5412 changes as compared with the assembled load release state, and different types of vibration can be transmitted to the player.

Due to the contact between the weight member 5412 and the second accommodating portion 5432, a force for moving the weight member 5412 upward (upward in FIG. 61B) is generated as a repulsive force. Here, since the weight member 5412 and the second accommodating portion 5432 move close to each other along the moving direction of the tilting device 310 (see FIG. 57), the direction of the repulsive force is set to the direction (upward) along the moving direction of the tilting device 310. ) Can be easily directed. Due to this repulsive force, the flexible member 5420 moves upward together with the drive motor 5411 that supports the weight member 5412, and the flexible member 5420 moves the tilting device 310 (see FIG. 57) upward (along the moving direction of the tilting device 310). The force to push back in the direction) can be reinforced.

In this way, the force that pushes the tilting device 310 (see FIG. 57) upward is the force generated as the elastic recovery force of the flexible member 5420 and the force generated by the contact between the weight member 5412 and the second accommodating portion 5432 separately. By configuring it with a combination of generated forces, it is possible to adjust the force that pushes back the tilting device 310.

That is, the elastic recovery force of the flexible member 5420 pushes back the tilting device 310 from the start of contact with the convex leg portion 5424 to the end region S52 (see FIG. 59 (a)). After the tilting device 310 reaches the terminal region S52, the repulsive force between the weight member 5412 and the second accommodating portion 5432 is applied to the force pushing back the tilting device 310. As a result, the force for pushing back the tilting device 310 can be particularly increased in the vicinity of the terminal region S52, so that the operation of the tilting device 310 can be lightened and the impact during the pushing operation can be mitigated satisfactorily. This adjustment can be performed while maintaining the rotation of the drive motor 5411. Therefore, it is not necessary to perform complicated control.

In the present embodiment, as in the first embodiment, the length of the left side detection piece 311 gL and the length of the right side detection piece 311 gR are different (see FIG. 57), and the tilting device 310 (see FIG. 57) is different due to the difference in detection timing. ) Is determined whether or not the operating speed is higher than a specific speed (for example, 40 km / h), and the arrangement of the weight member 5412 is changed according to the determined operating speed.

For example, when it is determined that the operating speed of the tilting device 310 is higher than a specific speed, the flexible member 5420 gives the tilting device 310 in order to alleviate the impact when the tilting device 310 collides with the lower frame member 5320. It is desirable to increase the load. Therefore, in the present embodiment, when it is determined that the operating speed of the tilting device 310 is higher than a specific speed, the weight member 5412 is operated in advance so as to be in a downward posture (see FIG. 61B).

As a result, the end of the lowering operation of the drive motor 5411 can be raised to a position where its rotation axis is raised by a radius Ra upward from the lower end of the inner wall of the second accommodating portion 5432. As a result, the weight member 5432 is located above the drive motor 5411 as compared with the case where the weight member 5432 is arranged upward (see FIG. 61 (a)) (when the weight member 5432 can be lowered downward from the state shown in FIG. 61 (a)). The movable area of the flexible member 5420 can be narrowed in the vertical direction.

That is, when the convex leg portion 5424 is pushed down by the tilting device 310 by the same amount, the compression dimension of the portion of the flexible member 5420 and the upper portion of the drive motor 5411 can be increased. Therefore, the repulsive force applied from the flexible member 5420 to the tilting device 310 can be increased, and the load for braking the tilting device 310 can be increased.

Although the description is omitted in the present embodiment, by keeping the drive motor 5411 stopped upward (see FIG. 61A), a force for pushing back the tilting device 310 is generated by the elastic recovery force of the flexible member 5420. It is also possible to prevent the force due to the contact between the weight member 5412 and the second accommodating portion 5432 from being generated.

Here, the contact of the members occurs between the transmission device 5410 and the accommodating member 5430 that is fastened and fixed to the lower frame member 5320, and does not occur between the tilting device 310. Therefore, the vibration transmitted to the hand of the player who pushes the tilting device 310 can be changed, and the transmission range of the vibration can be widened. That is, the vibration can be transmitted to a portion other than the portion touching the tilting device 310, for example, a portion touching the frame of the pachinko machine 10.

That is, when the player pushes the tilting device 310, the vibration can be transmitted to the lower frame member 5320, so that the palm or a part of the side surface of the hand placed on the lower frame member 5320 as a fulcrum for pushing is used. The vibration can be transmitted to the player through. As a result, it is possible to avoid a situation in which the vibration is not transmitted to the player.

As shown in FIGS. 61 (a) and 61 (b), the weight member 5412 only when the player pushes in the tilting device 310 (see FIG. 56) and the vibrating device 5400 forms an assembled load state. And the accommodating member 5430 come into contact with each other, and vibration is generated.

Therefore, even if the drive motor 5411 is in the rotating state in advance, the timing at which the vibration is transmitted to the player can be limited to the timing at which the tilting device 310 is pushed in, so that the pushing operation of the player can be detected. It is possible to make it easier to transmit the vibration to the player as compared with the case where the vibration is generated from the motor.

That is, when the player pushes the tilting device 310 and immediately releases the hand (pulse pushing), the tilting device 310 is detected to be pushed and then vibration is generated. Therefore, there is a possibility that the vibration cannot be generated by the time the player releases the hand (the vibration starts not in time), and the player may not be able to experience the effect of the vibration. On the other hand, in the present embodiment, since the drive motor 5411 is rotated in advance before the tilting device 310 is pushed in and is ready to generate vibration, the vibration can be transmitted at the same time as the tilting device 310 is pushed in. As a result, the player can experience the effect of vibration.

Further, due to the flexibility of the flexible member 5420, it is possible to prevent the vibration of the main body of the drive motor 5411 from being transmitted to the first accommodating portion 5431. Therefore, even if the drive motor 5411 is driven in advance, it is possible to prevent the vibration from being transmitted to the player even before the tilting device 310 is pushed in.

Therefore, the state in which the vibration is transmitted by pushing the tilting device 310 can be realized by driving the drive motor 5411 in advance before pushing the tilting device 310.

Next, the drive device 5340 will be described. The difference between the drive device 5340 and the drive device 340 in the first embodiment is the disk cam 5344 and the transmission shaft rod 5343. Others are the same as the drive device 340 of the first embodiment, so the same reference numerals are given and the description thereof will be omitted.

FIG. 62 is an exploded front perspective view of the drive device 5340. As shown in FIG. 62, a long hole recess C1 is formed in a central portion of a pair of disc cams 5344 composed of a left disc cam 5344L and a right disc cam 5344R.

FIG. 63 (a) is a front perspective view of the right disk cam 5344R, and FIG. 63 (b) is a rear perspective view of the right disk cam 5344R. Since the right disk cam 5344R and the left disk cam 5344L are formed in a symmetrical shape, only the right disk cam 5344R will be described, and the description of the left disk cam 5344L will be omitted.

The difference between the right disk cam 5344R and the right disk cam 344R in the first embodiment is that a pair of holding arm portions A1 for sandwiching the transmission shaft rod 5343 are arranged at the connecting portion with the transmission shaft rod 5343. Is.

That is, the right disc cam 5344R has a support cylinder portion P1 extending in a cylindrical shape from the disc portion to the side where the circular ribs 344b are arranged at the center position thereof, and the support cylinder portion P1 in the axial direction. Along the axis, a long hole recess C1 recessed from a disk portion in an axially symmetric long hole shape up to a position of about half of the extension distance, and a shaft of a support cylinder portion P1 recessed by the long hole recess C1. It mainly includes a pair of holding arm portions A1 extending from the end portion in the direction toward the disk portion side along the axial direction.

The support cylinder portion P1 is a portion that supports the cylindrical member 5343a by making the inner diameter of the support cylinder portion P1 equal to the diameter of the cylindrical member 5343a of the transmission shaft rod 5343. The support cylinder portion P1 is a portion having the same axial arrangement as the region recessed in the elongated hole recess C1, and includes a deformed portion P1a that remains without being recessed in the elongated hole recess C1.

The deformed portion P1a is a pair of connecting rod portions arranged so as to sandwich the elongated hole recess C1, and elastically deforms when the right disk cam 5344R is axially tilted and deformed with respect to the transmission shaft rod 5343 (see FIG. 62). It is configured as a part to do.

The elongated hole recess C1 is formed so that the shape of the recessed cross section is slightly longer than the width dimension of the holding arm portion A1. Therefore, the holding arm portion A1 is configured to be displaceable in a direction (longitudinal direction) perpendicular to the width direction of the concave cross section of the elongated hole recess C1.

Further, the facing surface of the elongated hole recess C1 is formed to engage with the D-shape of the fixing portion 5343a1 of the cylindrical member 5343a. That is, one side surface is formed from a flat surface, and the other side surface is formed from an arc shape along the outer shape of the cylindrical member 5343a. This makes it possible to prevent the cylindrical member 5343a from rotating relative to the disk cam 5344.

The holding arm portion A1 includes an engaging convex portion A1a that projects from the surface of the pair of arm portions facing the other side of the arm toward the opposite side of the arm. .. The engaging convex portion A1a engages with the tip end portion of the cylindrical member 5343a when connected to the transmission shaft rod 5343, and prevents the cylindrical member 5343a from coming off the disc cam 5344.

The tip shape of the engaging convex portion A1a is configured to match the arc shape of the engaging groove 5343a4 of the cylindrical member 5343a (see FIG. 64). As a result, the overlapping length in the radial direction in the state where the engaging convex portion A1a is engaged with the engaging groove 5343a4 is compared with the case where the tip shape is flat or the center is a convex curved surface (FIG. 65). (B) The length in the left-right direction) can be secured for a long time.

The engaging convex portion A1a has a concave surface portion C2 (long hole concave portion) in which the side surface on the side close to the connecting pin 344d in the axial direction is the side surface of the right disk cam 5344R and is recessed along the axis in the vicinity of the shaft. It is arranged at a position that is a surface position with the side surface on the opening side of C1).

As a result, the engagement between the cylindrical member 5343a and the engaging convex portion A1a can be completed on the support cylinder portion P1 side (lower side in FIG. 63 (b)) than the concave surface portion C2 (FIG. 65 (b)). reference). Therefore, on the outside of the recessed surface portion C2 (upper side in FIG. 63B), the length of the cylindrical member 5343a protruding from the recessed surface portion C2 is set to be longer than that in the case where the e-ring is fitted into the cylindrical member 5343a. Can be shortened by the thickness of (see FIG. 65 (b)).

Further, it is not necessary to secure a space for fitting the e-ring (a space required for sliding the e-ring against the surface) in the extending direction (direction parallel to the surface) of the right disk cam 5344R. Therefore, the recessed width (diametrically wide) of the recessed surface portion C2 can be reduced. As a result, the degree of freedom in designing the shape of the right disk cam 5344R can be improved.

The transmission shaft rod 5343 will be described with reference to FIG. 64. FIG. 64 is a front exploded perspective view of the transmission shaft rod 5343. The difference between the transmission shaft rod 5343 and the transmission shaft rod 353 in the first embodiment is the cylindrical member 5343a.

The cylindrical member 5343a is the same as the fixing portion 5343a1 with the fitting groove 5343a3 sandwiched from the fixing portion 5343a1 having a D-shaped cross section for fixing the disk cams 5344 formed at both ends thereof and the fixing portion 5343a1 on the left side in the front view. A clutch operating portion 5343a2 having a D-shaped cross section formed from a cross-sectional shape, a fitting groove 5343a3 that is a groove for fitting an e-ring and positioning the disk cam 5344 in the axial direction by the e-ring, and a fitting groove thereof. When the disc cam 5344 is fitted until it reaches the e-ring fitted in the 5343a3, the engaging groove 5343a4, which is the groove in which the engaging convex portion A1a of the holding arm portion A1 engages, is mainly used. Be prepared. The fitting groove 5343a3 is arranged on the outer side in the left-right direction of the pair of plates into which the shaft support holes 341b are bored in the assembled state.

The clutch operating portion 5343a2 is a portion inserted into the angle fixing hole 343c1 of the movable clutch 343c, and is a portion in which the movable clutch 343c slides by the urging force of the coil spring 343d in the assembled state.

Since the mechanism is adopted in which the e-ring is later fitted into the fitting groove 5343a3 to form a portion in which the diameter is partially increased in the cylindrical member 5343a by the e-ring, the cylinder is formed before the e-ring is fitted. The diameter of the member 5343a can be made uniform.

In a state where the diameter is uniform, a predetermined amount of the cylindrical member 5343a is inserted into the shaft support hole 341b (see FIG. 62), and then the e-ring is fitted. In addition to preventing the misalignment along the above, the e-ring can further prevent the misalignment of the disc cam 5344 in the axial direction.

With the above-described configuration of the disc cam 5344 and the transmission shaft rod 5343, the disc cam 5344 can be assembled to the transmission shaft rod 5343 with one touch. That is, when the disc cam 5344 is assembled to the transmission shaft rod 5343, the cylindrical member 5343a is located on the end of the support cylinder portion P1 of the disc cam 5344 on the side where the engaging convex portion A1a is arranged. Insert from the opposite end to the position where the engaging convex portion A1a fits into the engaging groove 5343a4. At this time, before the engaging convex portion A1a is inserted into the engaging groove 5343a4 to the position where the engaging convex portion A1a is fitted, the tip portion of the cylindrical member 5343a is inserted between the engaging convex portions A1a, so that the pair of engaging convex portions A1a are formed. The holding arm portion A1 is elastically deformed in such a manner that the distance between them can be expanded. After that, when the tip of the cylindrical member 5343a passes through the engaging convex portion A1a, the engaging convex portion A1a and the engaging groove 5343a4 are arranged to face each other, and the engaging convex portion A1a fits into the engaging groove 5343a4. Then, the holding arm portion A1 elastically recovers, and the disk cam 5344 and the transmission shaft rod 5343 are assembled (see FIG. 65 (b)).

On the other hand, the configuration of the disk cam 5344 and the transmission shaft rod 5343 functions not only as a one-touch assembly but also as a structure for preventing destruction in the present embodiment. This will be described with reference to FIGS. 65 and 66.

FIG. 65 (a) is a front view of the right disk cam 5344R in the direction of arrow LXVa of FIG. 62, and FIG. 65 (b) is a front view of the right disk cam 5344R in the LXVb-LXVb line of FIG. 65 (a). FIG. 65 (c) is a cross-sectional view of the right disk cam 5344R in the LXVc-LXVc line of FIG. 65 (a). 66 (a) is a front view of the right disk cam 5344R in the direction of arrow LXVa of FIG. 62, and FIG. 66 (b) is a right disk cam in the LXVIb-LXVIb line of FIG. 66 (a). It is sectional drawing of 5344R.

Note that FIG. 66 shows the deformed right disk cam 5344R when the player applies an overload to the right disk cam 5344R in the no-load state shown in FIG. 65.

As shown in FIGS. 65 and 66, in the present embodiment, the cylindrical member 5343a is supported by the extended tip side portion of the support cylinder portion P1 at a position separated from the disk portion of the right disk cam 5344R, and is a disk. In the vicinity of the portion, the engaging convex portion A1a only engages with the engaging groove 5343a4. Therefore, when an overload is applied to the cylindrical member 5343a or the right disk cam 5344R, the cylindrical member 5343a is configured to be capable of tilting around the extended tip portion of the support cylinder portion P1.

As shown in FIG. 65 (b), since the space of the elongated hole recess C1 is arranged in the direction in which the pair of holding arm portions A1 face each other, the resistance of the axial tilt displacement of the cylindrical member 5343a is reduced. On the other hand, as shown in FIG. 65 (c), in the direction in which the support cylinder portion P1 and the connecting pin 344d are connected, the cylindrical member 5343a and the right disk cam 5344R extend in the axial direction of the right disk cam 5344R. Since they come into contact with each other, the resistance of the axial tilt displacement of the cylindrical member 5343a becomes large.

Therefore, when the player forcibly presses (pulls up) the tilting device 310 and an overload is applied to the right disk cam 5344R (displacement of the connecting pin 344d via the arm member 345 (see FIG. 62)). The direction in which the right disk cam 5344R is deformed with respect to the cylindrical member 5343a can be restricted.

That is, since the right disk cam 5344R is deformed in the direction in which the resistance is small, as shown in FIGS. 66 (a) and 66 (b), when the right disk cam 5344R is overloaded, On a surface parallel to the surface of the disk portion, the disk portion is deformed by tilting around the support shaft r1 connecting the connecting pin 344d and the center of the support cylinder portion P1. As a result, the tip position of the connecting pin 344d is displaced along the circumferential direction of the right disk cam 5344R as compared with the position shown in FIG. 65 (a).

FIG. 67A is a cross-sectional view of the operation device 5300 in the line corresponding to the line XXII-XXII of FIG. 6A, and FIG. 67B is an operation in the direction of the arrow LXVIIb of FIG. 67A. It is a partial rear view of the device 5300. In FIG. 67B, the protective cover device 350 is not shown, and only the disk cam 5344, the arm member 345, and the release member 346 are shown. Further, in FIG. 67A, in order to facilitate understanding, the outer shape of the right disk cam 5344R in a state of being vertically inserted and fixed to the transmission shaft rod 5343 is shown by a solid line, and an overload is applied to cause the shaft to collapse. The outline of the state is shown by an imaginary line.

In FIG. 67A, the second state of the tilting device 310 is shown, the hand of the player holding the tilting device 310 is shown, and the state near the connecting pin 344d is enlarged and shown. ..

In the state shown in FIG. 67 (a), when the drive motor 342 (see FIG. 62) starts operating, the left disk cam 5344L is likely to start rotating, but the player is restricted from the displacement of the tilting device 310. Therefore, a load is generated between the arm member 345 that tries to stay in place and the connecting pin 344d of the left disk cam 5344L that tries to rotate. When this load is generated, the right disk cam 5344R can undergo the above-mentioned shaft tilt deformation, so that the load can be alleviated.

In FIG. 67A, the outer shape of the right disk cam 5344R after the shaft tilt deformation is shown by an imaginary line. The change in the connection mode with the arm member 345 due to the shaft tilt deformation will be described with reference to an enlarged view.

In FIG. 67 (a), when the outer circumference of the right disk cam 5344R is rotated clockwise by the dimension Rd due to the start of operation of the drive motor 342 (see FIG. 62), the shaft support of the arm member 345 is rotated by the dimension Rd. The hole 345a and the connecting pin 344d are misaligned, and in order to absorb this, the right disk cam 5344R is deformed by tilting the shaft.

Since the connecting pin 344d is tilted in the direction perpendicular to the paper surface in FIG. 67A due to the shaft tilt deformation, the center Pb on the root side of the connecting pin 344d and the center Pt on the convex tip side are right circles. The position shifts along the circumferential direction of the plate cam 5344R. Since this misalignment can partially absorb the misalignment between the connecting pin 344d and the arm member 345 due to the rotation of the dimension Rd of the right disk cam 5344R, the drive motor can be driven while the tilting device 310 is being gripped. When the 342 (see FIG. 62) is driven, the load applied to the drive motor 342 can be relaxed.

As shown in FIG. 67 (b), the disc cam 5344 is deformed by tilting the shaft, so that the disc cam 5344 and the release member 346 come into contact with each other. As a result, the driving force of the drive motor 342 is consumed by the frictional force generated between the release member 346 and the disc cam 5344, so that the player drives the drive motor 342 while holding and fixing the tilting device 310. In this case, the load applied to the arm member 345 connecting the disc cam 5344 and the tilting device 310 can be reduced.

As shown in FIG. 67 (a), when the disk cam 5344 rotates in the backward rotation direction (direction of arrow CW), the release member 346 is pushed upward by the frictional force, but the second spring is in the direction of repulsion. The elastic force of SP2 acts on the disk cam 5344 via the release member 346. In this case, since the rotary claw member 347 is stopped by the bottom plate portion 5321 and stops, the state of the first spring SP1 does not change (the elastic force does not change).

On the other hand, when the disc cam 5344 rotates in the forward rotation direction (arrow CCW direction, see FIG. 68), the release member 346 is pushed downward by the frictional force, but the elastic force of the first spring SP1 repels it. Acts on the disc cam 5344 via the release member 346 and the rotary claw member 347. In this case, since the relative positional relationship between the rotary claw member 347 and the release member 346 does not change, the state of the second spring SP2 does not change (the elastic force does not change).

Therefore, when the release member 346 and the disk cam 5344 come into contact with each other and the release member 346 operates along the operation direction of the disk cam 5344, the first spring SP1 or the first spring SP1 or Of any of the elastic forces of the second spring SP2, the elastic force acting on the disk cam 5344 can be increased in the direction opposite to the rotation direction of the disk cam 5344. As a result, the load applied to the disc cam 5344 by the release member 346 can be increased, and the amount of consumption of the driving force of the drive motor 342 can be increased. Therefore, the load applied to the arm member 345 can be increased by the disc cam 5344. It can be reduced regardless of the rotation direction of.

In the present embodiment, the right disk cam 5344R is formed from a shape that is axisymmetric with respect to the straight line passing through the connecting pin 344d and the center point (direction perpendicular to the straight line passing through the connecting pin 344d and the center point). (Because the elongated hole recess C1 is extended), the right disk cam 5344R is similarly deformed regardless of the rotation direction of the right disk cam 5344R (regardless of the misalignment direction of the connecting pin 344d with respect to the arm member 345). The shaft can be tilted and deformed by resistance.

68 (a) is a cross-sectional view of the operation device 5300 in the line corresponding to the XXII-XXII line of FIG. 6 (a), and FIG. 68 (b) is an operation in the direction of arrow LXVIIIb of FIG. 68 (a). It is a partial rear view of the device 5300. In FIG. 68 (b), the protective cover device 350 is not shown. Further, in FIG. 68A, in order to facilitate understanding, the outer shape of the right disk cam 5344R in a state of being vertically inserted and fixed to the transmission shaft rod 5343 is shown by a solid line, and an overload is applied and the shaft collapses. The outline of the state is shown by an imaginary line.

FIG. 68A shows a state in which the tilting device 310 is driven by the drive motor 342 (see FIG. 62) from the second state and tilted down by an angle D2, and the tilting device 310 is in the middle of the operation of the drive motor 342. The player's hand holding the is illustrated.

As shown in FIG. 68A, when the player grips the tilting device 310 during the operation of the tilting device 310, the right disk cam 5344R is used regardless of whether the tilting device 310 is in the second state or not. The tip of the connecting pin 344d can be displaced in the circumferential direction of the right disk cam 5344R due to the shaft tilting of the arm member 345, thereby reducing the load generated between the arm member 345 and the right disk cam 5344R. Therefore, the load applied to the drive motor 342 can be reduced.

The matter described as the right disc cam 5344R also applies to the left disc cam 5344L.

As shown in FIGS. 67 (b) and 68 (b), according to the present embodiment, the drive motor 342 (see FIG. 62) operates while the player holds the tilting device 310, and an overload occurs. Then, the right disk cam 5344R tilts in the axial direction.

Therefore, by detecting the degree of tilting motion in the axial direction, it is possible to notice the occurrence of overload at an early stage. That is, for example, according to the configuration of the first embodiment, if the drive motor 342 is driven for a period during which the right disk cam 344R makes one rotation, the detection hole 344eR of the right disk cam 344R passes through the right side detection sensor 353R. However, when the player is holding the tilting device 310, the right disk cam 344R does not rotate even if the drive motor 342 is rotated, so that the detection hole 344eR does not pass through the right side detection sensor 353R and the right side detection sensor. Since the input to the 353R does not change, it is detected that an overload has occurred.

In this case, since it is necessary to rotate the right disk cam 344R by a predetermined angle before the occurrence of the overload is detected, there is a problem that the detection of the overload is delayed. there were.

On the other hand, according to the present embodiment, when the right disk cam 5344R is overloaded and the right disk cam 5344R is tilted in the axial direction (see FIG. 66B), the overload is applied. Occurrence can be detected. Therefore, the occurrence of overload can be detected at an early stage. As a detection method, for example, a method using a notification device E1 fixed to the engaging rib 344c between the support cylinder portion P1 and the engaging rib 344c is exemplified (illustrated by an imaginary line in FIG. 66A). ).

The notification device E1 is a detection device that outputs a signal when an object comes into contact with an input unit, and is arranged in pairs at a position where a straight line connecting a pair of holding arm portions A1 and an engaging rib 344c intersect. At the same time, the input portion is arranged so as to project toward the support cylinder portion P1 side. In the no-load state, the notification device E1 and the support cylinder portion P1 are separated from each other (see FIG. 65B), and in the overload state, the notification device E1 and the support cylinder portion P1 are in contact with each other (FIG. FIG. 66 (b)). Thereby, by determining the output from the notification device E1, it is possible to determine at an early stage whether or not the disk cam 5344 is overloaded.

Next, the operation device 6300 according to the sixth embodiment will be described with reference to FIGS. 69 to 73.

In the first embodiment, the case where the disc cam 344, the connecting pin 344d, and the engaging rib 344c are integrally formed has been described, but the operation device 6300 in the sixth embodiment includes the disc cam 344 and the engaging rib. The 344c is composed of a separate member, and is configured to be rotatable relative to each other. The same parts as those in the above-described embodiments are designated by the same reference numerals, and the description thereof will be omitted. First, the difference in configuration from the first embodiment will be described with reference to FIGS. 69 and 70.

FIG. 69 is an exploded front perspective view of the drive device 6340 according to the sixth embodiment, and FIG. 70 is a front exploded perspective view of the disk member 6344L1, the ring member 6344L2, and the second transmission member 6348 of the left disk cam 6344L. Is. The right disk cam 6344R is also different from the configuration of the first embodiment, but since the right disk cam 6344R is composed of a mirrored shape with respect to the left disk cam 6344L, the description of the left disk cam 6344L will be described. Only the right disk cam 6344R will be omitted.

As shown in FIG. 69, in this embodiment, the configuration of the left disk cam 6344L and the shape of the fixing member 6342a are different from those of the first embodiment, and a second transmission device 6348 is added.

The left disk cam 6344L has a circular rib 344b connecting pin 344d and a detection hole 344eL arranged in the same manner as in the first embodiment, and the disk member 6344L1 pivotally supported by the cylindrical member 343a and the disk member 6344L1. A ring member 6344L2 that is coaxially pivotally supported and rotates relative to a disk member 6344L1 is provided.

In the disk member 6344L1, the central shaft portion 344a of the first embodiment is arranged at the center position of the disk portion, and is radially outwardly separated from the outer peripheral portion of the circular rib 344b in an annular shape in the axial direction. The annular rib 6344f is provided so as to be convex along the ring rib 6344f.

The ring member 6344L2 has a ring body 6344g having the same outer peripheral diameter as the engaging rib 344c in the first embodiment and a ring shape having an inner peripheral diameter slightly larger than the outer peripheral diameter of the circular rib 344b, and a circle thereof. A lid plate portion 6344h that is arranged at the axial end of the ring body 6344g and covers the ring-shaped opening of the ring body 6344g, and the thickness increases from the lid plate portion 6344h to the opposite side of the ring body 6344g. 6344i is provided with a receiving gear tooth 6344i, which is formed in a thickened portion thereof and is arranged on the outer side in the radial direction.

Since the inner peripheral diameter of the annular main body 6344g is formed to be larger than the outer peripheral diameter of the circular rib 344b, the central shaft portion 344a is formed by fitting the annular main body 6344g to the circular rib 344b in the assembled state. The ring member 6344L2 is supported so as to be relatively rotatable around the center.

The end face of the annular body 6344g on the axial disc member 6344L1 side comes into contact with the annular rib 6344f. As a result, the contact area can be reduced and the frictional resistance can be reduced as compared with the case where the annular rib 6344f is not formed and the surface is in contact with the disk member 6344L1. Therefore, the relative rotation between the disk member 6344L1 and the ring member 6344L2 can be smoothly performed.

The receiving gear tooth 6344i is meshed with the deceleration transmission gear 6348c of the second transmission device 6348. Therefore, the ring member 6344L2 rotates based on the rotation of the second transmission device 6348. In this embodiment, the number of rotations of the ring member 6344L2 is three times the number of rotations of the disk member 6344L1 (while the ring member 6344L2 makes three rotations, the disk member 6344L1 makes one rotation. , The number of teeth of the second transmission gear 6348b, the reduction transmission gear 6348c, and the receiving gear tooth 6344i is set).

The second transmission device 6348 is a device that is rotatably supported by the fixing member 6342a along with the transmission shaft rod 343, and is an auxiliary pillar member 6348a arranged in a posture parallel to the cylindrical member 343a and its auxiliary pillar. A second transmission gear 6348b fixed to the member 6348a and meshed with the transmission gear 343b, and a deceleration transmission gear fixed to both ends of the auxiliary column member 6348 and meshed with the receiving gear teeth 6344i of the ring member 6344L2. Mainly includes 6348c.

With reference to FIGS. 71 to 73, it will be described that the ascending operation of the tilting device 310 after the fixing by the rotary claw member 347 is removed from the first state of the tilting device 310 is composed of a plurality of types.

71, 72, and 73 are cross-sectional views of the operating device 6300 in the line corresponding to the XXII-XXII line of FIG. 6 (a). Note that FIG. 71 shows a state similar to the state shown in FIG. 36, and FIG. 72 shows a posture in which the ring member 6344R2 makes one rotation in the backflip direction (arrow CW direction) from the state shown in FIG. 71 (correctly). A state in which the disk member 6344R1 is rotated 1/3 in the backward rotation direction (arrow CW direction) while being rotated in the reverse direction by the amount of the rotation after one rotation. Is illustrated. Further, FIG. 73 shows a state in which the ring member 6344L2 is rotated in the forward rotation direction (arrow CCW direction) by a predetermined angle from the state shown in FIG. 72, and the tilting device 310 is raised.

Here, when the ring member 6344R2 is rotated in the forward rotation direction (arrow CCW direction) from the state shown in FIG. 71 to release the fixation by the rotary claw member 347, the tilting device 310 is subjected to the urging force of the torsion spring 315. It rises instantly and reaches the second state (see FIG. 34).

In the operation device 300 according to the first embodiment, the arrival position when the tilting device 310 is lifted in an instant (without waiting for the rotation of the disk cam 344) by releasing the fixing by the rotary claw member 347 is in the second state. It was limited to the position where it was placed (see FIG. 34).

On the other hand, in the present embodiment, since the disk member 6344R1 and the ring member 6344R2 rotate relative to each other, the connecting pin 344d, which is the supporting portion of the arm member 345 connected to the tilting device 310, and the engaging rib 344c The relative relationship between the two can be changed, and the types of arrival positions of the tilting device 310 can be increased.

That is, when the fixing by the rotary claw member 347 is released from the state shown in FIG. 72, the tilting device 310 is instantaneously raised by the urging force of the torsion spring 315 and tilted downward by an angle D6 from the second state. (See FIG. 73). In this way, the tilting device 310 instantaneously (disk cam) is released from the state shown in FIG. 71 by the rotary claw member 347 and from the state shown in FIG. 72 by the rotary claw member 347. It can rise to (without waiting for the rotation of 344) and change the position to reach.

As a result, for example, when the tilting device 310 instantly rises from the first state and configures the gaming machine in a manner in which the expectation of the effect is changed by the difference in the height reached, the attention of the tilting device 310 is increased. Can be improved. In this case, it is not limited whether the expectation of the tilting device 310 to rise higher or the expectation of the tilting device 310 to rise lower is higher.

However, by keeping the ascending arrival position of the normal tilting device 310 low (see FIG. 73) and reaching the second state (see FIG. 34) when the expected degree is maximized, the expected degree is reached. The magnitude of the above can be associated with the magnitude of the amount of displacement that the player pushes the tilting device 310 into, so that the player can easily understand the difference in the degree of expectation due to the displacement of the tilting device 310.

In this case, since the player can be motivated to check to what position the tilting device 310 is raised, the player can watch the movement of the tilting device 310 until the operation timing of the tilting device 310. You can make it happen. Therefore, regardless of the effect mode of the tilting device 310, the method of the game in which the tilting device 310 is operated in a disorderly manner can be suppressed.

Next, the operation device 7300 according to the seventh embodiment will be described with reference to FIGS. 74 to 85.

In the first embodiment, the case where the disk cam 344, the connecting pin 344d, and the engaging rib 344c are integrally formed has been described, but in the operation device 7300 in the seventh embodiment, the disk cam 7344 is a disk member. The 7344R1 and the connecting pin 344d are arranged on separate members, and the separate members can form a fixed state in which they are fixed to each other and a sliding state in which they are relatively rotatable. The same parts as those in the above-described embodiments are designated by the same reference numerals, and the description thereof will be omitted. First, the features of the disc cam 7344 used as a substitute for the disc cam 344 in the first embodiment will be described with reference to FIGS. 74 and 75.

74 (a) is a front view of the right disk cam 7344R in the seventh embodiment, FIG. 74 (b) is a rear view of the right disk cam 7344R, and FIG. 75 (a) is FIG. 74. (A) is a cross-sectional view of the right disk cam 7344R in the LXXVa-LXXBa line, and FIG. 75 (b) is a partial side view of the right disk cam 7344R in the direction of arrow LXXVb of FIG. 74 (a). Since the right disk cam 7344L is composed of a mirrored symmetrical shape of the right disk cam 7344R, the description thereof will be omitted.

As shown in FIGS. 74 and 75, the right disk cam 7344R includes a disk member 7344R1 having a central shaft portion 344a into which the cylindrical member 343a (see FIG. 62) is inserted and fixed in the assembled state, and the disk member 7344R1. 7434R2, which is inserted along the axial direction from the opening side of the ring member, and the engaging portion 7630, which is made immovable in the radial direction of the disk member 7344R1 in the assembled state and fits into the equally divided recessed portion 7522 of the ring member 7344R2. Mainly includes an engaging member 7344R3 having the above.

The disk member 7344R1 is formed from a cup shape having a central shaft portion 344a at the center, and has a detection hole 344eR at a portion extending radially outward from the edge of the cup in a flange shape and an engaging rib. It is a member having a shape in which 344c is partially omitted (between the first overhanging portion 344c1 and the first retracting portion 344c2 is omitted).

The disk member 7344R supports the ring-shaped plate portion 7510 of the ring member 7344R2 on a surface in the assembled state, and has a first circular recessed portion 7410 which is a circular recessed portion centered on the central shaft portion 344a, and a first circular recessed portion 7410 thereof. 1 In the radial direction between the second circular recessed portion 7420, which is a circular recessed portion having a diameter smaller than that of the circular recessed portion 7410 and deeper in the axial direction, and the first overhanging portion 344c1 and the first retracting portion 344c2. An L-shaped insertion hole 7430 to be drilled and a fixing that is projected radially outward from the back side surface (outer peripheral side of the disk member 7344R1) of the second circular recessed portion 7420 in the vicinity of the insertion hole 7430. It mainly includes a protrusion 7440.

The insertion hole 7430 is a first elongated rectangular hole portion that is elongated along the axial direction of the disk member 7344R1 at a position deviated from the intermediate position between the first overhanging portion 344c1 and the first retracting portion 344c2. The second elongated hole 7432 which is a rectangular elongated hole portion extending from the bottom end of the elongated hole 7431 and the disk member 7344R1 of the first elongated hole 7431 along the circumferential direction of the disk member 7344R1. A return portion 7433 formed by projecting toward the second elongated hole 7432 side with the first elongated hole 7431 side of the lower end portion of the second elongated hole 7432 as a fulcrum.

The width direction (short direction) of the second long hole 7432 is smaller than the width direction (short direction) of the first long hole 7431, and the width of the engaging portion 7630 of the engaging member 7344R3. It is made smaller than the dimension in the direction (short direction).

The return portion 7433 is configured to be elastically deformable with the lower end portion (lower end portion in FIG. 75 (b)) of the second elongated hole 7432 as a fulcrum. Due to this elastic deformation, the return portion 7433 is formed so as to be movable outward of the second elongated hole 7432.

The fixing protrusion 7440 is inserted into the coil spring CS1 of the engaging member 7344R3, and is configured with a convex height sufficient to fix the position of the coil spring SC1.

Next, the ring member 7344R2 will be described with reference to FIG. 76. 76 (a) is a front view of the ring member 7344R2, FIG. 76 (b) is a rear view of the ring member 7344R2, and FIG. 76 (c) is a view in the direction of the arrow LXXVIc of FIG. 76 (a). It is a side view of the ring member 7344R2.

As shown in FIGS. 76 (a) to 76 (c), the ring member 7344R2 has a ring plate-shaped ring-shaped plate portion 7510 on which the connecting pin 344d is convexly provided, and an inner peripheral surface of the ring-shaped plate portion 7510. Mainly includes a thick portion 7520 extending in the thickness direction of the ring-shaped plate portion 7510 along the above and forming a star-shaped through hole in the central portion.

The ring-shaped plate portion 7510 has a plate thickness dimension equal to the recessed depth of the first circular recessed portion 7410, and an outer diameter dimension slightly smaller than the inner diameter dimension of the first circular recessed portion 7410. NS. Thereby, in the assembled state, it is possible to prevent the resistance of relative rotation from becoming excessive while aligning the axes of the ring member 7344R2 and the disk member 7344R1.

The thick portion 7520 has a length extending from the side surface of the ring-shaped plate portion 7510 so as to approach (do not interfere with) the second elongated hole 7432 in the assembled state (see FIG. 75 (a)), and have an outer peripheral diameter. However, it is slightly smaller than the inner peripheral diameter of the second circular recessed portion 7420. As a result, in the assembled state, the engaging member 7344R3 can be operated in the radial direction (vertical direction in FIG. 75A), and the relative rotation resistance between the ring member 7344R2 and the disk member 7344R1 is prevented from becoming excessive. can do.

The thick portion 7520 is recessed in the deformed through hole 7521 formed along the axial direction and the deformed through hole 7521 at equal intervals in the circumferential direction (divided into five equal parts in the present embodiment) in the radial direction outward. It mainly includes an equally divided recessed portion 7522 to be provided.

The deformed through hole 7521 has an inner peripheral shape that is arranged radially outside the engaging portion 7630 when the engaging member 7344R3, which will be described later, is pushed inward in the radial direction of the disk member 7344R1. It is composed.

77 (a) is a front view of the engaging member 7344R3, and FIG. 77 (b) is a side view of the engaging member 7344R3 in the direction of the arrow LXXVIIb of FIG. 77 (a).

As shown in FIGS. 77 (a) and 77 (b), the engaging member 7344R3 is outside the radial direction of the first overhanging portion 344c1 and the first retracting portion 344c2 in the assembled state (see FIG. 74 (b)). An arcuate plate portion 7610 arranged in the direction, an extension portion 7620 extending in the thickness direction from the back side end portion (right end portion in FIG. 77B) of the arcuate plate portion 7610, and an extension thereof. The engaging portion 7630 extending along the front-rear direction (left-right direction in FIG. 77B) from the extending tip of the portion 7620 and the engaging portion 7630 of the arcuate plate portion 7610 are arranged on the opposite side to the engaging portion 7630. It mainly includes a coil spring CS1 formed from a coil spring.

The arcuate plate portion 7610 includes a spring fixing protrusion 7611 which is a protrusion for fitting the coil spring CS1 at a position facing the tip end portion of the engaging portion 7630 on the inner peripheral side side surface.

The extension portion 7620 is a portion that is inserted into the second elongated hole 7432 in the assembled state, and when the extension portion 7620 is pushed inward in the radial direction in opposition to the elastic force of the coil spring CS1, the extension tip thereof becomes. It is composed of an extension length that projects inward from the inner peripheral surface of the ring member 7344R2.

The width direction of the engaging portion 7630 is slightly shorter than the width direction of the first elongated hole 7431, and the engaging portion 7630 is extended so as to pass through the deformed through hole 7521 of the thick portion 7520 in the assembled state. (See FIG. 75 (a)).

As will be described later, the engaging member 7344R3 has both a function as a member that receives a load from the releasing member 346 and is displaced, and a function of positioning the ring member 7344R2 with respect to the disc member 7344R1. Therefore, the number of members can be reduced.

A method of assembling the right disk cam 7344R will be described with reference to FIG. 78. 78 (a) is a front view of the right disk cam 7344R, and FIG. 78 (b) is a side view of the right disk cam 7344R in the direction of arrow LXXVIIIb of FIG. 78 (a). c) is a front view of the right disk cam 7344R, FIG. 78 (d) is a side view of the right disk cam 7344R in the direction of arrow LXXVIIId of FIG. 78 (c), and FIG. 78 (e) is a side view. It is a front view of the right disk cam 7344R, and FIG. 78 (f) is a side view of the right disk cam 7344R in the direction of the arrow LXXVIIIf of FIG. 78 (e).

In addition, in FIG. 78 (a), FIG. 78 (b), FIG. 78 (c) and FIG. 78 (d), the state in which only the engaging member 7344R3 is inserted into the disk member 7344R1 is shown, and FIG. 78 (e) ) And FIG. 78 (f) show a state in which the ring member 7344R2 and the engaging member 7344R3 are inserted into the disk member 7344R1. Further, in order to facilitate understanding, in FIGS. 78 (b), 78 (d) and 78 (f), the arcuate plate portion 7610 and the coil element pudding portion CS1 are not shown.

As an assembly method of the right disk cam 7344R, first, the engaging portion 7630 of the engaging member 7344R3 is inserted into the first elongated hole 7431 (see FIGS. 78 (a) and 78 (b)). As described above, the widthwise dimension of the second elongated hole 7432 is shorter than the widthwise dimension of the engaging portion 7630, so that the engaging portion 7630 is erroneously inserted into the second elongated hole 7432. Can be prevented. Therefore, it is possible to prevent an assembly error.

Next, the engaging member 7344R3 is slid along the extending direction of the second elongated hole 7432 until the position where the engaging portion 7630 and the fixing protrusion 7440 coincide with each other in the depth direction of FIG. 78 (d). Moving.

At the position after this movement, the fixing protrusion 7440 is inserted into the coil spring CS1, and the engaging member 7344R3 is suppressed from being displaced in the circumferential direction (left-right direction in FIG. 78 (d)) of the disk member 7344R1 and is engaged. The member 7344R3 can be held immovably in the radial direction of the disk member 7344R1.

Further, the engaging member 7344R3 is restricted from moving in the circumferential direction by the return portion 7433. This will be described. First, in a state where the engaging portion 7630 is inserted into the first elongated hole 7431, the return portion 7433 is driven to the outside of the second elongated hole 7432 (see FIG. 78 (b)). Next, when the engaging member 7344R3 is slid in the extending direction of the second elongated hole 7432, the vertical contact between the engaging member 7344R3 and the return portion 7433 is released, and the return portion 7433 is seconded by the elastic recovery force. It enters the inside of the elongated hole 7432 (see FIG. 78 (d)).

The tip of the return portion 7433 abuts on the extended portion 7620 of the engaging member 7344R3 in a state where it has entered the inside of the second elongated hole 7432, but the contact direction is the longitudinal direction of the return portion 7433 (deformation resistance is large). (See FIG. 78 (d)), the movement of the extension portion 7620 (movement to the right in FIG. 78 (f)) is suppressed. As a result, the movement of the engaging member 7344R3 in the circumferential direction can be restricted, so that the position of the engaging member 7344R3 can be prevented from being displaced during operation.

After holding the engaging member 7344R3 on the disc member 7344R1, the ring member 7344R2 is inserted from the opening side of the disc member 7344R1 with the engaging member 7344R3 pushed inward in the radial direction of the disc member 7344R1. do. By releasing the load from the engaging member 7344R3, the elastic force of the coil spring CS1 causes the engaging portion 7630 to move along the radial outward direction D7. Due to this movement, the engaging portion 7630 is accommodated in the equally divided recessed portion 7522 of the ring member 7344R2, whereby the ring member 7344R2 is fixed to the disk member 7344R1.

By the above-mentioned steps, the right disk cam 7344R can be easily assembled. The right disk cam 7344L is formed of a mirrored symmetrical shape of the right disk cam 7344R, and can be assembled in the same process as the right disk cam 7344R.

Next, with reference to FIGS. 79 to 81, the operation of the engaging member 7344R3 when the disk cam 7344 rotates in the backflip direction will be described. 79 (a), 79 (b), 80 (a), 80 (b) and 81 are partial cross-sectional views of the operating device 7300 in the line corresponding to the XXII-XXII line of FIG. In FIGS. 79 (a), 79 (b), 80 (a), 80 (b), and 81, the release member 7346, the rotary claw member 7347, and the disk cam 7344 are shown as the center, and others. Illustration of unnecessary parts is omitted.

The length of the guide slot 7347b of the rotary claw member 7347 in the present embodiment is different from that in the first embodiment. That is, as shown in FIG. 80A, the convex pin 346b is configured to be the end of movement at the ascending position when the engaging rib 344c abuts and passes from below.

The release member 7346 is different from the first embodiment in that the rear upper portion (upper right portion in FIG. 80 (a)) of the main body portion of the release member 7346 is obliquely scraped in order to minimize the interference with the engaging rib 344c.

In FIGS. 79 (a), 79 (b), 80 (a), 80 (b) and 81, the disk cam 7344 rotates in the backflip direction (clockwise in FIG. 79 (a)). Is illustrated in chronological order.

79 (a) shows a state in which the engaging member 7344R3 of the right disk cam 7344R abuts on the releasing member 7346 and the releasing member 7346 starts to rotate. FIG. 79 (b) shows FIG. 79 (a). The state in which the right disk cam 7344R is further rotated from the state shown in) is shown, and FIG. 80 (a) shows the state in which the engaging member 7344R3 is pushed into the disk member 7344R1 to the end. In (b), a state in which the disk member 7344R1 is further rotated in the backward rotation direction from the state shown in FIG. 80 (a) is shown, and in FIG. The state after the 7344R rotates in the backward rotation direction and the engaging member 7344R3 is separated from the releasing member 7346 is shown. In addition, in FIG. 79 (a), FIG. 79 (b), FIG. 80 (a) and FIG. 80 (b), the release member 7346 reaches the end of the range in which it can rotate relative to the rotary claw member 7347 ( (Small angle state) is shown.

As shown in FIG. 79 (a), the elastic force of the coil spring CS1 is set to be larger than the elastic force of the second spring SP2 in the state immediately after the engaging member 7344R3 and the releasing member 7346 start to come into contact with each other. Therefore, the engaging member 7344R3 is not pushed inward, and the state of projecting outward is maintained.

As shown in FIG. 79 (b), when the engaging portion 346d of the releasing member 7346 is in contact with the side surface of the outermost diameter of the engaging member 7344R3, the angle between the releasing member 7346 and the rotary claw member 7347 is small. Will be done.

In the present embodiment, the arcuate plate portion 7610 is formed in a small angle state in which the release member 7346 rotates in the forward rotation direction and the rotary claw member 7347 is pressed against the side surface of the insertion hole 321c of the lower frame member 320. The disk cam 7344 has a positional relationship in which the outer peripheral surface of the engaging member 7344R3 rubs against the release member 346 in a state where the inner peripheral surface and the first overhanging portion 344c1 and the first retracting portion 344c2 of the engaging rib 344c are in contact with each other. It is arranged (see FIG. 80 (a)).

That is, as shown in FIG. 80 (a), when the release member 7346 rotates toward the small angle state due to the rotation of the disk cam 7344 and becomes unable to rotate any more (small angle state), the release member A load is applied to the engaging member 7344R3 by pushing the engaging member 7344R3 inward in the radial direction of the disc cam 7344 from the 7346.

Then, as shown in FIG. 79 (b), in the state where the engaging member 7344R3 projects outward in the radial direction, the rotation in the backflip direction cannot be continued, and therefore, based on the rotation of the disk cam 7344. , The engaging member 7344R3 is pushed inward in the radial direction (see FIG. 80 (a)). In this pushed state, the engaging portion 7630 is arranged radially inward with respect to the minimum diameter portion of the deformed through hole 7521.

Therefore, the load in the circumferential direction is not transmitted to the ring member 7344R2 via the engaging portion 7630. Therefore, as shown in FIG. 80 (b), the disk member 7344R1 is rotated from the state shown in FIG. 80 (a). However, the ring member 7344R2 does not follow the rotation and maintains the posture.

Due to this deviation in the amount of rotation, the engaging portion 7630 moves from the originally arranged one equally divided recess 7522 to another different equally divided recess 7522, so that the disk member 7344R1 and the ring member 7344R2 The phase with and is rotated relative to each other by the amount of one recess (72 degrees).

After that, as shown in FIG. 81, when the right disk cam 7344R further rotates, the contact between the engaging member 7344R3 and the releasing member 7346 is released, so that the engaging member 7344R3 projects outward in the radial direction. Then, the engaging portion 7630 is again housed in the equally divided recessed portion 7522. In this process, the equally divided recessed portion 7522 in which the engaging portion 7630 is housed is displaced by one.

That is, by passing through the process shown in FIGS. 79 (a) to 81, the arrangement of the engaging rib 344c and the arrangement of the connecting pin 344d arranged on the ring member 7344R2 are equally divided into the recessed portion 7522. It can be relatively shifted by the arrangement interval (72 degrees) of the recessed portion.

With reference to FIG. 82, the operation of the engaging member 7344R3 when the disk cam 7344 rotates in the forward rotation direction will be described. 82 (a), 82 (b), 83 (a) and 83 (b) are partial cross-sectional views of the operating device 7300 in the line corresponding to the XXII-XXII line of FIG. In FIG. 82, the release member 7346, the rotary claw member 7347, and the disk cam 7344 are shown as the center, and the other unnecessary parts are not shown.

In FIGS. 82 (a) to 83 (b), how the disk cam 7344 rotates in the forward rotation direction (counterclockwise direction in FIG. 82 (a)) is illustrated in chronological order. FIG. 82 (a) shows a state immediately before the release member 7346 and the engagement member 7344R3 of the right disk cam 7344R come into contact with each other, and in FIG. 82 (b), the engagement member 7344R3 is above the release member 7346. The state in which the descent is started by being abutted from the above is shown, and in FIG. 83 (a), the state in which the disk cam 7344 is further rotated in the forward rotation direction from the state shown in FIG. 82 (b) is shown. In (b), the state after the release member 7346 and the engagement member 7344R are separated from each other is shown.

As shown in FIGS. 82 (a) to 83 (b), the disc cam 7344 rotates in the forward rotation direction, so that the release member 7346 and the rotary claw member 7347 move in the backward rotation direction (clock 82 (a)). When rotating in the clockwise direction), there is no member that restricts the movement of the release member 7346 and the rotary claw member 7347, and the release member 7346 and the rotary claw member 7347 apply a load in the forward rotation direction by the elastic force of the first spring SP1. Will only be.

Therefore, a load that pushes the engaging member 7344R3 inward in the radial direction is not generated, and the engaging member 7344R3 is radially outward from the time when the engaging member 7344R3 comes into contact with the releasing member 7346 until the engagement member 7344R3 is separated. Keep overhanging. Therefore, when the disk cam 7344 is rotated in the forward rotation direction, it is possible to prevent the disk member 7344R1 and the ring member 7344R2 from rotating relative to each other.

From these configurations, by switching the rotation direction of the disk cam 7344, it is possible to switch whether or not the disk member 7344R1 and the ring member 7344R2 rotate relative to each other. Therefore, in the rotation direction in which relative rotation does not occur (see FIGS. 82 and 83), it is possible to repeatedly tilt the tilting device 310 with the same tilting width as in the first embodiment. In the rotation direction that causes relative rotation (see FIGS. 79, 80, and 81), the tilt width of the tilt device 310 can be changed, unlike the first embodiment.

Further, in the present embodiment, the rotation direction of the disk member 7344R1 that relatively rotates the disk member 744R1 and the ring member 7344R2 is opposite to the direction in which the fixing by the rotating claw member 7347 is released (the direction in which the fixing is not released). Since they match, the disk member 7344R1 and the ring member 7344R2 can be relatively rotated while the tilting device 310 is maintained in the first state (see FIG. 84) (the posture is maintained constant).

As a result, a state that is not noticed by the player (a state in which the tilting device 310 is stopped) is used as a state for changing the relative posture of the disk member 7344R1 and the ring member 7344R2 in a place that is not visible to the player. be able to.

With reference to FIGS. 84 and 85, it will be described that, according to the present embodiment, it is possible to form a plurality of types of modes in which the tilting device 310 is moved up from the first state. 84 and 85 are cross-sectional views of the operating device 7300 in the line corresponding to the XXII-XXII line of FIG. In FIG. 84, by releasing the fixing by the rotary claw member 347, the tilting device 310 is immediately moved from the first state to the second state shown in FIG. 7B (without rotating the disk cam 7344). ) A state in which the ring member 7344R2 is fixed to the disk member 7344R1 in a phase relationship that can be displaced is shown. , A state in which the disc member 7344R1 is rotated relative to the equally divided recessed portion 7522 by one portion is shown. In both FIGS. 84 and 85, the second overhanging portion 344c3 hits the engaging portion 346d. The state of contact is shown.

As shown in FIGS. 84 and 85, according to the present embodiment, by releasing the fixing by the rotating claw member 347 from the first state, the tilting device 310 immediately (without rotating the disk cam 7344R2). The range of movement can be changed.

That is, when the fixing is released by rotating the rotary claw member 347 from the state shown in FIG. 84, the tilting device 310 moves to the second state (a state in which the tilting device 310 has moved to the uppermost end of the moving range).

On the other hand, when the fixing is released by rotating the rotary claw member 347 from the state shown in FIG. 85, the position of the connecting pin 344d is displaced to the rear lower side than the position shown in FIG. 2 Move to a state where it sinks below the state.

Therefore, by releasing the fixing by the rotating claw member 347, the position where the tilting device 310 immediately reaches (without rotating the disk cam 7344) by the ascending operation can be changed from the first state. As a result, it is possible to increase the types of effects produced by the operation of the tilting device 310, and to improve the attention of the operating device 7300 as an effect device.

Although the present invention has been described above based on the above-described embodiment, the present invention is not limited to the above-described embodiment, and it is easy to make various modifications and improvements within a range that does not deviate from the gist of the present invention. It can be inferred.

In each of the above embodiments, a part or all of the configurations in one embodiment may be combined with or replaced with a part or all of the configurations in another embodiment to form another embodiment.

In the first embodiment, the case where the tilting device 310 is pushed down is described, but the present invention is not necessarily limited to this. For example, a state in which the tilting device 310 hangs downward is set as the initial position, and the tilting device 310 may be pushed up. In this case, since the force for returning the tilting device 310 to the initial position can be provided by gravity, the torsion spring 315 can be eliminated.

In the first embodiment, the case where the voice coil motor 352 is driven after the tilting device 310 has moved to the push-in end is described, but the present invention is not necessarily limited to this. For example, the voice coil motor 352 may be driven in advance when the tilting device 310 is in the first state. In this case, the load required to push the tilting device 310 from the first state can be increased, and the change in the load can be used for the effect (for example, the effect of "the button that cannot be pushed" can be performed. can).

In this case, even if the voice coil motor 352 moves to the end of the operation (the end of the overhanging operation), the voice coil motor 352 has a dimensional relationship in which a slight gap is generated between the voice coil motor 352 and the lower frame member 320. And the lower frame member 320 are preferably arranged. As a result, it is possible to suppress the generation of an impact sound of collision with the lower frame member 320 during the operation of the voice coil motor 352. Therefore, it is possible to prevent the player from noticing that the voice coil motor 352 is overhanging in advance, and it is possible to make the player notice that the tilting device 310 is in the "non-pushable button" state only after the pushing operation. can.

In the first embodiment, the case where the engaging rib 344c of the disk cam 344 and the connecting pin 344d are relatively fixed has been described, but the present invention is not necessarily limited to this. For example, the engaging rib 344c may be formed of a separate member and may be configured so as to rotate relative to the disc cam 344. In this case, for example, since the position of the connecting pin 344d in the state where the first overhanging portion 344c1 and the engaging portion 346d are in contact with each other can be changed, the engaging rib 344c is rotated in the forward rotation direction from that state. Immediately after changing the posture of the rotary claw member 347, the degree to which the tilting device 310 rises can be changed. Therefore, it is possible to form more operating states of the tilting operation of the tilting device 310 than in the first embodiment.

Further, the operating state of the tilting device 310 can be sequentially switched (the ascending end can be sequentially switched) depending on the driving mode in which the disk cam 344 is continuously rotated in the forward rotation direction. As a result, by operating the drive motor 342 in one direction, it is possible to perform an effect in a complicated operation mode in which the ascending position of the tilting device 310 is sequentially switched while suppressing deterioration of the drive motor 342.

In the third embodiment, the case where the operation timing of the voice coil motor 352 that applies the driving force to the tilting device 310 is controlled by the operating speed of the tilting device 310 and the direction of operation has been described, but the present invention is not necessarily limited to this. It's not a thing. For example, the drive mode of the drive motor 5411 that rotationally drives the weight member 5412 may be controlled by the operating speed of the tilting device 310 or the direction of operation. For example, the drive motor 5411 is fixed in a posture in which the center of gravity of the weight member 5412 is arranged above the rotation axis until the tilting device 310 reaches the pushing end (while the tilting device 310 is in the descending operation), and the tilting device 310 pushes in. The rotation operation of the drive motor 5411 may be started immediately after reaching the end and immediately before starting to move upward. In this case, while pushing back when the tilting device 310 is repeatedly hit, the repulsive force that pushes back the tilting device 310 can be reduced, while the repulsive force that pushes back the tilting device 310 at the start of the upward operation of the tilting device 310 can be increased. ..

In the fifth embodiment, the case where the accommodating member 5430 is fixed to the bottom plate portion 5321 has been described, but the present invention is not necessarily limited to this. For example, the accommodating member 5430 may be fixed to the tilting device 310, and the vibrating device 5400 may be operated inside the accommodating member 5430. When fixing the accommodating member 5430 to the tilting device 310, for example, when the convex leg portion 5424 is arranged on the side facing the bottom plate portion 5321 and the tilting device 310 is moved to the lower pushing end, the convex leg By adopting a mode in which the portion 5424 is pressed against the bottom plate portion 5321, the shape of the flexible member 5420 in the vibrating device 5400 is changed, and whether or not the weight member 5412 can abut on the accommodating member 5430 is switched. good.

In this case, the flexible member 5420 arranged inside the accommodating member 5430 moves in conjunction with the tilting operation of the tilting device 310, and at this time, the shape of the flexible member 5420 changes. The degree of change in the shape of the flexible member 5420 changes in conjunction with the magnitude of the tilting speed when the tilting device 310 is operated. Therefore, by operating the tilting device 310 at a predetermined speed or higher, the flexible member 5420 The amount of deformation of the weight member 5412 can be increased to form a state in which the weight member 5412 is in contact with the accommodating member 5430. That is, not only when the tilting device 310 is pushed to the end, but also when the tilting device 310 is operated at high speed, the player can feel the vibration, so that the player can operate the tilting device 310. It is possible to increase the variation of the production of.

For example, when the player is allowed to operate the tilting device 310, a display such as "press the button." Is displayed on the third symbol display device 81, but "press the button. Push it in at high speed and feel vibration." By displaying such as "Great chance.", It is possible to give the player an effect of designating how to press the button (tilting device 310). In this case, by setting whether or not the player has pressed the button (tilting device 310) with the specified pressing method as a condition for transmitting the vibration to the player, the button (tilting device 310) can be pressed with the specified pressing method. The motivation of the player for the operation can be increased, and the operation of the button (tilting device 310) can be prevented from becoming monotonous.

Regarding the degree of change in the shape of the flexible member 5420, the degree of pushing speed of the tilting device 310 and the magnitude relationship may be reversed. That is, when the tilting speed of the tilting device 310 is slow, the amount of deformation of the flexible member 5420 becomes large, and the weight member 5412 and the accommodating member 5430 may be formed in such a manner that they can come into contact with each other. In this case, a small pushing speed of the tilting device 310 can be a condition for transmitting the vibration generated from the vibrating device 5400 to the player, and the player is recommended to slow down the pushing speed of the tilting device 310. can do. As a result, it is possible to prevent the player from pushing the tilting device 310 by force and operating it, and it is possible to prevent a failure that occurs when the tilting device 310 is pushed by force.

In the fifth embodiment, the case where the player can feel the vibration generated from the vibrating device 5400 by pushing the tilting device 310 has been described, but the present invention is not necessarily limited to this. For example, the weight member 5412 of the vibrating device 5400 is arranged so as to be able to come into contact with the accommodating member 5430 when the tilting device 310 is not pushed in, while the weight member 310 is pushed to the end of movement. The 5412 may be formed in such a manner that the 5412 may be arranged so as not to be in contact with the accommodating member 5430. In this case, while the tilting device 310 can be transmitted to the player in a state where the tilting device 310 is not operated to make the effect lively, the player can change the effect mode (expected) by stopping the vibration when the tilting device 310 is pushed in. Since it is possible to recognize (difference in degree), it is possible to produce a premier feeling that only the player who is playing this machine can feel the change in the production mode, excluding the surrounding players. can.

As a variation of the effect, when the player pushes in the tilting device 310, the weight member 5412 and the accommodating member 5430 cannot be brought into contact with each other, and the weight member 5412 and the accommodating member 5430 continue. It is desired to generate both a case where the arrangement is possible to abut the same, and this can be realized by changing the operation mode of the weight member 5412. For example, two different cases can occur due to the difference in the rotation direction of the weight member 5412.

In the fifth embodiment, the case where the disc cam 5344 is deformed by tilting the shaft and the disc cam 5344 and the release member 346 come into contact with each other to generate a frictional force has been described, but the present invention is not necessarily limited to this. No. For example, the plate portion in which the shaft support hole 341b of the main body member 341 is bored partially projects in a direction close to the disc cam 5344, and is configured to come into contact with the disc cam 5344 when the shaft is tilted and deformed. You may. In this case, since the main body member 341 is not an operating part, a large frictional force generated between the disc cam 5344 and the movable release member 346 is secured as compared with the case where the disc cam 5344 and the movable release member 346 come into contact with each other. be able to. Therefore, the load applied to the arm member 345 that connects the disc cam 5344 and the tilting device 310 can be sufficiently reduced.

The present invention may be implemented in a pachinko machine or the like of a type different from each of the above embodiments. For example, once a jackpot is hit, a pachinko machine (commonly known as a two-time right item, a three-time right item) that raises the expected value of the jackpot until multiple times (for example, two or three times) a big hit state occurs. It may be carried out as). Further, after the jackpot symbol is displayed, it may be implemented as a pachinko machine that generates a special game that gives a player a predetermined game value on the condition that a ball is won in a predetermined area. Further, it may be carried out on a pachinko machine that has a winning device having a special area such as a V zone and is in a special gaming state on the condition that a ball is won in the special area. Further, in addition to the pachinko machine, it may be implemented as various game machines such as a pachinko machine, a sparrow ball, a slot machine, a so-called pachinko machine and a slot machine.

In the slot machine, for example, the symbol is changed by operating the operation lever in a state where a coin is inserted to determine the symbol effective line, and the symbol is stopped and confirmed by operating the stop button. It is a thing. Therefore, the basic concept of the slot machine is "provided with a display device that displays the identification information in a variable manner after displaying the identification information string composed of a plurality of identification information in a variable manner, and is caused by the operation of the starting operation means (for example, the operation lever). The variable display of the identification information is started, and the variable display of the identification information is stopped and confirmed and displayed due to the operation of the stop operation means (for example, the stop button) or after a predetermined time has elapsed, and the stop is stopped. It becomes a "slot machine that generates a special game that gives a player a predetermined game value on the condition that the combination of time identification information is specific". In this case, the game medium is represented by coins, medals, etc. Take as an example.

Further, as a specific example of a gaming machine in which a pachinko machine and a slot machine are fused, a display device for variably displaying a symbol sequence composed of a plurality of symbols and then confirming the symbol is provided, and a handle for launching a ball is provided. Some are not. In this case, after a predetermined amount of balls are thrown in based on a predetermined operation (button operation), the symbol variation is started, for example, due to the operation of the operation lever, and for example, due to the operation of the stop button or a predetermined amount. As time elapses, the fluctuation of the symbol is stopped, and a special game is generated that gives the player a predetermined game value on the condition that the confirmed symbol at the time of the stop is a so-called jackpot symbol, and the player is given a predetermined game value. Is for paying out a large amount of balls to the lower saucer. If such a game machine is used instead of a slot machine, only the ball can be treated as a game value in the game hall, which is a game value seen in the current game hall where pachinko machines and slot machines are mixed. Problems such as the burden on equipment due to the separate handling of medals and balls and restrictions on the locations where game machines are installed can be solved.

The concepts of various inventions included in the above-described embodiments in addition to the gaming machine of the present invention are shown below.

<Point where the player's pushing direction is from the back to the front>
In an operating device having an operating means for the player to push in, the operating device is arranged at a first state in a normal state and a position where the operating means projects from the first state with respect to the player. The two states can be configured, and the operating means is provided with an urging means for urging the operating means from the first state to the second state, and the pushing direction of the operating means in the second state is from the back side to the front side for the player. A gaming machine A1 characterized in that the direction is directed toward the side.

In a gaming machine such as a pachinko machine, there is a gaming machine in which an operating means that can be operated by a player moves back and forth between a first position and a second position (for example, Japanese Patent Application Laid-Open No. 2014-144218). See). However, in the above-mentioned conventional gaming machine, since the effect is performed in a manner that raises the expectation of the big hit to the player at the advance position, the player can easily operate the operating means at the advance position with a large acceleration. , It was necessary to design the strength of the operating means to be high. In this case, there is a problem that the operating means becomes heavy as a whole and the driving means for driving the operating means becomes large.

On the other hand, according to the gaming machine A1, when the pushing operation is performed in the second state, the pushing direction of the operating means is the direction from the back side to the front side for the player, so that the player moves straight up and down. Then, the momentum of pushing can be released by causing the part that cannot be operated as a slip between the player's hand and the operating means.

Also, from the player's playing posture, when the operating means is pushed around the shoulders and elbows, it becomes difficult to apply force toward the front, so the force applied by the player to the operating means should be naturally weakened. Can be done.

In the gaming machine A1, the operating device is rotatable about a shaft rod arranged on the back side of the player, is configured to be tilted up and down around the shaft rod, and has the operating means. A gaming machine A2 comprising tilting means, the tilting means arranging the operating means in the second state toward the opposite direction of the player.

According to the gaming machine A2, the tilting means having the operating means is configured to rotate, and the operating means are arranged in the opposite direction of the player in the second state, so that the game is played in the second state. It is possible to prevent a person from hitting an operating means.

Further, by placing the hand near the shaft rod and tilting the hand with the position as a fulcrum, the operating means can be easily pushed in, so that a new pushing operation method in which the acceleration of pushing is hard to be attached can be provided. , It is possible to prevent the operating device from being damaged by the pushing operation of the player.

The new pushing operation method is, for example, to place the outer side surface of the left little finger near the shaft rod and place the hand near the operating means with the palm raised in the vertical direction, and then turn the thumb side toward the operating means. Examples include a method of operating by tilting the palm, and a method of dropping the palm toward the operating means from a state in which the tip of the middle finger is placed near the shaft rod and the palm is arranged so as to face the operating means. Will be done.

In the gaming machine A1 or A2, the gaming machine A3 is characterized in that, in the first state, the direction of the pushing operation of the operating means is the vertical direction.

According to the gaming machine A3, in addition to the effect of the gaming machine A1 or A2, the direction of the pushing operation of the operating means in the first state is the vertical direction, so that the second state is ensured while ensuring the operability in the first state. It is possible to prevent destruction by pushing in the state.

In the gaming machine A3, the operating device includes a driving means for generating the driving force for the automatic operation while the operating means is configured to be automatically operable, and the driving force of the driving device is pushed by the player. The gaming machine A4 is characterized in that it acts in the direction in which it acts and does not act in the opposite direction.

According to the gaming machine A4, in addition to the effect of the gaming machine A3, the driving force of the driving means for automatically operating the operating device acts only in the pushing operation direction, so that the driving force is in the direction opposite to the operating direction of the player. Can be prevented from acting. Therefore, it is possible to prevent the driving means from being damaged by the operation of the player.

For example, by adopting a configuration in which only the button can be pushed in, it is possible to prevent the driving means from being pulled by the player in the opposite direction when performing the operation of retracting the button and receiving a high load on the driving means.

In the gaming machine A4, a maintenance state for maintaining the operation device in the first state or the second state can be formed, and a maintenance means for operating by the drive means is provided, and the drive means is said to be via an eccentric portion. The operating means has a rotating means for transmitting a driving force, and the rotating means can change the phase between the first phase and the second phase different from the first phase while keeping the maintaining means in the maintenance state. In the first phase and the second phase, the range in which the operating means can move is changed when the maintenance state is released, and in both the first phase and the second phase, the same rotation causes the operation means to move. A gaming machine A5 configured to be able to release the maintenance state.

According to the gaming machine A5, in addition to the effect of the gaming machine A4, the phase of the driving means can be changed while the maintaining means is kept in the maintenance state, and the movement for releasing the maintenance state is rotated in the phase after the change. By using the means, the movement width in which the operating device moves can be changed by the urging means. Therefore, it is possible to configure a plurality of operation modes by the urging means.

In the gaming machine A5, the maintenance means is movable in the urging direction of the urging means in the maintenance state, and the moving speed of the maintaining means increases or decreases according to the rotation speed of the rotating means. The gaming machine A6 configured in such a manner that the operating means moves following the movement of the maintaining means.

According to the gaming machine A6, in addition to the effect of the gaming machine A5, the movement of the urging means in the direction of the urging force is caused only by the urging force, so that the mode of movement is limited to one. Since it is possible to add a movement mode of moving following the maintenance means to the operation means, it is possible to increase the types of movement modes of the operation means. As a result, the degree of attention of the operating device can be improved.

In any of the gaming machines A1 to A6, a light emitting means that is arranged inside the operating device and irradiates light toward the player is provided, and the second state is compared with the first state. However, from the player's point of view, the gaming machine A7 is characterized in that the area of the operating means is reduced and the irradiation range of the light emitted by the light emitting means is expanded.

According to the gaming machine A7, in addition to the effect of any of the gaming machines A1 to A6, a light emitting means is provided, and the second state is irradiated by the light emitting means from the player's viewpoint as compared with the first state. Since the irradiation range of the light to be emitted is expanded and the area of the operating means is reduced, the player can pay attention to the light and the effect of the effect can be improved, and it is difficult to press the operating means without aiming. It is possible to reduce the power of the player at the time of operation.

In the gaming machine A7, the operating means is made of a non-transparent material, and the area of the exposed portion of the light emitting means changes as the operating means moves away from the display means in close proximity to the display means. A featured gaming machine A8.

According to the gaming machine A8, in addition to the effect of the gaming machine A7, the operating means is made of a non-transparent material, and the operating means moves away from the display means in close proximity to the display means. Since the area of the exposed portion of the above is changed, it is possible to prevent the emitted light from being reflected on the display means and making the image of the display means difficult to see.

<Points where the repulsive force during normal times is small while making it possible to respond to repeated hits>
In an operating device having an operating means capable of allowing a player to operate up to the terminal position, the first state and the second state in which the range of motion of the operation up to the terminal position is wider than that of the first state. A game in which a first driving means for generating a driving force for moving from a second state to a first state is provided, and an urging means for generating an urging force for moving from a first state to a second state is provided. The gaming machine B1 is characterized by comprising a second driving means for generating a driving force for moving the operating means from the first state to the second state according to the operation of the player.

In a gaming machine such as a pachinko machine, there is a gaming machine in which an operating means that can be operated by a player moves back and forth between a first position and a second position (for example, Japanese Patent Application Laid-Open No. 2014-144218). See). However, in the above-mentioned conventional gaming machine, the force for returning the operating means to the initial position is generated by the spring, and the driving motor automatically operates the operating means. However, it is better to lower the elastic constant of the spring to drive the driving motor. However, in that case, the return of the operating means is delayed, and when the player's operation is fast, the operating means does not follow the player's operation, which makes it difficult for the player to perform the continuous striking operation. There was a problem.

According to the gaming machine B1, by setting the urging force to be weak, the driving force of the motor can be reduced when the operating means is moved by the first driving means, while the driving force of the motor can be reduced, but when it is desired to speed up the return of the operating means, the first is By pushing back the operating means with the two driving means, the return can be made faster, so that the player can enjoy the continuous striking operation.

The gaming machine B1 is provided with a continuous striking discriminating means for determining whether or not a continuous striking operation is performed based on a sensor detection value of a stroke operating means within a predetermined time, and a second driving means is provided based on the detection value of the continuous striking discriminating means. A gaming machine B2 characterized in that it determines whether or not to drive it.

According to the gaming machine B2, since it is determined whether or not to drive the second driving means based on the detection value of the continuous hitting determination means, the player does not perform the continuous hitting operation (for example, a single push operation or a long press). It is possible to prevent the player from feeling the load of pushing his / her hand back by operating the second driving means even when the player is performing an operation or the like.

In the gaming machine B2, the terminal detecting means for detecting the position of the operating means and detecting whether or not the operating means is arranged at the terminal position, and whether or not the operating means is arranged at a position changed by a predetermined amount from the terminal position. The moving direction determining means is provided with the positional difference detecting means for detecting and the moving direction determining means for determining the moving direction of the operating means from the time relationship between the detected value of the terminal detecting means and the detected value of the positional difference detecting means. The gaming machine B3, characterized in that the second driving means is driven when the direction of movement determined by the above is the direction of returning from the push-in end to the first state.

According to the gaming machine B3, in addition to the effect of the gaming machine B2, when the direction of movement determined by the moving direction determining means is the direction of returning from the pushing end to the first state, that is, the player's hand is from the button. Since the second driving means is driven at the timing of moving in the direction of separation, it is possible to generate a load that pushes back the operating means in a form synchronized with the movement of the player.

Therefore, it is possible to prevent the second driving device from operating in the direction opposite to the moving direction of the player's hand and applying a high load to the player's hand.

In any of the gaming machines B1 to B3, the second driving means is composed of a voice coil motor that vibrates and displaces along the direction connecting the first state and the second state of the operating means. Game machine B4 to play.

According to the gaming machine B4, in addition to the effect of any of the gaming machines B1 to B3, the vibration displacement of the voice coil motor can be effectively used to generate a driving force for moving the operating means.

In any of the gaming machines B1 to B3, a support frame for supporting the operating means is provided, and the second driving means elastically supports a drive motor for rotating the eccentric weight and the drive motor on the support frame. A mode in which the supporting means is provided with, and the driving force for moving the operating means from the position of the first state to the position of the second state increases as the operating means approaches the terminal position. The gaming machine B5 is characterized in that the eccentric weight comes into contact with the support frame in a state where the operating means is arranged at the terminal position to generate a driving force.

According to the gaming machine B5, in addition to the effect of any of the gaming machines B1 to B3, the driving force by the second driving means is generated by the driving force generated by the supporting means and the contact between the eccentric weight and the support frame. By generating it separately from the driving force, it is possible to adjust the driving force given to the operating means while maintaining the rotation of the driving motor. At this time, it is not necessary to control the start or stop of the rotation of the drive motor, and the rotation of the drive motor can be maintained while being maintained.

In the gaming machine B5, the eccentric weight moves close to the support frame in the moving direction of the operation means based on the operation means being arranged at the terminal position, and comes into contact with the support frame. A game machine B6 characterized by.

According to the gaming machine B6, in addition to the effect of the gaming machine B5, the eccentric weight moves close to the support frame in the moving direction of the operating means and comes into contact with the support frame, so that the repulsive force generated by the contact is utilized. Then, the drive motor can be moved in the direction away from the support frame in the moving direction of the operating means. As a result, the support means for supporting the drive motor moves in a direction away from the support frame (direction closer to the operation means), so that the driving force for pushing back the operation means can be further increased.

<Points of using VCM as a braking device and vibration effecting device>
A detection sensor for detecting a position near the terminal position of the operating means is provided, and the detection sensor is composed of a plurality of sensors, a measuring means for measuring the speed of the operating means from the detection interval of the detection sensor, and the measuring means thereof. A threshold determination means for determining whether or not the measured value measured by the above is equal to or higher than a predetermined threshold, and a repulsion means for generating a driving force in the direction opposite to the pushing direction of the operating means are provided. When the measured threshold value is equal to or higher than a predetermined threshold value, the driving force generated by the repulsive means increases as compared with the case where the threshold value measured by the threshold value determination means is equal to or lower than the predetermined threshold value. Characteristic gaming machine C1.

In a gaming machine such as a pachinko machine, there is a gaming machine in which an operating means that can be operated by a player moves back and forth between a first position and a second position (for example, Japanese Patent Application Laid-Open No. 2014-144218). See). However, in the above-mentioned conventional gaming machine, if the player emphasizes the ability to operate lightly, the operation resistance becomes low and the operation means may be damaged by the operation of the player. Although the speed can be reduced and the possibility of damage to the operating means can be reduced, there is a problem that the force required for the player's operation increases and the operation of the operating means becomes a burden for the weak player. ..

On the other hand, according to the gaming machine C1, the threshold value determining means determines whether the speed of the operating means is equal to or higher than the threshold value, and if the speed is equal to or higher than the threshold value, the driving force generated by the repulsive means is increased. Therefore, the operation resistance can be reduced when the speed of the operation means is equal to or less than the threshold value, and the operation means can be decelerated only when necessary. Therefore, the repulsive means can improve the operability and prevent the destruction.

In the game machine C1, the repulsive means includes a voice coil motor that generates a driving force in the direction opposite to the pushing direction of the operating means, and the threshold measured by the threshold determining means is equal to or higher than a predetermined threshold. The voice coil motor is pushed out to an extended position, and the voice coil motor is driven in advance before the operating means is arranged at a position where it can come into contact with the voice coil motor. Game machine C2 to play.

According to the game machine C2, in addition to the effect of the game machine C1, the voice coil motor can be driven and controlled to decelerate the operating means, and the operating means is arranged at a position where it can come into contact with the voice coil motor. By driving the voice coil motor before the operation, the impact generated between the operating means and the voice coil motor can be suppressed.

The gaming machine C3 is characterized in that, after the operating means and the voice coil motor come into contact with each other, the gaming machine C1 or C2 is controlled to increase the current flowing through the voice coil motor.

According to the game machine C3, in addition to the effect of the game machine C1 or C2, the operation means is controlled by increasing the current flowing through the voice coil motor after the operation means and the voice coil motor come into contact with each other. It is possible to gradually improve the degree of braking of the operating means while suppressing the occurrence of a large load at the moment of contact with the voice coil motor, and it is possible to reduce the discomfort felt by the player during operation.

In the gaming machine C1, the repulsing means is arranged so as to be in contact with the operating means, and a driving force corresponding to a deformation amount deformed by the movement of the operating means is generated by spring elasticity. ..

According to the gaming machine C4, in addition to the effect of the gaming machine C1, the repulsive means generates a driving force corresponding to the amount of deformation by spring elasticity, so that the driving force is not delayed even when the moving speed of the operating means is high. Can be generated.

In the gaming machine C4, the repulsion means is compared when the value measured by the threshold value determination means is equal to or more than a predetermined threshold value and when the value measured by the threshold value determination means is equal to or less than a predetermined threshold value. The gaming machine C5 is characterized in that the movable region of the end portion of the repulsive means and the end portion on the opposite side of the operating means that comes into contact with the operating means is narrowed.

According to the gaming machine C5, in addition to the effect of the gaming machine C4, the movable area of the end of the repulsive means on the opposite side of the side that comes into contact with the operating means is narrowed, so that the operating means can be operated. When the speed is high, the elastic force generated by the repulsive means can be increased.

<Prevents damage to the driving means by blocking the transmission of driving force with a clutch>
In an operating device having an operating means operated by a player, the operating device includes a driving means for generating a driving force for operating the operating means, a transmitting means for transmitting the driving force of the driving means to the operating means, and a transmission means for transmitting the driving force of the driving means to the operating means. A release means for releasing the transmission of the driving force is provided, and the release means of the driving force when the load generated between the driving means and the operating means via the transmitting means becomes a predetermined amount or more. A gaming machine D1 characterized by canceling transmission.

In a gaming machine such as a pachinko machine, there is a gaming machine in which an operating means that can be operated by a player moves back and forth between a first position and a second position (for example, Japanese Patent Application Laid-Open No. 2014-144218). See). However, in the above-mentioned conventional gaming machine, when the operating means is automatically operated for the purpose of production, if the operating means is operated during the automatic operation, a large load may be generated on the drive system. There was a problem.

On the other hand, according to the gaming machine D1, the releasing means is configured to release the transmission of the driving force when the load generated between the driving means and the operating means via the transmitting means becomes a predetermined amount or more. Therefore, even if the player operates the operating means when the operating means is automatically operated, the transmission of the load to the drive system is canceled (disconnected), and the load applied to the drive system can be suppressed. can.

In the gaming machine D1, the driving means is capable of driving in the first direction and driving in the second direction opposite to the first direction, and is driving in the first direction. The gaming machine D2 is characterized in that the release by the release means functions regardless of whether the drive is in the second direction.

Here, when it is determined whether or not the transmission of the driving force can be canceled depending on the operating direction of the driving means, the operating means is operated by the player when the driving means is driven in the operating direction in which the transmission of the driving force cannot be canceled. Then, a large load may be generated on the drive means. Therefore, the degree of freedom in the production when the operation means is operated to produce the production is reduced.

When the button is driven between the first position and the second position, the lock member that locks the button is moved in the release direction or in the release direction depending on whether the drive means rotates in the forward direction or in the reverse direction. Switch whether to move in the opposite direction. In this case, it is possible to create two modes of button operation (two patterns, a release pattern and a non-release pattern), but it is necessary that the driving force is interrupted in both of them.

On the other hand, according to the gaming machine D2, in addition to the effect of the gaming machine D1, the transmission of the driving force can be canceled (disconnected) in both directions of the driving direction regardless of the driving direction of the driving means. , It is possible to improve the degree of freedom of operation of the effect of automatically operating the operation means.

As a method of releasing the transmission, the clutch moves in a direction intersecting the operating direction of the driving means. The intersecting direction means, for example, excluding the circumferential direction when the driving means rotates, and the clutch may move in the rotation axis direction or in the radial direction.

The gaming machine D1 or D2 includes an urging means that urges the driving means and the transmitting means into a state in which the driving force can be transmitted, and the releasing means is a contact portion between the driving means and the transmitting means. The engaging teeth are provided with engaging teeth that transmit a driving force in a state in which they are meshed with each other, and the engaging teeth have both sides facing the operating direction of the driving means from the contact surface. The gaming machine D3 is characterized in that it is formed in a shape that is inclined with respect to the contact surface in a manner that tapers as the distance increases.

According to the gaming machine D3, in addition to the effect of the gaming machine D1 or D2, the urging means presses the driving means and the transmitting means, and the releasing means applies the driving force in a meshed state on the pressed contact surface. On the other hand, since both sides facing the operating direction of the driving means are provided with engaging teeth that are inclined so as to taper away from the contact surface, the transmitting means can be transmitted from the driving means by engaging the engaging teeth with each other. It can be separated, thereby releasing the transmission of the driving force.

Further, an urging force by the urging means is constantly applied between the driving means and the transmitting means, and when the transmitting means separates from the driving means, the urging force is applied to the operating direction of the driving means via the engaging teeth. A load is applied. Therefore, it is possible to suppress a sudden change in the load applied to the driving means between the state in which the driving force is transmitted and the state in which the transmission is released.

The size of the engaging portion of the engaging tooth becomes smaller in the circumferential direction of the transmitting means as the transmitting means moves away from the driving means. Therefore, when the phase difference between the transmission means and the driving means becomes large, it is possible to prevent the load generated in the circumferential direction of the transmission means from becoming excessive.

In addition, in the released state, the resistance is periodically restored instead of being separated and completely eliminated. As a result, when the player releases his hand, the button can be started to operate within a short time.

That is, if the player holds the button when the button is driven "as an effect", one phase of the button operation will elapse. Then, if the player releases his hand in the middle of the process and moves from the end of the first phase, the period in which the button is stopped becomes longer, and the feeling that "the player has started to move because the load has been released" is reduced. It comes off.

On the other hand, according to the gaming machine D3, the operating means can be started within a short time after the player releases the hand and the load is released. As a result, it is possible to produce a feeling that the player has started to move because the load on the player has been released.

In any of the gaming machines D1 to D3, the engaging surface of the transmitting means and the releasing means is formed from a sawtooth shape that engages with each other.

According to the gaming machine D4, in addition to the effect of any of the gaming machines D1 to D3, when the load from the player is released, the releasing means can be easily returned to the engaging position with the transmitting means at an early stage. That is, when the tip of the engaging surface has a plane parallel to the direction in which the transmitting means and the releasing means are close to each other, the transmitting means and the releasing means abut on the plane to transmit the releasing means. It is possible to prevent the movement from being stopped along the direction of approaching and separating from the means. Therefore, after the load from the player is released, the operation means can be started to operate at an early stage.

In any of the gaming machines D1 to D4, the operation mode of the operating means differs depending on whether the driving means is continuously operated in the forward direction or the driving means is continuously operated in the opposite direction. The gaming machine D5 characterized by.

According to the gaming machine D5, in addition to the effect of any of the gaming machines D1 to D4, while preparing a plurality of operating modes of the operating means, the driving force transmission is released without being limited to any of the operating modes. It can be carried out.

In the gaming machine D5, when there is a difference in whether the driving means operates in the forward direction or the reverse direction, the operating mode of the operating means is the operation mode for a predetermined period from the start of the operation of the driving means. Similarly, the gaming machine D6 is characterized in that the operation after the elapse of a predetermined period is different.

According to the gaming machine D6, when there is a difference in the operating direction of the driving means in the operating mode of the operating means in addition to the effect of the gaming machine D5, the operating mode of the driving means for a predetermined period from the start of the operation is the same. Since the operation after the elapse of the predetermined period is different, the player's attention to the operating means can be improved.

Here, by entwining the difference in the operation mode of the operation means with information that is beneficial to the player, such as the jackpot expectation degree, the operation of the operation means is performed by the player for a predetermined period until the operation mode of the operation means changes. You can watch over.

Further, since this difference in the operation mode is caused by the difference in the operation direction of the drive means, if the operation direction of the drive means can be confirmed in advance, the player can grasp the difference in the jackpot expectation degree without watching the operation of the operation means. Can be done. However, usually, the driving means is hidden from the player, and the difference in the operating direction cannot be recognized from the vibration sound or the like. Therefore, the operating direction of the driving means cannot be confirmed in advance, and the player cannot confirm the operating direction. Can be watched over by the operation of the operating means.

<Change the position of the cam protrusion based on the rotation of the cam>
In an operating device having an operating means operated by a player, the operating device includes a driving means for generating a driving force for operating the operating means, a transmitting means for transmitting the driving force of the driving means to the operating means, and a transmission means for transmitting the driving force of the driving means to the operating means. A first means that is configured to operate the operating means between a first position and a second position different from the first position and that suppresses the position of the operating means from changing from the first position. An urging means that urges the operating means from the first position toward the second position, and an operating means that moves the operating means from the first position to the second position by the urging force of the urging means. In a gaming machine including a terminal means for forming a movable end of the above in a changeable manner, the first means suppresses a change in the position of the operating means by engaging with the operating means. The first means is provided with a release load means for giving a load for disengaging the engagement of the one means to the first means, the disengagement by the release load means, and the movement termination of the operation means in the termination means. The gaming machine E1 characterized in that the change is performed by a single driving means.

In a game machine such as a pachinko machine, a movable operating means operated by a cam is fixed at the first position, and the fixing is released by a release load means so that the pachinko machine or the like is extended by the urging force of the urging means. , There is a gaming machine in which the displacement amount of the overhanging motion can be changed by a terminal means (see, for example, Japanese Patent Application Laid-Open No. 2014-144218). However, in the above-mentioned conventional gaming machine, since the displacement amount of the overhanging operation of the operating means is changed depending on the phase of the cam at the time of releasing the fixing, the phase of the cam at the time of releasing the fixing is changed in various ways. The cam for moving the means and the release load means for releasing the fixing were operated by different driving forces. Therefore, there is a problem that a plurality of driving means are required and the space for arranging the driving means becomes large.

On the other hand, in the gaming machine E1, the release load means for releasing the fixing of the operating means is driven by the driving means for driving the operating means. As a result, the number of drive means can be reduced because the drive means for changing the terminal position of the operation means by the terminal means and the drive means for moving the release load means can be used in combination.

In the gaming machine E1, the gaming machine E2 is characterized in that the position of the releasing load means is changed based on the operation of the transmitting means.

According to the gaming machine E2, in addition to the effect of the gaming machine E1, a change in the position of the releasing load means can be generated based on the operation of the transmitting means. The state of the load means can be determined. As a result, the number of arrangements of the detection means such as the position sensor for detecting the state of the release load means can be reduced, and the number of parts can be reduced.

As a method of switching the state of the release load means, when the transmission means is composed of a cam and the release load means is composed of a protrusion that rotates coaxially with the cam, a method of shifting the rotation cycle between the cam and the protrusion is used. An example is a method in which the rotation of the cam and the rotation of the protrusion are synchronized when the cam is arranged in a predetermined phase, and the rotation of the cam and the rotation of the protrusion are synchronized in other phases.

In the gaming machine E2, the release load means is operably arranged with respect to the transmission means by the load given from the first means, and the release load means and the transmission means are operably arranged by the operation of the release load means. The gaming machine E3 is characterized in that it can be switched whether or not it operates synchronously.

According to the gaming machine E3, in addition to the effect of the gaming machine E2, the releasing load means is operably arranged with respect to the transmitting means by the load from the first means, and the releasing load means is operated by the operation of the releasing load means. Since it is switched whether or not the transmission means and the transmission means operate in synchronization with each other, the synchronization state between the release load means and the transmission means can be changed without adding a member.

In the game machine E2, the transmission means includes a rotating first rotating member, the operating means is supported eccentrically with respect to the rotation axis of the first rotating member, and the release load means rotates a second rotation. A gaming machine E4 comprising a member, wherein the first rotating member and the second rotating member have different rotation cycles.

According to the gaming machine E4, in addition to the effect of the gaming machine E2, the first rotating member and the second rotating member are operated by a single driving means, but since the rotation cycles are different, the second rotating means is predetermined. A plurality of types of phases of the first rotating member can be prepared when the first means is released by abutting with the first means in phase.

According to this configuration, it is possible to prepare a plurality of types of terminal positions when the operation of the first means is released from the state where the operating means is maintained at the first position and the operating means is moved toward the second position. , The range of production can be expanded. For example, an effect of gradually moving the terminal position away from the first position and an effect of gradually moving the terminal position closer to the first position can be realized with the same configuration.

<Vibration device supported by soft case>
In an operating device having an operating means operated by a player, the operating device includes a first position of the operating means and a second position reached by the operating means when the player operates from the first position. In a gaming machine including a vibrating means having a vibrating portion that is movable between and vibrating and a receiving means that is arranged so as to be in contact with the vibrating portion, the operating means is arranged at the first position. When this is done, the vibrating portion is in a separated state in which it cannot come into contact with the receiving means, while when the operating means is arranged at the second position, the vibrating portion can come into contact with the receiving means. A gaming machine F1 characterized in being in contact with each other.

In a gaming machine such as a pachinko machine, there is a gaming machine including an operating means that can be operated by the player and a vibrating means that transmits vibration to the player via the operating means or the frame of the gaming machine (for example, Japanese Patent Application Laid-Open No. (See 2014-144218). However, in the above-mentioned conventional gaming machine, when the vibrating means vibrates regardless of whether or not the operating means is operated, the vibration is transmitted to the operating means or the frame of the gaming machine. Alternatively, since it is transmitted to the player who touches the frame of the gaming machine, when performing an effect of transmitting vibration immediately after operating the operating means, it is necessary to operate the vibrating means after detecting the operation of the operating means. .. Therefore, after the player operates the operating means, it is necessary to operate the vibrating means before releasing the hand from the operating means, and the operation mode of the player (for example, an operation such as releasing the operating means at the moment when the operating means is pushed in). Depending on the mode), the start of vibration may not be in time before the hand is released, and there is a problem that the player may not notice the vibration.

On the other hand, according to the gaming machine F1, whether or not the vibrating portion comes into contact with the receiving means depends on whether the operating means is arranged in the first position or is operated by the player and arranged in the second position. Since it changes, even when the vibrating portion is continuously vibrated, the player can feel the vibration only when the player operates the operating means. Further, since the vibration of the vibrating portion is generated before the player pushes in, the vibrating portion can be vibrated before the player releases the hand, regardless of the mode of operation of the player. Vibration can be transmitted to a person.

In the gaming machine F1, the vibrating means is arranged so as to project over an occupied area occupied when the operating means is arranged at the second position in the separated state, and the operating means moves to the second position. The gaming machine F2 is characterized in that the vibrating means is brought out of the occupied area to change to the contact state.

According to the gaming machine F2, in addition to the effect of the gaming machine F1, the vibrating means moves based on the movement of the operating means, so that the separated state changes to the contacting state. Therefore, depending on the degree of movement of the operating means. The contact strength between the operating means or the receiving means and the vibrating portion can be changed, and the strength of the transmitted vibration can also be changed. Therefore, the effect of changing the strength of the transmitted vibration with respect to the operating strength of the player can be performed by vibrating the vibrating means in the same manner without any particular change in the driving mode.

In the gaming machine F1 or F2, the gaming machine F3 is characterized in that the vibrating means is supported by the receiving means via a supporting means having spring elasticity.

According to the gaming machine F3, in addition to the effect of the gaming machine F1 or F2, the supporting means can perform positioning with respect to the receiving means while suppressing the vibration of the vibrating means from being transmitted to the receiving means. As a result, the receiving means and the vibrating means can be separated from each other to prevent the transmission of vibration, and the displacement generated in the vibrating means during vibration can be suppressed.

In the gaming machine F3, the gaming machine F4 is characterized in that the supporting means expands and contracts based on the vibration of the vibrating portion in the contact state.

According to the gaming machine F4, in addition to the effect of the gaming machine F3, the elasticity of the supporting means can be used to increase the load generated when the vibrating portion and the receiving means come into contact with each other. That is, the expansion and contraction of the support means can give momentum when the vibrating portion moves in the direction close to the receiving means.

In the gaming machine F3, the supporting means is characterized in that the deformation resistance along the operating direction of the operating means is lower than the deformation resistance in the direction perpendicular to the operating direction of the operating means. ..

According to the gaming machine F5, in addition to the effect of the gaming machine F3, the direction in which the supporting means is deformed can be finely set when the operating means is operated and interferes with the supporting means due to the difference in the deformation resistance of the supporting means. can.

As a result, even if the difference in the amount of movement of the operating means is slight, the amount of expansion and contraction of the supporting means can be made different, and the load generated between the vibrating portion and the receiving means can be made different. ..

As a method of making the deformation resistance different, when the supporting means is composed of a rubber member surrounding the vibrating means, a method of extending the rubber legs along the operating direction of the operating means, or a method of supporting the vibrating means surrounding the vibrating means. In the case of being composed of rubber members, a method of manufacturing the rubber members by two-color molding and changing the deformation resistance in each direction, and a rail that guides the operating means so that the operating means move in the direction along the operating direction. , A method of configuring the coil spring that urges the vibrating means along the operating direction of the operating means, and the like are exemplified.

The gaming machine F6 is characterized in that a portion of the gaming machine F3 with which the vibrating portion abuts is the receiving means, and the receiving means is configured as a means different from the operating means.

According to the gaming machine F6, in addition to the effect of the gaming machine F3, the vibration is not transmitted to the player through the operating means, but is transmitted to the player through the receiving means which is a means different from the operating means. Therefore, it is possible to suppress the vibration of the vibrating means from being transmitted to the driving means via the operating means and the transmitting means, so that it is possible to prevent the driving means from being loaded. Thereby, the durability of the driving means can be improved.

Further, since it is possible to suppress the vibration from being transmitted to the hand of the player who operates the operating means, it is possible to prevent the player who is surprised by the vibration from stopping the operation during the operation.

As a receiving means, for example, in the frame part of the game machine, the part near the upper plate to which the game ball is supplied, the edge part of the glass frame, etc., the player does not notice during the game. Examples include a part that may be touched by a hand, a storage part that partially surrounds the operating means, and the like.

<One-touch mounting of cam and shaft. Shape deformation (elastic deformation) is possible at the mounting part>
In an operating device having an operating means operated by a player, the operating device is configured so that the operating means can move between a first position and a second position different from the first position, and the operating means can be moved. It is characterized by comprising a driving means for generating a driving force to be driven and a transmitting means for transmitting the driving force of the driving means to the operating means, and the transmitting means includes a deformed portion elastically deformed by an overload. Game machine G1 to play.

In a gaming machine such as a pachinko machine, an operating means that can be operated by a player, a driving means that generates a driving force that drives the operating means, and a transmitting means that transmits the driving force from the driving means to the operating means are provided. There is a gaming machine provided (see, for example, Japanese Patent Application Laid-Open No. 2014-144218). However, in the conventional gaming machine described above, when the operating means is gripped and fixed by the player, when the driving means generates a driving force for driving the operating means, the connecting portion between the transmitting means and the operating means and the transmitting means There is a problem that a load is accumulated in the connecting portion between the and the driving means, and these connecting portions may be damaged.

On the other hand, according to the gaming machine G1, when the operating device is overloaded, the deformed portion of the transmitting means is elastically deformed, so that the connecting portion between the operating means and the transmitting means and the driving means and the transmitting means are connected. The load given to the connecting portion with and can be relaxed.

In the game machine G1, the transmission means includes a cam member that is rotatably supported, and the deformed portion constitutes a connecting portion of the cam member with a rotating shaft, and the elasticity of the deformed portion causes the deformed portion to move to the rotating shaft. A game machine G2 characterized in that a fixing force of the above is generated.

According to the game machine G2, the deformed portion has a role as a portion responsible for elastic deformation of the cam member with respect to the rotation shaft of the transmission means and a role as a portion for generating a supporting force of the cam member with respect to the rotation shaft. Therefore, the configuration of the transmission member can be simplified by combining the functions. For example, individual fixing members such as e-rings can be omitted.

In the game machine G2, the cam member includes a convex portion that is convexly provided in parallel with the rotation axis, and the convex portion and the operating means are connected, and the elastic deformation of the deformed portion is applied to the cam member. On the other hand, the gaming machine G3 is characterized in that the rotation axis is tilted.

Here, the elastic deformation of the transmission means can also be performed, for example, by displacing the convex portion along the circumferential direction of the cam member. However, in this case, it becomes difficult to form the cam member and the convex portion with one member, and the number of members may increase.

On the other hand, according to the gaming machine G3, in addition to the effect of the gaming machine G2, the elastic deformation of the deformed portion is such that the rotation axis is tilted with respect to the cam member. On the other hand, as compared with the case of sliding movement, the cam member can be easily configured from a single member, and the member can be simplified.

In the game machine G3, the resistance of the elastic deformation of the deformed portion is compared with the rotation shaft in the first rotation direction in which the cam member is rotated about the straight line connecting the rotation shaft and the convex portion. A gaming machine characterized in that the deformation resistance is larger in the second rotation direction in which the straight line connecting the convex portion and the straight line perpendicular to both the extension direction of the rotation axis are rotated about the axis. G4.

According to the game machine G4, in addition to the effect of the game machine G3, by making the deformation resistance of the deformed part different for each direction, the state after the deformed part is elastically deformed in the direction of rotation axis is better. Compared with the state before elastic deformation, the convex tip of the convex portion can be displaced in the direction along the circumferential direction of the cam member. As a result, the convex portion can be displaced along the direction in which the convex portion of the cam member intends to move, so that the load generated between the convex portion and the operating means due to the elastic deformation of the deformed portion is alleviated. can do.

In the game machine G3 or G4, the cam member is provided with a friction member that is spaced apart by a predetermined distance along a direction parallel to the rotation axis of the cam member, and the deformed portion is elastically deformed to change the posture of the cam member. The gaming machine G5, characterized in that the cam member and the friction member come into contact with each other.

According to the gaming machine G5, in addition to the effect of the gaming machine G3 or G4, when an overload is applied to the operating means, the deformed portion is elastically deformed, so that the cam member changes its posture, and the cam member and the friction member Can increase the operating resistance of the cam member itself, thereby reducing the load applied to the connecting portion between the cam member and the operating means.

The gaming machine G6 is characterized in that any one of the gaming machines G3 to G5 includes a detecting means for detecting that at least a part of the cam member is tilted and displaced with respect to the axis.

Here, in a situation where the operating device is overloaded and the driving means is operating but the operating means is not operating, for example, the displacement expected due to the driving of the driving means and the actual displacement of the operating means. When detecting that an overload has occurred on the basis of the deviation from the above, it is necessary to drive the driving means for a predetermined period before detecting the occurrence of the overload. This period can be shortened as the arrangement interval of the detection means for detecting the displacement shift is smaller, but the smaller the arrangement interval of the detection means, the more complicated the configuration of the detection means becomes and the more expensive it becomes. Therefore, there is a problem that it is difficult to configure the configuration so that the occurrence of overload can be detected at an early stage at low cost.

On the other hand, according to the gaming machine G6, in addition to the effect of any of the gaming machines G3 to G5, the detecting means detects whether or not at least a part of the cam member is tilted and displaced with respect to the axis. Therefore, it is possible to determine that an overload has occurred at the same time that the detecting means detects at least a part of the cam member without having to drive the driving means for a predetermined period while suppressing the additional number of the detecting means. This makes it possible to reduce the load applied to the drive means when an overload occurs.

In any of the gaming machines A1 to A8, B1 to B3, C1 to C3, D1 to D6, E1 to E4, F1 to F6, and G1 to G6, the gaming machine Z1 is a slot machine. .. Among them, as a basic configuration of a slot machine, "a variable display means for dynamically displaying an identification information string composed of a plurality of identification information and then confirming the identification information is provided for operating a starting operation means (for example, an operation lever). Due to this, the dynamic display of the identification information is started, and the dynamic display of the identification information is stopped due to the operation of the stop operation means (stop button) or after a predetermined time has elapsed, and at the time of the stop. A gaming machine provided with a special gaming state generating means for generating a special gaming state advantageous to the player, provided that the definite identification information of the above is the specific identification information. In this case, coins, medals, and the like are typical examples of the game medium.

In any of the gaming machines A1 to A8, B1 to B3, C1 to C3, D1 to D6, E1 to E4, F1 to F6, and G1 to G6, the gaming machine is a pachinko gaming machine. Z2. Among them, the basic configuration of the pachinko gaming machine is provided with an operation handle, and the ball is launched into a predetermined game area according to the operation of the operation handle, and the ball is placed in a predetermined position in the game area. As a prerequisite for winning a prize (or passing through the operating port), the identification information dynamically displayed by the display means is fixedly stopped after a predetermined time. In addition, when a special gaming state occurs, a variable winning device (specific winning opening) arranged at a predetermined position in the gaming area is opened in a predetermined manner to enable a ball to be won, and is valuable according to the number of winnings. Some are given value (including not only prize balls but also data written on a magnetic card).

In any of the gaming machines A1 to A8, B1 to B3, C1 to C3, D1 to D6, E1 to E4, F1 to F6, and G1 to G6, the gaming machine is a fusion of a pachinko gaming machine and a slot machine. The gaming machine Z3 characterized by being. Among them, as a basic configuration of the fused gaming machine, "a variable display means for dynamically displaying an identification information string composed of a plurality of identification information and then confirming and displaying the identification information is provided, and a starting operation means (for example, an operation lever). The variation of the identification information is started due to the operation of, and the dynamic display of the identification information is stopped due to the operation of the stop operation means (for example, the stop button) or after a predetermined time elapses. A special gaming state generating means for generating a special gaming state advantageous to the player is provided on the condition that the definite identification information at the time of stopping is the specific identification information, the ball is used as the game medium, and the identification information is described. A game machine that requires a predetermined number of balls to start the dynamic display of the game, and is configured to pay out a large number of balls when a special game state occurs. "

10 Pachinko machine (game machine)
81 Third symbol display device (display means)
300, 2300, 3300, 4300, 5300, 6300, 7300
Operating devices 310, 2310, 3310, 4310 Tilt device (tilting means, operating means)
311gL, 3311gL Left side detection piece (part of continuous striking determination means, part of position difference detection means, part of movement direction determination means)
311gR Right side detection piece (part of continuous hit determination means, part of end detection means, part of position difference detection means, part of movement direction determination means)
312a1 Operation surface (part of operation means)
314 shaft part (shaft rod)
315 Torsion spring (urging means)
324L left side detection sensor (part of continuous hit determination means, part of position difference detection means, part of movement direction determination means)
324R Right side detection sensor (part of continuous hit determination means, part of end detection means, part of position difference detection means, part of movement direction determination means)
340, 5340, 6340 Drive device (drive means, first drive means)
341 Main body member (part of friction member)
341f LED device (light emitting means)
343 Transmission shaft rod (part of transmission means)
343a Cylindrical member (part of transmission means)
343b Transmission gear (part of drive means, part of release means)
343b2 Clutch part (engaged teeth)
343c Movable clutch (part of transmission means, part of release means)
343c2 Clutch part (engaged teeth)
343d Coil spring (biasing means)
344, 6344, 7344 Disc cams (part of transmission means, part of termination means, part of release load means)
344c Engagement rib (part of release load means)
344d connecting pin (convex part)
345 arm member (part of transmission means, part of termination means)
346, 2346, 7346 Release member (part of maintenance means, part of first means, part of friction member)
347, 7347 Rotating claw member (part of maintenance means, part of first means)
352 Voice coil motor (second drive means, repulsion means)
2347 Rotating plate member (part of maintenance means)
2348 Slide claw member (part of maintenance means)
4321d Upper detection sensor (detection sensor)
4321e Lower detection sensor (detection sensor)
5320 Lower frame member (part of support frame)
5344 Disk cam (part of transmission means, part of termination means, part of release load means, cam member)
5400 Vibration device (vibration means, repulsion means)
5411 Drive motor 5412 Weight member (vibrating part, part of repulsive means)
5420 Flexible member (part of support means, repulsion means)
5430 Accommodating member (receiving means, part of repulsion means, part of support frame)
6344L1, 6344R1 disk member (first rotating member)
6344L2, 6344R2 Ring member (second rotating member)
7344L1, 7344R1 Disk member (part of transmission means, part of termination means)
7344L3, 7344R3 engaging member (release load means)
E1 notification device (detection means)
S52 Termination area (occupied area)
P1a deformed part (deformed part)

The present invention relates to a gaming machine such as a pachinko machine.

In a gaming machine such as a pachinko machine, there is a gaming machine provided with an operating means for moving between a first position and a second position by a player manually operating the machine (Patent Document 1).

Japanese Unexamined Patent Publication No. 2014-014571

However, the above-mentioned conventional gaming machine has a problem that there is room for improvement in the operability of the operating means. The present invention has been made to solve the above-exemplified problems and the like, and an object of the present invention is to provide a gaming machine having good operability of operating means.

In order to achieve this object, the gaming machine according to claim 1 includes an operating device that is operable by the player and has an operating means that can move to the terminal position , and the operating device is in the first state. It is possible to form a second state in which the range of motion to the terminal position is wider than that in the first state, and for generating a driving force for moving the operating means from the second state to the first state. a first driving means, a game machine and a biasing means for generating a biasing force for moving said operating means into said second state from the first state, for thereby operating the operating means to the player In the operation effect, a second driving means for generating a driving force for moving the operating means from the first state to the second state is provided .

According to claim 1 the gaming machine according, it is possible to improve the operability of the operating means.

It is a front view of the pachinko machine in 1st Embodiment. It is a front view of the game board of a pachinko machine. It is a rear view of a pachinko machine. It is a block diagram which shows the electric structure of a pachinko machine. It is a front perspective view of the operation device. (A) is a partial front view of the pachinko machine, and (b) is a partial cross-sectional view of the pachinko machine on the VIb-VIb line of FIG. 6 (a). (A) is a partial front view of the pachinko machine, and (b) is a partial cross-sectional view of the pachinko machine in line VIIb-VIIb of FIG. 7 (a). It is a front perspective view of the operation device in the direction view of arrow VIII of FIG. FIG. 7 is a front perspective view of the operating device in the direction of arrow IX in FIG. 7. It is a front perspective view of the operation device. It is a rear perspective view of the operation device. It is a front view exploded perspective view of an operation device. It is a rear view exploded perspective view of an operation device. (A) is a front view of the tilting device, (b) is a side view of the tilting device in the direction of arrow XIVb of FIG. 14 (a), and (c) is a side view of the tilting device of FIG. 14 (a). It is sectional drawing of the tilting device in line XIVc. It is a front view exploded perspective view of a tilting device. It is a rear view exploded perspective view of the lid of a tilting device. (A) is a front view of the drive device, and (b) is a side view of the drive device in the direction of arrow XVIIb of FIG. 17 (a). It is a front view exploded perspective view of a drive device. It is a front view exploded perspective view of a transmission shaft rod. (A) is a side view of the left disk cam in the direction of arrow XXa of FIG. 18, and (b) is a side view of the left disk cam in the direction of arrow XXb of FIG. (A) and (b) are front views of the release member and the rotary claw member. It is sectional drawing of the operation device in line XXII-XXII of FIG. 6A. It is sectional drawing of the operation device in line XXII-XXII of FIG. 6A. It is sectional drawing of the operation device in line XXII-XXII of FIG. 6A. It is sectional drawing of the operation device in line XXII-XXII of FIG. 6A. It is sectional drawing of the operation device in line XXII-XXII of FIG. 6A. It is sectional drawing of the operation device in line XXII-XXII of FIG. 6A. It is sectional drawing of the operation device in line XXII-XXII of FIG. 6A. It is sectional drawing of the operation device in line XXII-XXII of FIG. 6A. It is sectional drawing of the operation device in line XXII-XXII of FIG. 6A. It is sectional drawing of the operation device in line XXII-XXII of FIG. 6A. It is sectional drawing of the operation device in line XXII-XXII of FIG. 6A. It is sectional drawing of the operation device in line XXII-XXII of FIG. 6A. It is sectional drawing of the operation device in line XXII-XXII of FIG. 6A. It is sectional drawing of the operation device in line XXII-XXII of FIG. 6A. It is sectional drawing of the operation device in line XXII-XXII of FIG. 6A. It is sectional drawing of the operation device in line XXII-XXII of FIG. 6A. It is sectional drawing of the operation device in line XXII-XXII of FIG. 6A. It is a partial cross-sectional view of the operation device in the XXXIX-XXXIX line of FIG. 38. It is sectional drawing of the operation device in line XXII-XXII of FIG. 6A. It is sectional drawing of the operation device in line XXII-XXII of FIG. 6A. It is sectional drawing of the operation device in line XXII-XXII of FIG. 6A. It is sectional drawing of the operation device in line XXII-XXII of FIG. 6A. It is sectional drawing of the operation device in line XXII-XXII of FIG. 6A. (A) is a side view of the slide claw member in the second embodiment, (b) is a side view of the rotating plate member, and (c) is a side view of the release member. (A) and (b) are side views of a release member, a rotating plate member, and a slide claw member. 6 is a cross-sectional view of the operating device in the line corresponding to the XXII-XXII line of FIG. 6A. 6 is a cross-sectional view of the operating device in the line corresponding to the XXII-XXII line of FIG. 6A. 6 is a cross-sectional view of the operating device in the line corresponding to the XXII-XXII line of FIG. 6A. It is a side view of the tilting device in 3rd Embodiment. (A) and (b) are side views of the operation device. (A) and (b) are side views of the operation device. It is a side view of the tilting device in 4th Embodiment. (A) and (b) are side views of the operation device. (A) and (b) are side views of the operation device. It is an exploded front perspective view of the operation device in 5th Embodiment. It is an exploded rear perspective view of an operation device. It is an exploded front perspective view of a lower frame member and a vibrating device. (A) is a side view of the lower frame member, (b) is a partial cross-sectional view of the lower frame member in the LIXb-LIXb line of FIG. 59 (a), and (c) is a partial cross-sectional view of FIG. 59 (a). It is a partial top view of the lower frame member in the direction view of the arrow LIXc. (A) and (b) are sectional views of the vibrating apparatus in the line LXa-LXa of FIG. 59 (a). (A) and (b) are sectional views of the transmission device 5410 and the accommodating member 5430 in the LIXb-LIXb line of FIG. 59 (a). It is an exploded front perspective view of a drive device. (A) is a front perspective view of the right disk cam, and (b) is a rear perspective view of the right disk cam. It is a front view exploded perspective view of a transmission shaft rod. (A) is a front view of the right disk cam in the direction of the arrow LXVa of FIG. 62, and (b) is a cross-sectional view of the right disk cam in the LXVb-LXVb line of FIG. 65 (a). c) is a cross-sectional view of the right disk cam in the LXVc-LXVc line of FIG. 65 (a). (A) is a front view of the right disk cam in the direction of arrow LXVa of FIG. 62, and (b) is a cross-sectional view of the right disk cam in the LXVIb-LXVIb line of FIG. 66 (a). (A) is a cross-sectional view of the operation device in the line corresponding to the line corresponding to the line XXII-XXII of FIG. 6 (a), and FIG. Is. (A) is a cross-sectional view of the operating device in the line corresponding to the line XXII-XXII of FIG. 6A, and FIG. 68B is a partial rear view of the operating device in the direction of arrow LXVIIIb of FIG. Is. It is an exploded front perspective view of the drive device in 6th Embodiment. It is a front view exploded perspective view of the disk member, the ring member, and the second transmission member of the left disk cam. 6 is a cross-sectional view of the operating device in the line corresponding to the XXII-XXII line of FIG. 6A. 6 is a cross-sectional view of the operating device in the line corresponding to the XXII-XXII line of FIG. 6A. 6 is a cross-sectional view of the operating device in the line corresponding to the XXII-XXII line of FIG. 6A. (A) is a front view of the right disk cam according to the seventh embodiment, and (b) is a rear view of the right disk cam. (A) is a cross-sectional view of the right disk cam in the LXXVa-LXXVa line of FIG. 74 (a), and (b) is a partial side view of the right disk cam in the direction of arrow LXXVb of FIG. Is. (A) is a front view of the ring member, (b) is a rear view of the ring member, and (c) is a side view of the ring member in the direction of arrow LXXVIc of FIG. 76 (a). (A) is a front view of the engaging member, and (b) is a side view of the engaging member in the direction of arrow LXXVIIb of FIG. 77 (a). (A) is a front view of the right disk cam, (b) is a side view of the right disk cam in the direction of arrow LXXVIIIb of FIG. 78 (a), and (c) is a right disk cam. (D) is a side view of the right disk cam in the direction of arrow LXXVIIId in FIG. 78 (c), (e) is a front view of the right disk cam, and (f). Is a side view of the right disk cam in the direction of arrow LXXVIIIf in FIG. 78 (e). (A) and (b) are partial cross-sectional views of the operation device in the line corresponding to the XXII-XXII line of FIG. (A) and (b) are partial cross-sectional views of the operation device in the line corresponding to the XXII-XXII line of FIG. 6 is a partial cross-sectional view of the operating device in the line corresponding to the XXII-XXII line of FIG. (A) and (b) are partial cross-sectional views of the operation device in the line corresponding to the XXII-XXII line of FIG. (A) and (b) are partial cross-sectional views of the operation device in the line corresponding to the XXII-XXII line of FIG. It is sectional drawing of the operation device in the line corresponding to line XXII-XXII of FIG. It is sectional drawing of the operation device in the line corresponding to line XXII-XXII of FIG.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings. First, with reference to FIGS. 1 to 44, as a first embodiment, an embodiment when the present invention is applied to a pachinko gaming machine (hereinafter, simply referred to as “pachinko machine”) 10 will be described. FIG. 1 is a front view of the pachinko machine 10 according to the first embodiment, FIG. 2 is a front view of the game board 13 of the pachinko machine 10, and FIG. 3 is a rear view of the pachinko machine 10.

As shown in FIG. 1, the pachinko machine 10 has an outer frame 11 in which an outer shell is formed by a wooden frame combined in a substantially rectangular shape, and an outer frame 11 formed in substantially the same outer shape as the outer frame 11. It is provided with an inner frame 12 that is supported so as to be openable and closable. Metal hinges 18 are attached to the outer frame 11 at two upper and lower positions on the left side of the front view (see FIG. 1) in order to support the inner frame 12, and the side on which the hinge 18 is provided is used as an opening / closing axis. The frame 12 is supported so as to be openable and closable toward the front side of the front surface.

A game board 13 (see FIG. 2) having a large number of nails, winning openings 63, 64, etc. is detachably attached to the inner frame 12 from the back surface side. A ball game is performed by a ball (game ball) flowing down in front of the game board 13. The inner frame 12 includes a ball launching unit 112a (see FIG. 4) that launches a ball into the front region of the game board 13 and a launch that guides the ball launched from the ball launching unit 112a to the front region of the game board 13. Rails (not shown) etc. are attached.

On the front side of the inner frame 12, a front frame 14 that covers the upper side of the front surface and a lower plate unit 15 that covers the lower side thereof are provided. In order to support the front frame 14 and the lower plate unit 15, metal hinges 19 are attached to the upper and lower two places on the left side of the front view (see FIG. 1), and the side on which the hinges 19 are provided is used as an opening / closing axis for the front frame. The 14 and the lower plate unit 15 are supported so as to be openable and closable toward the front side of the front surface. The lock of the inner frame 12 and the lock of the front frame 14 are released by inserting a dedicated key into the key hole 21 of the cylinder lock 20 and performing a predetermined operation.

The front frame 14 is formed by assembling decorative resin parts, electric parts, and the like, and a window portion 14c having a substantially elliptical opening is provided at a substantially central portion thereof. A glass unit 16 having two flat glass sheets is arranged on the back surface side of the front frame 14, and the front surface of the game board 13 can be visually recognized on the front side of the pachinko machine 10 through the glass unit 16.

In the front frame 14, an upper plate 17 for storing balls is formed in a substantially box shape with the upper surface open so as to project toward the front side, and prize balls, rented balls, and the like are discharged to the upper plate 17. The bottom surface of the upper plate 17 is formed so as to be inclined downward to the right side when viewed from the front (see FIG. 1), and the ball thrown into the upper plate 17 is guided to the ball launching unit 112a (see FIG. 4) by the inclination. Further, a frame button 22 is provided on the upper surface of the upper plate 17. The frame button 22 is operated by the player, for example, when changing the stage of the effect displayed on the third symbol display device 81 (see FIG. 2) or changing the effect content of the super reach. NS.

The front frame 14 is provided with light emitting means such as various lamps around the front frame 14 (for example, a corner portion). These light emitting means change and control the light emitting mode by lighting or blinking according to a change in the gaming state at the time of a big hit or a predetermined reach, and play a role of enhancing the effect during the game. Illuminations 29 to 33 having a light emitting means such as an LED are provided on the peripheral edge of the window portion 14c. In the pachinko machine 10, these illumination units 29 to 33 function as effect lamps such as jackpot lamps, and each illumination unit 29 to 33 lights up by lighting or blinking the built-in LED at the time of jackpot or reach production. Or, it blinks to notify that the jackpot is in progress or that the reach is one step before the jackpot. Further, in the upper left portion of the front frame 14 when viewed from the front (see FIG. 1), a light emitting means such as an LED is built in, and a display lamp 34 capable of displaying when the prize ball is being paid out and when an error occurs is provided.

Further, on the lower side of the illuminated portion 32 on the right side, a small window 35 is formed by attaching a transparent resin from the back side so that the back side of the front frame 14 can be visually recognized, and a sticking space K1 on the front of the game board 13 (FIG. The certificate stamp or the like attached to (see 2) can be visually recognized from the front of the pachinko machine 10. Further, in the pachinko machine 10, in order to bring out more glitter, a plating member 36 made of ABS resin having chrome plating is attached to the area around the illumination portions 29 to 33.

A ball lending operation unit 40 is arranged below the window unit 14c. The ball lending operation unit 40 is provided with a frequency display unit 41, a ball lending button 42, and a return button 43. When the ball lending operation unit 40 is operated with bills, cards, etc. inserted into the card unit (ball lending unit) (not shown) arranged on the side of the pachinko machine 10, the ball is operated according to the operation. Lending is done. Specifically, the frequency display unit 41 is an area in which the remaining amount information such as a card is displayed, and the built-in LED lights up and the remaining amount is displayed as a numerical value as the remaining amount information. The ball lending button 42 is operated to obtain a lending ball based on the information recorded on the card or the like (recording medium), and the lending ball is supplied to the upper plate 17 as long as the remaining amount is present on the card or the like. Will be done. The return button 43 is operated when requesting the return of the card or the like inserted in the card unit. A pachinko machine in which balls are lent directly to the upper plate 17 from a ball lending device or the like without going through a card unit, a so-called cash machine, does not require a ball lending operation unit 40. In this case, the ball lending operation unit 40 is not required. A decorative sticker or the like may be added to the installation portion of the above to make the component configuration common. It is possible to standardize pachinko machines and cash machines that use card units.

In the lower plate unit 15 located on the lower side of the upper plate 17, a lower plate 50 for storing balls that could not be stored in the upper plate 17 is formed on the left side thereof in a substantially box shape with an open upper surface. There is. On the right side of the lower plate 50, an operation handle 51 and an operation device 300 operated by the player to drive the ball into the front of the game board 13 are arranged. The operation device 300 will be described later.

Inside the operation handle 51, there is a touch sensor 51a for permitting the driving of the ball launch unit 112a, a launch stop switch 51b for stopping the launch of the ball during the pressing operation period, and a rotation of the operation handle 51. It has a built-in variable resistor (not shown) that detects the amount of dynamic operation (rotation position) by the change in electrical resistance. When the operation handle 51 is rotated clockwise by the player, the touch sensor 51a is turned on and the resistance value of the variable resistor changes according to the amount of rotation operation, and the resistance value of the variable resistor is changed. The ball is launched with a strength corresponding to (launch intensity), whereby the ball is driven into the front of the game board 13 with a flying amount corresponding to the operation of the player. Further, when the operation handle 51 is not operated by the player, the touch sensor 51a and the firing stop switch 51b are turned off.

A ball pulling lever 52 for operating the ball stored in the lower plate 50 when the ball stored in the lower plate 50 is discharged downward is provided in the lower portion of the front surface of the lower plate 50. The ball pulling lever 52 is always urged to the right, and by sliding it to the left against the urging, the bottom opening formed on the bottom surface of the lower plate 50 is opened, and the bottom opening is opened. The ball naturally falls from the bottom opening and is discharged. The operation of the ball removing lever 52 is usually performed in a state where a box (generally referred to as "Senryobako") for receiving the balls discharged from the lower plate 50 is placed below the lower plate 50. An operation handle 51 is arranged on the right side of the lower plate 50 as described above, and an ashtray (not shown) is attached to the left side of the lower plate 50.

As shown in FIG. 2, the game board 13 has a base plate 60 machined into a substantially square shape in front view, a large number of nails (not shown) and windmills (not shown) for ball guidance, and a rail 61. , 62, general winning opening 63, first winning opening 64, second winning opening 640, variable winning device 330, through gate 67, variable display device unit 80, etc. are assembled, and the peripheral portion thereof is an inner frame 12 (FIG. 1) is attached to the back side. The base plate 60 is made of a light-transmitting resin material, and is formed so that the player can visually recognize various structures arranged on the back side of the base plate 60 from the front side thereof. The general winning opening 63, the first winning opening 64, the second winning opening 640, and the variable display device unit 80 are arranged in through holes formed in the base plate 60 by router processing, and tapping screws are provided from the front side of the game board 13. It is fixed by etc.

The front central portion of the game board 13 can be visually recognized from the front side of the inner frame 12 through the window portion 14c (see FIG. 1) of the front frame 14. Hereinafter, the configuration of the game board 13 will be described mainly with reference to FIG. 2.

An outer rail 62 formed by bending a strip-shaped metal plate into a substantially arc shape is planted on the front surface of the game board 13, and a strip-shaped metal plate is placed inside the outer rail 62 in the same manner as the outer rail 62. The arc-shaped inner rail 61 formed in 1 is planted. The inner rail 61 and the outer rail 62 surround the front outer periphery of the game board 13, and the game board 13 and the glass unit 16 (see FIG. 1) surround the front and back, so that the front of the game board 13 has a ball. A game area in which the game is played is formed by the behavior of. The game area is the area in front of the game board 13 that is partitioned by the two rails 61 and 62 and the resin outer edge member 73 that connects the rails (a winning opening or the like is arranged and fired). This is the area where the sphere flows down).

The two rails 61 and 62 are provided to guide the ball launched from the ball launching unit 112a (see FIG. 4) to the upper part of the game board 13. A return ball prevention member 68 is attached to the tip of the inner rail 61 (upper left portion in FIG. 2) to prevent the ball once guided to the upper part of the game board 13 from returning to the ball guide passage. Will be done. A return rubber 69 is attached to the tip of the outer rail 62 (upper right part in FIG. 2) at a position corresponding to the maximum flight portion of the ball. Is dampened and bounced back toward the center.

In the lower left side of the front view (lower left side of FIG. 2) of the game area, first symbol display devices 37A and 37B including a plurality of LEDs as light emitting means and a 7-segment display are arranged. The first symbol display devices 37A and 37B display according to each control performed by the main control device 110 (see FIG. 4), and mainly display the gaming state of the pachinko machine 10. In the present embodiment, the first symbol display devices 37A and 37B are configured to be used properly depending on whether the ball has won the first winning opening 64 or the second winning opening 640. Specifically, when the ball wins the first winning opening 64, the first symbol display device 37A operates, while when the ball wins the second winning opening 640, the first The symbol display device 37B is configured to operate.

Further, the first symbol display devices 37A and 37B use LEDs to indicate whether the pachinko machine 10 is in the probabilistic change, the time reduction, or the normal state by the lighting state, or indicate whether the pachinko machine 10 is in the changing state or not by the lighting state. , Whether the stop symbol is a symbol corresponding to a probabilistic jackpot, a symbol corresponding to a normal jackpot, or a missed symbol is indicated by the lighting state, the number of reserved balls is indicated by the lighting state, and the round during the jackpot is indicated by the 7-segment display device. Display the number and error. It should be noted that the plurality of LEDs are configured so that the emission colors (for example, red, green, blue) of the respective LEDs are different, and the combination of the emission colors may suggest various gaming states of the pachinko machine 10 with a small number of LEDs. can.

In the pachinko machine 10, a lottery is performed when the first winning opening 64 and the second winning opening 640 have won a prize. In the lottery, the pachinko machine 10 determines whether or not it is a big hit (big hit lottery), and if it is determined to be a big hit, it also determines the type of the big hit. As the jackpot type determined here, 15R probability variation jackpot, 4R probability variation jackpot, and 15R normal jackpot are prepared. The first symbol display devices 37A and 37B not only indicate whether or not the lottery result is a big hit as a stop symbol after the end of the fluctuation, and if it is a big hit, a symbol corresponding to the jackpot type is shown. ..

Here, the "15R probability variation jackpot" is a probability variation jackpot in which the maximum number of rounds shifts to a high probability state after the jackpot of 15 rounds, and the "4R probability variation jackpot" is a jackpot with a maximum number of rounds of 4 rounds. It is a probabilistic jackpot that shifts to a high probability state after. Further, "15R normal jackpot" is a jackpot in which the maximum number of rounds is 15 rounds, and then the probability shifts to a low probability state, and the time is shortened during a predetermined number of fluctuations (for example, 100 fluctuations). be.

In addition, the "high probability state" refers to a state in which the probability of a jackpot is increased as an added value after the end of the jackpot, that is, during a so-called probability fluctuation (probability change), in other words, a game in which it is easy to shift to a special gaming state. It is the state of. The high-probability state (during probabilistic change) in the present embodiment includes a game state in which the winning probability of the second symbol, which will be described later, is increased and the ball is likely to win the second winning opening 640. The "low probability state" refers to a state in which the probability change is not in progress, and a state in which the jackpot probability is normal, that is, a state in which the jackpot probability is lower than that in the probability change state. In addition, in the "low probability state", the time saving state (time saving medium) is a state in which the jackpot probability is a normal state, and the jackpot probability remains the same and only the hit probability of the second symbol is increased to increase the second winning opening 640. It refers to the state of the game in which the ball is easy to win. On the other hand, when the pachinko machine 10 is in the normal state, it is a state of the game in which neither the probability change nor the time reduction is performed (the jackpot probability and the hit probability of the second symbol are not increased).

During the probability change and the time reduction, not only the probability of hitting the second symbol increases, but also the time when the electric accessory 640a attached to the second winning opening 640 is opened is changed, which is a longer time than during normal times. Set. When the electric accessory 640a is in the open state (open state), the ball wins the second winning opening 640 as compared with the case where the electric accessory 640a is in the closed state (closed state). It will be easy. Therefore, during the probability change or the time reduction, it becomes easy for the ball to win the second winning opening 640, and the number of times the big hit lottery is performed can be increased.

In addition, during the probability change or the time reduction, the opening time of the electric accessory 640a attached to the second winning opening 640 is not changed, or in addition to changing the opening time, electric motors are applied once. The change may be made so that the number of times that the accessory 640a is opened is increased from the normal time. Further, during the probability change or the time reduction, the hit probability of the second symbol is not changed, and the electric accessory 640a is opened at the time when the electric accessory 640a attached to the second winning opening 640 is opened and at one hit. At least one of the times may be changed. In addition, during the probability change or the time reduction, the time when the electric accessory 640a attached to the second winning opening 640 is opened and the number of times when the electric accessory 640a is opened per hit is not performed, and the second symbol is hit. Only the probability may be changed so as to be higher than the normal one.

In the game area, a plurality of general winning openings 63 are arranged in which 5 to 15 balls are paid out as prize balls when the balls are won. Further, a variable display device unit 80 is arranged in the central portion of the game area. The variable display device unit 80 is triggered by winning a prize (starting prize) in the first winning opening 64 and the second winning opening 640, and synchronizes with the variable display in the first symbol display devices 37A and 37B, while synchronizing with the variable display of the third symbol. It is composed of a third symbol display device 81 composed of a liquid crystal display (hereinafter simply abbreviated as "display device") that performs variable display, and an LED that variablely displays the second symbol triggered by the passage of a sphere of a through gate 67. A second symbol display device (not shown) is provided. Further, in the variable display device unit 80, a center frame 86 is arranged so as to surround the outer periphery of the third symbol display device 81.

The third symbol display device 81 is composed of a large 9-inch size liquid crystal display, and by controlling the display contents by the display control device 114 (see FIG. 4), for example, the upper, middle, and lower 3 Two symbol columns are displayed. Each symbol row is composed of a plurality of symbols (third symbol), and these third symbols are horizontally scrolled for each symbol row, and the third symbol is variably displayed on the display screen of the third symbol display device 81. It has become like. In the third symbol display device 81 of the present embodiment, the game state displayed by the control of the main control device 110 (see FIG. 4) is displayed by the first symbol display devices 37A and 37B, whereas the first of the third symbol display devices 81 is A decorative display is performed according to the display of the symbol display devices 37A and 37B. In addition, instead of the display device, for example, a reel or the like may be used to configure the third symbol display device 81.

The second symbol display device alternately lights the “○” symbol and the “×” symbol as the display symbol (second symbol (not shown)) each time the sphere passes through the through gate 67 for a predetermined time. It is a variable display. When the pachinko machine 10 detects that the ball has passed through the through gate 67, a winning lottery is performed. As a result of the winning lottery, if it is a winning, the symbol "○" is stopped and displayed on the second symbol display device after the variation display of the second symbol. Further, if the result of the winning lottery is a failure, the symbol "x" is stopped and displayed on the second symbol display device after the variation display of the third symbol.

In the pachinko machine 10, when the variation display in the second symbol display device is stopped at a predetermined symbol (in the present embodiment, the symbol “○”), the electric accessory 640a attached to the second winning opening 640 is used for a predetermined time. It is configured to be activated (opened) only.

The time required for the variation display of the second symbol is set to be shorter during the probability change or the time reduction than when the game state is normal. As a result, during the probability change and the time reduction, the variation display of the second symbol is performed in a short time, so that the winning lottery can be performed more than during the normal time. Therefore, since the chances of winning in the winning lottery increase, it is possible to give the player many opportunities to open the electric accessory 640a of the second winning opening 640. Therefore, it is possible to make it easy for the ball to win the second winning opening 640 during the probability change and the time saving.

In addition, during the probability change or the time reduction, the second winning opening 640 can be reached during the probability change or the time reduction by other methods such as increasing the opening time and the number of times of opening the electric accessory 640a per hit. When the ball is in a state where it is easy to win a prize, the time required for the variable display of the second symbol may be constant regardless of the gaming state. On the other hand, when the time required for the variation display of the second symbol is set to be shorter than the normal time during the probability change or the time reduction, the hit probability may be constant regardless of the gaming state, or one hit. The opening time and the number of times of opening of the electric accessory 640a may be made constant regardless of the gaming state.

The through gate 67 is assembled to the game board 13 in the left and right regions of the variable display device unit 80, and is configured so that a part of the balls launched on the game board 13 can pass through. When the ball passes through the through gate 67, a winning lottery for the second symbol is performed. After the winning lottery, variable display is performed on the second symbol display device, and if the winning lottery result is a winning symbol, a symbol "○" is displayed as a stop symbol of the variable display, and if the winning lottery result is incorrect. For example, a symbol of "x" is displayed as a stop symbol of the variable display.

The number of times the ball has passed through the through gate 67 is held up to a total of four times, and the number of held balls is displayed by the above-mentioned first symbol display devices 37A and 37B and on the second symbol holding lamp (not shown). Is also lit and displayed. Four second symbol holding lamps are provided for the maximum number of holding lamps, and are symmetrically arranged below the third symbol display device 81.

The variation display of the second symbol is performed by switching the lighting and non-lighting of a plurality of lamps in the second symbol display device as in the present embodiment, as well as the first symbol display devices 37A, 37B and the third. It may be performed by using a part of the symbol display device 81. Similarly, the second symbol holding lamp may be turned on by a part of the third symbol display device 81. Further, the maximum number of reserved balls for the passage of the balls of the through gate 67 is not limited to 4, but may be set to 3 times or less, or 5 times or more (for example, 8 times). Further, the number of through gates 67 assembled is not limited to two, and may be one, for example. Further, the assembly position of the through gate 67 is not limited to the left and right sides of the variable display device unit 80, and may be, for example, below the variable display device unit 80. Further, since the number of reserved balls is indicated by the first symbol display devices 37A and 37B, the lighting display may not be performed by the second symbol holding lamp.

Below the variable display device unit 80, a first winning opening 64 in which a ball can win a prize is arranged. When the ball wins the first winning opening 64, the first winning opening switch (not shown) provided on the back side of the game board 13 is turned on, and the main control device 110 is caused by the turning on of the first winning opening switch. A big hit lottery is made in (see FIG. 4), and the display according to the lottery result is shown by the first symbol display device 37A.

On the other hand, below the front view of the first winning opening 64, a second winning opening 640 in which the ball can win is arranged. When the ball wins the second winning opening 640, the second winning opening switch (not shown) provided on the back side of the game board 13 is turned on, and the main control device 110 is caused by the turning on of the second winning opening switch. A big hit lottery is made in (see FIG. 4), and the display according to the lottery result is shown on the first symbol display device 37B.

In addition, the first winning opening 64 and the second winning opening 640 are also one of the winning openings in which five balls are paid out as prize balls when the balls are won. In the present embodiment, the number of prize balls paid out when a ball wins in the first winning opening 64 and the number of prize balls paid out when a ball wins in the second winning opening 640 are configured to be the same. , The number of prize balls paid out when a ball wins in the first winning opening 64 and the number of prize balls paid out when a ball wins in the second winning opening 640, for example, a ball to the first winning opening 64 The number of prize balls paid out when a prize is won may be three, and the number of prize balls paid out when a ball is won in the second winning opening 640 may be configured as five.

An electric accessory 640a is attached to the second winning opening 640. The electric accessory 640a is configured to be openable and closable, and normally the electric accessory 640a is in a closed state (reduced state), making it difficult for the ball to win a prize in the second winning opening 640. On the other hand, when the symbol "○" is displayed on the second symbol display device as a result of the variation display of the second symbol performed when the ball passes through the through gate 67, the electric accessory 640a is in the open state (enlarged). State), and the ball is in a state where it is easy to win a prize in the second winning opening 640.

As described above, during the probabilistic change and the time reduction, the probability of hitting the second symbol is higher than during the normal time, and the time required for the variation display of the second symbol is short. ”Is easy to display, and the number of times that the electric accessory 640a is in the open state (enlarged state) increases. Further, during the probability change and the time reduction, the time during which the electric accessory 640a is released is also longer than during the normal operation. Therefore, during the probability change and the time reduction, it is possible to create a state in which the ball is more likely to win the second winning opening 640 as compared with the normal time.

Here, the probability of winning a jackpot is the same in both the low probability state and the high probability state when the ball wins in the first winning opening 64 and when the ball wins in the second winning opening 640. However, the probability of becoming a 15R probability variation jackpot as the type of jackpot selected in the case of a jackpot is higher when the ball wins the second winning opening 640 than when the ball wins the first winning opening 64. It is set. On the other hand, the first winning opening 64 does not have an electric accessory as in the second winning opening 640, and the ball is in a state where it can always win a prize.

Therefore, in normal times, the electric accessory attached to the second winning opening 640 is often in a closed state, and it is difficult to win the second winning opening 640. Then, the ball is fired so that the ball passes to the left side of the variable display device unit 80 (so-called "left-handed"), and by winning the first winning opening 64, many chances of a big hit lottery are obtained and the big hit is obtained. It is advantageous for the player to aim at that.

On the other hand, during the probability change or the time reduction, by passing the ball through the through gate 67, the electric accessory 640a attached to the second winning opening 640 is likely to be opened, and the second winning opening 640 is likely to be won. Therefore, the ball is launched toward the second winning opening 640 so that the ball passes to the right of the variable display device 80 (so-called "right-handed"), and the electric accessory is opened by passing through the through gate 67. At the same time, it is advantageous for the player to aim for a 15R probability variation jackpot by winning the second winning opening 640.

Since the pachinko machine 10 in the present embodiment has a symmetrical configuration of the game board 13, it is possible to aim at the first winning opening 64 by "right-handed" or to aim at the second winning opening 640 by "left-handing". You can also aim. Therefore, the pachinko machine 10 of the present embodiment is a method of firing a ball to the player according to the gaming state of the pachinko machine 10 (whether it is in the probabilistic change, in the time saving, or in the normal state). Can be eliminated from changing to "left-handed" and "right-handed". Therefore, it is possible to eliminate the hassle of changing the way the ball is hit.

A variable winning device 330 (see FIG. 11) is arranged below the first winning opening 64, and a specific winning opening 65a is provided in a substantially central portion thereof. In the pachinko machine 10, when the jackpot lottery performed due to the winning of the first winning opening 64 or the second winning opening 640 becomes a jackpot, after a predetermined time (variable time) has elapsed, the jackpot stop symbol is displayed. The first symbol display device 37A or the first symbol display device 37B is turned on so that the stop symbol corresponding to the jackpot is displayed on the third symbol display device 81 to indicate the occurrence of the jackpot. After that, the game state shifts to a special game state (big hit) in which the ball is easy to win. As this special game state, the specific winning opening 65a, which is normally closed, is opened for a predetermined time (for example, until 30 seconds have passed or until 10 balls are won).

The specific winning opening 65a is closed after a lapse of a predetermined time, and after the closing, the specific winning opening 65a is opened again for a predetermined time. The opening / closing operation of the specific winning opening 65a can be repeated up to 15 times (15 rounds), for example. The state in which this opening / closing operation is performed is a form of a special gaming state that is advantageous to the player, and a larger amount of prize balls than usual is paid out to the player as a game value (game value). Is done.

The special gaming state is not limited to the above-described form. A large opening that opens and closes separately from the specific winning opening 65a is provided in the game area, and when the LED corresponding to the big hit is turned on in the first symbol display devices 37A and 37B, the specific winning opening 65a is opened for a predetermined time. A special game in which a large opening provided separately from the specific winning opening 65a is opened a predetermined number of times for a predetermined time when the ball wins a prize in the specific winning opening 65a while the specific winning opening 65a is open. It may be formed as a state. Further, the specific winning opening 65a is not limited to one, and one or two or more (for example, three) may be arranged, and the arrangement position is also the lower right side of the first winning opening 64 or the first. Not limited to the lower left side of the winning opening 64, for example, the left side of the variable display device unit 80 may be used.

In the right corner on the lower side of the game board 13, a sticking space K1 for sticking a certificate stamp or an identification label is provided, and the certificate stamp or the like stuck on the sticking space K1 is a small window of the front frame 14. It can be visually recognized through 35 (see FIG. 1).

The game board 13 is provided with an out port 71. Balls that flow down the game area and do not win any of the winning openings 63, 64, 65a, 640 are guided to a ball discharge path (not shown) through the out opening 71. The out openings 71 are arranged in pairs on the left and right sides of the specific winning opening 65a.

A large number of nails are planted on the game board 13 in order to appropriately disperse and adjust the falling direction of the ball, and various members (accessories) such as a windmill are arranged.

As shown in FIG. 3, the control board units 90 and 91 and the back pack unit 94 are mainly provided on the back side of the pachinko machine 10. The control board unit 90 is unitized by mounting a main board (main control device 110), a voice lamp control board (voice lamp control device 113), and a display control board (display control device 114). The control board unit 91 is unitized by mounting a payout control board (payout control device 111), a launch control board (launch control device 112), a power supply board (power supply device 115), and a card unit connection board 116.

In the back pack unit 94, the back pack 92 forming the protective cover portion and the payout unit 93 are unitized. In addition, each control board is used for MPU as a one-chip microcomputer that controls each control, a port for contacting various devices, a random number generator used for various lottery, and for time counting and synchronization. A clock pulse generation circuit, etc. is installed as needed.

The main control device 110, the voice lamp control device 113 and the display control device 114, the payout control device 111 and the launch control device 112, the power supply device 115, and the card unit connection board 116 are housed in the board boxes 100 to 104, respectively. .. The board boxes 100 to 104 include a box base and a box cover that covers an opening of the box base, and the box base and the box cover are connected to each other to house each control device and each board.

Further, in the board box 100 (main control device 110) and the board box 102 (payout control device 111 and launch control device 112), the box base and the box cover are connected by a sealing unit (not shown) so as not to be opened (caulking structure). (Consolidated by). Further, a sealing sticker (not shown) is attached to the connecting portion between the box base and the box cover over the box base and the box cover. This sealing seal is made of a brittle material, and if the sealing seal is to be peeled off in order to open the board boxes 100 and 102, or if the board boxes 100 and 102 are forcibly opened, the box base side and the box cover are used. Cut to the side. Therefore, by checking the sealing unit or the sealing seal, it is possible to know whether or not the substrate boxes 100 and 102 have been opened.

The payout unit 93 includes a tank 130 located at the uppermost portion of the back pack unit 94 and opened upward, a tank rail 131 connected below the tank 130 and gently inclined toward the downstream side, and a downstream of the tank rail 131. A case rail 132 vertically connected to the side and a payout device 133 provided at the most downstream portion of the case rail 132 and paying out balls by a predetermined electrical configuration of a payout motor 216 (see FIG. 4) are provided. ing. The tank 130 is sequentially replenished with balls supplied from the island equipment of the game hall, and the required number of balls is appropriately paid out by the payout device 133. A vibrator 134 for adding vibration to the tank rail 131 is attached to the tank rail 131.

Further, the payout control device 111 is provided with a state return switch 120, the launch control device 112 is provided with a variable resistor operation knob 121, and the power supply device 115 is provided with a RAM erase switch 122. The state return switch 120 is operated to clear the ball clogging (return to the normal state) when a payout error occurs, such as a ball clogging of the payout motor 216 (see FIG. 4). The operation knob 121 is operated to adjust the firing force of the firing solenoid. The RAM erase switch 122 is operated when the power is turned on when it is desired to return the pachinko machine 10 to the initial state.

Next, the electrical configuration of the pachinko machine 10 will be described with reference to FIG. FIG. 4 is a block diagram showing an electrical configuration of the pachinko machine 10.

The main control device 110 is equipped with an MPU 201 as a one-chip microcomputer which is an arithmetic unit. The MPU 201 is a ROM 202 that stores various control programs and fixed value data executed by the MPU 201, and a memory for temporarily storing various data and the like when the control program stored in the ROM 202 is executed. A certain RAM 203 and various other circuits such as an interrupt circuit, a timer circuit, and a data transmission / reception circuit are built in. In the main control device 110, the MPU 201 is used to perform main processing of the pachinko machine 10 such as a jackpot lottery, display settings in the first symbol display devices 37A and 37B and the third symbol display device 81, and a lottery of display results in the second symbol display device. To execute.

In order to instruct the operation of the sub control device such as the payout control device 111 and the voice lamp control device 113, various commands are transmitted from the main control device 110 to the sub control device by the data transmission / reception circuit. Such a command is transmitted from the main control device 110 to the sub control device in only one direction.

The RAM 203 includes various areas, counters, flags, a stack area in which the contents of the internal registers of the MPU 201 and the return address of the control program executed by the MPU 201 are stored, various flags, counters, I / O, and the like. It has a work area (work area) in which values are stored. The RAM 203 has a configuration in which a backup voltage is supplied from the power supply device 115 to hold (back up) data even after the power supply of the pachinko machine 10 is cut off, and all the data stored in the RAM 203 is backed up. ..

When the power supply is cut off due to the occurrence of a power failure or the like, the stack pointer at the time of the power failure (including the time when a power failure occurs; the same applies hereinafter) and the value of each register are stored in the RAM 203. On the other hand, when the power is turned on (including power on due to power failure elimination; the same applies hereinafter), the state of the pachinko machine 10 is restored to the state before the power was cut off based on the information stored in the RAM 203. Writing to the RAM 203 is executed by the main process (not shown) when the power is cut off, and restoration of each value written in the RAM 203 is executed in the start-up process (not shown) at the time of turning on the power. The NMI terminal (non-maskable interrupt terminal) of the MPU 201 is configured so that a power failure signal SG1 from the power failure monitoring circuit 252 is input when the power is cut off due to a power failure or the like, and the power failure signal SG1 is the MPU201. When input to, the NMI interrupt process (not shown) as the power failure process is immediately executed.

An input / output port 205 is connected to the MPU 201 of the main control device 110 via a bus line 204 composed of an address bus and a data bus. The input / output port 205 is centered on the lower side of the payout control device 111, the voice lamp control device 113, the first symbol display devices 37A and 37B, the second symbol display device, the second symbol hold lamp, and the opening / closing plate of the specific winning opening 65a. A solenoid 209 consisting of a large opening solenoid for driving the opening and closing and a solenoid for driving an electric accessory is connected to the front side, and the MPU 201 sends various commands and control signals to these via the input / output port 205. To send.

Further, the input / output port 205 includes various switches 208 including a switch group (not shown), a sensor group including a slide position detection sensor S and a rotation position detection sensor R, and a RAM erasing switch circuit 253 provided in the power supply device 115, which will be described later. Is connected, and the MPU 201 executes various processes based on the signals output from the various switches 208 and the RAM erase signal SG2 output from the RAM erase switch circuit 253.

The payout control device 111 drives the payout motor 216 to control the payout of prize balls and rented balls. The MPU 211, which is an arithmetic unit, has a ROM 212 that stores a control program and fixed value data executed by the MPU 211, and a RAM 213 that is used as a work memory or the like.

The RAM 213 of the payout control device 111, like the RAM 203 of the main control device 110, has a stack area in which the contents of the internal registers of the MPU 211 and the return address of the control program executed by the MPU 211 are stored, and various flags and counters. It has a work area (work area) in which values such as, I / O, etc. are stored. The RAM 213 has a configuration in which a backup voltage is supplied from the power supply device 115 to hold (back up) data even after the power supply of the pachinko machine 10 is cut off, and all the data stored in the RAM 213 is backed up. Similar to the MPU 201 of the main control device 110, the NMI terminal of the MPU 211 is also configured so that the power failure signal SG1 is input from the power failure monitoring circuit 252 when the power is cut off due to the occurrence of a power failure or the like. When input to the MPU211, an NMI interrupt process (not shown) as a power failure process is immediately executed.

An input / output port 215 is connected to the MPU 211 of the payout control device 111 via a bus line 214 composed of an address bus and a data bus. A main control device 110, a payout motor 216, a launch control device 112, and the like are connected to the input / output port 215, respectively. Further, although not shown, the payout control device 111 is connected to a prize ball detection switch for detecting the paid out prize balls. The prize ball detection switch is connected to the payout control device 111, but is not connected to the main control device 110.

The launch control device 112 controls the ball launch unit 112a so that when the main control device 110 gives an instruction to launch the ball, the launch strength of the ball corresponds to the amount of rotation of the operation handle 51. .. The ball launching unit 112a includes a firing solenoid and an electromagnet (not shown), and the firing solenoid and the electromagnet are allowed to be driven when predetermined conditions are met. Specifically, the touch sensor 51a detects that the player is touching the operation handle 51, and the operation is performed on condition that the launch stop switch 51b for stopping the launch of the ball is off (not operated). The firing solenoid is excited in response to the rotation operation amount (rotation position) of the handle 51, and the ball is launched with a strength corresponding to the operation amount of the operation handle 51.

The audio lamp control device 113 is an audio output in an audio output device (speaker, etc. not shown) 226, an output of lighting and extinguishing in a lamp display device (illumination units 29 to 33, indicator lamp 34, etc.) 227, and a variation effect (variation). It controls the setting of the display mode of the third symbol display device 81 performed by the display control device 114 such as the display) and the advance notice effect. The arithmetic unit MPU 221 has a ROM 222 that stores a control program and fixed value data executed by the MPU 221 and a RAM 223 that is used as a work memory or the like.

An input / output port 225 is connected to the MPU 221 of the voice lamp control device 113 via a bus line 224 composed of an address bus and a data bus. A main control device 110, a display control device 114, an audio output device 226, a lamp display device 227, other devices 228, a frame button 22, and the like are connected to the input / output port 225, respectively. Other devices 228 include a drive motor 342 and a voice coil motor 352.

The voice lamp control device 113 determines the display mode of the third symbol display device 81 based on various commands (variation pattern command, stop type command, etc.) received from the main control device 110, and commands the determined display mode. The display control device 114 is notified by (display fluctuation pattern command, display stop type command, etc.). Further, the voice lamp control device 113 monitors the input from the frame button 22, and when the frame button 22 is operated by the player, the stage displayed on the third symbol display device 81 can be changed or the super reach can be changed. The display control device 114 is instructed to change the effect content of the time. When the stage is changed, a rear image change command including information about the changed stage is transmitted to the display control device 114 in order to display the rear image corresponding to the changed stage on the third symbol display device 81. .. Here, the back image is an image displayed on the back side of the third symbol, which is a main image to be displayed on the third symbol display device 81. The display control device 114 displays various images on the third symbol display device 81 according to a command transmitted from the voice lamp control device 113.

Further, the voice lamp control device 113 receives a command (display command) indicating the display content of the third symbol display device 81 from the display control device 114. Based on the display command received from the display control device 114, the voice lamp control device 113 outputs the voice corresponding to the display content according to the display content of the third symbol display device 81 from the voice output device 226, and also outputs the voice corresponding to the display content. The lighting and extinguishing of the lamp display device 227 are controlled according to the display content.

In the display control device 114, the voice lamp control device 113 and the third symbol display device 81 are connected, and based on the command received from the voice lamp control device 113, the third symbol variation effect of the third symbol display device 81 and the like are performed. It controls the display. Further, the display control device 114 appropriately transmits a display command for notifying the display content of the third symbol display device 81 to the voice lamp control device 113. The voice lamp control device 113 outputs voice from the voice output device 226 according to the display content indicated by this display command, thereby matching the display of the third symbol display device 81 with the voice output from the voice output device 226. be able to.

The power supply device 115 is provided with a power supply unit 251 for supplying power to each part of the pachinko machine 10, a power failure monitoring circuit 252 for monitoring power failure due to a power failure, and a RAM erasing switch 122 (see FIG. 3). It has an erasing switch circuit 253. The power supply unit 251 is a device that supplies the required operating voltage to each of the control devices 110 to 114 and the like through a power supply path (not shown). As an outline, the power supply unit 251 takes in a voltage of 24 volt AC supplied from the outside, and has a voltage of 12 volt for driving various switches such as various switches 208, a solenoid such as a solenoid 209, and a motor. A 5 volt voltage for logic, a backup voltage for RAM backup, and the like are generated, and these 12 volt voltage, 5 volt voltage, and backup voltage are supplied to each control device 110 to 114 and the like.

The power failure monitoring circuit 252 is a circuit for outputting a power failure signal SG1 to each NMI terminal of the MPU 201 of the main control device 110 and the MPU 211 of the payout control device 111 when the power is cut off due to the occurrence of a power failure or the like. The power failure monitoring circuit 252 monitors the DC stable 24 volt voltage, which is the maximum voltage output from the power supply unit 251 and determines that a power failure (power cutoff, power cutoff) has occurred when this voltage becomes less than 22 volt. Then, the power failure signal SG1 is output to the main control device 110 and the payout control device 111. By the output of the power failure signal SG1, the main control device 110 and the payout control device 111 recognize the occurrence of the power failure and execute the NMI interrupt process. The power supply unit 251 outputs a voltage of 5 volts, which is the drive voltage of the control system, for a sufficient time for executing the NMI interrupt process even after the voltage of DC stable 24 volts becomes less than 22 volts. Is configured to maintain a normal value. Therefore, the main control device 110 and the payout control device 111 can normally execute and complete the NMI interrupt process (not shown).

The RAM erase switch circuit 253 is a circuit for outputting the RAM erase signal SG2 for clearing the backup data to the main control device 110 when the RAM erase switch 122 (see FIG. 3) is pressed. When the RAM erase signal SG2 is input when the power of the pachinko machine 10 is turned on, the main control device 110 clears the backup data, and the payout control device 111 issues a payout initialization command for clearing the backup data. It transmits to the device 111.

FIG. 5 is a front perspective view of the operation device 300. As shown in FIG. 5, the operation device 300 is arranged at the center portion in the left-right direction of the inner frame 12 in the front view (that is, the center portion in the left-right direction of the pachinko machine 10).

The operation device 300 includes a tilting device 310 that is configured to be tilted by being pushed by a player, and is located in an area composed of a housing recess 17a recessed in the front-rear direction along the outer frame of the upper plate 17. Arranged. When the player tilts (rotates) the tilting device 310, a signal is input to the pachinko machine 10 (see FIG. 1).

There is a gap between the tilting device 310 and the accommodating recess 17a so that at least the fingers of the hand can be comfortably inserted. As a result, the player can prepare to operate the tilting device 310 by arranging the fingertips on the back side of the upper surface of the tilting device 310 (see FIG. 7).

Since the player holds the operation handle 51 with his right hand, the tilting device 310 is often operated with his left hand. Therefore, in the following description, the description will be made on the assumption that the player operates the tilting device 310 with the left hand.

6 (a) is a partial front view of the pachinko machine 10, and FIG. 6 (b) is a partial cross-sectional view of the pachinko machine 10 in the VIb-VIb line of FIG. 6 (a). Is a partial front view of the pachinko machine 10, and FIG. 7 (b) is a partial cross-sectional view of the pachinko machine 10 in line VIIb-VIIb of FIG. 7 (a).

In FIGS. 6 and 7, the vicinity of the operating device 300 of the pachinko machine 10 is partially illustrated. Note that FIG. 6 shows a state in which the tilting device 310 is arranged in the first state (initial state in the present embodiment) in which the operation surface 312a1 faces in the vertical direction, and FIG. 7 shows the tilting device 310 from the first state. The state in which the operation surface 312a1 is arranged in the second state facing upward and rearward by rising around the shaft portion 314 is shown. In FIG. 7, an example of a player's hand operating the tilting device 310 is illustrated by an imaginary line.

The tilting device 310 is configured to be able to automatically operate between the first state and the second state by the driving force of the driving device 340. The details of the drive device 340 will be described later.

An example of the operation of the tilting device 310 will be described. The operation of the tilting device 310 is performed by the player, for example, when a specific display (for example, a display of "press a button") appears on the third symbol display device 81 (see FIG. 2).

Here, for example, when the tilting device 310 is pushed in by a method of dropping the hand vigorously downward, as in the case of pushing a button that moves up and down, the position of the operation surface 312a1 moves toward the front side depending on the degree of tilting. The palm and the operation surface 312a1 are easily rubbed against each other. Therefore, it is possible to give a sense of discomfort to the player, and it is possible to suppress the player from performing the pushing operation by dropping his / her hand downward vigorously.

In the present embodiment, as shown in FIG. 7, the fingertip is placed near the shaft portion 314 of the tilting device 310, and the palm is lowered downward with the fingertip as a fulcrum, so that the palm is integrated with the operation surface 312a1. The tilting device 310 can be comfortably pushed in and operated.

Therefore, the player can be guided to operate by lowering the palm with the fingertip as a fulcrum so as not to forcefully drop the hand downward. As a result, the degree of impact applied to the tilting device 310 by the operation of the player can be reduced, and the possibility of damage to the tilting device 310 can be reduced.

The difference in the appearance of the tilting device 310 from the player's viewpoint will be described with reference to FIGS. 8 and 9. FIG. 8 is a front perspective view of the operation device 300 in the direction of arrow VIII of FIG. 6, and FIG. 9 is a front perspective view of the operation device 300 in the direction of arrow IX of FIG. In addition, in FIGS. 8 and 9, the shape of the pachinko machine 10 is partially illustrated by an imaginary line. Further, in FIG. 9, an example of a player's hand for pushing and operating the tilting device 310 is illustrated by an imaginary line.

As shown in FIGS. 8 and 9, the operation surface 312a1 of the tilting device 310 is visible from the player's point of view in the first state, while the area is reduced to the extent that it is invisible in the second state. (The operation surface 312a1 is directed to the outside of the player's viewpoint). As a result, the appearance of the tilting device 310 can be significantly changed between the first state and the second state.

In the present embodiment, the area of the protective lens member 311i is gradually increased in the process of changing from the first state to the second state, and the LED device 341f arranged inside the operation device 300 accordingly (FIG. FIG. Since the amount of light in (see 12) is gradually increased, the difference in the amount of light (degree of brightness) that the player can see between the first state and the second state becomes large, and the first state and the second state are displayed. Can greatly change the appearance of the tilting device 310.

An example of the operation of the tilting device 310 will be described. In the present embodiment, as shown in FIG. 9, the outer side surface of the little finger is placed near the shaft portion 314 (see FIG. 7) of the tilting device 310, and the palm is lowered downward with the outer side surface portion of the little finger as a fulcrum. (By rotating the wrist as an axis), the tilting device 310 can be comfortably pushed in while the palm is integrated with the operation surface 312a1.

Therefore, the player can be guided to perform the operation by lowering the palm downward with the outer side surface portion of the little finger as a fulcrum so as not to force the hand to drop downward. As a result, the degree of impact applied to the tilting device 310 by the operation of the player can be reduced, and the possibility of damage to the tilting device 310 can be reduced.

Next, the operation device 300 will be described with reference to FIGS. 10 and 11. FIG. 10 is a front perspective view of the operation device 300, and FIG. 11 is a rear perspective view of the operation device 300. As shown in FIG. 10, the operation device 300 is rotatably supported around a shaft portion 314 in which the tilting device 310 is arranged at the rear end portion.

Further, as shown in FIG. 11, a voice coil motor 352 that gives an impact in the straight direction to the tilting device 310 and detection sensors 324L and 324R that detect a pushing operation from the first state lower the tilting device 310. It is arranged outside the lower frame member 320 that surrounds it from the side.

In this way, by arranging the sensor that detects the position of the tilting device 310, the voice coil motor that gives the driving force, and the like outside the lower frame member 320, the region inside the lower frame member 320 is largely used and the tilting device 320 is tilted. The device 310 can be housed in the lower frame member 320. As a result, a large amount of movable amount of the tilting device 310 can be secured.

FIG. 12 is a front exploded perspective view of the operating device 300, and FIG. 13 is a rear exploded perspective view of the operating device 300. As shown in FIGS. 12 and 13, the operation device 300 includes a tilting device 310 having ring members BR1 arranged at the left and right end portions at the rear side end portion (the back end portion on the paper surface of FIG. 12), and a tilting device 310 thereof. A lower frame member 320 having a lower bearing portion 323 that supports the ring member BR1 of the device 310 from below and determining the push-in end of the tilting device 310, and a lower frame member 320 that supports the ring member BR1 of the tilting device 310 from above. It is a member having a recessed portion arranged opposite to the lower frame member 320 and having a large opening in the central portion, and is fastened and fixed to the lower frame member 320 in a manner in which the tilting member 310 is arranged between the lower frame member 320 and the lower frame member 320. To the tilting device 310 via the upper frame member 330 that determines the arrangement of the tilting device 310 in the second state, and the arm member 345 that is fastened and fixed to the lower side of the lower frame member 320 and constitutes the tilting device 310 and the link mechanism. It mainly includes a drive device 340 that transmits a driving force, and a protective cover device 350 that is fastened and fixed to the drive device 340 and protects the drive device 340 by covering the drive device 340 from three sides in the left-right direction and the rear direction.

The lower frame member 320 is a cup-shaped member that is configured such that the left and right portions of the bottom surface are inclined downward toward the front side, and the bottom plate portion 321 that is inclined downward toward the front side and the bottom plate portion 321 thereof. A horizontal portion 322 composed of a plate-shaped member arranged horizontally at the upper end portion on the back side of the above, and a semicircular receiving portion open upward near the rear end portion of the horizontal portion 322, which is a tilting device 310. The lower bearing portion 323 that receives the shaft portion 314 from the lower side, the left side detection sensor 324L arranged in pairs on the lower side of the bottom plate portion 321 and the right side detection sensor 324R, and the bottom plate portion 321 horizontally at the center position in the left-right direction. It mainly includes an opening 325, which is an opening that is opened by scraping a portion arranged on the lower side of the portion 322.

The bottom plate portion 321 defines the moving end of the tilting device 310 by abutting with the tilting device 310, and has a plurality of openings so that the portion of the tilting device 310 can pass through the bottom plate portion 321. NS.

The bottom plate portion 321 has a transmission hole 321a drilled in the central portion on the front side, a detection hole 321b drilled along the detection grooves of the left and right detection sensors 324L and 324R, and left and right on the left and right of the opening 325. It mainly includes an insertion hole 321c which is formed symmetrically.

The transmission hole 321a is arranged at a front position of the voice coil motor 352 of the protective cover device 350, and is formed in a size that allows the overhanging convex portion 311j of the tilting device 310 to pass through. By driving the voice coil motor 352 in a state where the overhanging convex portion 311j of the tilting device 310 projects below the bottom plate portion 321, a driving force in the linear motion direction can be applied to the tilting device 310.

The detection hole 321b is a through hole through which detection pieces 311 gL and 311 gR projecting from the lower surface of the tilting device 310 can be inserted. By arranging the detection pieces 311 gL and 311 gR protruding from the detection hole 321b in the detection grooves of the detection sensors 324L and 324R, the posture of the tilting device 310 can be detected.

The insertion hole 321c is sized so that the shaft portion 311c arranged on the flange of the tilting device 310 and the arm member 345 of the drive device 340 can be inserted, and the arm member is formed when the drive device 340 is operated. A through hole is formed to a position where interference with the 345 can be avoided.

The horizontal portion 322 constitutes a flat surface for fastening and fixing the lower frame member 320 and the drive device 340, and is formed of a U-shape having an open portion on the front side while extending upward from the upper surface thereof. A locking portion 322a is provided.

The locking portion 322a is a portion that locks one end of the torsion spring 315 of the tilting device 310 so as not to move backward. When the locking portion 322a locks the torsion spring 315, the urging force of the torsion spring 322a acts in the direction of moving the tilting device 310 to the second state.

The detection sensors 324L and 324R are photocoupler type sensors that detect the position of the tilting device 310. The detection sensors 324L and 324R are arranged at positions where the distances (positions of the detection grooves) from the bottom plate portion 321 of the lower frame member 320 are the same on the left and right sides.

Further, the photocoupler type sensor includes a light projecting unit that emits light and a light receiving unit that receives light from the light emitting unit, and a gap (slit, detection groove) into which a detection portion can be inserted. Means a sensor that is arranged in a substantially U-shape.

The opening 325 is a through hole for allowing the LED device 341f of the drive device 340, the rotary claw member 347, and the like to enter the inside of the lower frame member 320. Therefore, the left-right width thereof is made larger than the left-right width of the pair of rotating claw members 347.

On the other hand, regarding the vertical width, since the drive device 340 is configured to project the LED device 341f toward the upper front side (see FIG. 17B), the drive device 341f passes through the opening 325 and then the drive device. By pushing the 340 upward, the LED device 341f can be arranged above the opening 325, and the opening 325 is compared with the vertical width including the LED device 341f to the rotary claw member 347. The vertical width can be shortened.

The upper frame member 330 is arranged so as to face the opening 331, which is an opening sized to catch the extension portion 311h extending from the lower end surface of the tilting device 310 to the front side, and the lower bearing portion 323 of the lower frame member 320. It is mainly provided with an upper bearing portion 332 which is formed of a semicircular shape whose lower side is open and supports the ring member BR1 of the tilting device 310.

The protective cover device 350 is configured so that it can be divided in the vertical direction and covers three directions except the front side, and the main body cover 351 and the main body cover 351 which are fastened and fixed to the lower end of the drive device 340. A voice coil motor 352 that is supported by the bottom plate and is arranged on the front side and whose vibration surface is directed diagonally forward and upward, a left side detection sensor 353L that is a detection sensor having a detection groove on the upper side of the bottom plate of the main body cover 351 and a right side. It mainly includes a detection sensor 353R.

Note that FIG. 12 shows a state in which the main body cover 351 is partially broken so that the right side detection sensor 353R arranged on the opposite side of the left side detection sensor 353L with respect to the left and right center can be visually recognized.

The voice coil motor 352 is arranged in a posture in which the vibration surface is substantially parallel to the bottom plate portion 321 of the lower frame member 320 in the assembled state (see FIG. 10). As a result, the voice coil motor 352 is driven when the tilting device 310 projects the overhanging convex portion 311j downward through the transmission hole 321a, so that the driving force can be efficiently transmitted to the tilting device 310.

The detection sensors 353L and 353R are photocoupler type sensors that detect the phase of the disk cams 344L and 344R of the drive device 340. The disc cams 344L and 344R of the drive device 340 are arranged in such a manner that they are arranged inside the detection groove of the detection sensors 353L and 353R. Detecting whether or not the detection holes 344eL and 344eR of the disc cams 344L and 344R are arranged in the detection grooves of the detection sensors 353L and 353R, and detecting that the disc cams 344L and 344R are arranged in a specific phase. Can be done.

In the present embodiment, since the left and right disk cams 344L and 344R of the drive device 340 include the detection holes 344eL and 344eR in different phases, the specific phase that can be detected by the detection sensors 353L and 353R is 2. It becomes a kind.

Next, the tilting device 310 will be described with reference to FIGS. 14 to 16. 14 (a) is a front view of the tilting device 310, FIG. 14 (b) is a side view of the tilting device 310 in the direction of arrow XIVb of FIG. 14 (a), and FIG. 14 (c) is a side view of the tilting device 310. It is sectional drawing of the tilting apparatus 310 in the XIVc-XIVc line of FIG. 14A. FIG. 15 is a front exploded perspective view of the tilting device 310, and FIG. 16 is a rear exploded perspective view of the lid 312 of the tilting device 310.

As shown in FIGS. 14 to 16, the tilting device 310 has a mode in which a case main body 311 formed of a box-shaped body having side fan-shaped openings at the top and bottom and an upper opening of the case main body 311 are covered with a lid. A mode in which the lid 312 fastened and fixed to the case body 311, the spherical lens member 313 fastened and fixed to the front end of the lid 312 and hung downward, and the rear end of the case body 311 and the lid 312 are sandwiched between them. In a ring shape, the shaft portion 314 arranged in the above, the torsion spring 315 wound around the shaft portion 314, and the case body 311 and the lid 312 are indivisiblely fixed at the rear ends of the case body 311 and the lid 312. Mainly includes a ring member BR1.

The case body 311 has a bottom plate portion 311a that is tilted downward from the back side to the front side in the first state, an opening 311b opened in the center of the bottom plate portion 311a, and left and right of the opening 311b. A cylindrical shaft portion 311c extending downward from a flange extending downward along the edge of the spring and a recessed portion 311d which is a semicircular concave portion supporting the shaft portion 314 at the rear end portion. The insertion groove 311e, which is a groove in which both arm portions 315a of the torsion spring 315 can be inserted, and the hook-shaped portion 311f, which is formed in a hook shape and locks the central portion 315b of the torsion spring 315. A pair of left and right detection pieces 311 gL extending below the bottom plate portion 311a, a right side detection piece 311 gR (see FIG. 15), and a extension extending from the front end portion of the bottom plate portion 311a to the front side by a predetermined amount. A protective lens member 311i, which is arranged above the front end of the bottom plate 311h, has a shape along an arc centered on the shaft 314, and is formed of a light-transmitting material, and a bottom plate. Mainly includes an overhanging convex portion 311j which is projected downward from the central portion in the left-right direction at the front end portion of the 311a.

The bottom plate portion 311a is a portion that comes into contact with the bottom plate portion 321 of the lower frame member 320 on a surface when the tilting device 310 is pushed downward by the player.

The opening 311b is configured as an opening through which the LED device 341f of the drive device 340 and the arm member 345 of the drive device 340 can be inserted.

The shaft portion 311c is a cylindrical member inserted into the guide hole 345b of the arm member 345 (see FIG. 17B) of the drive device 340, and serves as a portion for transmitting a driving force to and from the drive device 340. To be equipped.

The left side detection piece 311 gL and the right side detection piece 311 gR are portions inserted into the detection grooves of the left side detection sensor 324L and the right side detection sensor 324R (see FIG. 15) of the lower frame member 320, respectively, and the left side detection piece 311 gL However, the overhang length is longer than that of the right side detection piece 311 gR.

In the present embodiment, the angle from the tip of the right side detection piece 311 gR to the tip of the left side detection piece 311 gL with respect to the shaft portion 314 is about 3 ° (from the first state (see FIG. 22) to the push-in end (FIG. 22). The left side detection piece 311 gL is projected as compared with the right side detection piece 311 gR so that the tilting device 310 rotates up to (see 23).

The extension portion 311h is a portion that projects from the lower end portion of the protective lens member 311i to the front side, and extends to a position where it is locked to the opening 331 of the upper frame member 330 in the assembled state (see FIG. 10). Consists of aspects.

The protective lens member 311i has a curved shape in the top view (see FIG. 14 (a)) and a curved shape in the left-right direction view (see FIG. 14 (c)), so that the player can use it. The configuration is such that the load when pushing the tilting device 310 is easily released (easy to flow). Thereby, the durability of the tilting device 310 can be improved.

The overhanging convex portion 311j is projected at a right angle from the lower surface of the bottom plate portion 311a and has a cross-sectional shape smaller than that of the transmission hole 321a of the lower frame member 320, and the player pushes the tilting device 310 into operation. In the state (see FIG. 29), it is inserted into the transmission hole 321a and its tip is projected below the lower frame member 320.

As shown in FIG. 16, the lid 312 has a top plate member 312a having an operation surface 312a1, an intermediate plate member 312b fastened and fixed to the lower surface of the top plate member 312a, and the intermediate plate member 312b attached to the top plate member 312a. It is mainly provided with a cylindrical member 312c having a cylindrical shape having a size surrounding the LED device 341f in the first state (see FIG. 6).

The cylindrical member 312c improves the strength of the lid 312 by the rigidity in the axial direction, and in the first state (see FIG. 6), the light emitted from the LED device 341f toward the tilting device 310 is cylindrical due to its positional relationship. While it is fastened to the inside of the member 312c, in the second state (see FIG. 7), it is arranged in such a manner that such limitation is released and the light from the LED device 341f can be irradiated over a wide range.

The lens member 313 is formed of a light-transmitting material, and the upper and lower end portions are extended forward in a flange shape, and the extended end portion is formed in a shape that matches the curved shape of the protective lens member 311i. A spherical shell portion 313a formed from a spherical shell shape is provided in the central portion.

The torsion spring 315 is wound around the shaft portion 314 with a pair of left and right twisted portions, and has both arm portions 315a extending rearward from the left and right outer ends of the twisted portion and a central portion 315b connecting the pair of twisted portions. , Equipped with.

Next, the drive device 340 will be described with reference to FIGS. 17 and 18. 17 (a) is a front view of the drive device 340, FIG. 17 (b) is a side view of the drive device 340 in the direction of arrow XVIIb of FIG. 17 (a), and FIG. 18 is a side view of the drive device 340. It is a front view exploded perspective view of.

As shown in FIGS. 17 and 18, the drive device 340 is a drive motor that is fastened and fixed to a main body member 341 that constitutes a frame by bending a plate-shaped sheet metal member and a driving force that generates a driving force. A pair of disc cams 344 (left disc cam 344L, right disc cam) fixed to both ends of the transmission shaft rod 343 that transmits the driving force of the 342 and its drive motor 342 and the transmission shaft rod 343 so as not to rotate. 344R), the arm member 345 pivotally supported by the connecting pin 344d of the disc cam 344, and the first overhanging portion 344c1 and the second of the disc cam 344 while being pivotally supported by the shaft portion 341c of the main body member 341. The release member 346 that comes into contact with the overhanging portion 344c3 in the rotational direction, the rotary claw member 347 that is pivotally supported by the release member 346 and operates relative to the release member 346, and the rotary claw member 347 are tilted down. A torsion spring-like first spring SP1 which is a coil spring-like spring member that generates an urging force in the direction of causing the force, and a torsion spring-like spring member that generates an urging force in the direction of separating the release member 346 and the rotary claw member 347 from each other. It mainly includes a second spring SP2, which is a spring member.

The main body member 341 is bored at the same position of the motor accommodating portion 341a which is bent rearward on the left and right to form a U-shape in the top view and the plate portion of the motor accommodating portion 341a which is arranged to face each other, and is a disk. A shaft support hole 341b that pivotally supports the cam 344, and a shaft portion 341c that is convex in the left-right direction at a position deviated from the shaft support hole 341b to the front side in a manner having a shaft parallel to the shaft of the shaft support hole 341b. , An extension portion 341d extending from the motor accommodating portion 341a below the shaft portion 341c, an illumination support portion 341e extending forward and upward from the motor accommodating portion 341a, and the illumination support portion 341e thereof. It mainly includes an LED device 341f which is arranged at the upper end and has an LED light source inside.

The LED device 341f has a triangular member on the upper surface thereof, and includes a portion that refracts light (a portion that refracts light). As a result, the light of the LED device 341f can be evenly irradiated upward and forward.

The drive motor 342 includes a fixing member 342a that is fastened and fixed to the motor housing portion 341a inside the U-shape of the motor housing portion 341a.

The fixing member 342a pivotally supports the rotary gear of the drive motor 342 and supports the transmission shaft rod 343 in such a manner that the transmission gear 343b meshes with the rotary gear.

The arm member 345 is bored at one end in a perfect circular shape, and at the shaft support hole 345a axially supported by the connecting pin 344d of the disc cam 344, and at the other end in a rectangular shape. Along with this, a guide hole 345b through which the shaft portion 311c (see FIG. 15) of the tilting device 310 is inserted is mainly provided.

The guide hole 345b is formed at a position where the end on the opposite side of the shaft support hole 345a comes into contact with the shaft portion 311c in the first state of the tilting device 310, and the disc cam 344 makes one or more rotations on the opposite end. It is formed in a position sufficient to be rotatable.

The transmission shaft rod 343 will be described with reference to FIG. FIG. 19 is a front exploded perspective view of the transmission shaft rod 343. The transmission shaft rod 343 has a cylindrical member 343a to which a disc cam 344 (see FIG. 18) is fixed at both ends, and a transmission gear 343b that is pivotally supported by the cylindrical member 343a and meshes with the rotary gear of the drive motor 342. A movable clutch 343c that can switch whether or not to transmit a driving force between the transmission gear 343b and the cylindrical member 343a by axial movement, a coil spring 343d that presses the movable clutch 343c against the transmission gear 343b, and the like. Mainly prepared.

The cylindrical member 343a includes fixing portions 343a1 and 343a2 having a D-shaped cross section for fixing the disc cam 344 at both ends thereof, and the fixing portion 343a2 on the right side is formed longer toward the center side than the fixing portion 343a1 on the left side. NS. Here, in detail, the fixed portion 343a2 is formed with a length capable of moving to a position where the movable clutch 343c does not interfere with the transmission gear 343b when the movable clutch 343c moves against the urging force of the coil spring 343d.

The transmission gear 343b is a clutch in which a perfect circular insertion hole 343b1 through which a cylindrical member 343a is inserted and an unevenness along the axial direction are formed at a circumferential position of the axial center from a surface arranged facing the movable clutch 343c. A unit 343b2 is provided.

Since the insertion hole 343b1 has a perfect circular shape, the transmission gear 343b can rotate (idle) with respect to the cylindrical member 343a even when the cylindrical member 343a is fixed.

The movable clutch 343c has an angle fixing hole 343c1 having a D-shaped cross section through which the cylindrical member 343a is inserted, and irregularities along the axial direction at the circumferential position of the axial center from the surface arranged opposite to the transmission gear 343b. It also includes a clutch portion 343c2 that is configured to be engageable with the clutch portion 343b2.

In the present embodiment, the clutch portions 343b2 and 343c2 are composed of a mountain-shaped convex portion and a concave portion having a top angle of about 100 °.

Since the angle fixing hole 343c1 has a D-shaped cross section, the movable clutch 343c cannot rotate relative to the cylindrical member 343a. Therefore, the clutch portion 343b2 of the transmission gear 343b and the clutch portion 343c2 of the movable clutch 343c are engaged with each other. Therefore, the driving force transmitted from the drive motor 342 to the transmission gear 343b is transmitted to the cylindrical member 343a via the movable clutch 343c. This makes it possible to rotate the disc cam 344 (see FIG. 18) by rotating the drive motor 342.

The movable clutch 343c is usually arranged at a position close to the transmission gear 343b by the urging force of the coil spring 343d, and the engagement relationship between the clutch portions 343b2 and 343c2 is maintained. On the other hand, by applying an axial load to the movable clutch 343c, the movable clutch 343c is configured to be movable along the fixed portion 343a2 so as to be separated from the transmission gear 343b.

The disk cam 344 will be described with reference to FIG. As for the disc cam 344, the left disc cam 344L and the right disc cam 344R have a substantially mirrored shape, and the only difference is the positions of the detection holes 344eL and 344eR, so only the left disc cam 344L. The description of the right disk cam 344R will be omitted.

20 (a) is a side view of the left disk cam 344L in the direction of arrow XXa of FIG. 18, and FIG. 20 (b) is a side view of the left disk cam 344L in the direction of arrow XXb of FIG. be. In addition, in FIG. 20A and FIG. 20B, the state in which the drive device 340 is set to the first initial state is shown as shown in FIG.

As shown in FIGS. 20 (a) and 20 (b), the left disk cam 344L is a member having a portion protruding from both sides of a perfect circular disk, and is at the center position of the disk. A central shaft portion 344a projecting inwardly in a cylindrical shape, a circular rib 344b projecting inwardly as a ring-shaped rib centered on the central shaft portion 344a, and a circular rib 344b outside the circular rib 344b. The engaging rib 344c, which is projected inward as a rib having a height lower than that of the circular rib 344b and has a portion protruding outward in the radial direction at two points, and the outer side between the circular rib 344b and the engaging rib 344c. It mainly includes a connecting pin 344d which is projected in a cylindrical shape in the direction and is connected to an arm member 345 (see FIG. 18), and a detection hole 344eL which is formed in the vicinity of the outer periphery.

The right disk cam 344R differs only in that the detection hole 344eR is arranged at an angle of 60 ° with the detection hole 344eL, and the other components are a mirror image of the shape of the left disk cam 344L. ..

The central shaft portion 344a has a D-shaped cross section in which the inner circumference engages with both ends of the cylindrical member 343a (see FIG. 19), and the outer circumference is fitted into the shaft support hole 341b (see FIG. 18). It is composed. That is, the disk cam 344 is rotatably supported in the shaft support hole 341b.

The circular rib 344b is projected to a position where it can come into contact with the left and right wall surfaces of the motor accommodating portion 341a (see FIG. 18) in a state where the disc cam 344 is pivotally supported by the shaft support hole 341b. As a result, misalignment of the disc cam 344 can be suppressed.

In the first initial state, the engaging rib 344c protrudes outward in the radial direction at a position deviated by 80 ° in the backward rotation direction (clockwise in FIG. 20A) from the position where the detection hole 344eL is arranged. From the overhanging portion 344c1 and the first retracting portion 344c2 and the first overhanging portion 344c1 that retract inward in the radial direction at a position deviated from the first overhanging portion 344c1 by an angle θ1 (angle θ1 = 50 ° in this embodiment). At a position deviated by an angle θ2 (angle θ2 = 150 ° in this embodiment), a second overhanging portion 344c3 that overhangs outward again in the radial direction and an angle θ3 (angle in this embodiment) from the second overhanging portion 344c3. θ3 = 20 °) Mainly provided with a second retractable portion 344c4 that retracts inward in the radial direction at a displaced position.

In the first initial state of the drive device 340, the connecting pin 344d is arranged at a position having the longest separation distance from the shaft portion 311e of the tilting device 310 in the first state (see FIG. 22). That is, the connecting pin 344d is arranged on the opposite side of the shaft portion 311e of the tilting device 310 in the first state with respect to the central shaft portion 344a.

The release member 346 and the rotary claw member 347 will be described with reference to FIG. Since the release member 346 and the rotary claw member 347 are arranged in pairs on the left and right, and their configurations are the same on the left and right, only one of them will be described.

21 (a) and 21 (b) are front views of the release member 346 and the rotary claw member 347. Note that FIG. 21 (a) shows a large angle state in which the rotary claw member 347 rotates to the end position in the urging direction of the second spring SP2 with respect to the release member 346, and FIG. 21 (b) shows the release member 346. On the other hand, a small angle state in which the rotary claw member 347 rotates to the terminal position against the urging force of the second spring SP2 is shown.

The state in which the release member 346 is rotated by being brought into contact with the disk cam 344 is a state between a large angle state and a small angle state (the convex pin 346b is arranged at an intermediate position of the guide slot 347b). (See FIG. 35).

As shown in FIGS. 21 (a) and 21 (b), the release member 346 is formed of a substantially rectangular plate member and is pivotally supported by a shaft portion 341c (see FIG. 18) with a shaft support hole 346a. From the convex pin 346b which is formed in an arc shape centered on the central axis of the shaft support hole 346a in the plate thickness direction, the insertion hole 346c into which the end of the second spring SP2 is inserted, and the shaft support hole 346a. It mainly includes an engaging portion 346d formed as a portion overhanging with the maximum diameter.

The engaging portion 346d is a portion configured to be in contact with the engaging rib 344c (see FIG. 20) of the disk cam 344 in the assembled state (see FIG. 10). In the present embodiment, since the outer circumference of the engaging portion 346d is formed to be curved, the contact with the engaging rib 344 can be smoothly performed.

The rotary claw member 347 is formed of a substantially rectangular plate member, and has a shaft support hole 347a pivotally supported by a shaft portion 341c (see FIG. 18) and an arc shape centered on the central axis of the shaft support hole 347a. A guide elongated hole 347b (drilled with a size that includes the movement locus of the convex pin 346b inside) and an end of the second spring SP2 are bored along the convex pin 346b of the release member 346 so as to be guideable. It is possible to insert the insertion hole 347c through which the portion is inserted, the hook-shaped portion 347d which is projected downward in a hook shape at the opposite end of the shaft support hole 347a, and the end of the first spring (see FIG. 18). It is mainly provided with a pull-down hole 347e drilled in the.

In the present embodiment, the release member 346 is arranged at the terminal position in the backflip direction (clockwise direction in FIG. 21A) with respect to the rotary claw member 347 in the large angle state shown in FIG. 21A. Therefore, when a load in the pushing-down direction is applied to the engaging portion 346d in the large angle state, the release member 346 and the rotary claw member 347 are integrally rotated in the backward rotation direction, while the engaging portion is in the large angle state. When a load in the push-up direction is applied to the 346d, only the release member 346 can be rotated to maintain the posture of the rotary claw member 347 until the angle is small as shown in FIG. 21B.

Next, an operation example of the operation device will be described. First, with reference to FIGS. 22 to 24, an operation example in which the player pushes in the tilting device 310 in the first state will be described. In the following description of the operation example, the illustration of the lid 312 is simplified for easy understanding.

22 to 24 are cross-sectional views of the operating device 300 in line XXII-XXII of FIG. 6A. Note that FIG. 22 shows a state in which the tilting device 310 is in the first state, and FIG. 23 shows a state in which the player pushes the tilting device 310 to the terminal position from the state shown in FIG. 22. FIG. 24 Then, the state after the tilting device 310 returns from the state of FIG. 23 to the first state is shown. Further, in FIGS. 22 to 24, an example of a player's hand that repeatedly strikes the tilting device 310 is shown.

As shown in FIG. 22, the tilting device 310 receives an urging force in the backward rotation direction (clockwise in FIG. 22) by the torsion spring 315, and the bottom plate portion 311a is hooked on the hook-shaped portion 347d of the rotary claw member 347. As a result, the tilting device 310 is maintained in the posture in the first state. That is, in the first state, an urging force in the backflip direction (clockwise in FIG. 22) is constantly acting on the tilting device 310.

In the state shown in FIG. 22, the left side detection piece 311 gL is inserted into the detection groove of the left side detection sensor 324L (ON state), while the right side detection piece 311 gR is arranged in front of the detection groove of the right side detection sensor 324R. (OFF state, see FIG. 11).

As shown in FIG. 23, when the player pushes the tilting device 310, the tilting device 310 rotates about 3 ° in the forward rotation direction (counterclockwise in FIG. 23). In this state, the left side detection piece 311 gL is inserted into the detection groove of the left side detection sensor 324L (ON state), and similarly, the right side detection piece 311 gR is inserted into the detection groove of the right side detection sensor 324R (ON state).

Therefore, by determining the change in the detection state of the left side detection sensor 324L and the right side detection sensor 324R, it can be determined that the tilting device 310 has been pushed by the player from the first state.

Here, when the tilting device 310 is repeatedly hit, the state shown in FIG. 22 and the state shown in FIG. 23 are alternately repeated, but depending on the time interval in which the player repeatedly hits, the tilting device 310 by the torsion spring 315 is used. The return of the spring is not in time, and the pushing operation is performed at a halfway position, which may cause the player to feel a sense of discomfort.

Conventionally, it was possible to deal with this by increasing the spring constant of the torsion spring 315, but in the present embodiment, when the spring constant of the torsion spring 315 is increased, the tilting device 310 resists the urging force of the torsion spring 315. It is necessary to increase the driving force of the driving motor 342 that pushes down (see FIG. 18), and it is necessary to increase the size of the driving motor 342. Therefore, there are problems that the product cost rises and the space cannot be saved.

On the other hand, in the present embodiment, in the state where the tilting device 310 is pushed in, a voice coil motor 352 capable of producing an effect by vibration operation is arranged at a position facing the overhanging convex portion 311j of the tilting device 310. NS.

As shown in FIG. 24, by driving the voice coil motor 352 in the extension direction from the state shown in FIG. 23, the tilting device 310 can be quickly returned without increasing the spring constant of the torsion spring 315. can.

Here, when the voice coil motor 352 is always driven when the tilting device 310 is pushed in, for example, when the player presses and holds the tilting device 310 for a long time, the voice coil motor 352 is driven, and the player is informed. Since it gives an unnecessary load, the player may feel uncomfortable.

On the other hand, in the present embodiment, when the left side detection sensor 324L is in the ON state, the number of times the right side detection sensor 324R is switched between the ON state and the OFF state is calculated in a predetermined period, and when the number of times is equal to or greater than the threshold value, the voice coil is used. By driving the motor 352, it is possible to improve the load for returning the tilting device 310 only when the player repeatedly strikes. As a result, the player can comfortably operate the tilting device 310.

Next, a case (first operation mode) in which the tilting device 310 starts a reciprocating operation (fanning operation) up and down from the first state will be described with reference to FIGS. 25 to 30. 25 to 30 are cross-sectional views of the operating device 300 in line XXII-XXII of FIG. 6A.

Note that FIG. 25 shows a state in which the tilting device 310 is in the first state, and FIG. 26 shows that the disk cam 344 rotates in the forward rotation direction by a predetermined amount from the state shown in FIG. 25, and the rotary claw member 347 rotates. The state in which the posture has changed is shown, and FIG. 27 shows a state in which the disc cam 344 rotates in the forward rotation direction by a predetermined amount from the state shown in FIG. 26 and the posture of the rotary claw member 347 returns. A state in which the tilting device 310 reciprocates and rotates is shown. FIG. 29 shows a state in which the player pushes the tilting device 310 to the terminal position from the state shown in FIG. 28, and FIG. 30 shows a circle from the state shown in FIG. 29. A state in which the plate cam 344 rotates in the forward rotation direction by a predetermined amount to reach the second initial state in which the second overhanging portion 344c3 of the engaging rib 344c comes into contact with the engaging portion 346d of the release member 346. Is illustrated. Further, in FIG. 28, the position of the tilting device 310 in the state of FIG. 27 is illustrated by an imaginary line, and in FIG. 29, an example of a player's hand pushing and operating the tilting device 310 is illustrated by an imaginary line.

As shown in FIG. 25, when the tilting device 310 is in the first state, the upper end portion (prism portion) of the LED device 341f is housed inside the cylindrical member 312c of the lid 312. Therefore, while the amount of light emitted in the radial direction of the cylindrical member 312c is suppressed by the thickness of the cylindrical member 312c, the amount of light emitted in the axial direction can be largely secured. As a result, the cylindrical member 312c can have the effect of improving the intensity as a rib of the lid 312 and the effect of adjusting the light irradiation intensity of the LED device 341f in the first state of the tilting device 310.

As shown in FIG. 26, from the state shown in FIG. 25 in which the tilting device 310 is in the first state and the driving device 340 is in the first initial state, the disk cam 344 is rotated forward (counterclockwise in FIG. 26). When rotated in the direction), the first overhanging portion 344c1 of the disk cam 344 pushes down the engaging portion 346d of the releasing member 346, so that the releasing member 346 rotates in the backward rotation direction (clockwise in FIG. 26). Along with this, the rotary claw member 347 rotates in the backward rotation direction to a position where the tilting device 310 is disengaged from the bottom plate portion 311a.

The posture change of the release member 346 is continued until the disc cam 344 is rotated until the first retractable portion 344c2 of the engaging rib 344c and the engaging portion 346d face each other, so that the tilting device 310 twists during that time. It rises due to the urging force of the spring 315 (rotates clockwise in FIG. 26).

At this time, in the states of FIGS. 25 and 26, the shaft portion 311c of the tilting device 310 is arranged at one end position of the guide hole 345b of the arm member 345 (the end position on the side far from the rotation axis of the disk cam 344). Since the movement of the tilting device 310 in the ascending direction is regulated by the arm member 345, the ascending operation of the tilting device 310 becomes an operation mode corresponding to the rotation angle of the disk cam 344.

As shown in FIG. 27, when the disc cam 344 rotates in the forward rotation direction (counterclockwise direction in FIG. 27) and the first retractable portion 344c2 of the disc cam 344 passes through the engaging portion 346d of the release member 346, Due to the urging force of the first spring SP1, the release member 346 and the rotary claw member 347 rotate in the forward rotation direction (counterclockwise direction in FIG. 27), and the rotary claw member 347 can engage with the tilting device 310 (FIG. 27). Return to the state shown in 25). At this time, since the urging force of the second spring SP2 acts in the direction of increasing the angle between the release member 346 and the rotary claw member 347 (the upper angle in FIG. 27), the release member 346 and the rotary claw member The 347 rotates while maintaining the state shown in FIG. 26 (large angle state).

In this state, the lid 312 retracts above the LED device 341f, and the area in which the protective lens member 311i can be seen from the player's point of view increases as compared with the tilting device 310 in the first state. , The light of the LED device 341f can be irradiated in the front direction (direction toward the player) as well. Therefore, by changing the posture of the tilting device 310, the traveling direction of the light emitted from the LED device 341f can be changed, and the effect of producing the light can be improved.

In this state, the right side detection sensor 353R of the protective cover device 350 is turned on, and the start point of the vertical reciprocating operation can be detected.

As shown in FIG. 28, the disk cam 344 is rotated in the forward rotation direction (counterclockwise in FIG. 28) by a predetermined amount from the state shown in FIG. 27, and then the disk cam 344 is rotated by the same amount in the backward rotation direction (counterclockwise in FIG. 28). By repeating the operation of rotating clockwise (FIG. 28), the tilting device 310 can be repeatedly operated up and down within the range of the angle D1 shown in FIG. 28. As a result, the appearance of the tilting device 310 to the player can be changed, and the player's attention to the operating device 300 can be improved.

Further, the area of the portion protruding above the upper frame member 331 of the protective lens member 313 changes in response to the operation of the tilting device 310 repeatedly operating up and down within the range of the angle D1. Therefore, among the light emitted from the LED device 341f, the amount of light that can be visually recognized through the protective lens member 313 can be changed according to the operation of the tilting device 310. Therefore, the brightness of the tilting device 310 can be changed, and the player's attention to the operating device 300 can be improved.

In the state shown in FIG. 28, since the spherical shell portion 313a of the lens member 313 is arranged on the front side (left side of FIG. 28) of the LED device 341f, the irradiation range of the light emitted from the LED device 341f is set in the front-rear direction. It can be expanded not only in the vertical direction but also in the horizontal direction (vertical direction on the paper in FIG. 28).

According to the present embodiment, as described above, when the tilting device 310 is arranged in the first state, the light of the LED device 341f travels upward, and the irradiation range thereof is narrowed by the cylindrical member 312c. (See FIG. 25). On the other hand, when the tilting device 310 ascends from the first state, the light of the LED device 341f is also irradiated in the direction toward the player (front direction), and the irradiation range is expanded by the lens member 313.

That is, according to the present embodiment, not only the light irradiation direction can be changed but also the light irradiation range can be changed at the same time as the posture of the tilting device 310 is changed. Thereby, the degree of attention of the tilting device 310 can be improved.

As shown in FIG. 29, in the state where the tilting device 310 is moving up and down in FIG. 28, the player can push the tilting device 310 into operation. In the state of FIG. 28, the load given from the arm member 345 to the tilting device 310 is only the load in the direction of lowering the tilting device 310 (even if the arm member 345 moves in the ascending direction, the shaft portion 311c Only moves through the guide hole 345b of the arm member 345, and no load is generated).

Therefore, when the player pushes the tilting device 310 in the state of FIG. 28, it is possible to prevent the player from being subjected to a load due to the driving force of the drive motor 342 (see FIG. 18). At this time, the player is given only the load due to the urging force of the torsion spring 315. As a result, when the player pushes the tilting device 310 into operation, it is possible to prevent a large load from being generated on the player, so that the player can comfortably operate the operation device 300.

As shown in FIG. 29, in the process from the state shown in FIG. 28 to the pushing end of the tilting device 310, the bottom plate portion 311a of the tilting device 310 pushes the hook-shaped portion 347d of the rotary claw member 347 to push the rotary claw. When the member 347 rotates in the backward rotation direction (clockwise in FIG. 29) and the bottom plate portion 311a passes through the hook-shaped portion 347d by subsequently pushing the tilting device 310, the rotating claw member 347 becomes the tilting device 310. Return to the engageable position (rotate in the forward rotation direction). Therefore, the tilting device 310 is restricted from moving in the ascending direction by the rotating claw member 347.

Therefore, the tilting device 310 can be maintained in the first state when the player releases the tilting device 310 after the player pushes down the tilting device 310 from the state in which the tilting device 310 is moved up and down as shown in FIG. 28. ..

In the state shown in FIG. 29, the voice coil motor 352 performs a vibration operation (an operation of repeating movement in the extension direction and movement in the contraction direction). As a result, it is possible to perform an effect of transmitting vibration to the player who keeps his / her hand on the tilting device 310 after pushing the tilting device 310 to the end.

That is, the purpose of the voice coil motor 352 is to generate a driving force that assists the tilting device 310 to rise (see FIG. 24), and the purpose of vibrating the tilting device 310 arranged at the push-in end position to produce a vibration effect. Can be used for.

As shown in FIG. 30, when the player releases the tilting device 310 and the tilting device 310 returns to the first state, the overhanging convex portion 311j of the tilting device 310 is attached to the lower frame member 320. It is buried in the lower surface and the contact with the voice coil motor 352 is released. Therefore, the vibration effect is effective only when the player pushes the tilting device 310 toward the end.

Therefore, as compared with a gaming machine in which the operation buttons simply vibrate, the player who pushes the tilting device 310 to determine whether or not vibration is generated by the voice coil motor 352 at the pushing end when the tilting device 310 is pushed in. Can only be grasped.

Here, whether or not the lottery is a big hit does not depend on the pushing operation of the tilting device 310. Therefore, depending on the player, there is a possibility that the tilting device 310 is not operated at all, and in that case, the value of the tilting device 310 as an operating means is lowered.

On the other hand, in the present embodiment, the player can feel the vibration of the voice coil motor 352 for the first time by pushing the tilting device 310.

Here, for example, by controlling the voice coil motor 352 to vibrate when the jackpot is confirmed, it is possible to improve the expectation when the player pushes the tilting device 310 and operates the tilting device 310. It is possible to improve the value as a look-ahead means. As a result, the player can easily operate the tilting device 310, and the value of the tilting device 310 as an operating means can be increased.

As shown in FIG. 30, from the state shown in FIG. 29, the disc cam 344 is rotated forward in the forward rotation direction until the second overhanging portion 344c1 abuts on the engaging portion 346d of the disengaging member 346 (FIG. 29). By rotating the drive device 340 by a predetermined amount in the clockwise direction), the drive device 340 can be brought into the second initial state.

The second initial state is a state in which the engaging rib 344c and the release member 346 come into contact with each other in the rotational direction, as in the first initial state. In the first initial state, the first overhanging portion 344c1 comes into contact with the engaging rib 344c, while in the second initial state, the second overhanging portion 344c3 and the engaging rib 344c come into contact with each other.

From the state of FIG. 29, the disk cam 344 is rotated in the backward rotation direction (clockwise direction in FIG. 29), and after the first overhanging portion 344c1 of the engaging rib 344c passes through the engaging portion 346d, it rotates in the reverse direction. The drive device 340 can be returned from the state shown in FIG. 29 to the first initial state shown in FIG. In this case, a load in the direction of pushing up the release member 346 is applied to the release member 346, and only the release member 346 can be rotated in the forward rotation direction (counterclockwise direction in FIG. 29) while maintaining the posture of the rotary claw member 347. can.

Next, referring to FIGS. 31 to 34, when the tilting device 310 is moved up and down (fanning operation) from the state where the tilting device 310 is in the first state and the driving device 340 is in the second initial state ( The second operation mode) will be described. In this case, the tilting device 310 starts a motion of reciprocating up and down (fanning motion) through the second state.

31 to 34 are cross-sectional views of the operating device 300 in line XXII-XXII of FIG. 6A. In FIG. 31, the disc cam 344 is rotated in the forward rotation direction (counterclockwise in FIG. 31) from the state shown in FIG. 30, and the release member 346 and the rotary claw member 347 are rotated in the backward rotation direction (clockwise in FIG. 31). In FIG. 32, the state in which the disk cam 344 is rotated by a predetermined amount and the tilting device 310 reaches the second state from the state shown in FIG. 31 is shown, and in FIG. 33, the state shown in FIG. 32 is shown. A state in which the disk cam 344 reciprocates and rotates is shown, and FIG. 34 shows a state in which the player pushes the tilting device 310 to the terminal position from the state shown in FIG. 33. Further, in FIG. 33, the position of the tilting device 310 in the state of FIG. 32 is illustrated by an imaginary line, and in FIG. 34, an example of a player's hand for pushing and operating the tilting device 310 is illustrated by an imaginary line.

As shown in FIG. 31, when the disk cam 344 is rotated in the forward rotation direction (counterclockwise in FIG. 31) from the state shown in FIG. 30, the engagement between the rotary claw member 347 and the tilting device 310 is released, and the disc cam 344 is tilted. The device 310 operates in the ascending direction.

At this time, since the guide hole 345b of the arm member 345 extends (has a space) in the direction in which the shaft portion 311c of the tilting device 310 moves, the tilting device 310 passes through the arm member 345 to the disk cam 344. The tilting device 310 can be raised with low resistance without being pulled by the tilting device 310, and the tilting device 310 can be changed from the first state to the second state in a short time.

As shown in FIG. 32, the posture of the disc cam 344 is tilted by rotating the disc cam 344 by about 10 degrees from the state shown in FIG. 31 (the state in which the tilting device 310 and the rotary claw member 347 are disengaged). The posture of the 310 can be arranged in the second state (the posture in which the disk cam 344 is rotated by 180 ° from the first initial state). Therefore, when the tilting device 310 rises at a high speed and the tilting device 310 tries to reach the second state from the state of FIG. 30 in a short period of time, the disk cam 344 interferes with the state change (disk). It is possible to prevent the cam 344 from rotating slowly by a predetermined angle and taking a long time until the tilting device 310 is in the second state).

As shown in FIG. 33, the disk cam 344 is rotated in the forward rotation direction (counterclockwise in FIG. 32) by a predetermined amount from the state shown in FIG. 32, and then the disk cam 344 is rotated by the same amount in the backward rotation direction (counterclockwise direction in FIG. 32). By repeating the operation of rotating clockwise (FIG. 32), the tilting device 310 can be repeatedly operated up and down within the range of the angle D2 shown in FIG. 33. As a result, the appearance of the tilting device 310 to the player can be changed, and the player's attention to the operating device 300 can be improved.

Further, the area of the portion protruding above the upper frame member 331 of the protective lens member 313 changes in response to the operation of the tilting device 310 repeatedly operating up and down within the range of the angle D2. Therefore, among the light emitted from the LED device 341f, the amount of light that can be visually recognized through the protective lens member 313 can be changed according to the operation of the tilting device 310. Therefore, the brightness of the tilting device 310 can be changed, and the player's attention to the operating device 300 can be improved.

In the state shown in FIG. 33, since the spherical shell portion 313a of the lens member 313 is arranged on the front side (left side of FIG. 33) of the LED device 341f, the irradiation range of the light emitted from the LED device 341f is set in the front-rear direction. It can be expanded not only in the vertical direction but also in the horizontal direction (vertical direction on the paper in FIG. 33).

That is, according to the present embodiment, not only the light irradiation direction can be changed but also the light irradiation range can be changed at the same time as the posture of the tilting device 310 is changed. Thereby, the degree of attention of the tilting device 310 can be improved.

The range of the angle D2 shown in FIG. 33 is different from the range of the angle D1 shown in FIG. 28. That is, in the present embodiment, as an aspect of the vertical movement of the tilting device 310, two types of vertical movements (fanning movements), that is, the vertical movement shown in FIG. 28 and the vertical movement shown in FIG. 33, are tilted by the rotating claw member 347. This can be done immediately after the restriction on the ascending movement of the device 310 is lifted. Therefore, it is possible to create two types of modes in which the tilting device 310 in the first state is operated by the driving force of the driving motor 342.

As a result, the operating member 310 can have a different meaning (for example, a difference in the expectation of the jackpot) in the operation mode as compared with the case where the operating member 310 performs the same operation each time, and the player pays attention to the tilting device 310. The degree can be improved.

As shown in FIG. 33, in the state where the tilting device 310 is moving up and down in FIG. 32, the player can push the tilting device 310 into operation. In the state of FIG. 33, the load given from the arm member 345 to the tilting device 310 is only the load in the direction of pulling down the tilting device 310 (even if the arm member 345 moves in the upward direction, the shaft portion The 311c only moves through the guide hole 345b of the arm member 345, and there is no load for lifting the shaft portion 311c from the arm member 345).

Therefore, when the player pushes the tilting device 310 in the state of FIG. 33, it is possible to prevent the player from being subjected to a load due to the driving force of the drive motor 342 (see FIG. 18). At this time, the player is given only the load due to the urging force of the torsion spring 315. As a result, when the player pushes the tilting device 310 into operation, it is possible to prevent a large load from being generated on the player, so that the player can comfortably operate the operation device 300.

As shown in FIG. 34, in the process of pushing the tilting device 310 into operation, the bottom plate portion 311a of the tilting device 310 pushes the hook-shaped portion 347d of the rotary claw member 347, so that the rotary claw member 347 rotates backward. When the bottom plate portion 311a passes through the hook-shaped portion 347d by rotating in the direction (clockwise in FIG. 34) and subsequently pushing the tilting device 310. The rotary claw member 347 returns to a position where it can engage with the tilting device 310 (rotates in the forward rotation direction). Therefore, the tilting device 310 is restricted from moving in the ascending direction by the rotating claw member 347.

Therefore, when the player releases the tilting device 310 after the player pushes down the tilting device 310 from the state in which the tilting device 310 shown in FIG. 33 is moved up and down (see FIG. 34), the tilting device 310 is put into the first state. Can be maintained.

Next, with reference to FIGS. 35 to 37, the operation of setting the disc cam 344 to the second initial state after the player push-in operation without releasing the regulation of the tilting device 310 by the rotating claw member 347 will be described. do. By this method, it is possible to alternately perform two types of vertical movements (fanning movements) of the tilting device 310, or to continuously perform one of them.

35 to 37 are cross-sectional views of the operating device 300 in line XXII-XXII of FIG. 6A. In FIG. 35, a state in which the disk cam 344 is rotated in the backward rotation direction (clockwise in FIG. 35) and the release member 346 is rotated in the forward rotation direction (counterclockwise in FIG. 35) from the state shown in FIG. 34 is shown. In FIG. 36, after the rotary cam 344 rotates in the backward rotation direction (clockwise in FIG. 35) more than the state shown in FIG. 35, the forward rotation direction is reached until the disc cam 344 comes into contact with the engaging portion 346d of the release member 346. The state of rotation (counterclockwise in FIG. 35) is shown, and in FIG. 37, the disk cam 344 rotates in the forward rotation direction (counterclockwise in FIG. 36) from the state shown in FIG. 36 to detect the left side of the protective cover device 350. The state in which the sensor 353L is turned on is illustrated. In addition, in FIGS. 35 to 37, an example of a player's hand swinging from above on the tilting device 310 is illustrated by an imaginary line.

As shown in FIG. 35, when the disk cam 344 is rotated in the backflip direction (clockwise in FIG. 34) from the state shown in FIG. 34, the second retractable portion 344c4 of the engaging rib 344c becomes the engaging portion of the releasing member 346. It comes into contact with 346d. In this case, the posture of the release member 346 is changed by the engaging rib 344c pushing up the release member 346, but the convex pin 346b of the release member 346 moves in the space portion of the guide slot 347b of the rotary claw member 347. The rotating claw member 347 stays and is maintained in the posture shown in FIG. 35.

That is, in the process of further rotating the disk cam 344 in the backward rotation direction (clockwise in FIG. 35) from the state shown in FIG. 35 to disengage the engaging rib 344c and the disengaging member 346, the rotating claw member 347 is used. The regulation of the rise of the tilting device 310 can be maintained.

From the state shown in FIG. 35, the disc cam 344 is further rotated in the backward rotation direction (clockwise in FIG. 35), and then the rotary cam 344 is continuously rotated in the forward rotation direction (counterclockwise in FIG. 35). As shown in, the drive device 340 can be in the second initial state.

In the present embodiment, since there is no sensor for detecting the second initial state, it is difficult to accurately stop the disk cam 344 in the state shown in FIG. 36, but the disk cam 344 passes through the second initial state shown in FIG. It is possible. Therefore, by operating the disk cam 344 from the state shown in FIG. 36, it is possible to perform the vertical movement (fanning operation) from the second initial state in the range of the angle D2 as described above.

Here, the player who pushes the tilting device 310 may perform an operation of keeping his / her hand on the tilting device 310 after the pushing operation even if a special display such as "long press" is not displayed. be.

This is an operation that occurs, for example, by pushing the tilting device 310 too much to concentrate on the effect and forgetting to release the operated hand. In this case, the tilting device 310 rises even if the regulation by the rotating claw member 347 is released. Therefore, even if the disk cam 344 performs a reciprocating operation (forward / reverse switching operation) for moving the tilting device 310 up and down (fanning operation) within the range of the angle D2, the posture of the tilting device 310 can be changed. Can not. In this case, the rotation of the drive motor 342 is wasted, and if the rotation can be omitted, the life of the drive motor 342 can be extended.

Therefore, in the present embodiment, the left side detection sensor 324L (see FIG. 15) of the lower frame member 320 is turned on in the state where the disk cam 344 is rotated in the forward rotation direction (counterclockwise in FIG. 36) from the state shown in FIG. While the state is maintained (while the tilting device 310 tilts to the first state or lower), the disk cam 344 is not rotated in the reverse direction, and as shown in FIG. 37, the left side detection sensor 353L of the protective cover device 350 (See FIG. 14) is controlled in a mode in which the rotation of the disk cam 344 is stopped (the drive of the drive motor 342 is stopped) in the first initial state of the drive device 340 in which the drive device 340 is turned on.

In the states shown in FIGS. 36 and 37, the tilting device 310 does not rise due to the player's hand being placed on the upper side of the tilting device 310. In this case, the state shown in FIG. 36 to the state shown in FIG. 37 The change occurs by rotating the drive motor 342 in one direction.

Therefore, as shown in FIGS. 35 to 37, the drive motor 342 is reciprocated (forward / reverse switching) until the player's hand is continuously placed on the upper side of the tilting device 310 and the tilting device 310 cannot be moved up and down. Operation) can be avoided, the load on the drive motor 342 can be reduced, and the motor life can be extended.

When the left side detection sensor 324L (see FIG. 15) is maintained in the ON state when the disk cam 344 is rotated by a predetermined amount (to the state shown in FIG. 31) from the state shown in FIG. 36, it is a circle as it is. Instead of rotating the plate cam 344, it may be controlled to immediately reversely rotate the plate cam 344 to return to the state shown in FIG. As a result, the drive device 340 can be returned to the second initial state at an early stage, and an unnecessary load is not applied to the drive device 340, so that the motor life of the drive motor 342 (see FIG. 18) can be extended.

A device for preventing the destruction of the drive device 340 will be described with reference to FIGS. 38 and 39. FIG. 38 is a cross-sectional view of the operating device 300 on the XXII-XXII line of FIG. 6A, and FIG. 39 is a partial cross-sectional view of the operating device 300 on the XXXIX-XXXIX line of FIG. 38. In FIG. 38, the player's hand that grips and fixes the tilting device 310 in the state where the tilting device 310 is in the second state is illustrated by an imaginary line, and in FIG. 39, the upper member of the main body cover 351 is illustrated. Omitted.

As shown in FIG. 38, when the player grabs and fixes the tilting device 310, the movement of the arm member 345 is restricted, so that the disk cam 344 cannot be rotated from the state of FIG. 38. Therefore, when the drive motor 342 (see FIG. 39) starts to rotate, a high load is generated between the drive motor 342 and the transmission gear 343b, and if left unattended, the drive motor 342 (see FIG. 18) may break down. be.

On the other hand, in the present embodiment, since the transmission gear 343b is configured to be idle with respect to the transmission shaft rod 343a fixing the disk cam 344, it is possible to prevent the drive motor 342 from failing.

That is, as shown in FIG. 39, the drive motor 342 starts driving with the disk cam 344 fixed, and the transmission gear 343b is urged in the rotational direction, so that the clutch portions 343b2 and 343c2 are used. Power is transmitted, and the movable clutch 343c moves in a direction away from the transmission gear 343b. As a result, the engagement between the transmission gear 343b and the movable clutch 343c can be released, and the transmission gear 343b can be idled. This makes it possible to prevent the drive motor 342 from failing.

If the player does not grasp the tilting device 310, the tilting device 310 goes through the first state if the disk cam 344 is rotated once due to the configuration of the operating device 300. Therefore, in the present embodiment, when the left side detection sensor 324L of the lower frame member 320 is not turned on while the drive motor 342 is rotated by a predetermined angle (for example, 360 °) (when the tilting device 310 is not in the first state). In addition, it is determined that the player intentionally performs an unnecessary operation of gripping and fixing the tilting device 310, and the third symbol display device 81 is notified to stop the gripping operation, for example. While doing so, the rotation of the drive motor 342 is stopped.

As a result, it is possible to select a case where the player intentionally performs an erroneous operation and notify that the erroneous operation is stopped only at that time, and stop the drive motor 342 at an early stage to prevent a failure. be able to.

When the transmission gear 343b and the movable clutch 343c are separated from each other to cause a phase shift, the initial phase of the drive motor and the initial phase of the disk cam 344 having the same phase as the movable clutch 343c are shifted. Therefore, if the drive motor 342 is continuously controlled (by the number of steps or the like) from the state before the phase shift occurs, the disk cam 344 cannot be operated accurately (the phase shift cannot be corrected).

On the other hand, in the present embodiment, it is possible to identify that the drive device 340 is in the first initial state by detecting that the left side detection sensor 353L of the protective cover member 350 is in the ON state. By restarting the control of the drive motor 352 (resetting the initial phase of the drive motor 342) with that state as the initial position, even after the phase shift occurs between the transmission gear 343b and the movable clutch 343c. The control can be performed in a state where the phase of the drive motor 342 and the phase of the disk cam 344 are realigned.

As a result, when the effect is produced by operating the tilting device 310, there is a discrepancy between the operation of the tilting device 310 due to the rotation control of the drive motor 342 and the operation actually performed by the tilting device 310. It is prevented from occurring. Therefore, even after the phase shift occurs between the transmission gear 343b and the movable clutch 343c, the tilting device 310 can be properly operated to produce an effect.

Here, as shown in FIG. 39, the movable clutch 343c is configured to idle with respect to the transmission gear 343b regardless of the rotation direction of the transmission gear 343b. The necessity will be described below.

40, 41, 42 and 43 are cross-sectional views of the operating device 300 in line XXII-XXII of FIG. 6 (a). Note that FIG. 40 shows a state in which the disk cam 344 is rotated 180 degrees in the forward rotation direction (arrow CCW direction) from the state shown in FIG. 38, and FIG. 41 shows a state in which the disk cam is further rotated from the state shown in FIG. 40. The state in which 344 is rotated in the direction of the arrow CCW is shown. Further, FIG. 42 shows a state in which the disk cam 344 is rotated 180 degrees in the backward rotation direction (arrow CW direction) from the state shown in FIG. 38, and FIG. 43 shows a state in which the disk cam is further rotated from the state shown in FIG. 42. The state in which 344 is rotated in the direction of arrow CW is shown.

As shown in FIG. 41, when the disk cam 344 rotates in the direction of the arrow CCW, the tilting device 310 moves upright toward the second state via the first state shown in FIG. 40. On the other hand, as shown in FIG. 43, when the disk cam 344 rotates in the direction of the arrow CW, the tilting device 310 is configured to maintain the first state shown in FIG. 42.

This is not only due to the fact that the engaging rib 344c operates in a manner of separating from the release member 346 as the state shown in FIG. 42 shifts to the state shown in FIG. 43, but the disk cam 344 rotates in the direction of the arrow CW. In this case, even if the engaging rib 344c comes into contact with the release member 346, the fixing by the rotary claw member 347 is not released. That is, when the disk cam 344 rotates in the direction of the arrow CW, the engaging rib 344c abuts on the disengaging member 346 from below, but in this case, the disengaging member 346 is lifted by the engaging rib 344c, and the rotating claw No load is generated in the direction of pushing up the member 347. Therefore, the fixing by the rotating claw member 347 is not released.

Here, when the operation of the tilting device 310 is viewed from the player's point of view, both of the first states shown in FIGS. 38 to 40 and 42 appear to be the same operation, and the subsequent movements after the first state is reached. Is a different operation of either FIG. 41 or FIG. 43.

For example, a difference in operation after the tilting device 310 reaches the first state may be generated by controlling the drive motor 342 (see FIG. 39), but the drive noise due to the change in the rotation speed of the drive motor 342 may be generated. Due to the difference in the change, the player may notice the mode of control being performed, and the player may be aware of the effect to be executed in the future, which may discourage the player's interest. Further, when the operation of suddenly stopping the tilting device 310 is performed by suddenly stopping the drive motor 342, the load applied to the drive motor 342 becomes large, and the durability of the drive motor 342 may decrease.

On the other hand, according to the present embodiment, when the tilting device 310 moves from the state shown in FIG. 38 toward the first state and the subsequent operation of the tilting device 310 is changed, the rotation of the drive motor 342 is changed. Since the directions are different only, it is possible to make it difficult for the player to grasp the rotation direction depending on the driving mode (vibration, sound, etc.). Therefore, for example, when the expectation of the effect changes depending on whether the tilting device 310 rises from the first state or the tilting device 310 is maintained in the first state, the tilting device 310 is operating toward the first state. In addition, it is possible to prevent the player from grasping the change in the degree of expectation. As a result, it is possible to improve the attention to the operation of the tilting device 310.

On the other hand, when the tilting device 310 reaches the first state and the drive motor 342 further rotates, the player confirms whether the tilting device 310 rises or maintains the first state, so that the player can produce the effect. Since the change in the degree of expectation can be grasped, the movement of the tilting device 310 when the tilting device 310 is in the second state (see FIG. 38) and is moved toward the first state by the drive motor 342 for the player. You can make them watch over.

That is, when the tilting device 310 is in the second state, it is possible to prevent the player from gripping the tilting device 310. Therefore, when the drive motor 342 is driven, the player erroneously operates the tilting device 310 and the drive. It is possible to prevent the device 340 from being overloaded.

Further, since it is not necessary to suddenly stop the drive motor 342 (see FIG. 39) in order to perform the effect of suddenly stopping the tilting device 310, the burden given to the drive motor 342 when the drive motor 342 is suddenly stopped is eliminated. This makes it possible to improve the durability of the drive motor 342.

Next, with reference to FIG. 44, even when the player pushes down the tilting device 310, the tilting device 310 moves up and down without being restricted by the rotating claw member 347 (third operation mode). explain.

FIG. 44 is a cross-sectional view of the operating device 300 in line XXII-XXII of FIG. 6A. In addition, in FIG. 44, a state in which the disk cam 344 is rotated in a predetermined amount forward rotation direction (counterclockwise in FIG. 44) from the first initial state (see FIG. 25) of the drive device 340 is shown, and the first state is shown. The outer shape of the tilting device 310 after rotating the disk cam 344 in the backward rotation direction (clockwise in FIG. 44) at an angle at which the overhanging portion 344c1 does not pass through the engaging portion 346d of the release member 346 is illustrated by an imaginary line. ..

As shown in FIG. 44, in a state where the release member 346 is pushed down by the first overhanging portion 344c1 of the disk cam 344, the first overhanging portion 344c1 and the first retracting portion 344c2 are engaged with the releasing member 346. By reciprocating the disk cam 344 while maintaining the positional relationship that does not pass through the 346d, the tilting device 310 can be reciprocated up and down while maintaining the posture of the release member 346.

In this case, the posture of the rotary claw member 347 is maintained in a state of being rotated in the backward rotation direction (clockwise in FIG. 44) as the posture of the release member 346 changes. When the player moves up and down, even if the tilting device 310 is pushed in and operated, the tilting device 310 and the rotary claw member 347 do not engage with each other, and the tilting device 310 is in the first state (rotation) when the player releases the hand. When the claw member 347 engages with the tilting device 310, it is possible to carry out an operation mode in which the tilting device 310 moves upward from the position (position where the ascending is restricted) and continues the vertical movement.

Therefore, for example, as the operation mode of the tilting device 310, the operation is performed by providing a difference in effect between the above-mentioned first operation mode and the second operation mode and the third operation mode shown in FIG. The operation of the device 300 can have a meaning different from the conventional one. That is, according to the present embodiment, the tilting device 310 moves up and down in the first operation mode or the second operation mode only when the player pushes in the tilting device 310 and then releases the tilting device 310. It is possible to know whether the movement was performed or the movement was performed up and down in the third operation mode.

As a difference in production, when the tilting device 310 moves up and down in the first operation mode and the second operation mode (when the tilting device 310 is pushed in and then released, the tilting device 310 is maintained in the first state. Compared to the case where the tilting device 310 moves up and down in the third operation mode (when the tilting device 310 continues to move up and down even if the tilting device 310 is pushed in and then released). Assuming that the difference is that the expectation of the jackpot is high, the player recognizes the expectation of whether or not to hit the jackpot not only when the player pushes the tilting device 310 but also when the player releases the tilting device 310. Since the opportunity can be obtained, it is possible to provide many timings for the player to pay attention to the operation device 300. Thereby, the degree of attention of the operation device 300 can be improved.

Next, the second embodiment will be described with reference to FIGS. 45 to 49. In the first embodiment, the case where the state of the rotary claw member 347 is maintained when the release member 346 is pushed up has been described, but in the operation device 2300 in the second embodiment, the drive device 2340 has the slide claw member 2348. The slide claw member 2348 slides when the release member 2346 is pushed up. The same parts as those in the above-described embodiments are designated by the same reference numerals, and the description thereof will be omitted. First, the difference from the first embodiment will be described with reference to FIGS. 45 and 46.

45 (a) is a side view of the slide claw member 2348 according to the second embodiment, FIG. 45 (b) is a side view of the rotating plate member 2347, and FIG. 45 (c) is a side view of the release member 2346. It is a side view.

46 (a) and 46 (b) are side views of the release member 2346, the rotary plate member 2347, and the slide claw member 2348 showing the interlocking of the release member 2346, the rotary plate member 2347, and the slide claw member 2348. ..

FIG. 46 (a) shows a large angle state in which the rotary plate member 2347 rotates with respect to the release member 2346 to the end position in the urging direction of the second spring SP2, and FIG. 46 (b) shows the release member 2346. The small angle state in which the rotary plate member 2347 is rotated to the terminal position against the urging force of the second spring SP2 is shown. The state in which the release member 2346 is rotated by being brought into contact with the disk cam 344 is a state between a large angle state and a small angle state (the convex pin 346b is arranged at an intermediate position of the guide slot 347b). (See FIG. 48).

As shown in FIGS. 45 and 46, the drive device 2340 (see FIG. 47) includes a release member 2346, a rotating plate member 2347, and their rotation as functional members pivotally supported by the shaft portion 341c (see FIG. 47). With the slide claw member 2348, which is arranged on the opposite side of the release member 2346 with the plate member 2347 in between and is configured to be slidable along an arc trajectory centered on the rotation axis of the tilting device 2310 (see FIG. 47). , Is mainly provided. The release member 2346, the rotary plate member 2347, and the slide claw member 2348 have the same reference numerals as those of the first embodiment, and the description thereof will be omitted.

As shown in FIG. 45 (a), the slide claw member 2348 has a curved portion 2348a formed from a curved shape in which the slide claw member 2348 is slidably fitted in the rail portion 2347f, and the front end portion of the curved portion 2348a. The hook-shaped portion 2348b is projected in a hook shape toward the left side of FIG. 45, and the curved portion 2348a and the hook-shaped portion 2348b are arranged so as to be overlapped with each other in the thickness direction (FIG. 47 (a) perpendicular to the paper surface). Mainly, a reinforcing portion 2348c formed from a curved plate shape wider than the curved portion 2348a, and a convex pin 2348d projecting in a columnar shape toward the release member 2346 at the lower end portion of the reinforcing portion 2348c. Be prepared.

The length of the curved portion 2348a is set to be slightly shorter than the separation width of the rail portion 2347f. Therefore, the curved portion 2348a of the slide claw member 2348 is configured to be slidable with respect to the rotating plate member 2347 in a state of being internally fitted in the rail portion 2347f.

The hook-shaped portion 2348b has the same shape as the hook-shaped portion 347d of the first embodiment, and a magnetic material is arranged on the lower side surface thereof. This magnetic material is a magnetic material for generating a magnetic force that is attracted to the bottom plate portion 2311a of the tilting device 2310, which will be described later.

The reinforcing portion 2348c is a portion facing the surface of the rotating plate member 2347 facing the slide claw member 2348 in the assembled state (see FIG. 46), and is formed wider than the curved portion 2348a. , A portion that reinforces the slide claw member 2348.

The convex pin 2348d is a cylindrical member that is inserted into the functional elongated hole 2346e of the release member 2346, and is composed of a metal rod that is inserted and fixed in the main body plate portion 2348e. When the release member 2346 rotates relative to the rotating plate member 2347, the convex pin 2348d is pushed to the side surface of the functional elongated hole 2346e, and the slide claw member 2348 slides and moves.

The rotating plate member 2347 includes a shaft support hole 347a, a guide elongated hole 347b, an insertion hole 347c, a pull-down hole 347e, a rail portion 2347f for guiding the sliding operation of the slide claw member 2348, and a slide. The support elongated hole 2347g through which the convex pin 2348d of the claw member 2348 is inserted is provided.

The rail portion 2347f is formed of a pair of plate-shaped portions extending from the upper end portion of the rotating plate member 2347, and the rotating plate member 2347 is forward-rotating on the side surfaces of the pair of plate-shaped portions arranged to face each other (FIG. It is formed from a curved shape along an arc centered on a shaft portion 314 (see FIG. 47) in a state of being arranged at a terminal position (46 counterclockwise).

Like the rail portion 2347f, the support elongated hole 2347g is formed from a curved shape along an arc centered on the shaft portion 314 (see FIG. 47). When the slide claw member 2348 is slid and moved with the convex pin 2348d inserted through the support elongated hole 2347g, the slide claw member 2348 can be supported by the rail portion 2347f and the support elongated hole 2347g, and the slide claw member 2348 can be supported. It is possible to suppress wobbling.

The release member 2346 includes a shaft support hole 346a, a convex pin 346b, an insertion hole 346c, an engaging portion 346d, and a functional elongated hole 2346e which is an elongated hole drilled in the thickness direction. ..

The functional elongated hole 2346e is configured as an elongated hole slightly wider than the diameter of the convex pin 2348d of the slide claw member 2348, and has a first length formed of a curved shape along an arc centered on the shaft support hole 346a. It mainly includes a hole portion 2346e1 and a second elongated hole portion 2346e2 extending in a direction inclined from one end of the first elongated hole portion 2346e toward the opposite direction of the shaft support hole 346a.

As shown in FIG. 46, when the release member 2346 rotates with respect to the rotating plate member 2347 and the state changes between the large angle state and the small angle state, the slide claw member 2348 follows the curved shape of the rail portion 2347f. Slide to move.

Since the functional elongated hole 2346e is configured as an elongated hole slightly wider than the diameter of the convex pin 2348d, the movement speed of the release member 2346 remains unchanged from the movement of the convex pin 2348d without a time delay with respect to the movement of the release member 2346. It is reflected in the speed.

That is, if the release member 2346 is rotated quickly, the slide claw member 2348 slides quickly, while if the speed at which the release member 2346 is rotated is reduced, the operation speed of the slide claw member 2348 also decreases.

As shown in FIG. 46A, in a large angle state, even if the slide claw member 2348 is pulled in the slide direction, the first arc portion 2346e1 has a shape along an arc centered on the shaft support hole 346a. Therefore, the load applied from the convex pin 2348d to the functional elongated hole 2346e is directed in the linear direction passing through the shaft support hole 346a. Therefore, the force for rotating the release member 2346 is not generated, and the slide claw member 2348 can be prevented from sliding and moving.

That is, in the present embodiment, although the slide claw member 2347 may slide and move due to the rotational operation of the release member 2346, the slide claw member 2347 slides when the slide claw member 2347 is pulled when the angle is large. It doesn't move. Therefore, as in the first embodiment, when the tilting device 2310 is arranged in the first state, the tilting device 2310 can be restricted from rising by engaging the slide claw member 2348 with the tilting device 2310.

47 to 49 are drawings showing changes in the posture of the tilting device 2310 in chronological order, and are cross-sectional views of the operation device 2300 in the line corresponding to the XXII-XXII line of FIG. 6A. Note that FIG. 47 shows a state in which the second retractable portion 344c4 of the disc cam 344 is arranged below the engaging portion 346d of the release member 2346, and FIG. 48 shows the disc cam 344 from the state shown in FIG. 47. Is rotated in the backward rotation direction (clockwise in FIG. 47) and the engaging portion 346d of the release member 2346 is pushed up. A state in which the release member 2346 is rotated clockwise) and returned by the urging force of the second spring SP2 is shown in the figure.

In the present embodiment, the bottom plate portion 2311a of the tilting device 2310 is fixed to the upper side surface in the vicinity of the lower edge portion of the opening 311b and includes a magnet portion 2311a1 made of a magnetic material.

In the state shown in FIG. 47, the magnet portion 2311a1 and the hook-shaped portion 2348b are attracted by magnetic force. When the player pushes the tilting device 2310 from this state, the tilting device 2310 disengages the attraction between the magnet portion 2311a1 and the hook-shaped portion 2348b due to the posture change of the tilting device 2310, so that a large load is applied from the tilting device 2310 to the slide claw member 2348. It will not be done.

As shown in FIG. 48, when the release member 2346 is pushed up, the slide claw member 2348 slides in the ascending direction in conjunction with the operation. At this time, since the magnet portion 2311a1 and the hook-shaped portion 2348b are attracted by a magnetic force, if the release member 2346 operates quickly, the tilting device 2310 also operates quickly.

Therefore, by sliding the slide claw member 2348 at a speed different from the speed at which the tilting device 2310 rotates in the ascending direction due to the urging force of the torsion spring 315, the slide claw member 2348 is moved backward (clockwise in FIG. 48). The tilting device 2310 can be moved ascending at a speed different from the ascending movement when the restriction on the ascending movement of the tilting device 2310 is lifted (fourth operation mode). That is, the speed at which the tilting device 2310 moves in the ascending direction can be changed.

As shown in FIG. 49, when the disc cam 344 and the release member 2346 are disengaged, the release member 2346 rotates in the backflip direction (clockwise in FIG. 48) due to the urging force of the second spring SP2. As a result, the slide claw member 2348 is returned to the first state.

By enabling the operation modes shown in FIGS. 47 to 49, the tilting device 2310 can be operated in four operation modes in addition to the first to third operation modes described in the first embodiment. .. As the number of operation modes increases, by associating the operation mode with the expected degree of jackpot, it becomes easier for the player to use the operation device 2300 as a means of pre-reading, so that the operation device 2300 for the player can be used. The degree of attention can be improved.

Further, according to the present embodiment, as shown in FIG. 48, when the tilting device 2310 is raised by raising the slide claw member 2348, the hook-shaped portion 2348b of the slide claw member 2348 and the magnet portion 2311a1 of the tilting device 2310 are used. Since the tilting device 2310 is raised by the magnetic force attraction between the tilting device 2310 and the tilting device 2310, the tilting device 2310 can be applied to the tilting device 2310 by securing a large magnetic force as compared with the case where the tilting device 2310 is raised by the urging force of the torsion spring 315. The load can be increased.

That is, normally, when the player puts his / her hand on the upper part of the tilting device 2310, when the restriction by the slide claw member 2348 is released, the tilting device 2310 is prevented from being raised by the weight of the hand. (Even if the urging force of the torsion spring 315 is not large enough to lift the weight of the hand), if the magnetic force is large enough to lift the weight of the hand, lift the player's hand in the state shown in FIG. The tilting device 2310 can be raised in an embodiment.

Thereby, when raising the tilting device 2310, it is possible to provide a difference in the load in the ascending direction (force for maintaining the posture of the tilting device 2310 with respect to the downward load). Therefore, the player who plays the game by placing his / her hand on the upper part of the tilting device 2310 before pushing the tilting device 2310 can feel the difference in the load.

For example, by associating the difference in load with the expected degree of jackpot, the player can easily use the operation device 2300 as a means of pre-reading, so that the degree of attention of the operation device 2300 to the player can be determined. Can be improved.

Next, a third embodiment will be described with reference to FIGS. 50 to 52. In the first embodiment, the case where the detection sensors 324L and 324R can detect whether the tilting device 310 is in the first state or in the state of being pushed by the player has been described, but the operation device 3300 in the third embodiment has been described. Is configured in such a manner that the detection sensors 324L and 324R can detect whether the tilting device 3310 is in the middle of the first state and the state of being pushed by the player or the state of being pushed by the player. NS. The same parts as those in the above-described embodiments are designated by the same reference numerals, and the description thereof will be omitted.

FIG. 50 is a side view of the tilting device 3310 according to the third embodiment. As shown in FIG. 50, the tilting device 3310 has the same position as the right side detection piece 311 gR extending downward from the bottom plate portion 311a of the case body 3311 and the left side detection piece 311 gL in the first embodiment (rotation of the tilt device 3310). It is provided with a left side detection piece 3311 gL extending at a surface perpendicular to the axis and located at a position opposite to the right side detection piece 311 gR with respect to the surface arranged at the center position in the rotation axis direction. The left side detection piece 3311 gL has a longer extension length than the right side detection piece 311 gR, and its extension length is shorter than that of the left side detection piece 311 gL in the first embodiment.

51 (a) and 51 (b) are side views of the operating device 3300. Note that FIG. 51 (a) shows the tilting device 3310 in the first state, and FIG. 51 (b) shows a state in which the tilting device 3310 is being pushed in. Further, in FIGS. 51 (a) and 51 (b), in order to facilitate understanding, the outer shapes of the lower frame member 320, the upper frame member 330, and the protective cover device 350 are illustrated by imaginary lines, while each of them is shown by an imaginary line. The detection sensors 324L and 324R and the voice coil motor 352 are shown by solid lines, and the portion where the detection sensors 324L and 324R and the detection pieces 3311gL and 311gR overlap is schematically shown.

As shown in FIG. 51 (a), when the tilting device 3310 is in the first state, the left side detection piece 3311 gL is not inserted through the left side detection sensor 324L and the right side detection piece 311 gR is inserted through the right side detection sensor 324R. None (the left side detection sensor 324L is in the OFF state and the right side detection sensor 324R is in the OFF state).

As shown in FIG. 51 (b), when the tilting device 3310 is in the process of being pushed from the first state to the pushing end, the left side detection piece 3311gL is inserted through the left side detection sensor 324L, while the right side is inserted. The detection piece 311gR is not inserted through the right side detection sensor 324R (the left side detection sensor 324L is in the ON state and the right side detection sensor 324R is in the OFF state).

By detecting the change in the state of each of these detection sensors 324L and 324R, when the tilting device 3310 is in the middle of the first state and the state of being pushed to the end of pushing, it is in the middle of pushing. It is possible to detect whether it is in the process of returning or not.

That is, if the left side detection sensor 324L is ON and the right side detection sensor 324R is OFF, the tilting device 3310 is in the middle of the first state and the state of being pushed to the end of pushing. By detecting that the left side detection sensor 324L is in the OFF state and the right side detection sensor 324R is in the state of being changed from the OFF state, it can be determined that the tilting device 3310 is in the middle of the pushing operation.

52 (a) and 52 (b) are side views of the operating device 3300. Note that FIG. 52 (a) shows a state in which the tilting device 3310 is pushed to the pushing end, and FIG. 52 (b) shows a state in which the tilting device 3310 is in the process of moving from the pushing end to the first state. .. Further, in FIGS. 51 (a) and 51 (b), in order to facilitate understanding, the outer shapes of the lower frame member 320, the upper frame member 330, and the protective cover device 350 are illustrated by imaginary lines, while each of them is shown by an imaginary line. The detection sensors 324L and 324R and the voice coil motor 352 are shown by solid lines, and the portion where the detection sensors 324L and 324R and the detection pieces 3311gL and 311gR overlap is schematically shown.

As shown in FIG. 52A, when the tilting device 3310 is pushed to the end of pushing, the left side detection piece 3311 gL is inserted through the left side detection sensor 324L and the right side detection piece 311 gR is inserted through the right side detection sensor 324R. (The left side detection sensor 324L is ON and the right side detection sensor 324R is ON).

As shown in FIG. 52 (b), when the tilting device 3310 is between the first state and the state arranged at the push-in end, the left side detection piece 3311 gL is inserted through the left side detection sensor 324 L. The right side detection piece 311gR is not inserted through the right side detection sensor 324R (the left side detection sensor 324L is in the ON state and the right side detection sensor 324R is in the OFF state).

If the left side detection sensor 324L is ON and the right side detection sensor 324R is OFF, the tilting device 3310 is in the middle of the first state and the state of being pushed to the end of pushing, which is the left side detection. By detecting that the sensor 324L is in the ON state and the right side detection sensor 324R is in the state of being changed from the ON state, it can be determined that the tilting device 3310 is in the process of returning to the first state.

Here, when the driving force of the voice coil motor 352 is transmitted to the tilting device 3310 to give an auxiliary load for raising the tilting device 3310, the voice coil motor 352 is moved to the tilting device 3310 while the tilting device 3310 is descending. It is possible to effectively give a load for raising the tilting device 3310 by colliding the voice coil motor 352 with the tilting device 3310 while the tilting device 3310 is operating ascending rather than colliding with the tilting device 3310.

Therefore, as shown in FIG. 52B, the operating direction of the tilting device 3310 is determined from the detection history of each of the detection sensors 324L and 324R, and the tilting device 3310 is in the process of ascending and reaches the first state. By driving the voice coil motor 352 when not in use, the driving force of the voice coil motor 352 can be effectively transmitted to the tilting device 3310, and the ascending speed of the tilting device 3310 can be improved.

Here, when the urging force of the torsion spring 315 is suppressed in order to suppress the driving force of the drive motor 342 (see FIG. 18), the ascending speed of the tilting device 3310 after the tilting device 3310 is pushed in from the first state is slow. Become. In this case, even if the player repeatedly hits the tilting device 3310, the ascending operation of the tilting device 3310 does not follow the movement of the player's hand, and the continuous hitting operation cannot be performed comfortably.

On the other hand, according to the present embodiment, by effectively using the driving force of the voice coil motor 352, the tilting device 3310 moves up as compared with the case where the tilting device 3310 is raised only by the urging force of the torsion spring 315. Since the ascending speed can be improved, the continuous striking operation of the tilting device 3310 can be comfortably performed.

Next, a fourth embodiment will be described with reference to FIGS. 53 to 55. In the first embodiment, the case where the detection sensors 324L and 324R can detect whether the tilting device 310 is in the first state or in the state of being pushed by the player has been described, but the operation device 4300 in the fourth embodiment has been described. Is an embodiment in which the tilting device 4310 detects the operating speed during the change from the second state to the first state, and changes the driving method of the voice coil motor 352 according to the detection result. The same parts as those in the above-described embodiments are designated by the same reference numerals, and the description thereof will be omitted.

FIG. 53 is a side view of the tilting device 4310 according to the fourth embodiment. As shown in FIG. 53, the tilting device 4310 includes a front detection piece 4311k that is projected in a plate shape from the front side of the overhanging convex portion 311j of the case body 4311.

The front detection piece 4311k is configured to be able to pass through the detection grooves (slits) of the upper detection sensor 4321d and the lower detection sensor 4321e (see FIG. 54) arranged in the bottom plate portion 4321 of the lower frame member 4320, and each detection is performed. This is a part for determining the operating speed of the tilting device 4310 based on the detection timing of the sensors 4321d and 4321e.

54 (a) and 54 (b) are side views of the operation device 4300 showing the pressing operation of the operation device 4300 in chronological order. In FIG. 54 (a), the tilting device 4310 is in the second state, and in FIG. 54 (b), the tilting device 4310 is pushed in from the state shown in FIG. 54 (a) and the front detection piece 4311k is detected on the lower side. The state in which the sensor 4321e has passed downward is shown. Further, in FIGS. 54 (a) and 54 (b), in order to facilitate understanding, the outer shapes of the lower frame member 4320, the upper frame member 330, and the protective cover device 350 are illustrated by imaginary lines, while each of them. The detection sensors 324L, 324R, 4321d, 4321e and the voice coil motor 352 are shown by solid lines.

As shown in FIGS. 54 (a) and 54 (b), the lower frame member 4320 includes an upper detection sensor 4321d and a lower detection sensor 4321e in a portion on the front side of the bottom plate portion 4321. The upper detection sensor 4321d and the lower detection sensor 4321e are photocoupler type sensors, and are arranged in a posture in which the detection groove is oriented so that the front detection piece 4311k can pass through. In the present embodiment, the upper detection sensor 4321d and the lower detection sensor 4321e are arranged at intervals of 20 ° on an arc orbit centered on the rotation axis of the tilting device 4310.

When the player changes from the state shown in FIG. 54 (a) to the state shown in FIG. 54 (b) by pushing the tilting device 4310, the front detection piece 4311k has the upper detection sensor 4321d and the lower detection sensor. It passes through 4321e in order. By detecting the interval of the passing timing, it is possible to determine the magnitude of the operating speed of the tilting device 4310, and it is selected whether or not to drive the voice coil motor 352 by the determination.

Here, when the tilting device 4310 is pushed in from the second position, the pushing length is long (because the period during which acceleration can be applied is long), so that the tilting device is compared with the operation button having a short pushing length. The upper limit of the operating speed of 4310 is increased. Therefore, if there is no means for deceleration, it is necessary to make the tilting device 4310 strong as a safety measure for the player to push in with full force, and the tilting device 4310 tends to be heavy. Challenges arise.

Further, it is also possible to incorporate an elastic spring that applies an urging force to the tilting device 4310 only when the tilting device 4310 is arranged near the end of pushing, and to decelerate the tilting device 4310 by the urging force of the elastic spring. However, in this case, for a player with a weak force or a player who has decided to perform a gentle pushing operation, the fact that the reaction force is always large near the pushing position becomes a burden on the pushing operation, and it becomes easy to feel fatigue. Therefore, there is a risk that the tilting device 4310 cannot be pushed in comfortably.

On the other hand, in the present embodiment, it is determined whether or not the upper detection sensor 4321d and the lower detection sensor 4321e drive the voice coil motor 352 by the timing interval at which the upper detection sensor 4321d and the lower detection sensor 4321e are switched between the ON state and the OFF state, respectively. Therefore, it is possible to prevent a strong reaction force from being applied to the tilting device 4310 even when it is not necessary.

That is, for example, when the timing interval at which the upper detection sensor 4321d and the lower detection sensor 4321e are switched between the ON state and the OFF state is longer than a predetermined period (for example, 1 second), the voice coil motor 352 is used. On the other hand, when the above-mentioned timing interval is shorter than a predetermined period, the voice coil motor 352 is driven.

As a result, when the operation speed of the pushing operation of the tilting device 4310 is slow, the reaction force felt by the player from the tilting device 4310 is only the urging force generated by the torsion spring 315, and the tilting device 4310 can be easily operated even with a weak force. It can be pushed in.

Further, when the operation speed of the pushing operation of the tilting device 4310 is high, not only the urging force generated by the torsion spring 315 but also the driving force generated by the voice coil motor 352 at the pushing end is used as the reaction force against the tilting device 4310. Can be added. Therefore, the operating speed of the tilting device 4310 can be suppressed.

In the present embodiment, as shown in FIG. 54B, the voice coil motor 352 is driven before the overhanging convex portion 311j of the tilting device 4310 projects below the lower frame member 4320. It is controlled in such a manner that the movable member of the voice coil motor 352 is extruded in advance to the side close to the tilting device 4310.

As a result, the impact applied to the tilting device 4310 can be suppressed as compared with the case where the tilting device 4310 and the voice coil motor 352 collide with each other during the extrusion of the movable member of the voice coil motor 352.

55 (a) and 55 (b) are side views of the operating device 4300. Note that FIG. 55 (a) shows a state in which the tilting device 4310 is being pushed from the first state to the pushing end, and FIG. 55 (b) shows a state in which the tilting device 4310 reaches the pushing end. ..

Further, in FIGS. 55 (a) and 55 (b), in order to facilitate understanding, the outer shapes of the lower frame member 4320, the upper frame member 330, and the protective cover device 350 are illustrated by imaginary lines, while each of them. The detection sensors 324L, 324R, 4321d, 4321e and the voice coil motor 352 are shown by solid lines.

As shown in FIG. 55 (a), when the tilting device 4310 is pushed in at high speed from the second state, the tilting device 4310 is in the process of reaching the pushing end from the first state, and the tilting device 4310 is projected. The setting portion 311j and the voice coil motor 352 are brought into contact with each other.

By pushing the tilting device 4310, the overhanging convex portion 311j moves the voice coil motor 352 in the direction along the extension direction D41 of the voice coil motor 352, so that the voice coil motor 352 is reduced. The force of the push operation can be consumed to move to. Therefore, while the tilting device 4310 continues to move, the driving force of the voice coil motor 352 can apply a load in the direction of pushing up the tilting device 4310, and the tilting device 4310 can be decelerated.

At this time, since the voice coil motor 352 does not have a structure in which a load is applied by friction like a disc brake, but a structure in which a load is applied by an electromagnetic force, damage to members can be suppressed and durability can be ensured.

In the state shown in FIG. 55 (a), the overhanging convex portion 311j of the tilting device 4310 and the voice coil motor 352 are already in contact with each other, so that the state shown in FIG. 55 (a) (the left side detection sensor 324L is By gradually increasing the current flowing through the voice coil motor 352 from the ON state), the reaction force applied to the tilting device 4310 from the voice coil motor 352 can be gradually increased.

Therefore, while suppressing the reaction force felt by the player at the timing when the overhanging convex portion 311j of the tilting device 4310 and the voice coil motor 352 come into contact with each other, the tilting device 4310 decelerates on the way from the first state to the pushing end. The effect can be improved.

As shown in FIG. 55 (b), when the tilting device 4310 is arranged at the push-in end position, the right side detection sensor 324R is turned on. In this state, the tilting device 4310 abuts on the lower frame member 4320 in the rotational direction and stops descending. Therefore, it is not necessary to decelerate the tilting device 4310 by the voice coil motor 352.

In the present embodiment, in the state shown in FIG. 55 (b), the voice coil motor 352 performs a vibration operation (an operation of repeating movement in the extension direction and movement in the contraction direction). As a result, it is possible to perform an effect of transmitting vibration to the player who keeps his / her hand on the tilting device 4310 after pushing the tilting device 4310 to the end.

That is, the voice coil motor 352 can be used for the purpose of reducing the speed of the pushing operation of the tilting device 4310 and for the purpose of vibrating the tilting device 4310 arranged at the pushing end position to produce a vibration effect.

Next, the operation device 5300 according to the fifth embodiment will be described with reference to FIGS. 56 to 68.

In the first embodiment, the case where the vibration is transmitted to the player who pushes and operates the tilting device 310 by vibrating the voice coil motor 352 has been described, but the operation device 5300 in the fifth embodiment is attached to the lower frame member 5320. The drive motor 5411 for rotating the weight member 5412 whose center of gravity is eccentric is provided, and the vibration is transmitted to the player who touches the lower frame member 5320 based on the rotation of the drive motor 5411. The same parts as those in the above-described embodiments are designated by the same reference numerals, and the description thereof will be omitted. First, the difference in configuration from the first embodiment will be described with reference to FIGS. 56 and 57.

FIG. 56 is an exploded front perspective view of the operating device 5300 according to the fifth embodiment, and FIG. 57 is an exploded rear perspective view of the operating device 5300.

As shown in FIGS. 56 and 57, in the operation device 5300, the lower frame member 320 is the lower frame member 5320 and the drive device 340 is the drive device 5340, as compared with the operation device 300 in the first embodiment. At the same time, the voice coil motor 352 is omitted from the protective cover member 350. The tilting device 310 and the upper frame member 330 have the same configuration as that of the first embodiment.

The lower frame member 5320 is provided with a vibration device 5400 including a drive motor 5411, and the drive device 5340 is provided with a disk cam 5344 fixed to the transmission shaft rod 5343 with one touch. First, the vibrating device 5400 will be described with reference to FIGS. 58 to 61, and then the disk cam 5344 will be described.

FIG. 58 is an exploded front perspective view of the lower frame member 5320 and the vibrating device 5400. As shown in FIG. 58, the vibrating device 5400 includes a transmission device 5410 that rotationally drives a fan-shaped weight member 5412, a transmission device 5410, and a drive motor 5411 of the transmission device 5410, and is composed of a flexible material. The flexible member 5420 and the flexible member 5420 are formed in a bottomed dish shape with an open upper surface, and the weight member 5412 and the flexible member 5420 are separately accommodated and are fastened and fixed to the bottom plate portion 5321 of the lower frame member 5320. Mainly equipped with 5430.

The transmission device 5410 includes a drive motor 5411 formed of a rotary drive electric motor, and a weight member 5412 whose outer shape is fan-shaped and whose rotating shaft of the drive motor 5411 is pivotally supported by a portion corresponding to the main part of the fan. And mainly prepare.

The drive motor 5411 includes a fixed portion 5411a which is arranged in pairs on the left and right and is formed in a flange shape from a metal material on the side surface on the side where the shaft projects.

The weight member 5412 has a radius Ra and is eccentrically supported with the rotation axis of the drive motor 5411. Therefore, when the drive motor 5411 is rotationally driven, the position of the center of gravity of the weight member 5412 fluctuates, and the drive motor 5411 can vibrate together with the drive motor 5411.

The flexible member 5420 has a main body 5421 formed of a cylindrical container shape in which the drive motor 5411 is inserted along the axial direction and has a bottom on the opposite side of the insertion side, and the main body 5421 in the assembled state. The rib-shaped legs 5422, which are projected in a pair of ribs on the left, right, left and right and downward in the radial direction, and the rib-shaped legs 5422, which are convex on the left and right on the open portion side of the main body 5421, are connected to each other. It mainly includes a posture maintaining portion 5423 in which the fixing portion 5411a is embedded, and a convex leg portion 5424 projecting upward from the upper surface of the main body portion 5421 in a pair of columns.

The main body portion 5421 has a container-shaped depth formed at the same depth as the axial length of the drive motor 5411. Therefore, in a state where the drive motor 5411 is completely inserted into the main body portion 5421, the end face on the shaft side of the drive motor 5411 and the end face on the opening side of the main body portion 5421 are formed on the same surface. Further, in this state, the fixing portion 5411a is embedded in the posture maintaining portion 5423.

The rib-shaped leg portion 5422 is formed on the left and right sides and the lower side of the main body portion 5421, but the rib-shaped leg portion 5422 on the left and right sides is larger than the rib-shaped leg portion 5422 on the left and right sides because the posture maintaining portion 5423 is arranged on the left and right sides. Deformation resistance is larger than that of the lower ribbed leg portion 5422.

Since the convex leg portion 5424 is projected in a columnar shape, it is possible to easily concentrate the load on one point in contact with the tilting device 310 described later. Therefore, when the flexible member 5420 is deformed by tilting the tilting device 310, the resolution of the degree of deformation of the flexible member 5420 with respect to the tilting angle of the tilting device 310 can be made finer.

In the assembled state, the accommodating member 5430 is provided next to the first accommodating portion 5431 in which the drive motor 5411 and the flexible member 5420 are accommodated, and the second accommodating portion 5412 in which the weight member 5412 is accommodated. 5432 and a concave groove 5433 that is recessed downward from the upper surface on the connecting surface of the first accommodating portion 5431 and the second accommodating portion 5432 are mainly provided.

The depth of the first accommodating portion 5431 is adjusted from the upper surface when the flexible member 5420 is inserted until the lower rib-shaped leg portion 5422 touches the bottom and the load applied during the insertion is released (assembly load release state). The depth is such that the convex leg portion 5424 overhangs.

The depth of the second accommodating portion 5432 is a depth that is recessed to the outside of the rotation locus of the weight member 5412 in the assembled load release state, while the player applies a load to the convex leg portion 5424 to provide a flexible member. When the 5420 is deformed (assembled load state), the depth is set to interfere with the rotation locus of the weight member 5412.

The concave groove 5433 has a width dimension that is slightly wider than the diameter of the rotation shaft of the drive motor 5411, and a depth dimension that extends slightly downward from the rotation shaft of the drive motor 5411 under the assembled load state. NS.

59 (a) is a side view of the lower frame member 5320, and FIG. 59 (b) is a partial cross-sectional view of the lower frame member 5320 in the LIXb-LIXb line of FIG. 59 (a). ) Is a partial top view of the lower frame member 5320 in the direction of arrow LIXc in FIG. 59 (a). In FIG. 59 (a), the portion corresponding to the vibrating device 5400 is partially cross-sectionally viewed. Further, in FIG. 59 (a), when the tilting device 310 is in the first state, the first region S51, which is the area occupied by the tilting device 310, and the first region are pushed into the player by three degrees. The end area S52, which is the area occupied by the tilting device 310 when arranged at the end position of the push-in, is illustrated by an imaginary line.

As shown in FIG. 59 (a), the convex leg portion 5424 is convexly provided in the direction along the circular orbit formed with the central axis of the arc of the lower bearing portion 323 as the rotation axis. Therefore, the amount of deformation of the convex leg portion 5424 with respect to the angle change of the tilting device 310 (see FIG. 56) can be secured to the maximum.

As shown in FIG. 59 (b), the weight member 5412 is separated from the second accommodating portion 5432 in the assembled load release state in which the convex leg portion 5424 is not loaded.

As shown in FIG. 59 (c), the convex leg portions 5424 are arranged symmetrically with respect to the left and right center lines of the lower frame member 5320 in the extension direction view. Therefore, since the convex leg portion 5424 can be pushed evenly to the left and right on the bottom surface of the tilting device 310, it is possible to prevent the flexible member 5420 from tilting to the left or right (tilting to the left or right on the paper surface in FIG. 59 (b)). The convex leg portion 5424 can be pushed in while maintaining the posture shown in FIG. 59 (b).

As shown in FIG. 59 (c), the bottom plate portion 5321 of the lower frame member 5320 includes a pair of through holes 5321d into which the convex leg portion 5424 can be inserted. Since the width dimension of the through hole 5321d in the left-right direction is slightly larger than the diameter dimension of the convex leg portion 5424, the tilting device 310 is pushed by the player and the lower side surface of the tilting device 310 is convex. When pressed against the leg portion 5424, deformation of the convex leg portion 5424 in the left-right direction can be suppressed. Therefore, the deformation of the shape of the convex leg portion 5424 can be suppressed, and the main body portion 5421 together with the convex leg portion 5424 can be easily translated downward (downward in FIG. 59B).

60 (a) and 60 (b) are cross-sectional views of the vibrating device 5400 in the LXa-LXa line of FIG. 59 (a). Note that FIG. 60 (a) shows an assembly load release state, and FIG. 60 (b) shows the convex leg portion 5424 in a state where the tilting device 310 occupies the terminal region S52 (see FIG. 59 (a)). The assembly load state after being pushed inward of the first accommodating portion 5431 is shown. The outer shapes of the second accommodating portion 5432 and the weight member 5412 are illustrated by imaginary lines.

As shown in FIGS. 60A and 60B, when a load is applied to the vibrating device 5400 from the assembly load release state and the assembly load state is reached, the convex leg portion 5424 and the lower ribbed leg portion As the 5422 is deformed, the drive motor 5411 and the weight member 5412 are displaced downward.

In the assembled load state, as shown in FIG. 60 (b), the flexible member 5420 is elastically deformed by being pushed by the tilting device 310 (see FIG. 57). The elastic recovery force of this deformation acts as a force to push back the tilting device 310, and the force increases as the tilting device 310 approaches the flexible member 5420. Therefore, when the tilting device 310 is pushed to the terminal position, the tilting device 310 is pushed back. The impact when the 310 collides with the lower frame member 5320 (see FIG. 57) can be mitigated. Further, since the load is due to the elastic recovery force, the load can be generated without a time delay even when the tilting device 310 moves at high speed.

Here, when the urging force of the torsion spring 315 is suppressed in order to suppress the driving force of the drive motor 342 (see FIG. 57), from the first state (the state in which the tilting device 310 is arranged at the rising end, see FIG. 38). The ascending speed of the tilting device 310 after the tilting device 310 is pushed in is slowed down. In this case, even if the player repeatedly hits the tilting device 310, the ascending operation of the tilting device 310 does not follow the movement of the player's hand, and the continuous hitting operation cannot be performed comfortably.

On the other hand, according to the present embodiment, by effectively using the elastic recovery force of the flexible member 5420, the tilting device 310 is compared with the case where the tilting device 310 is ascended only by the urging force of the torsion spring 315. Since the ascending speed can be improved, the continuous striking operation of the tilting device 310 can be comfortably performed.

As shown in FIG. 60A, the weight member 5412 does not come into contact with the inner wall of the second accommodating portion 5432 regardless of its posture in the assembled load release state. Therefore, even if the drive motor 5411 is started to be driven in the assembled load release state, the vibration due to the contact between the weight member 5412 and the second accommodating portion 5432 does not occur.

Further, the vibration of the drive motor 5411 itself and the slight vibration generated in the drive motor 5411 due to the movement of the center of gravity of the weight member 5412 are absorbed by the flexibility of the flexible member 5420, and transmission to the accommodating member 5430 is prevented. This makes it difficult for the player to grasp the drive start timing of the drive motor 5411.

As shown in FIG. 60B, the main body portion 5421 of the flexible member 5420 is displaced vertically due to deformation of the upper convex leg portion 5424 and the lower rib-shaped leg portion 5422 under the assembly load state. Consists of acceptable aspects.

When the flexible member 5420 moves downward, the state of the rib-shaped leg portion 5422 arranged under the main body portion 5421 changes to a state of being compressed more vertically, and the rib-shaped leg portion 5422 is slightly hardened. Therefore, the damping effect of the vibration by the rib-shaped leg portion 5422 can be weakened, and the vibration generated by the vibration device 5400 can be easily transmitted to the player.

Further, the main body portion 5421 of the flexible member 5420 is formed in a cylindrical shape, and the lower rib-shaped leg portion 5422 is extended along the axial direction of the cylinder of the main body portion 5421 and at uniform intervals to the left and right from the central axis. Since the flexible members 5420 are arranged in pairs on the left and right, the radial outer ends of the rib-shaped leg 5422 move outward on the left and right (at the connection position between the main body 5421 and the rib-leg 5422) as the flexible members 5420 move downward. It deforms in a manner of moving to (the one with the smaller resistance) (see FIG. 60 (b)). In this case, since the convex direction of the rib-shaped leg portion 5422 arranged on the lower side of the main body portion 5421 has a left-right direction component, the elastic force of the rib-shaped leg portion 5422 can be applied in the left-right direction. .. Therefore, in the assembled load state, the load in the left-right direction that may occur when the weight member 5421 and the second accommodating portion 5432 collide is partially applied by the elastic force of the rib-shaped leg portion 5422 on the lower side of the main body portion 5421. Can be absorbed. As a result, the displacement of the drive motor 5411 in the left-right direction can be suppressed.

61 (a) and 61 (b) are cross-sectional views of the transmission device 5410 and the accommodating member 5430 in the LIXb-LIXb line of FIG. 59 (a).

61 (a) and 61 (b) show an assembly load state, and FIG. 61 (a) shows a state in which the position of the center of gravity of the weight member 5412 is arranged above the rotation axis. In b), a state in which the position of the center of gravity of the weight member 5412 is arranged below the rotation axis is illustrated. Note that FIGS. 61 (a) and 61 (b) show a state of the vibrating device 5400 in a state where the tilting device 310 is pushed by the player and occupies the terminal region S52.

The operation of the transmission device 5410 based on the rotation of the weight member 5412 will be described. First, in the present embodiment, when the center of gravity of the weight member 5412 is arranged on the upper side in the assembled load state, the drive motor 5411 rotates at a position where the distance from the lower bottom portion of the second accommodating portion 5432 is the distance Q1. The axis is placed. In the present embodiment, the distance Q1 is equal to the radius Ra of the weight member 5412 (Q1 = Ra).

That is, when the weight member 5412 rotates in the assembled load state, the outer peripheral side surface thereof comes into contact with (rubs) the second accommodating portion 5432. Therefore, the vibration generated by the rotation of the weight member 5412 changes as compared with the assembled load release state, and different types of vibration can be transmitted to the player.

Due to the contact between the weight member 5412 and the second accommodating portion 5432, a force for moving the weight member 5412 upward (upward in FIG. 61B) is generated as a repulsive force. Here, since the weight member 5412 and the second accommodating portion 5432 move close to each other along the moving direction of the tilting device 310 (see FIG. 57), the direction of the repulsive force is set to the direction (upward) along the moving direction of the tilting device 310. ) Can be easily directed. Due to this repulsive force, the flexible member 5420 moves upward together with the drive motor 5411 that supports the weight member 5412, and the flexible member 5420 moves the tilting device 310 (see FIG. 57) upward (along the moving direction of the tilting device 310). The force to push back in the direction) can be reinforced.

In this way, the force that pushes the tilting device 310 (see FIG. 57) upward is the force generated as the elastic recovery force of the flexible member 5420 and the force generated by the contact between the weight member 5412 and the second accommodating portion 5432 separately. By configuring it with a combination of generated forces, it is possible to adjust the force that pushes back the tilting device 310.

That is, the elastic recovery force of the flexible member 5420 pushes back the tilting device 310 from the start of contact with the convex leg portion 5424 to the end region S52 (see FIG. 59 (a)). After the tilting device 310 reaches the terminal region S52, the repulsive force between the weight member 5412 and the second accommodating portion 5432 is applied to the force pushing back the tilting device 310. As a result, the force for pushing back the tilting device 310 can be particularly increased in the vicinity of the terminal region S52, so that the operation of the tilting device 310 can be lightened and the impact during the pushing operation can be mitigated satisfactorily. This adjustment can be performed while maintaining the rotation of the drive motor 5411. Therefore, it is not necessary to perform complicated control.

In the present embodiment, as in the first embodiment, the length of the left side detection piece 311 gL and the length of the right side detection piece 311 gR are different (see FIG. 57), and the tilting device 310 (see FIG. 57) is different due to the difference in detection timing. ) Is determined whether or not the operating speed is higher than a specific speed (for example, 40 km / h), and the arrangement of the weight member 5412 is changed according to the determined operating speed.

For example, when it is determined that the operating speed of the tilting device 310 is higher than a specific speed, the flexible member 5420 gives the tilting device 310 in order to alleviate the impact when the tilting device 310 collides with the lower frame member 5320. It is desirable to increase the load. Therefore, in the present embodiment, when it is determined that the operating speed of the tilting device 310 is higher than a specific speed, the weight member 5412 is operated in advance so as to be in a downward posture (see FIG. 61B).

As a result, the end of the lowering operation of the drive motor 5411 can be raised to a position where its rotation axis is raised by a radius Ra upward from the lower end of the inner wall of the second accommodating portion 5432. As a result, the weight member 5432 is located above the drive motor 5411 as compared with the case where the weight member 5432 is arranged upward (see FIG. 61 (a)) (when the weight member 5432 can be lowered downward from the state shown in FIG. 61 (a)). The movable area of the flexible member 5420 can be narrowed in the vertical direction.

That is, when the convex leg portion 5424 is pushed down by the tilting device 310 by the same amount, the compression dimension of the portion of the flexible member 5420 and the upper portion of the drive motor 5411 can be increased. Therefore, the repulsive force applied from the flexible member 5420 to the tilting device 310 can be increased, and the load for braking the tilting device 310 can be increased.

Although the description is omitted in the present embodiment, by keeping the drive motor 5411 stopped upward (see FIG. 61A), a force for pushing back the tilting device 310 is generated by the elastic recovery force of the flexible member 5420. It is also possible to prevent the force due to the contact between the weight member 5412 and the second accommodating portion 5432 from being generated.

Here, the contact of the members occurs between the transmission device 5410 and the accommodating member 5430 that is fastened and fixed to the lower frame member 5320, and does not occur between the tilting device 310. Therefore, the vibration transmitted to the hand of the player who pushes the tilting device 310 can be changed, and the transmission range of the vibration can be widened. That is, the vibration can be transmitted to a portion other than the portion touching the tilting device 310, for example, a portion touching the frame of the pachinko machine 10.

That is, when the player pushes the tilting device 310, the vibration can be transmitted to the lower frame member 5320, so that the palm or a part of the side surface of the hand placed on the lower frame member 5320 as a fulcrum for pushing is used. The vibration can be transmitted to the player through. As a result, it is possible to avoid a situation in which the vibration is not transmitted to the player.

As shown in FIGS. 61 (a) and 61 (b), the weight member 5412 only when the player pushes in the tilting device 310 (see FIG. 56) and the vibrating device 5400 forms an assembled load state. And the accommodating member 5430 come into contact with each other, and vibration is generated.

Therefore, even if the drive motor 5411 is in the rotating state in advance, the timing at which the vibration is transmitted to the player can be limited to the timing at which the tilting device 310 is pushed in, so that the pushing operation of the player can be detected. It is possible to make it easier to transmit the vibration to the player as compared with the case where the vibration is generated from the motor.

That is, when the player pushes the tilting device 310 and immediately releases the hand (pulse pushing), the tilting device 310 is detected to be pushed and then vibration is generated. Therefore, there is a possibility that the vibration cannot be generated by the time the player releases the hand (the vibration starts not in time), and the player may not be able to experience the effect of the vibration. On the other hand, in the present embodiment, since the drive motor 5411 is rotated in advance before the tilting device 310 is pushed in and is ready to generate vibration, the vibration can be transmitted at the same time as the tilting device 310 is pushed in. As a result, the player can experience the effect of vibration.

Further, due to the flexibility of the flexible member 5420, it is possible to prevent the vibration of the main body of the drive motor 5411 from being transmitted to the first accommodating portion 5431. Therefore, even if the drive motor 5411 is driven in advance, it is possible to prevent the vibration from being transmitted to the player even before the tilting device 310 is pushed in.

Therefore, the state in which the vibration is transmitted by pushing the tilting device 310 can be realized by driving the drive motor 5411 in advance before pushing the tilting device 310.

Next, the drive device 5340 will be described. The difference between the drive device 5340 and the drive device 340 in the first embodiment is the disk cam 5344 and the transmission shaft rod 5343. Others are the same as the drive device 340 of the first embodiment, so the same reference numerals are given and the description thereof will be omitted.

FIG. 62 is an exploded front perspective view of the drive device 5340. As shown in FIG. 62, a long hole recess C1 is formed in a central portion of a pair of disc cams 5344 composed of a left disc cam 5344L and a right disc cam 5344R.

FIG. 63 (a) is a front perspective view of the right disk cam 5344R, and FIG. 63 (b) is a rear perspective view of the right disk cam 5344R. Since the right disk cam 5344R and the left disk cam 5344L are formed in a symmetrical shape, only the right disk cam 5344R will be described, and the description of the left disk cam 5344L will be omitted.

The difference between the right disk cam 5344R and the right disk cam 344R in the first embodiment is that a pair of holding arm portions A1 for sandwiching the transmission shaft rod 5343 are arranged at the connecting portion with the transmission shaft rod 5343. Is.

That is, the right disc cam 5344R has a support cylinder portion P1 extending in a cylindrical shape from the disc portion to the side where the circular ribs 344b are arranged at the center position thereof, and the support cylinder portion P1 in the axial direction. Along the axis, a long hole recess C1 recessed from a disk portion in an axially symmetric long hole shape up to a position of about half of the extension distance, and a shaft of a support cylinder portion P1 recessed by the long hole recess C1. It mainly includes a pair of holding arm portions A1 extending from the end portion in the direction toward the disk portion side along the axial direction.

The support cylinder portion P1 is a portion that supports the cylindrical member 5343a by making the inner diameter of the support cylinder portion P1 equal to the diameter of the cylindrical member 5343a of the transmission shaft rod 5343. The support cylinder portion P1 is a portion having the same axial arrangement as the region recessed in the elongated hole recess C1, and includes a deformed portion P1a that remains without being recessed in the elongated hole recess C1.

The deformed portion P1a is a pair of connecting rod portions arranged so as to sandwich the elongated hole recess C1, and elastically deforms when the right disk cam 5344R is axially tilted and deformed with respect to the transmission shaft rod 5343 (see FIG. 62). It is configured as a part to do.

The elongated hole recess C1 is formed so that the shape of the recessed cross section is slightly longer than the width dimension of the holding arm portion A1. Therefore, the holding arm portion A1 is configured to be displaceable in a direction (longitudinal direction) perpendicular to the width direction of the concave cross section of the elongated hole recess C1.

Further, the facing surface of the elongated hole recess C1 is formed to engage with the D-shape of the fixing portion 5343a1 of the cylindrical member 5343a. That is, one side surface is formed from a flat surface, and the other side surface is formed from an arc shape along the outer shape of the cylindrical member 5343a. This makes it possible to prevent the cylindrical member 5343a from rotating relative to the disk cam 5344.

The holding arm portion A1 includes an engaging convex portion A1a that projects from the surface of the pair of arm portions facing the other side of the arm toward the opposite side of the arm. .. The engaging convex portion A1a engages with the tip end portion of the cylindrical member 5343a when connected to the transmission shaft rod 5343, and prevents the cylindrical member 5343a from coming off the disc cam 5344.

The tip shape of the engaging convex portion A1a is configured to match the arc shape of the engaging groove 5343a4 of the cylindrical member 5343a (see FIG. 64). As a result, the overlapping length in the radial direction in the state where the engaging convex portion A1a is engaged with the engaging groove 5343a4 is compared with the case where the tip shape is flat or the center is a convex curved surface (FIG. 65). (B) The length in the left-right direction) can be secured for a long time.

The engaging convex portion A1a has a concave surface portion C2 (long hole concave portion) in which the side surface on the side close to the connecting pin 344d in the axial direction is the side surface of the right disk cam 5344R and is recessed along the axis in the vicinity of the shaft. It is arranged at a position that is a surface position with the side surface on the opening side of C1).

As a result, the engagement between the cylindrical member 5343a and the engaging convex portion A1a can be completed on the support cylinder portion P1 side (lower side in FIG. 63 (b)) than the concave surface portion C2 (FIG. 65 (b)). reference). Therefore, on the outside of the recessed surface portion C2 (upper side in FIG. 63B), the length of the cylindrical member 5343a protruding from the recessed surface portion C2 is set to be longer than that in the case where the e-ring is fitted into the cylindrical member 5343a. Can be shortened by the thickness of (see FIG. 65 (b)).

Further, it is not necessary to secure a space for fitting the e-ring (a space required for sliding the e-ring against the surface) in the extending direction (direction parallel to the surface) of the right disk cam 5344R. Therefore, the recessed width (diametrically wide) of the recessed surface portion C2 can be reduced. As a result, the degree of freedom in designing the shape of the right disk cam 5344R can be improved.

The transmission shaft rod 5343 will be described with reference to FIG. 64. FIG. 64 is a front exploded perspective view of the transmission shaft rod 5343. The difference between the transmission shaft rod 5343 and the transmission shaft rod 353 in the first embodiment is the cylindrical member 5343a.

The cylindrical member 5343a is the same as the fixing portion 5343a1 with the fitting groove 5343a3 sandwiched from the fixing portion 5343a1 having a D-shaped cross section for fixing the disk cams 5344 formed at both ends thereof and the fixing portion 5343a1 on the left side in the front view. A clutch operating portion 5343a2 having a D-shaped cross section formed from a cross-sectional shape, a fitting groove 5343a3 that is a groove for fitting an e-ring and positioning the disk cam 5344 in the axial direction by the e-ring, and a fitting groove thereof. When the disc cam 5344 is fitted until it reaches the e-ring fitted in the 5343a3, the engaging groove 5343a4, which is the groove in which the engaging convex portion A1a of the holding arm portion A1 engages, is mainly used. Be prepared. The fitting groove 5343a3 is arranged on the outer side in the left-right direction of the pair of plates into which the shaft support holes 341b are bored in the assembled state.

The clutch operating portion 5343a2 is a portion inserted into the angle fixing hole 343c1 of the movable clutch 343c, and is a portion in which the movable clutch 343c slides by the urging force of the coil spring 343d in the assembled state.

Since the mechanism is adopted in which the e-ring is later fitted into the fitting groove 5343a3 to form a portion in which the diameter is partially increased in the cylindrical member 5343a by the e-ring, the cylinder is formed before the e-ring is fitted. The diameter of the member 5343a can be made uniform.

In a state where the diameter is uniform, a predetermined amount of the cylindrical member 5343a is inserted into the shaft support hole 341b (see FIG. 62), and then the e-ring is fitted. In addition to preventing the misalignment along the above, the e-ring can further prevent the misalignment of the disc cam 5344 in the axial direction.

With the above-described configuration of the disc cam 5344 and the transmission shaft rod 5343, the disc cam 5344 can be assembled to the transmission shaft rod 5343 with one touch. That is, when the disc cam 5344 is assembled to the transmission shaft rod 5343, the cylindrical member 5343a is located on the end of the support cylinder portion P1 of the disc cam 5344 on the side where the engaging convex portion A1a is arranged. Insert from the opposite end to the position where the engaging convex portion A1a fits into the engaging groove 5343a4. At this time, before the engaging convex portion A1a is inserted into the engaging groove 5343a4 to the position where the engaging convex portion A1a is fitted, the tip portion of the cylindrical member 5343a is inserted between the engaging convex portions A1a, so that the pair of engaging convex portions A1a are formed. The holding arm portion A1 is elastically deformed in such a manner that the distance between them can be expanded. After that, when the tip of the cylindrical member 5343a passes through the engaging convex portion A1a, the engaging convex portion A1a and the engaging groove 5343a4 are arranged to face each other, and the engaging convex portion A1a fits into the engaging groove 5343a4. Then, the holding arm portion A1 elastically recovers, and the disk cam 5344 and the transmission shaft rod 5343 are assembled (see FIG. 65 (b)).

On the other hand, the configuration of the disk cam 5344 and the transmission shaft rod 5343 functions not only as a one-touch assembly but also as a structure for preventing destruction in the present embodiment. This will be described with reference to FIGS. 65 and 66.

FIG. 65 (a) is a front view of the right disk cam 5344R in the direction of arrow LXVa of FIG. 62, and FIG. 65 (b) is a front view of the right disk cam 5344R in the LXVb-LXVb line of FIG. 65 (a). FIG. 65 (c) is a cross-sectional view of the right disk cam 5344R in the LXVc-LXVc line of FIG. 65 (a). 66 (a) is a front view of the right disk cam 5344R in the direction of arrow LXVa of FIG. 62, and FIG. 66 (b) is a right disk cam in the LXVIb-LXVIb line of FIG. 66 (a). It is sectional drawing of 5344R.

Note that FIG. 66 shows the deformed right disk cam 5344R when the player applies an overload to the right disk cam 5344R in the no-load state shown in FIG. 65.

As shown in FIGS. 65 and 66, in the present embodiment, the cylindrical member 5343a is supported by the extended tip side portion of the support cylinder portion P1 at a position separated from the disk portion of the right disk cam 5344R, and is a disk. In the vicinity of the portion, the engaging convex portion A1a only engages with the engaging groove 5343a4. Therefore, when an overload is applied to the cylindrical member 5343a or the right disk cam 5344R, the cylindrical member 5343a is configured to be capable of tilting around the extended tip portion of the support cylinder portion P1.

As shown in FIG. 65 (b), since the space of the elongated hole recess C1 is arranged in the direction in which the pair of holding arm portions A1 face each other, the resistance of the axial tilt displacement of the cylindrical member 5343a is reduced. On the other hand, as shown in FIG. 65 (c), in the direction in which the support cylinder portion P1 and the connecting pin 344d are connected, the cylindrical member 5343a and the right disk cam 5344R extend in the axial direction of the right disk cam 5344R. Since they come into contact with each other, the resistance of the axial tilt displacement of the cylindrical member 5343a becomes large.

Therefore, when the player forcibly presses (pulls up) the tilting device 310 and an overload is applied to the right disk cam 5344R (displacement of the connecting pin 344d via the arm member 345 (see FIG. 62)). The direction in which the right disk cam 5344R is deformed with respect to the cylindrical member 5343a can be restricted.

That is, since the right disk cam 5344R is deformed in the direction in which the resistance is small, as shown in FIGS. 66 (a) and 66 (b), when the right disk cam 5344R is overloaded, On a surface parallel to the surface of the disk portion, the disk portion is deformed by tilting around the support shaft r1 connecting the connecting pin 344d and the center of the support cylinder portion P1. As a result, the tip position of the connecting pin 344d is displaced along the circumferential direction of the right disk cam 5344R as compared with the position shown in FIG. 65 (a).

FIG. 67A is a cross-sectional view of the operation device 5300 in the line corresponding to the line XXII-XXII of FIG. 6A, and FIG. 67B is an operation in the direction of the arrow LXVIIb of FIG. 67A. It is a partial rear view of the device 5300. In FIG. 67B, the protective cover device 350 is not shown, and only the disk cam 5344, the arm member 345, and the release member 346 are shown. Further, in FIG. 67A, in order to facilitate understanding, the outer shape of the right disk cam 5344R in a state of being vertically inserted and fixed to the transmission shaft rod 5343 is shown by a solid line, and an overload is applied to cause the shaft to collapse. The outline of the state is shown by an imaginary line.

In FIG. 67A, the second state of the tilting device 310 is shown, the hand of the player holding the tilting device 310 is shown, and the state near the connecting pin 344d is enlarged and shown. ..

In the state shown in FIG. 67 (a), when the drive motor 342 (see FIG. 62) starts operating, the left disk cam 5344L is likely to start rotating, but the player is restricted from the displacement of the tilting device 310. Therefore, a load is generated between the arm member 345 that tries to stay in place and the connecting pin 344d of the left disk cam 5344L that tries to rotate. When this load is generated, the right disk cam 5344R can undergo the above-mentioned shaft tilt deformation, so that the load can be alleviated.

In FIG. 67A, the outer shape of the right disk cam 5344R after the shaft tilt deformation is shown by an imaginary line. The change in the connection mode with the arm member 345 due to the shaft tilt deformation will be described with reference to an enlarged view.

In FIG. 67 (a), when the outer circumference of the right disk cam 5344R is rotated clockwise by the dimension Rd due to the start of operation of the drive motor 342 (see FIG. 62), the shaft support of the arm member 345 is rotated by the dimension Rd. The hole 345a and the connecting pin 344d are misaligned, and in order to absorb this, the right disk cam 5344R is deformed by tilting the shaft.

Since the connecting pin 344d is tilted in the direction perpendicular to the paper surface in FIG. 67A due to the shaft tilt deformation, the center Pb on the root side of the connecting pin 344d and the center Pt on the convex tip side are right circles. The position shifts along the circumferential direction of the plate cam 5344R. Since this misalignment can partially absorb the misalignment between the connecting pin 344d and the arm member 345 due to the rotation of the dimension Rd of the right disk cam 5344R, the drive motor can be driven while the tilting device 310 is being gripped. When the 342 (see FIG. 62) is driven, the load applied to the drive motor 342 can be relaxed.

As shown in FIG. 67 (b), the disc cam 5344 is deformed by tilting the shaft, so that the disc cam 5344 and the release member 346 come into contact with each other. As a result, the driving force of the drive motor 342 is consumed by the frictional force generated between the release member 346 and the disc cam 5344, so that the player drives the drive motor 342 while holding and fixing the tilting device 310. In this case, the load applied to the arm member 345 connecting the disc cam 5344 and the tilting device 310 can be reduced.

As shown in FIG. 67 (a), when the disk cam 5344 rotates in the backward rotation direction (direction of arrow CW), the release member 346 is pushed upward by the frictional force, but the second spring is in the direction of repulsion. The elastic force of SP2 acts on the disk cam 5344 via the release member 346. In this case, since the rotary claw member 347 is stopped by the bottom plate portion 5321 and stops, the state of the first spring SP1 does not change (the elastic force does not change).

On the other hand, when the disc cam 5344 rotates in the forward rotation direction (arrow CCW direction, see FIG. 68), the release member 346 is pushed downward by the frictional force, but the elastic force of the first spring SP1 repels it. Acts on the disc cam 5344 via the release member 346 and the rotary claw member 347. In this case, since the relative positional relationship between the rotary claw member 347 and the release member 346 does not change, the state of the second spring SP2 does not change (the elastic force does not change).

Therefore, when the release member 346 and the disk cam 5344 come into contact with each other and the release member 346 operates along the operation direction of the disk cam 5344, the first spring SP1 or the first spring SP1 or Of any of the elastic forces of the second spring SP2, the elastic force acting on the disk cam 5344 can be increased in the direction opposite to the rotation direction of the disk cam 5344. As a result, the load applied to the disc cam 5344 by the release member 346 can be increased, and the amount of consumption of the driving force of the drive motor 342 can be increased. Therefore, the load applied to the arm member 345 can be increased by the disc cam 5344. It can be reduced regardless of the rotation direction of.

In the present embodiment, the right disk cam 5344R is formed from a shape that is axisymmetric with respect to the straight line passing through the connecting pin 344d and the center point (direction perpendicular to the straight line passing through the connecting pin 344d and the center point). (Because the elongated hole recess C1 is extended), the right disk cam 5344R is similarly deformed regardless of the rotation direction of the right disk cam 5344R (regardless of the misalignment direction of the connecting pin 344d with respect to the arm member 345). The shaft can be tilted and deformed by resistance.

68 (a) is a cross-sectional view of the operation device 5300 in the line corresponding to the XXII-XXII line of FIG. 6 (a), and FIG. 68 (b) is an operation in the direction of arrow LXVIIIb of FIG. 68 (a). It is a partial rear view of the device 5300. In FIG. 68 (b), the protective cover device 350 is not shown. Further, in FIG. 68A, in order to facilitate understanding, the outer shape of the right disk cam 5344R in a state of being vertically inserted and fixed to the transmission shaft rod 5343 is shown by a solid line, and an overload is applied and the shaft collapses. The outline of the state is shown by an imaginary line.

FIG. 68A shows a state in which the tilting device 310 is driven by the drive motor 342 (see FIG. 62) from the second state and tilted down by an angle D2, and the tilting device 310 is in the middle of the operation of the drive motor 342. The player's hand holding the is illustrated.

As shown in FIG. 68A, when the player grips the tilting device 310 during the operation of the tilting device 310, the right disk cam 5344R is used regardless of whether the tilting device 310 is in the second state or not. The tip of the connecting pin 344d can be displaced in the circumferential direction of the right disk cam 5344R due to the shaft tilting of the arm member 345, thereby reducing the load generated between the arm member 345 and the right disk cam 5344R. Therefore, the load applied to the drive motor 342 can be reduced.

The matter described as the right disc cam 5344R also applies to the left disc cam 5344L.

As shown in FIGS. 67 (b) and 68 (b), according to the present embodiment, the drive motor 342 (see FIG. 62) operates while the player holds the tilting device 310, and an overload occurs. Then, the right disk cam 5344R tilts in the axial direction.

Therefore, by detecting the degree of tilting motion in the axial direction, it is possible to notice the occurrence of overload at an early stage. That is, for example, according to the configuration of the first embodiment, if the drive motor 342 is driven for a period during which the right disk cam 344R makes one rotation, the detection hole 344eR of the right disk cam 344R passes through the right side detection sensor 353R. However, when the player is holding the tilting device 310, the right disk cam 344R does not rotate even if the drive motor 342 is rotated, so that the detection hole 344eR does not pass through the right side detection sensor 353R and the right side detection sensor. Since the input to the 353R does not change, it is detected that an overload has occurred.

In this case, since it is necessary to rotate the right disk cam 344R by a predetermined angle before the occurrence of the overload is detected, there is a problem that the detection of the overload is delayed. there were.

On the other hand, according to the present embodiment, when the right disk cam 5344R is overloaded and the right disk cam 5344R is tilted in the axial direction (see FIG. 66B), the overload is applied. Occurrence can be detected. Therefore, the occurrence of overload can be detected at an early stage. As a detection method, for example, a method using a notification device E1 fixed to the engaging rib 344c between the support cylinder portion P1 and the engaging rib 344c is exemplified (illustrated by an imaginary line in FIG. 66A). ).

The notification device E1 is a detection device that outputs a signal when an object comes into contact with an input unit, and is arranged in pairs at a position where a straight line connecting a pair of holding arm portions A1 and an engaging rib 344c intersect. At the same time, the input portion is arranged so as to project toward the support cylinder portion P1 side. In the no-load state, the notification device E1 and the support cylinder portion P1 are separated from each other (see FIG. 65B), and in the overload state, the notification device E1 and the support cylinder portion P1 are in contact with each other (FIG. FIG. 66 (b)). Thereby, by determining the output from the notification device E1, it is possible to determine at an early stage whether or not the disk cam 5344 is overloaded.

Next, the operation device 6300 according to the sixth embodiment will be described with reference to FIGS. 69 to 73.

In the first embodiment, the case where the disc cam 344, the connecting pin 344d, and the engaging rib 344c are integrally formed has been described, but the operation device 6300 in the sixth embodiment includes the disc cam 344 and the engaging rib. The 344c is composed of a separate member, and is configured to be rotatable relative to each other. The same parts as those in the above-described embodiments are designated by the same reference numerals, and the description thereof will be omitted. First, the difference in configuration from the first embodiment will be described with reference to FIGS. 69 and 70.

FIG. 69 is an exploded front perspective view of the drive device 6340 according to the sixth embodiment, and FIG. 70 is a front exploded perspective view of the disk member 6344L1, the ring member 6344L2, and the second transmission member 6348 of the left disk cam 6344L. Is. The right disk cam 6344R is also different from the configuration of the first embodiment, but since the right disk cam 6344R is composed of a mirrored shape with respect to the left disk cam 6344L, the description of the left disk cam 6344L will be described. Only the right disk cam 6344R will be omitted.

As shown in FIG. 69, in this embodiment, the configuration of the left disk cam 6344L and the shape of the fixing member 6342a are different from those of the first embodiment, and a second transmission device 6348 is added.

The left disk cam 6344L has a circular rib 344b connecting pin 344d and a detection hole 344eL arranged in the same manner as in the first embodiment, and the disk member 6344L1 pivotally supported by the cylindrical member 343a and the disk member 6344L1. A ring member 6344L2 that is coaxially pivotally supported and rotates relative to a disk member 6344L1 is provided.

In the disk member 6344L1, the central shaft portion 344a of the first embodiment is arranged at the center position of the disk portion, and is radially outwardly separated from the outer peripheral portion of the circular rib 344b in an annular shape in the axial direction. The annular rib 6344f is provided so as to be convex along the ring rib 6344f.

The ring member 6344L2 has a ring body 6344g having the same outer peripheral diameter as the engaging rib 344c in the first embodiment and a ring shape having an inner peripheral diameter slightly larger than the outer peripheral diameter of the circular rib 344b, and a circle thereof. A lid plate portion 6344h that is arranged at the axial end of the ring body 6344g and covers the ring-shaped opening of the ring body 6344g, and the thickness increases from the lid plate portion 6344h to the opposite side of the ring body 6344g. 6344i is provided with a receiving gear tooth 6344i, which is formed in a thickened portion thereof and is arranged on the outer side in the radial direction.

Since the inner peripheral diameter of the annular main body 6344g is formed to be larger than the outer peripheral diameter of the circular rib 344b, the central shaft portion 344a is formed by fitting the annular main body 6344g to the circular rib 344b in the assembled state. The ring member 6344L2 is supported so as to be relatively rotatable around the center.

The end face of the annular body 6344g on the axial disc member 6344L1 side comes into contact with the annular rib 6344f. As a result, the contact area can be reduced and the frictional resistance can be reduced as compared with the case where the annular rib 6344f is not formed and the surface is in contact with the disk member 6344L1. Therefore, the relative rotation between the disk member 6344L1 and the ring member 6344L2 can be smoothly performed.

The receiving gear tooth 6344i is meshed with the deceleration transmission gear 6348c of the second transmission device 6348. Therefore, the ring member 6344L2 rotates based on the rotation of the second transmission device 6348. In this embodiment, the number of rotations of the ring member 6344L2 is three times the number of rotations of the disk member 6344L1 (while the ring member 6344L2 makes three rotations, the disk member 6344L1 makes one rotation. , The number of teeth of the second transmission gear 6348b, the reduction transmission gear 6348c, and the receiving gear tooth 6344i is set).

The second transmission device 6348 is a device that is rotatably supported by the fixing member 6342a along with the transmission shaft rod 343, and is an auxiliary pillar member 6348a arranged in a posture parallel to the cylindrical member 343a and its auxiliary pillar. A second transmission gear 6348b fixed to the member 6348a and meshed with the transmission gear 343b, and a deceleration transmission gear fixed to both ends of the auxiliary column member 6348 and meshed with the receiving gear teeth 6344i of the ring member 6344L2. Mainly includes 6348c.

With reference to FIGS. 71 to 73, it will be described that the ascending operation of the tilting device 310 after the fixing by the rotary claw member 347 is removed from the first state of the tilting device 310 is composed of a plurality of types.

71, 72, and 73 are cross-sectional views of the operating device 6300 in the line corresponding to the XXII-XXII line of FIG. 6 (a). Note that FIG. 71 shows a state similar to the state shown in FIG. 36, and FIG. 72 shows a posture in which the ring member 6344R2 makes one rotation in the backflip direction (arrow CW direction) from the state shown in FIG. 71 (correctly). A state in which the disk member 6344R1 is rotated 1/3 in the backward rotation direction (arrow CW direction) while being rotated in the reverse direction by the amount of the rotation after one rotation. Is illustrated. Further, FIG. 73 shows a state in which the ring member 6344L2 is rotated in the forward rotation direction (arrow CCW direction) by a predetermined angle from the state shown in FIG. 72, and the tilting device 310 is raised.

Here, when the ring member 6344R2 is rotated in the forward rotation direction (arrow CCW direction) from the state shown in FIG. 71 to release the fixation by the rotary claw member 347, the tilting device 310 is subjected to the urging force of the torsion spring 315. It rises instantly and reaches the second state (see FIG. 34).

In the operation device 300 according to the first embodiment, the arrival position when the tilting device 310 is lifted in an instant (without waiting for the rotation of the disk cam 344) by releasing the fixing by the rotary claw member 347 is in the second state. It was limited to the position where it was placed (see FIG. 34).

On the other hand, in the present embodiment, since the disk member 6344R1 and the ring member 6344R2 rotate relative to each other, the connecting pin 344d, which is the supporting portion of the arm member 345 connected to the tilting device 310, and the engaging rib 344c The relative relationship between the two can be changed, and the types of arrival positions of the tilting device 310 can be increased.

That is, when the fixing by the rotary claw member 347 is released from the state shown in FIG. 72, the tilting device 310 is instantaneously raised by the urging force of the torsion spring 315 and tilted downward by an angle D6 from the second state. (See FIG. 73). In this way, the tilting device 310 instantaneously (disk cam) is released from the state shown in FIG. 71 by the rotary claw member 347 and from the state shown in FIG. 72 by the rotary claw member 347. It can rise to (without waiting for the rotation of 344) and change the position to reach.

As a result, for example, when the tilting device 310 instantly rises from the first state and configures the gaming machine in a manner in which the expectation of the effect is changed by the difference in the height reached, the attention of the tilting device 310 is increased. Can be improved. In this case, it is not limited whether the expectation of the tilting device 310 to rise higher or the expectation of the tilting device 310 to rise lower is higher.

However, by keeping the ascending arrival position of the normal tilting device 310 low (see FIG. 73) and reaching the second state (see FIG. 34) when the expected degree is maximized, the expected degree is reached. The magnitude of the above can be associated with the magnitude of the amount of displacement that the player pushes the tilting device 310 into, so that the player can easily understand the difference in the degree of expectation due to the displacement of the tilting device 310.

In this case, since the player can be motivated to check to what position the tilting device 310 is raised, the player can watch the movement of the tilting device 310 until the operation timing of the tilting device 310. You can make it happen. Therefore, regardless of the effect mode of the tilting device 310, the method of the game in which the tilting device 310 is operated in a disorderly manner can be suppressed.

Next, the operation device 7300 according to the seventh embodiment will be described with reference to FIGS. 74 to 85.

In the first embodiment, the case where the disk cam 344, the connecting pin 344d, and the engaging rib 344c are integrally formed has been described, but in the operation device 7300 in the seventh embodiment, the disk cam 7344 is a disk member. The 7344R1 and the connecting pin 344d are arranged on separate members, and the separate members can form a fixed state in which they are fixed to each other and a sliding state in which they are relatively rotatable. The same parts as those in the above-described embodiments are designated by the same reference numerals, and the description thereof will be omitted. First, the features of the disc cam 7344 used as a substitute for the disc cam 344 in the first embodiment will be described with reference to FIGS. 74 and 75.

74 (a) is a front view of the right disk cam 7344R in the seventh embodiment, FIG. 74 (b) is a rear view of the right disk cam 7344R, and FIG. 75 (a) is FIG. 74. (A) is a cross-sectional view of the right disk cam 7344R in the LXXVa-LXXBa line, and FIG. 75 (b) is a partial side view of the right disk cam 7344R in the direction of arrow LXXVb of FIG. 74 (a). Since the right disk cam 7344L is composed of a mirrored symmetrical shape of the right disk cam 7344R, the description thereof will be omitted.

As shown in FIGS. 74 and 75, the right disk cam 7344R includes a disk member 7344R1 having a central shaft portion 344a into which the cylindrical member 343a (see FIG. 62) is inserted and fixed in the assembled state, and the disk member 7344R1. 7434R2, which is inserted along the axial direction from the opening side of the ring member, and the engaging portion 7630, which is made immovable in the radial direction of the disk member 7344R1 in the assembled state and fits into the equally divided recessed portion 7522 of the ring member 7344R2. Mainly includes an engaging member 7344R3 having the above.

The disk member 7344R1 is formed from a cup shape having a central shaft portion 344a at the center, and has a detection hole 344eR at a portion extending radially outward from the edge of the cup in a flange shape and an engaging rib. It is a member having a shape in which 344c is partially omitted (between the first overhanging portion 344c1 and the first retracting portion 344c2 is omitted).

The disk member 7344R supports the ring-shaped plate portion 7510 of the ring member 7344R2 on a surface in the assembled state, and has a first circular recessed portion 7410 which is a circular recessed portion centered on the central shaft portion 344a, and a first circular recessed portion 7410 thereof. 1 In the radial direction between the second circular recessed portion 7420, which is a circular recessed portion having a diameter smaller than that of the circular recessed portion 7410 and deeper in the axial direction, and the first overhanging portion 344c1 and the first retracting portion 344c2. An L-shaped insertion hole 7430 to be drilled and a fixing that is projected radially outward from the back side surface (outer peripheral side of the disk member 7344R1) of the second circular recessed portion 7420 in the vicinity of the insertion hole 7430. It mainly includes a protrusion 7440.

The insertion hole 7430 is a first elongated rectangular hole portion that is elongated along the axial direction of the disk member 7344R1 at a position deviated from the intermediate position between the first overhanging portion 344c1 and the first retracting portion 344c2. The second elongated hole 7432 which is a rectangular elongated hole portion extending from the bottom end of the elongated hole 7431 and the disk member 7344R1 of the first elongated hole 7431 along the circumferential direction of the disk member 7344R1. A return portion 7433 formed by projecting toward the second elongated hole 7432 side with the first elongated hole 7431 side of the lower end portion of the second elongated hole 7432 as a fulcrum.

The width direction (short direction) of the second long hole 7432 is smaller than the width direction (short direction) of the first long hole 7431, and the width of the engaging portion 7630 of the engaging member 7344R3. It is made smaller than the dimension in the direction (short direction).

The return portion 7433 is configured to be elastically deformable with the lower end portion (lower end portion in FIG. 75 (b)) of the second elongated hole 7432 as a fulcrum. Due to this elastic deformation, the return portion 7433 is formed so as to be movable outward of the second elongated hole 7432.

The fixing protrusion 7440 is inserted into the coil spring CS1 of the engaging member 7344R3, and is configured with a convex height sufficient to fix the position of the coil spring SC1.

Next, the ring member 7344R2 will be described with reference to FIG. 76. 76 (a) is a front view of the ring member 7344R2, FIG. 76 (b) is a rear view of the ring member 7344R2, and FIG. 76 (c) is a view in the direction of the arrow LXXVIc of FIG. 76 (a). It is a side view of the ring member 7344R2.

As shown in FIGS. 76 (a) to 76 (c), the ring member 7344R2 has a ring plate-shaped ring-shaped plate portion 7510 on which the connecting pin 344d is convexly provided, and an inner peripheral surface of the ring-shaped plate portion 7510. Mainly includes a thick portion 7520 extending in the thickness direction of the ring-shaped plate portion 7510 along the above and forming a star-shaped through hole in the central portion.

The ring-shaped plate portion 7510 has a plate thickness dimension equal to the recessed depth of the first circular recessed portion 7410, and an outer diameter dimension slightly smaller than the inner diameter dimension of the first circular recessed portion 7410. NS. Thereby, in the assembled state, it is possible to prevent the resistance of relative rotation from becoming excessive while aligning the axes of the ring member 7344R2 and the disk member 7344R1.

The thick portion 7520 has a length extending from the side surface of the ring-shaped plate portion 7510 so as to approach (do not interfere with) the second elongated hole 7432 in the assembled state (see FIG. 75 (a)), and have an outer peripheral diameter. However, it is slightly smaller than the inner peripheral diameter of the second circular recessed portion 7420. As a result, in the assembled state, the engaging member 7344R3 can be operated in the radial direction (vertical direction in FIG. 75A), and the relative rotation resistance between the ring member 7344R2 and the disk member 7344R1 is prevented from becoming excessive. can do.

The thick portion 7520 is recessed in the deformed through hole 7521 formed along the axial direction and the deformed through hole 7521 at equal intervals in the circumferential direction (divided into five equal parts in the present embodiment) in the radial direction outward. It mainly includes an equally divided recessed portion 7522 to be provided.

The deformed through hole 7521 has an inner peripheral shape that is arranged radially outside the engaging portion 7630 when the engaging member 7344R3, which will be described later, is pushed inward in the radial direction of the disk member 7344R1. It is composed.

77 (a) is a front view of the engaging member 7344R3, and FIG. 77 (b) is a side view of the engaging member 7344R3 in the direction of the arrow LXXVIIb of FIG. 77 (a).

As shown in FIGS. 77 (a) and 77 (b), the engaging member 7344R3 is outside the radial direction of the first overhanging portion 344c1 and the first retracting portion 344c2 in the assembled state (see FIG. 74 (b)). An arcuate plate portion 7610 arranged in the direction, an extension portion 7620 extending in the thickness direction from the back side end portion (right end portion in FIG. 77B) of the arcuate plate portion 7610, and an extension thereof. The engaging portion 7630 extending along the front-rear direction (left-right direction in FIG. 77B) from the extending tip of the portion 7620 and the engaging portion 7630 of the arcuate plate portion 7610 are arranged on the opposite side to the engaging portion 7630. It mainly includes a coil spring CS1 formed from a coil spring.

The arcuate plate portion 7610 includes a spring fixing protrusion 7611 which is a protrusion for fitting the coil spring CS1 at a position facing the tip end portion of the engaging portion 7630 on the inner peripheral side side surface.

The extension portion 7620 is a portion that is inserted into the second elongated hole 7432 in the assembled state, and when the extension portion 7620 is pushed inward in the radial direction in opposition to the elastic force of the coil spring CS1, the extension tip thereof becomes. It is composed of an extension length that projects inward from the inner peripheral surface of the ring member 7344R2.

The width direction of the engaging portion 7630 is slightly shorter than the width direction of the first elongated hole 7431, and the engaging portion 7630 is extended so as to pass through the deformed through hole 7521 of the thick portion 7520 in the assembled state. (See FIG. 75 (a)).

As will be described later, the engaging member 7344R3 has both a function as a member that receives a load from the releasing member 346 and is displaced, and a function of positioning the ring member 7344R2 with respect to the disc member 7344R1. Therefore, the number of members can be reduced.

A method of assembling the right disk cam 7344R will be described with reference to FIG. 78. 78 (a) is a front view of the right disk cam 7344R, and FIG. 78 (b) is a side view of the right disk cam 7344R in the direction of arrow LXXVIIIb of FIG. 78 (a). c) is a front view of the right disk cam 7344R, FIG. 78 (d) is a side view of the right disk cam 7344R in the direction of arrow LXXVIIId of FIG. 78 (c), and FIG. 78 (e) is a side view. It is a front view of the right disk cam 7344R, and FIG. 78 (f) is a side view of the right disk cam 7344R in the direction of the arrow LXXVIIIf of FIG. 78 (e).

In addition, in FIG. 78 (a), FIG. 78 (b), FIG. 78 (c) and FIG. 78 (d), the state in which only the engaging member 7344R3 is inserted into the disk member 7344R1 is shown, and FIG. 78 (e) ) And FIG. 78 (f) show a state in which the ring member 7344R2 and the engaging member 7344R3 are inserted into the disk member 7344R1. Further, in order to facilitate understanding, in FIGS. 78 (b), 78 (d) and 78 (f), the arcuate plate portion 7610 and the coil element pudding portion CS1 are not shown.

As an assembly method of the right disk cam 7344R, first, the engaging portion 7630 of the engaging member 7344R3 is inserted into the first elongated hole 7431 (see FIGS. 78 (a) and 78 (b)). As described above, the widthwise dimension of the second elongated hole 7432 is shorter than the widthwise dimension of the engaging portion 7630, so that the engaging portion 7630 is erroneously inserted into the second elongated hole 7432. Can be prevented. Therefore, it is possible to prevent an assembly error.

Next, the engaging member 7344R3 is slid along the extending direction of the second elongated hole 7432 until the position where the engaging portion 7630 and the fixing protrusion 7440 coincide with each other in the depth direction of FIG. 78 (d). Moving.

At the position after this movement, the fixing protrusion 7440 is inserted into the coil spring CS1, and the engaging member 7344R3 is suppressed from being displaced in the circumferential direction (left-right direction in FIG. 78 (d)) of the disk member 7344R1 and is engaged. The member 7344R3 can be held immovably in the radial direction of the disk member 7344R1.

Further, the engaging member 7344R3 is restricted from moving in the circumferential direction by the return portion 7433. This will be described. First, in a state where the engaging portion 7630 is inserted into the first elongated hole 7431, the return portion 7433 is driven to the outside of the second elongated hole 7432 (see FIG. 78 (b)). Next, when the engaging member 7344R3 is slid in the extending direction of the second elongated hole 7432, the vertical contact between the engaging member 7344R3 and the return portion 7433 is released, and the return portion 7433 is seconded by the elastic recovery force. It enters the inside of the elongated hole 7432 (see FIG. 78 (d)).

The tip of the return portion 7433 abuts on the extended portion 7620 of the engaging member 7344R3 in a state where it has entered the inside of the second elongated hole 7432, but the contact direction is the longitudinal direction of the return portion 7433 (deformation resistance is large). (See FIG. 78 (d)), the movement of the extension portion 7620 (movement to the right in FIG. 78 (f)) is suppressed. As a result, the movement of the engaging member 7344R3 in the circumferential direction can be restricted, so that the position of the engaging member 7344R3 can be prevented from being displaced during operation.

After holding the engaging member 7344R3 on the disc member 7344R1, the ring member 7344R2 is inserted from the opening side of the disc member 7344R1 with the engaging member 7344R3 pushed inward in the radial direction of the disc member 7344R1. do. By releasing the load from the engaging member 7344R3, the elastic force of the coil spring CS1 causes the engaging portion 7630 to move along the radial outward direction D7. Due to this movement, the engaging portion 7630 is accommodated in the equally divided recessed portion 7522 of the ring member 7344R2, whereby the ring member 7344R2 is fixed to the disk member 7344R1.

By the above-mentioned steps, the right disk cam 7344R can be easily assembled. The right disk cam 7344L is formed of a mirrored symmetrical shape of the right disk cam 7344R, and can be assembled in the same process as the right disk cam 7344R.

Next, with reference to FIGS. 79 to 81, the operation of the engaging member 7344R3 when the disk cam 7344 rotates in the backflip direction will be described. 79 (a), 79 (b), 80 (a), 80 (b) and 81 are partial cross-sectional views of the operating device 7300 in the line corresponding to the XXII-XXII line of FIG. In FIGS. 79 (a), 79 (b), 80 (a), 80 (b), and 81, the release member 7346, the rotary claw member 7347, and the disk cam 7344 are shown as the center, and others. Illustration of unnecessary parts is omitted.

The length of the guide slot 7347b of the rotary claw member 7347 in the present embodiment is different from that in the first embodiment. That is, as shown in FIG. 80A, the convex pin 346b is configured to be the end of movement at the ascending position when the engaging rib 344c abuts and passes from below.

The release member 7346 is different from the first embodiment in that the rear upper portion (upper right portion in FIG. 80 (a)) of the main body portion of the release member 7346 is obliquely scraped in order to minimize the interference with the engaging rib 344c.

In FIGS. 79 (a), 79 (b), 80 (a), 80 (b) and 81, the disk cam 7344 rotates in the backflip direction (clockwise in FIG. 79 (a)). Is illustrated in chronological order.

79 (a) shows a state in which the engaging member 7344R3 of the right disk cam 7344R abuts on the releasing member 7346 and the releasing member 7346 starts to rotate. FIG. 79 (b) shows FIG. 79 (a). The state in which the right disk cam 7344R is further rotated from the state shown in) is shown, and FIG. 80 (a) shows the state in which the engaging member 7344R3 is pushed into the disk member 7344R1 to the end. In (b), a state in which the disk member 7344R1 is further rotated in the backward rotation direction from the state shown in FIG. 80 (a) is shown, and in FIG. The state after the 7344R rotates in the backward rotation direction and the engaging member 7344R3 is separated from the releasing member 7346 is shown. In addition, in FIG. 79 (a), FIG. 79 (b), FIG. 80 (a) and FIG. 80 (b), the release member 7346 reaches the end of the range in which it can rotate relative to the rotary claw member 7347 ( (Small angle state) is shown.

As shown in FIG. 79 (a), the elastic force of the coil spring CS1 is set to be larger than the elastic force of the second spring SP2 in the state immediately after the engaging member 7344R3 and the releasing member 7346 start to come into contact with each other. Therefore, the engaging member 7344R3 is not pushed inward, and the state of projecting outward is maintained.

As shown in FIG. 79 (b), when the engaging portion 346d of the releasing member 7346 is in contact with the side surface of the outermost diameter of the engaging member 7344R3, the angle between the releasing member 7346 and the rotary claw member 7347 is small. Will be done.

In the present embodiment, the arcuate plate portion 7610 is formed in a small angle state in which the release member 7346 rotates in the forward rotation direction and the rotary claw member 7347 is pressed against the side surface of the insertion hole 321c of the lower frame member 320. The disk cam 7344 has a positional relationship in which the outer peripheral surface of the engaging member 7344R3 rubs against the release member 346 in a state where the inner peripheral surface and the first overhanging portion 344c1 and the first retracting portion 344c2 of the engaging rib 344c are in contact with each other. It is arranged (see FIG. 80 (a)).

That is, as shown in FIG. 80 (a), when the release member 7346 rotates toward the small angle state due to the rotation of the disk cam 7344 and becomes unable to rotate any more (small angle state), the release member A load is applied to the engaging member 7344R3 by pushing the engaging member 7344R3 inward in the radial direction of the disc cam 7344 from the 7346.

Then, as shown in FIG. 79 (b), in the state where the engaging member 7344R3 projects outward in the radial direction, the rotation in the backflip direction cannot be continued, and therefore, based on the rotation of the disk cam 7344. , The engaging member 7344R3 is pushed inward in the radial direction (see FIG. 80 (a)). In this pushed state, the engaging portion 7630 is arranged radially inward with respect to the minimum diameter portion of the deformed through hole 7521.

Therefore, the load in the circumferential direction is not transmitted to the ring member 7344R2 via the engaging portion 7630. Therefore, as shown in FIG. 80 (b), the disk member 7344R1 is rotated from the state shown in FIG. 80 (a). However, the ring member 7344R2 does not follow the rotation and maintains the posture.

Due to this deviation in the amount of rotation, the engaging portion 7630 moves from the originally arranged one equally divided recess 7522 to another different equally divided recess 7522, so that the disk member 7344R1 and the ring member 7344R2 The phase with and is rotated relative to each other by the amount of one recess (72 degrees).

After that, as shown in FIG. 81, when the right disk cam 7344R further rotates, the contact between the engaging member 7344R3 and the releasing member 7346 is released, so that the engaging member 7344R3 projects outward in the radial direction. Then, the engaging portion 7630 is again housed in the equally divided recessed portion 7522. In this process, the equally divided recessed portion 7522 in which the engaging portion 7630 is housed is displaced by one.

That is, by passing through the process shown in FIGS. 79 (a) to 81, the arrangement of the engaging rib 344c and the arrangement of the connecting pin 344d arranged on the ring member 7344R2 are equally divided into the recessed portion 7522. It can be relatively shifted by the arrangement interval (72 degrees) of the recessed portion.

With reference to FIG. 82, the operation of the engaging member 7344R3 when the disk cam 7344 rotates in the forward rotation direction will be described. 82 (a), 82 (b), 83 (a) and 83 (b) are partial cross-sectional views of the operating device 7300 in the line corresponding to the XXII-XXII line of FIG. In FIG. 82, the release member 7346, the rotary claw member 7347, and the disk cam 7344 are shown as the center, and the other unnecessary parts are not shown.

In FIGS. 82 (a) to 83 (b), how the disk cam 7344 rotates in the forward rotation direction (counterclockwise direction in FIG. 82 (a)) is illustrated in chronological order. FIG. 82 (a) shows a state immediately before the release member 7346 and the engagement member 7344R3 of the right disk cam 7344R come into contact with each other, and in FIG. 82 (b), the engagement member 7344R3 is above the release member 7346. The state in which the descent is started by being abutted from the above is shown, and in FIG. 83 (a), the state in which the disk cam 7344 is further rotated in the forward rotation direction from the state shown in FIG. 82 (b) is shown. In (b), the state after the release member 7346 and the engagement member 7344R are separated from each other is shown.

As shown in FIGS. 82 (a) to 83 (b), the disc cam 7344 rotates in the forward rotation direction, so that the release member 7346 and the rotary claw member 7347 move in the backward rotation direction (clock 82 (a)). When rotating in the clockwise direction), there is no member that restricts the movement of the release member 7346 and the rotary claw member 7347, and the release member 7346 and the rotary claw member 7347 apply a load in the forward rotation direction by the elastic force of the first spring SP1. Will only be.

Therefore, a load that pushes the engaging member 7344R3 inward in the radial direction is not generated, and the engaging member 7344R3 is radially outward from the time when the engaging member 7344R3 comes into contact with the releasing member 7346 until the engagement member 7344R3 is separated. Keep overhanging. Therefore, when the disk cam 7344 is rotated in the forward rotation direction, it is possible to prevent the disk member 7344R1 and the ring member 7344R2 from rotating relative to each other.

From these configurations, by switching the rotation direction of the disk cam 7344, it is possible to switch whether or not the disk member 7344R1 and the ring member 7344R2 rotate relative to each other. Therefore, in the rotation direction in which relative rotation does not occur (see FIGS. 82 and 83), it is possible to repeatedly tilt the tilting device 310 with the same tilting width as in the first embodiment. In the rotation direction that causes relative rotation (see FIGS. 79, 80, and 81), the tilt width of the tilt device 310 can be changed, unlike the first embodiment.

Further, in the present embodiment, the rotation direction of the disk member 7344R1 that relatively rotates the disk member 744R1 and the ring member 7344R2 is opposite to the direction in which the fixing by the rotating claw member 7347 is released (the direction in which the fixing is not released). Since they match, the disk member 7344R1 and the ring member 7344R2 can be relatively rotated while the tilting device 310 is maintained in the first state (see FIG. 84) (the posture is maintained constant).

As a result, a state that is not noticed by the player (a state in which the tilting device 310 is stopped) is used as a state for changing the relative posture of the disk member 7344R1 and the ring member 7344R2 in a place that is not visible to the player. be able to.

With reference to FIGS. 84 and 85, it will be described that, according to the present embodiment, it is possible to form a plurality of types of modes in which the tilting device 310 is moved up from the first state. 84 and 85 are cross-sectional views of the operating device 7300 in the line corresponding to the XXII-XXII line of FIG. In FIG. 84, by releasing the fixing by the rotary claw member 347, the tilting device 310 is immediately moved from the first state to the second state shown in FIG. 7B (without rotating the disk cam 7344). ) A state in which the ring member 7344R2 is fixed to the disk member 7344R1 in a phase relationship that can be displaced is shown. , A state in which the disc member 7344R1 is rotated relative to the equally divided recessed portion 7522 by one portion is shown. In both FIGS. 84 and 85, the second overhanging portion 344c3 hits the engaging portion 346d. The state of contact is shown.

As shown in FIGS. 84 and 85, according to the present embodiment, by releasing the fixing by the rotating claw member 347 from the first state, the tilting device 310 immediately (without rotating the disk cam 7344R2). The range of movement can be changed.

That is, when the fixing is released by rotating the rotary claw member 347 from the state shown in FIG. 84, the tilting device 310 moves to the second state (a state in which the tilting device 310 has moved to the uppermost end of the moving range).

On the other hand, when the fixing is released by rotating the rotary claw member 347 from the state shown in FIG. 85, the position of the connecting pin 344d is displaced to the rear lower side than the position shown in FIG. 2 Move to a state where it sinks below the state.

Therefore, by releasing the fixing by the rotating claw member 347, the position where the tilting device 310 immediately reaches (without rotating the disk cam 7344) by the ascending operation can be changed from the first state. As a result, it is possible to increase the types of effects produced by the operation of the tilting device 310, and to improve the attention of the operating device 7300 as an effect device.

Although the present invention has been described above based on the above-described embodiment, the present invention is not limited to the above-described embodiment, and it is easy to make various modifications and improvements within a range that does not deviate from the gist of the present invention. It can be inferred.

In each of the above embodiments, a part or all of the configurations in one embodiment may be combined with or replaced with a part or all of the configurations in another embodiment to form another embodiment.

In the first embodiment, the case where the tilting device 310 is pushed down is described, but the present invention is not necessarily limited to this. For example, a state in which the tilting device 310 hangs downward is set as the initial position, and the tilting device 310 may be pushed up. In this case, since the force for returning the tilting device 310 to the initial position can be provided by gravity, the torsion spring 315 can be eliminated.

In the first embodiment, the case where the voice coil motor 352 is driven after the tilting device 310 has moved to the push-in end is described, but the present invention is not necessarily limited to this. For example, the voice coil motor 352 may be driven in advance when the tilting device 310 is in the first state. In this case, the load required to push the tilting device 310 from the first state can be increased, and the change in the load can be used for the effect (for example, the effect of "the button that cannot be pushed" can be performed. can).

In this case, even if the voice coil motor 352 moves to the end of the operation (the end of the overhanging operation), the voice coil motor 352 has a dimensional relationship in which a slight gap is generated between the voice coil motor 352 and the lower frame member 320. And the lower frame member 320 are preferably arranged. As a result, it is possible to suppress the generation of an impact sound of collision with the lower frame member 320 during the operation of the voice coil motor 352. Therefore, it is possible to prevent the player from noticing that the voice coil motor 352 is overhanging in advance, and it is possible to make the player notice that the tilting device 310 is in the "non-pushable button" state only after the pushing operation. can.

In the first embodiment, the case where the engaging rib 344c of the disk cam 344 and the connecting pin 344d are relatively fixed has been described, but the present invention is not necessarily limited to this. For example, the engaging rib 344c may be formed of a separate member and may be configured so as to rotate relative to the disc cam 344. In this case, for example, since the position of the connecting pin 344d in the state where the first overhanging portion 344c1 and the engaging portion 346d are in contact with each other can be changed, the engaging rib 344c is rotated in the forward rotation direction from that state. Immediately after changing the posture of the rotary claw member 347, the degree to which the tilting device 310 rises can be changed. Therefore, it is possible to form more operating states of the tilting operation of the tilting device 310 than in the first embodiment.

Further, the operating state of the tilting device 310 can be sequentially switched (the ascending end can be sequentially switched) depending on the driving mode in which the disk cam 344 is continuously rotated in the forward rotation direction. As a result, by operating the drive motor 342 in one direction, it is possible to perform an effect in a complicated operation mode in which the ascending position of the tilting device 310 is sequentially switched while suppressing deterioration of the drive motor 342.

In the third embodiment, the case where the operation timing of the voice coil motor 352 that applies the driving force to the tilting device 310 is controlled by the operating speed of the tilting device 310 and the direction of operation has been described, but the present invention is not necessarily limited to this. It's not a thing. For example, the drive mode of the drive motor 5411 that rotationally drives the weight member 5412 may be controlled by the operating speed of the tilting device 310 or the direction of operation. For example, the drive motor 5411 is fixed in a posture in which the center of gravity of the weight member 5412 is arranged above the rotation axis until the tilting device 310 reaches the pushing end (while the tilting device 310 is in the descending operation), and the tilting device 310 pushes in. The rotation operation of the drive motor 5411 may be started immediately after reaching the end and immediately before starting to move upward. In this case, while pushing back when the tilting device 310 is repeatedly hit, the repulsive force that pushes back the tilting device 310 can be reduced, while the repulsive force that pushes back the tilting device 310 at the start of the upward operation of the tilting device 310 can be increased. ..

In the fifth embodiment, the case where the accommodating member 5430 is fixed to the bottom plate portion 5321 has been described, but the present invention is not necessarily limited to this. For example, the accommodating member 5430 may be fixed to the tilting device 310, and the vibrating device 5400 may be operated inside the accommodating member 5430. When fixing the accommodating member 5430 to the tilting device 310, for example, when the convex leg portion 5424 is arranged on the side facing the bottom plate portion 5321 and the tilting device 310 is moved to the lower pushing end, the convex leg By adopting a mode in which the portion 5424 is pressed against the bottom plate portion 5321, the shape of the flexible member 5420 in the vibrating device 5400 is changed, and whether or not the weight member 5412 can abut on the accommodating member 5430 is switched. good.

In this case, the flexible member 5420 arranged inside the accommodating member 5430 moves in conjunction with the tilting operation of the tilting device 310, and at this time, the shape of the flexible member 5420 changes. The degree of change in the shape of the flexible member 5420 changes in conjunction with the magnitude of the tilting speed when the tilting device 310 is operated. Therefore, by operating the tilting device 310 at a predetermined speed or higher, the flexible member 5420 The amount of deformation of the weight member 5412 can be increased to form a state in which the weight member 5412 is in contact with the accommodating member 5430. That is, not only when the tilting device 310 is pushed to the end, but also when the tilting device 310 is operated at high speed, the player can feel the vibration, so that the player can operate the tilting device 310. It is possible to increase the variation of the production of.

For example, when the player is allowed to operate the tilting device 310, a display such as "press the button." Is displayed on the third symbol display device 81, but "press the button. Push it in at high speed and feel vibration." By displaying such as "Great chance.", It is possible to give the player an effect of designating how to press the button (tilting device 310). In this case, by setting whether or not the player has pressed the button (tilting device 310) with the specified pressing method as a condition for transmitting the vibration to the player, the button (tilting device 310) can be pressed with the specified pressing method. The motivation of the player for the operation can be increased, and the operation of the button (tilting device 310) can be prevented from becoming monotonous.

Regarding the degree of change in the shape of the flexible member 5420, the degree of pushing speed of the tilting device 310 and the magnitude relationship may be reversed. That is, when the tilting speed of the tilting device 310 is slow, the amount of deformation of the flexible member 5420 becomes large, and the weight member 5412 and the accommodating member 5430 may be formed in such a manner that they can come into contact with each other. In this case, a small pushing speed of the tilting device 310 can be a condition for transmitting the vibration generated from the vibrating device 5400 to the player, and the player is recommended to slow down the pushing speed of the tilting device 310. can do. As a result, it is possible to prevent the player from pushing the tilting device 310 by force and operating it, and it is possible to prevent a failure that occurs when the tilting device 310 is pushed by force.

In the fifth embodiment, the case where the player can feel the vibration generated from the vibrating device 5400 by pushing the tilting device 310 has been described, but the present invention is not necessarily limited to this. For example, the weight member 5412 of the vibrating device 5400 is arranged so as to be able to come into contact with the accommodating member 5430 when the tilting device 310 is not pushed in, while the weight member 310 is pushed to the end of movement. The 5412 may be formed in such a manner that the 5412 may be arranged so as not to be in contact with the accommodating member 5430. In this case, while the tilting device 310 can be transmitted to the player in a state where the tilting device 310 is not operated to make the effect lively, the player can change the effect mode (expected) by stopping the vibration when the tilting device 310 is pushed in. Since it is possible to recognize (difference in degree), it is possible to produce a premier feeling that only the player who is playing this machine can feel the change in the production mode, excluding the surrounding players. can.

As a variation of the effect, when the player pushes in the tilting device 310, the weight member 5412 and the accommodating member 5430 cannot be brought into contact with each other, and the weight member 5412 and the accommodating member 5430 continue. It is desired to generate both a case where the arrangement is possible to abut the same, and this can be realized by changing the operation mode of the weight member 5412. For example, two different cases can occur due to the difference in the rotation direction of the weight member 5412.

In the fifth embodiment, the case where the disc cam 5344 is deformed by tilting the shaft and the disc cam 5344 and the release member 346 come into contact with each other to generate a frictional force has been described, but the present invention is not necessarily limited to this. No. For example, the plate portion in which the shaft support hole 341b of the main body member 341 is bored partially projects in a direction close to the disc cam 5344, and is configured to come into contact with the disc cam 5344 when the shaft is tilted and deformed. You may. In this case, since the main body member 341 is not an operating part, a large frictional force generated between the disc cam 5344 and the movable release member 346 is secured as compared with the case where the disc cam 5344 and the movable release member 346 come into contact with each other. be able to. Therefore, the load applied to the arm member 345 that connects the disc cam 5344 and the tilting device 310 can be sufficiently reduced.

The present invention may be implemented in a pachinko machine or the like of a type different from each of the above embodiments. For example, once a jackpot is hit, a pachinko machine (commonly known as a two-time right item, a three-time right item) that raises the expected value of the jackpot until multiple times (for example, two or three times) a big hit state occurs. It may be carried out as). Further, after the jackpot symbol is displayed, it may be implemented as a pachinko machine that generates a special game that gives a player a predetermined game value on the condition that a ball is won in a predetermined area. Further, it may be carried out on a pachinko machine that has a winning device having a special area such as a V zone and is in a special gaming state on the condition that a ball is won in the special area. Further, in addition to the pachinko machine, it may be implemented as various game machines such as a pachinko machine, a sparrow ball, a slot machine, a so-called pachinko machine and a slot machine.

In the slot machine, for example, the symbol is changed by operating the operation lever in a state where a coin is inserted to determine the symbol effective line, and the symbol is stopped and confirmed by operating the stop button. It is a thing. Therefore, the basic concept of the slot machine is "provided with a display device that displays the identification information in a variable manner after displaying the identification information string composed of a plurality of identification information in a variable manner, and is caused by the operation of the starting operation means (for example, the operation lever). The variable display of the identification information is started, and the variable display of the identification information is stopped and confirmed and displayed due to the operation of the stop operation means (for example, the stop button) or after a predetermined time has elapsed, and the stop is stopped. It becomes a "slot machine that generates a special game that gives a player a predetermined game value on the condition that the combination of time identification information is specific". In this case, the game medium is represented by coins, medals, etc. Take as an example.

Further, as a specific example of a gaming machine in which a pachinko machine and a slot machine are fused, a display device for variably displaying a symbol sequence composed of a plurality of symbols and then confirming the symbol is provided, and a handle for launching a ball is provided. Some are not. In this case, after a predetermined amount of balls are thrown in based on a predetermined operation (button operation), the symbol variation is started, for example, due to the operation of the operation lever, and for example, due to the operation of the stop button or a predetermined amount. As time elapses, the fluctuation of the symbol is stopped, and a special game is generated that gives the player a predetermined game value on the condition that the confirmed symbol at the time of the stop is a so-called jackpot symbol, and the player is given a predetermined game value. Is for paying out a large amount of balls to the lower saucer. If such a game machine is used instead of a slot machine, only the ball can be treated as a game value in the game hall, which is a game value seen in the current game hall where pachinko machines and slot machines are mixed. Problems such as the burden on equipment due to the separate handling of medals and balls and restrictions on the locations where game machines are installed can be solved.

The concepts of various inventions included in the above-described embodiments in addition to the gaming machine of the present invention are shown below.

<Point where the player's pushing direction is from the back to the front>
In an operating device having an operating means for the player to push in, the operating device is arranged at a first state in a normal state and a position where the operating means projects from the first state with respect to the player. The two states can be configured, and the operating means is provided with an urging means for urging the operating means from the first state to the second state, and the pushing direction of the operating means in the second state is from the back side to the front side for the player. A gaming machine A1 characterized in that the direction is directed toward the side.

In a gaming machine such as a pachinko machine, there is a gaming machine in which an operating means that can be operated by a player moves back and forth between a first position and a second position (for example, Japanese Patent Application Laid-Open No. 2014-144218). See). However, in the above-mentioned conventional gaming machine, since the effect is performed in a manner that raises the expectation of the big hit to the player at the advance position, the player can easily operate the operating means at the advance position with a large acceleration. , It was necessary to design the strength of the operating means to be high. In this case, there is a problem that the operating means becomes heavy as a whole and the driving means for driving the operating means becomes large.

On the other hand, according to the gaming machine A1, when the pushing operation is performed in the second state, the pushing direction of the operating means is the direction from the back side to the front side for the player, so that the player moves straight up and down. Then, the momentum of pushing can be released by causing the part that cannot be operated as a slip between the player's hand and the operating means.

Also, from the player's playing posture, when the operating means is pushed around the shoulders and elbows, it becomes difficult to apply force toward the front, so the force applied by the player to the operating means should be naturally weakened. Can be done.

In the gaming machine A1, the operating device is rotatable about a shaft rod arranged on the back side of the player, is configured to be tilted up and down around the shaft rod, and has the operating means. A gaming machine A2 comprising tilting means, the tilting means arranging the operating means in the second state toward the opposite direction of the player.

According to the gaming machine A2, the tilting means having the operating means is configured to rotate, and the operating means are arranged in the opposite direction of the player in the second state, so that the game is played in the second state. It is possible to prevent a person from hitting an operating means.

Further, by placing the hand near the shaft rod and tilting the hand with the position as a fulcrum, the operating means can be easily pushed in, so that a new pushing operation method in which the acceleration of pushing is hard to be attached can be provided. , It is possible to prevent the operating device from being damaged by the pushing operation of the player.

The new pushing operation method is, for example, to place the outer side surface of the left little finger near the shaft rod and place the hand near the operating means with the palm raised in the vertical direction, and then turn the thumb side toward the operating means. Examples include a method of operating by tilting the palm, and a method of dropping the palm toward the operating means from a state in which the tip of the middle finger is placed near the shaft rod and the palm is arranged so as to face the operating means. Will be done.

In the gaming machine A1 or A2, the gaming machine A3 is characterized in that, in the first state, the direction of the pushing operation of the operating means is the vertical direction.

According to the gaming machine A3, in addition to the effect of the gaming machine A1 or A2, the direction of the pushing operation of the operating means in the first state is the vertical direction, so that the second state is ensured while ensuring the operability in the first state. It is possible to prevent destruction by pushing in the state.

In the gaming machine A3, the operating device includes a driving means for generating the driving force for the automatic operation while the operating means is configured to be automatically operable, and the driving force of the driving device is pushed by the player. The gaming machine A4 is characterized in that it acts in the direction in which it acts and does not act in the opposite direction.

According to the gaming machine A4, in addition to the effect of the gaming machine A3, the driving force of the driving means for automatically operating the operating device acts only in the pushing operation direction, so that the driving force is in the direction opposite to the operating direction of the player. Can be prevented from acting. Therefore, it is possible to prevent the driving means from being damaged by the operation of the player.

For example, by adopting a configuration in which only the button can be pushed in, it is possible to prevent the driving means from being pulled by the player in the opposite direction when performing the operation of retracting the button and receiving a high load on the driving means.

In the gaming machine A4, a maintenance state for maintaining the operation device in the first state or the second state can be formed, and a maintenance means for operating by the drive means is provided, and the drive means is said to be via an eccentric portion. The operating means has a rotating means for transmitting a driving force, and the rotating means can change the phase between the first phase and the second phase different from the first phase while keeping the maintaining means in the maintenance state. In the first phase and the second phase, the range in which the operating means can move is changed when the maintenance state is released, and in both the first phase and the second phase, the same rotation causes the operation means to move. A gaming machine A5 configured to be able to release the maintenance state.

According to the gaming machine A5, in addition to the effect of the gaming machine A4, the phase of the driving means can be changed while the maintaining means is kept in the maintenance state, and the movement for releasing the maintenance state is rotated in the phase after the change. By using the means, the movement width in which the operating device moves can be changed by the urging means. Therefore, it is possible to configure a plurality of operation modes by the urging means.

In the gaming machine A5, the maintenance means is movable in the urging direction of the urging means in the maintenance state, and the moving speed of the maintaining means increases or decreases according to the rotation speed of the rotating means. The gaming machine A6 configured in such a manner that the operating means moves following the movement of the maintaining means.

According to the gaming machine A6, in addition to the effect of the gaming machine A5, the movement of the urging means in the direction of the urging force is caused only by the urging force, so that the mode of movement is limited to one. Since it is possible to add a movement mode of moving following the maintenance means to the operation means, it is possible to increase the types of movement modes of the operation means. As a result, the degree of attention of the operating device can be improved.

In any of the gaming machines A1 to A6, a light emitting means that is arranged inside the operating device and irradiates light toward the player is provided, and the second state is compared with the first state. However, from the player's point of view, the gaming machine A7 is characterized in that the area of the operating means is reduced and the irradiation range of the light emitted by the light emitting means is expanded.

According to the gaming machine A7, in addition to the effect of any of the gaming machines A1 to A6, a light emitting means is provided, and the second state is irradiated by the light emitting means from the player's viewpoint as compared with the first state. Since the irradiation range of the light to be emitted is expanded and the area of the operating means is reduced, the player can pay attention to the light and the effect of the effect can be improved, and it is difficult to press the operating means without aiming. It is possible to reduce the power of the player at the time of operation.

In the gaming machine A7, the operating means is made of a non-transparent material, and the area of the exposed portion of the light emitting means changes as the operating means moves away from the display means in close proximity to the display means. A featured gaming machine A8.

According to the gaming machine A8, in addition to the effect of the gaming machine A7, the operating means is made of a non-transparent material, and the operating means moves away from the display means in close proximity to the display means. Since the area of the exposed portion of the above is changed, it is possible to prevent the emitted light from being reflected on the display means and making the image of the display means difficult to see.

<Points where the repulsive force during normal times is small while making it possible to respond to repeated hits>
In an operating device having an operating means capable of allowing a player to operate up to the terminal position, the first state and the second state in which the range of motion of the operation up to the terminal position is wider than that of the first state. A game in which a first driving means for generating a driving force for moving from a second state to a first state is provided, and an urging means for generating an urging force for moving from a first state to a second state is provided. The gaming machine B1 is characterized by comprising a second driving means for generating a driving force for moving the operating means from the first state to the second state according to the operation of the player.

In a gaming machine such as a pachinko machine, there is a gaming machine in which an operating means that can be operated by a player moves back and forth between a first position and a second position (for example, Japanese Patent Application Laid-Open No. 2014-144218). See). However, in the above-mentioned conventional gaming machine, the force for returning the operating means to the initial position is generated by the spring, and the driving motor automatically operates the operating means. However, it is better to lower the elastic constant of the spring to drive the driving motor. However, in that case, the return of the operating means is delayed, and when the player's operation is fast, the operating means does not follow the player's operation, which makes it difficult for the player to perform the continuous striking operation. There was a problem.

According to the gaming machine B1, by setting the urging force to be weak, the driving force of the motor can be reduced when the operating means is moved by the first driving means, while the driving force of the motor can be reduced, but when it is desired to speed up the return of the operating means, the first is By pushing back the operating means with the two driving means, the return can be made faster, so that the player can enjoy the continuous striking operation.

The gaming machine B1 is provided with a continuous striking discriminating means for determining whether or not a continuous striking operation is performed based on a sensor detection value of a stroke operating means within a predetermined time, and a second driving means is provided based on the detection value of the continuous striking discriminating means. A gaming machine B2 characterized in that it determines whether or not to drive it.

According to the gaming machine B2, since it is determined whether or not to drive the second driving means based on the detection value of the continuous hitting determination means, the player does not perform the continuous hitting operation (for example, a single push operation or a long press). It is possible to prevent the player from feeling the load of pushing his / her hand back by operating the second driving means even when the player is performing an operation or the like.

In the gaming machine B2, the terminal detecting means for detecting the position of the operating means and detecting whether or not the operating means is arranged at the terminal position, and whether or not the operating means is arranged at a position changed by a predetermined amount from the terminal position. The moving direction determining means is provided with the positional difference detecting means for detecting and the moving direction determining means for determining the moving direction of the operating means from the time relationship between the detected value of the terminal detecting means and the detected value of the positional difference detecting means. The gaming machine B3, characterized in that the second driving means is driven when the direction of movement determined by the above is the direction of returning from the push-in end to the first state.

According to the gaming machine B3, in addition to the effect of the gaming machine B2, when the direction of movement determined by the moving direction determining means is the direction of returning from the pushing end to the first state, that is, the player's hand is from the button. Since the second driving means is driven at the timing of moving in the direction of separation, it is possible to generate a load that pushes back the operating means in a form synchronized with the movement of the player.

Therefore, it is possible to prevent the second driving device from operating in the direction opposite to the moving direction of the player's hand and applying a high load to the player's hand.

In any of the gaming machines B1 to B3, the second driving means is composed of a voice coil motor that vibrates and displaces along the direction connecting the first state and the second state of the operating means. Game machine B4 to play.

According to the gaming machine B4, in addition to the effect of any of the gaming machines B1 to B3, the vibration displacement of the voice coil motor can be effectively used to generate a driving force for moving the operating means.

In any of the gaming machines B1 to B3, a support frame for supporting the operating means is provided, and the second driving means elastically supports a drive motor for rotating the eccentric weight and the drive motor on the support frame. A mode in which the supporting means is provided with, and the driving force for moving the operating means from the position of the first state to the position of the second state increases as the operating means approaches the terminal position. The gaming machine B5 is characterized in that the eccentric weight comes into contact with the support frame in a state where the operating means is arranged at the terminal position to generate a driving force.

According to the gaming machine B5, in addition to the effect of any of the gaming machines B1 to B3, the driving force by the second driving means is generated by the driving force generated by the supporting means and the contact between the eccentric weight and the support frame. By generating it separately from the driving force, it is possible to adjust the driving force given to the operating means while maintaining the rotation of the driving motor. At this time, it is not necessary to control the start or stop of the rotation of the drive motor, and the rotation of the drive motor can be maintained while being maintained.

In the gaming machine B5, the eccentric weight moves close to the support frame in the moving direction of the operation means based on the operation means being arranged at the terminal position, and comes into contact with the support frame. A game machine B6 characterized by.

According to the gaming machine B6, in addition to the effect of the gaming machine B5, the eccentric weight moves close to the support frame in the moving direction of the operating means and comes into contact with the support frame, so that the repulsive force generated by the contact is utilized. Then, the drive motor can be moved in the direction away from the support frame in the moving direction of the operating means. As a result, the support means for supporting the drive motor moves in a direction away from the support frame (direction closer to the operation means), so that the driving force for pushing back the operation means can be further increased.

<Points of using VCM as a braking device and vibration effecting device>
A detection sensor for detecting a position near the terminal position of the operating means is provided, and the detection sensor is composed of a plurality of sensors, a measuring means for measuring the speed of the operating means from the detection interval of the detection sensor, and the measuring means thereof. A threshold determination means for determining whether or not the measured value measured by the above is equal to or higher than a predetermined threshold, and a repulsion means for generating a driving force in the direction opposite to the pushing direction of the operating means are provided. When the measured threshold value is equal to or higher than a predetermined threshold value, the driving force generated by the repulsive means increases as compared with the case where the threshold value measured by the threshold value determination means is equal to or lower than the predetermined threshold value. Characteristic gaming machine C1.

In a gaming machine such as a pachinko machine, there is a gaming machine in which an operating means that can be operated by a player moves back and forth between a first position and a second position (for example, Japanese Patent Application Laid-Open No. 2014-144218). See). However, in the above-mentioned conventional gaming machine, if the player emphasizes the ability to operate lightly, the operation resistance becomes low and the operation means may be damaged by the operation of the player. Although the speed can be reduced and the possibility of damage to the operating means can be reduced, there is a problem that the force required for the player's operation increases and the operation of the operating means becomes a burden for the weak player. ..

On the other hand, according to the gaming machine C1, the threshold value determining means determines whether the speed of the operating means is equal to or higher than the threshold value, and if the speed is equal to or higher than the threshold value, the driving force generated by the repulsive means is increased. Therefore, the operation resistance can be reduced when the speed of the operation means is equal to or less than the threshold value, and the operation means can be decelerated only when necessary. Therefore, the repulsive means can improve the operability and prevent the destruction.

In the game machine C1, the repulsive means includes a voice coil motor that generates a driving force in the direction opposite to the pushing direction of the operating means, and the threshold measured by the threshold determining means is equal to or higher than a predetermined threshold. The voice coil motor is pushed out to an extended position, and the voice coil motor is driven in advance before the operating means is arranged at a position where it can come into contact with the voice coil motor. Game machine C2 to play.

According to the game machine C2, in addition to the effect of the game machine C1, the voice coil motor can be driven and controlled to decelerate the operating means, and the operating means is arranged at a position where it can come into contact with the voice coil motor. By driving the voice coil motor before the operation, the impact generated between the operating means and the voice coil motor can be suppressed.

The gaming machine C3 is characterized in that, after the operating means and the voice coil motor come into contact with each other, the gaming machine C1 or C2 is controlled to increase the current flowing through the voice coil motor.

According to the game machine C3, in addition to the effect of the game machine C1 or C2, the operation means is controlled by increasing the current flowing through the voice coil motor after the operation means and the voice coil motor come into contact with each other. It is possible to gradually improve the degree of braking of the operating means while suppressing the occurrence of a large load at the moment of contact with the voice coil motor, and it is possible to reduce the discomfort felt by the player during operation.

In the gaming machine C1, the repulsing means is arranged so as to be in contact with the operating means, and a driving force corresponding to a deformation amount deformed by the movement of the operating means is generated by spring elasticity. ..

According to the gaming machine C4, in addition to the effect of the gaming machine C1, the repulsive means generates a driving force corresponding to the amount of deformation by spring elasticity, so that the driving force is not delayed even when the moving speed of the operating means is high. Can be generated.

In the gaming machine C4, the repulsion means is compared when the value measured by the threshold value determination means is equal to or more than a predetermined threshold value and when the value measured by the threshold value determination means is equal to or less than a predetermined threshold value. The gaming machine C5 is characterized in that the movable region of the end portion of the repulsive means and the end portion on the opposite side of the operating means that comes into contact with the operating means is narrowed.

According to the gaming machine C5, in addition to the effect of the gaming machine C4, the movable area of the end of the repulsive means on the opposite side of the side that comes into contact with the operating means is narrowed, so that the operating means can be operated. When the speed is high, the elastic force generated by the repulsive means can be increased.

<Prevents damage to the driving means by blocking the transmission of driving force with a clutch>
In an operating device having an operating means operated by a player, the operating device includes a driving means for generating a driving force for operating the operating means, a transmitting means for transmitting the driving force of the driving means to the operating means, and a transmission means for transmitting the driving force of the driving means to the operating means. A release means for releasing the transmission of the driving force is provided, and the release means of the driving force when the load generated between the driving means and the operating means via the transmitting means becomes a predetermined amount or more. A gaming machine D1 characterized by canceling transmission.

In a gaming machine such as a pachinko machine, there is a gaming machine in which an operating means that can be operated by a player moves back and forth between a first position and a second position (for example, Japanese Patent Application Laid-Open No. 2014-144218). See). However, in the above-mentioned conventional gaming machine, when the operating means is automatically operated for the purpose of production, if the operating means is operated during the automatic operation, a large load may be generated on the drive system. There was a problem.

On the other hand, according to the gaming machine D1, the releasing means is configured to release the transmission of the driving force when the load generated between the driving means and the operating means via the transmitting means becomes a predetermined amount or more. Therefore, even if the player operates the operating means when the operating means is automatically operated, the transmission of the load to the drive system is canceled (disconnected), and the load applied to the drive system can be suppressed. can.

In the gaming machine D1, the driving means is capable of driving in the first direction and driving in the second direction opposite to the first direction, and is driving in the first direction. The gaming machine D2 is characterized in that the release by the release means functions regardless of whether the drive is in the second direction.

Here, when it is determined whether or not the transmission of the driving force can be canceled depending on the operating direction of the driving means, the operating means is operated by the player when the driving means is driven in the operating direction in which the transmission of the driving force cannot be canceled. Then, a large load may be generated on the drive means. Therefore, the degree of freedom in the production when the operation means is operated to produce the production is reduced.

When the button is driven between the first position and the second position, the lock member that locks the button is moved in the release direction or in the release direction depending on whether the drive means rotates in the forward direction or in the reverse direction. Switch whether to move in the opposite direction. In this case, it is possible to create two modes of button operation (two patterns, a release pattern and a non-release pattern), but it is necessary that the driving force is interrupted in both of them.

On the other hand, according to the gaming machine D2, in addition to the effect of the gaming machine D1, the transmission of the driving force can be canceled (disconnected) in both directions of the driving direction regardless of the driving direction of the driving means. , It is possible to improve the degree of freedom of operation of the effect of automatically operating the operation means.

As a method of releasing the transmission, the clutch moves in a direction intersecting the operating direction of the driving means. The intersecting direction means, for example, excluding the circumferential direction when the driving means rotates, and the clutch may move in the rotation axis direction or in the radial direction.

The gaming machine D1 or D2 includes an urging means that urges the driving means and the transmitting means into a state in which the driving force can be transmitted, and the releasing means is a contact portion between the driving means and the transmitting means. The engaging teeth are provided with engaging teeth that transmit a driving force in a state in which they are meshed with each other, and the engaging teeth have both sides facing the operating direction of the driving means from the contact surface. The gaming machine D3 is characterized in that it is formed in a shape that is inclined with respect to the contact surface in a manner that tapers as the distance increases.

According to the gaming machine D3, in addition to the effect of the gaming machine D1 or D2, the urging means presses the driving means and the transmitting means, and the releasing means applies the driving force in a meshed state on the pressed contact surface. On the other hand, since both sides facing the operating direction of the driving means are provided with engaging teeth that are inclined so as to taper away from the contact surface, the transmitting means can be transmitted from the driving means by engaging the engaging teeth with each other. It can be separated, thereby releasing the transmission of the driving force.

Further, an urging force by the urging means is constantly applied between the driving means and the transmitting means, and when the transmitting means separates from the driving means, the urging force is applied to the operating direction of the driving means via the engaging teeth. A load is applied. Therefore, it is possible to suppress a sudden change in the load applied to the driving means between the state in which the driving force is transmitted and the state in which the transmission is released.

The size of the engaging portion of the engaging tooth becomes smaller in the circumferential direction of the transmitting means as the transmitting means moves away from the driving means. Therefore, when the phase difference between the transmission means and the driving means becomes large, it is possible to prevent the load generated in the circumferential direction of the transmission means from becoming excessive.

In addition, in the released state, the resistance is periodically restored instead of being separated and completely eliminated. As a result, when the player releases his hand, the button can be started to operate within a short time.

That is, if the player holds the button when the button is driven "as an effect", one phase of the button operation will elapse. Then, if the player releases his hand in the middle of the process and moves from the end of the first phase, the period in which the button is stopped becomes longer, and the feeling that "the player has started to move because the load has been released" is reduced. It comes off.

On the other hand, according to the gaming machine D3, the operating means can be started within a short time after the player releases the hand and the load is released. As a result, it is possible to produce a feeling that the player has started to move because the load on the player has been released.

In any of the gaming machines D1 to D3, the engaging surface of the transmitting means and the releasing means is formed from a sawtooth shape that engages with each other.

According to the gaming machine D4, in addition to the effect of any of the gaming machines D1 to D3, when the load from the player is released, the releasing means can be easily returned to the engaging position with the transmitting means at an early stage. That is, when the tip of the engaging surface has a plane parallel to the direction in which the transmitting means and the releasing means are close to each other, the transmitting means and the releasing means abut on the plane to transmit the releasing means. It is possible to prevent the movement from being stopped along the direction of approaching and separating from the means. Therefore, after the load from the player is released, the operation means can be started to operate at an early stage.

In any of the gaming machines D1 to D4, the operation mode of the operating means differs depending on whether the driving means is continuously operated in the forward direction or the driving means is continuously operated in the opposite direction. The gaming machine D5 characterized by.

According to the gaming machine D5, in addition to the effect of any of the gaming machines D1 to D4, while preparing a plurality of operating modes of the operating means, the driving force transmission is released without being limited to any of the operating modes. It can be carried out.

In the gaming machine D5, when there is a difference in whether the driving means operates in the forward direction or the reverse direction, the operating mode of the operating means is the operation mode for a predetermined period from the start of the operation of the driving means. Similarly, the gaming machine D6 is characterized in that the operation after the elapse of a predetermined period is different.

According to the gaming machine D6, when there is a difference in the operating direction of the driving means in the operating mode of the operating means in addition to the effect of the gaming machine D5, the operating mode of the driving means for a predetermined period from the start of the operation is the same. Since the operation after the elapse of the predetermined period is different, the player's attention to the operating means can be improved.

Here, by entwining the difference in the operation mode of the operation means with information that is beneficial to the player, such as the jackpot expectation degree, the operation of the operation means is performed by the player for a predetermined period until the operation mode of the operation means changes. You can watch over.

Further, since this difference in the operation mode is caused by the difference in the operation direction of the drive means, if the operation direction of the drive means can be confirmed in advance, the player can grasp the difference in the jackpot expectation degree without watching the operation of the operation means. Can be done. However, usually, the driving means is hidden from the player, and the difference in the operating direction cannot be recognized from the vibration sound or the like. Therefore, the operating direction of the driving means cannot be confirmed in advance, and the player cannot confirm the operating direction. Can be watched over by the operation of the operating means.

<Change the position of the cam protrusion based on the rotation of the cam>
In an operating device having an operating means operated by a player, the operating device includes a driving means for generating a driving force for operating the operating means, a transmitting means for transmitting the driving force of the driving means to the operating means, and a transmission means for transmitting the driving force of the driving means to the operating means. A first means that is configured to operate the operating means between a first position and a second position different from the first position and that suppresses the position of the operating means from changing from the first position. An urging means that urges the operating means from the first position toward the second position, and an operating means that moves the operating means from the first position to the second position by the urging force of the urging means. In a gaming machine including a terminal means for forming a movable end of the above in a changeable manner, the first means suppresses a change in the position of the operating means by engaging with the operating means. The first means is provided with a release load means for giving a load for disengaging the engagement of the one means to the first means, the disengagement by the release load means, and the movement termination of the operation means in the termination means. The gaming machine E1 characterized in that the change is performed by a single driving means.

In a game machine such as a pachinko machine, a movable operating means operated by a cam is fixed at the first position, and the fixing is released by a release load means so that the pachinko machine or the like is extended by the urging force of the urging means. , There is a gaming machine in which the displacement amount of the overhanging motion can be changed by a terminal means (see, for example, Japanese Patent Application Laid-Open No. 2014-144218). However, in the above-mentioned conventional gaming machine, since the displacement amount of the overhanging operation of the operating means is changed depending on the phase of the cam at the time of releasing the fixing, the phase of the cam at the time of releasing the fixing is changed in various ways. The cam for moving the means and the release load means for releasing the fixing were operated by different driving forces. Therefore, there is a problem that a plurality of driving means are required and the space for arranging the driving means becomes large.

On the other hand, in the gaming machine E1, the release load means for releasing the fixing of the operating means is driven by the driving means for driving the operating means. As a result, the number of drive means can be reduced because the drive means for changing the terminal position of the operation means by the terminal means and the drive means for moving the release load means can be used in combination.

In the gaming machine E1, the gaming machine E2 is characterized in that the position of the releasing load means is changed based on the operation of the transmitting means.

According to the gaming machine E2, in addition to the effect of the gaming machine E1, a change in the position of the releasing load means can be generated based on the operation of the transmitting means. The state of the load means can be determined. As a result, the number of arrangements of the detection means such as the position sensor for detecting the state of the release load means can be reduced, and the number of parts can be reduced.

As a method of switching the state of the release load means, when the transmission means is composed of a cam and the release load means is composed of a protrusion that rotates coaxially with the cam, a method of shifting the rotation cycle between the cam and the protrusion is used. An example is a method in which the rotation of the cam and the rotation of the protrusion are synchronized when the cam is arranged in a predetermined phase, and the rotation of the cam and the rotation of the protrusion are synchronized in other phases.

In the gaming machine E2, the release load means is operably arranged with respect to the transmission means by the load given from the first means, and the release load means and the transmission means are operably arranged by the operation of the release load means. The gaming machine E3 is characterized in that it can be switched whether or not it operates synchronously.

According to the gaming machine E3, in addition to the effect of the gaming machine E2, the releasing load means is operably arranged with respect to the transmitting means by the load from the first means, and the releasing load means is operated by the operation of the releasing load means. Since it is switched whether or not the transmission means and the transmission means operate in synchronization with each other, the synchronization state between the release load means and the transmission means can be changed without adding a member.

In the game machine E2, the transmission means includes a rotating first rotating member, the operating means is supported eccentrically with respect to the rotation axis of the first rotating member, and the release load means rotates a second rotation. A gaming machine E4 comprising a member, wherein the first rotating member and the second rotating member have different rotation cycles.

According to the gaming machine E4, in addition to the effect of the gaming machine E2, the first rotating member and the second rotating member are operated by a single driving means, but since the rotation cycles are different, the second rotating means is predetermined. A plurality of types of phases of the first rotating member can be prepared when the first means is released by abutting with the first means in phase.

According to this configuration, it is possible to prepare a plurality of types of terminal positions when the operation of the first means is released from the state where the operating means is maintained at the first position and the operating means is moved toward the second position. , The range of production can be expanded. For example, an effect of gradually moving the terminal position away from the first position and an effect of gradually moving the terminal position closer to the first position can be realized with the same configuration.

<Vibration device supported by soft case>
In an operating device having an operating means operated by a player, the operating device includes a first position of the operating means and a second position reached by the operating means when the player operates from the first position. In a gaming machine including a vibrating means having a vibrating portion that is movable between and vibrating and a receiving means that is arranged so as to be in contact with the vibrating portion, the operating means is arranged at the first position. When this is done, the vibrating portion is in a separated state in which it cannot come into contact with the receiving means, while when the operating means is arranged at the second position, the vibrating portion can come into contact with the receiving means. A gaming machine F1 characterized in being in contact with each other.

In a gaming machine such as a pachinko machine, there is a gaming machine including an operating means that can be operated by the player and a vibrating means that transmits vibration to the player via the operating means or the frame of the gaming machine (for example, Japanese Patent Application Laid-Open No. (See 2014-144218). However, in the above-mentioned conventional gaming machine, when the vibrating means vibrates regardless of whether or not the operating means is operated, the vibration is transmitted to the operating means or the frame of the gaming machine. Alternatively, since it is transmitted to the player who touches the frame of the gaming machine, when performing an effect of transmitting vibration immediately after operating the operating means, it is necessary to operate the vibrating means after detecting the operation of the operating means. .. Therefore, after the player operates the operating means, it is necessary to operate the vibrating means before releasing the hand from the operating means, and the operation mode of the player (for example, an operation such as releasing the operating means at the moment when the operating means is pushed in). Depending on the mode), the start of vibration may not be in time before the hand is released, and there is a problem that the player may not notice the vibration.

On the other hand, according to the gaming machine F1, whether or not the vibrating portion comes into contact with the receiving means depends on whether the operating means is arranged in the first position or is operated by the player and arranged in the second position. Since it changes, even when the vibrating portion is continuously vibrated, the player can feel the vibration only when the player operates the operating means. Further, since the vibration of the vibrating portion is generated before the player pushes in, the vibrating portion can be vibrated before the player releases the hand, regardless of the mode of operation of the player. Vibration can be transmitted to a person.

In the gaming machine F1, the vibrating means is arranged so as to project over an occupied area occupied when the operating means is arranged at the second position in the separated state, and the operating means moves to the second position. The gaming machine F2 is characterized in that the vibrating means is brought out of the occupied area to change to the contact state.

According to the gaming machine F2, in addition to the effect of the gaming machine F1, the vibrating means moves based on the movement of the operating means, so that the separated state changes to the contacting state. Therefore, depending on the degree of movement of the operating means. The contact strength between the operating means or the receiving means and the vibrating portion can be changed, and the strength of the transmitted vibration can also be changed. Therefore, the effect of changing the strength of the transmitted vibration with respect to the operating strength of the player can be performed by vibrating the vibrating means in the same manner without any particular change in the driving mode.

In the gaming machine F1 or F2, the gaming machine F3 is characterized in that the vibrating means is supported by the receiving means via a supporting means having spring elasticity.

According to the gaming machine F3, in addition to the effect of the gaming machine F1 or F2, the supporting means can perform positioning with respect to the receiving means while suppressing the vibration of the vibrating means from being transmitted to the receiving means. As a result, the receiving means and the vibrating means can be separated from each other to prevent the transmission of vibration, and the displacement generated in the vibrating means during vibration can be suppressed.

In the gaming machine F3, the gaming machine F4 is characterized in that the supporting means expands and contracts based on the vibration of the vibrating portion in the contact state.

According to the gaming machine F4, in addition to the effect of the gaming machine F3, the elasticity of the supporting means can be used to increase the load generated when the vibrating portion and the receiving means come into contact with each other. That is, the expansion and contraction of the support means can give momentum when the vibrating portion moves in the direction close to the receiving means.

In the gaming machine F3, the supporting means is characterized in that the deformation resistance along the operating direction of the operating means is lower than the deformation resistance in the direction perpendicular to the operating direction of the operating means. ..

According to the gaming machine F5, in addition to the effect of the gaming machine F3, the direction in which the supporting means is deformed can be finely set when the operating means is operated and interferes with the supporting means due to the difference in the deformation resistance of the supporting means. can.

As a result, even if the difference in the amount of movement of the operating means is slight, the amount of expansion and contraction of the supporting means can be made different, and the load generated between the vibrating portion and the receiving means can be made different. ..

As a method of making the deformation resistance different, when the supporting means is composed of a rubber member surrounding the vibrating means, a method of extending the rubber legs along the operating direction of the operating means, or a method of supporting the vibrating means surrounding the vibrating means. In the case of being composed of rubber members, a method of manufacturing the rubber members by two-color molding and changing the deformation resistance in each direction, and a rail that guides the operating means so that the operating means move in the direction along the operating direction. , A method of configuring the coil spring that urges the vibrating means along the operating direction of the operating means, and the like are exemplified.

The gaming machine F6 is characterized in that a portion of the gaming machine F3 with which the vibrating portion abuts is the receiving means, and the receiving means is configured as a means different from the operating means.

According to the gaming machine F6, in addition to the effect of the gaming machine F3, the vibration is not transmitted to the player through the operating means, but is transmitted to the player through the receiving means which is a means different from the operating means. Therefore, it is possible to suppress the vibration of the vibrating means from being transmitted to the driving means via the operating means and the transmitting means, so that it is possible to prevent the driving means from being loaded. Thereby, the durability of the driving means can be improved.

Further, since it is possible to suppress the vibration from being transmitted to the hand of the player who operates the operating means, it is possible to prevent the player who is surprised by the vibration from stopping the operation during the operation.

As a receiving means, for example, in the frame part of the game machine, the part near the upper plate to which the game ball is supplied, the edge part of the glass frame, etc., the player does not notice during the game. Examples include a part that may be touched by a hand, a storage part that partially surrounds the operating means, and the like.

<One-touch mounting of cam and shaft. Shape deformation (elastic deformation) is possible at the mounting part>
In an operating device having an operating means operated by a player, the operating device is configured so that the operating means can move between a first position and a second position different from the first position, and the operating means can be moved. It is characterized by comprising a driving means for generating a driving force to be driven and a transmitting means for transmitting the driving force of the driving means to the operating means, and the transmitting means includes a deformed portion elastically deformed by an overload. Game machine G1 to play.

In a gaming machine such as a pachinko machine, an operating means that can be operated by a player, a driving means that generates a driving force that drives the operating means, and a transmitting means that transmits the driving force from the driving means to the operating means are provided. There is a gaming machine provided (see, for example, Japanese Patent Application Laid-Open No. 2014-144218). However, in the conventional gaming machine described above, when the operating means is gripped and fixed by the player, when the driving means generates a driving force for driving the operating means, the connecting portion between the transmitting means and the operating means and the transmitting means There is a problem that a load is accumulated in the connecting portion between the and the driving means, and these connecting portions may be damaged.

On the other hand, according to the gaming machine G1, when the operating device is overloaded, the deformed portion of the transmitting means is elastically deformed, so that the connecting portion between the operating means and the transmitting means and the driving means and the transmitting means are connected. The load given to the connecting portion with and can be relaxed.

In the game machine G1, the transmission means includes a cam member that is rotatably supported, and the deformed portion constitutes a connecting portion of the cam member with a rotating shaft, and the elasticity of the deformed portion causes the deformed portion to move to the rotating shaft. A game machine G2 characterized in that a fixing force of the above is generated.

According to the game machine G2, the deformed portion has a role as a portion responsible for elastic deformation of the cam member with respect to the rotation shaft of the transmission means and a role as a portion for generating a supporting force of the cam member with respect to the rotation shaft. Therefore, the configuration of the transmission member can be simplified by combining the functions. For example, individual fixing members such as e-rings can be omitted.

In the game machine G2, the cam member includes a convex portion that is convexly provided in parallel with the rotation axis, and the convex portion and the operating means are connected, and the elastic deformation of the deformed portion is applied to the cam member. On the other hand, the gaming machine G3 is characterized in that the rotation axis is tilted.

Here, the elastic deformation of the transmission means can also be performed, for example, by displacing the convex portion along the circumferential direction of the cam member. However, in this case, it becomes difficult to form the cam member and the convex portion with one member, and the number of members may increase.

On the other hand, according to the gaming machine G3, in addition to the effect of the gaming machine G2, the elastic deformation of the deformed portion is such that the rotation axis is tilted with respect to the cam member. On the other hand, as compared with the case of sliding movement, the cam member can be easily configured from a single member, and the member can be simplified.

In the game machine G3, the resistance of the elastic deformation of the deformed portion is compared with the rotation shaft in the first rotation direction in which the cam member is rotated about the straight line connecting the rotation shaft and the convex portion. A gaming machine characterized in that the deformation resistance is larger in the second rotation direction in which the straight line connecting the convex portion and the straight line perpendicular to both the extension direction of the rotation axis are rotated about the axis. G4.

According to the game machine G4, in addition to the effect of the game machine G3, by making the deformation resistance of the deformed part different for each direction, the state after the deformed part is elastically deformed in the direction of rotation axis is better. Compared with the state before elastic deformation, the convex tip of the convex portion can be displaced in the direction along the circumferential direction of the cam member. As a result, the convex portion can be displaced along the direction in which the convex portion of the cam member intends to move, so that the load generated between the convex portion and the operating means due to the elastic deformation of the deformed portion is alleviated. can do.

In the game machine G3 or G4, the cam member is provided with a friction member that is spaced apart by a predetermined distance along a direction parallel to the rotation axis of the cam member, and the deformed portion is elastically deformed to change the posture of the cam member. The gaming machine G5, characterized in that the cam member and the friction member come into contact with each other.

According to the gaming machine G5, in addition to the effect of the gaming machine G3 or G4, when an overload is applied to the operating means, the deformed portion is elastically deformed, so that the cam member changes its posture, and the cam member and the friction member Can increase the operating resistance of the cam member itself, thereby reducing the load applied to the connecting portion between the cam member and the operating means.

The gaming machine G6 is characterized in that any one of the gaming machines G3 to G5 includes a detecting means for detecting that at least a part of the cam member is tilted and displaced with respect to the axis.

Here, in a situation where the operating device is overloaded and the driving means is operating but the operating means is not operating, for example, the displacement expected due to the driving of the driving means and the actual displacement of the operating means. When detecting that an overload has occurred on the basis of the deviation from the above, it is necessary to drive the driving means for a predetermined period before detecting the occurrence of the overload. This period can be shortened as the arrangement interval of the detection means for detecting the displacement shift is smaller, but the smaller the arrangement interval of the detection means, the more complicated the configuration of the detection means becomes and the more expensive it becomes. Therefore, there is a problem that it is difficult to configure the configuration so that the occurrence of overload can be detected at an early stage at low cost.

On the other hand, according to the gaming machine G6, in addition to the effect of any of the gaming machines G3 to G5, the detecting means detects whether or not at least a part of the cam member is tilted and displaced with respect to the axis. Therefore, it is possible to determine that an overload has occurred at the same time that the detecting means detects at least a part of the cam member without having to drive the driving means for a predetermined period while suppressing the additional number of the detecting means. This makes it possible to reduce the load applied to the drive means when an overload occurs.

In any of the gaming machines A1 to A8, B1 to B3, C1 to C3, D1 to D6, E1 to E4, F1 to F6, and G1 to G6, the gaming machine Z1 is a slot machine. .. Among them, as a basic configuration of a slot machine, "a variable display means for dynamically displaying an identification information string composed of a plurality of identification information and then confirming the identification information is provided for operating a starting operation means (for example, an operation lever). Due to this, the dynamic display of the identification information is started, and the dynamic display of the identification information is stopped due to the operation of the stop operation means (stop button) or after a predetermined time has elapsed, and at the time of the stop. A gaming machine provided with a special gaming state generating means for generating a special gaming state advantageous to the player, provided that the definite identification information of the above is the specific identification information. In this case, coins, medals, and the like are typical examples of the game medium.

In any of the gaming machines A1 to A8, B1 to B3, C1 to C3, D1 to D6, E1 to E4, F1 to F6, and G1 to G6, the gaming machine is a pachinko gaming machine. Z2. Among them, the basic configuration of the pachinko gaming machine is provided with an operation handle, and the ball is launched into a predetermined game area according to the operation of the operation handle, and the ball is placed in a predetermined position in the game area. As a prerequisite for winning a prize (or passing through the operating port), the identification information dynamically displayed by the display means is fixedly stopped after a predetermined time. In addition, when a special gaming state occurs, a variable winning device (specific winning opening) arranged at a predetermined position in the gaming area is opened in a predetermined manner to enable a ball to be won, and is valuable according to the number of winnings. Some are given value (including not only prize balls but also data written on a magnetic card).

In any of the gaming machines A1 to A8, B1 to B3, C1 to C3, D1 to D6, E1 to E4, F1 to F6, and G1 to G6, the gaming machine is a fusion of a pachinko gaming machine and a slot machine. The gaming machine Z3 characterized by being. Among them, as a basic configuration of the fused gaming machine, "a variable display means for dynamically displaying an identification information string composed of a plurality of identification information and then confirming and displaying the identification information is provided, and a starting operation means (for example, an operation lever). The variation of the identification information is started due to the operation of, and the dynamic display of the identification information is stopped due to the operation of the stop operation means (for example, the stop button) or after a predetermined time elapses. A special gaming state generating means for generating a special gaming state advantageous to the player is provided on the condition that the definite identification information at the time of stopping is the specific identification information, the ball is used as the game medium, and the identification information is described. A game machine that requires a predetermined number of balls to start the dynamic display of the game, and is configured to pay out a large number of balls when a special game state occurs. "
<Others>
In a gaming machine such as a pachinko machine, there is a gaming machine including an operating member that moves between a first position and a second position by a manual operation by a player (for example, Patent Document 1: Japanese Patent Application Laid-Open No. 2014-014571). Gazette).
However, the above-mentioned conventional gaming machine has a problem that there is room for improvement in the operation of the operating member. The present technical idea has been made to solve the above-exemplified problems and the like, and an object thereof is to provide a gaming machine having good durability of operating members.
<Means>
In order to achieve this object, the gaming machine of the technical idea 1 is an operating device having an operating means operated by the player, and the operating device is such that the operating means is from the first position and the first position. A vibrating means having a vibrating portion that is configured to be movable between a second position reached by the operating means by a player's operation and a receiving means that is arranged so as to be in contact with the vibrating portion. When the operating means is arranged in the first position, the vibrating portion is in a separated state in which it cannot come into contact with the receiving means, while the operating means is placed in the second position. When arranged, the vibrating portion is in a contact state where it can come into contact with the receiving means.
The gaming machine according to the technical idea 2 is the gaming machine according to the technical idea 1. In the gaming machine described in the technical idea 1, the vibrating means is arranged so as to project over an occupied area occupied when the operating means is arranged at the second position in the separated state. Then, when the operating means moves to the second position, the vibrating means is taken out of the occupied area, and the contact state is changed.
In the gaming machine according to the technical idea 1 or 2, the vibrating means is supported by the receiving means via a supporting means having spring elasticity.
<Effect>
According to the gaming machine described in Technical Thought 1, the operation of the operating device can be improved.
According to the gaming machine described in the technical idea 2, in addition to the effect of the gaming machine described in the technical idea 1, the operation of the operating device can be improved by the relationship between the operating means and the vibrating means.
According to the gaming machine described in Technical Thought 3, in addition to the effects of the gaming machine described in Technical Thought 1 or 2, the operation of the operating device can be improved by devising a method of supporting the vibrating means. ..

10 Pachinko machine (game machine)
81 Third symbol display device (display means)
300, 2300, 3300, 4300, 5300, 6300, 7300
Operating devices 310, 2310, 3310, 4310 Tilt device (tilting means, operating means)
311gL, 3311gL Left side detection piece (part of continuous striking determination means, part of position difference detection means, part of movement direction determination means)
311gR Right side detection piece (part of continuous hit determination means, part of end detection means, part of position difference detection means, part of movement direction determination means)
312a1 Operation surface (part of operation means)
314 shaft part (shaft rod)
315 Torsion spring (urging means)
324L left side detection sensor (part of continuous hit determination means, part of position difference detection means, part of movement direction determination means)
324R Right side detection sensor (part of continuous hit determination means, part of end detection means, part of position difference detection means, part of movement direction determination means)
340, 5340, 6340 Drive device (drive means, first drive means)
341 Main body member (part of friction member)
341f LED device (light emitting means)
343 Transmission shaft rod (part of transmission means)
343a Cylindrical member (part of transmission means)
343b Transmission gear (part of drive means, part of release means)
343b2 Clutch part (engaged teeth)
343c Movable clutch (part of transmission means, part of release means)
343c2 Clutch part (engaged teeth)
343d Coil spring (biasing means)
344, 6344, 7344 Disc cams (part of transmission means, part of termination means, part of release load means)
344c Engagement rib (part of release load means)
344d connecting pin (convex part)
345 arm member (part of transmission means, part of termination means)
346, 2346, 7346 Release member (part of maintenance means, part of first means, part of friction member)
347, 7347 Rotating claw member (part of maintenance means, part of first means)
352 Voice coil motor (second drive means, repulsion means)
2347 Rotating plate member (part of maintenance means)
2348 Slide claw member (part of maintenance means)
4321d Upper detection sensor (detection sensor)
4321e Lower detection sensor (detection sensor)
5320 Lower frame member (part of support frame)
5344 Disk cam (part of transmission means, part of termination means, part of release load means, cam member)
5400 Vibration device (vibration means, repulsion means)
5411 Drive motor 5412 Weight member (vibrating part, part of repulsive means)
5420 Flexible member (part of support means, repulsion means)
5430 Accommodating member (receiving means, part of repulsion means, part of support frame)
6344L1, 6344R1 disk member (first rotating member)
6344L2, 6344R2 Ring member (second rotating member)
7344L1, 7344R1 Disk member (part of transmission means, part of termination means)
7344L3, 7344R3 engaging member (release load means)
E1 notification device (detection means)
S52 Termination area (occupied area)
P1a deformed part (deformed part)

Claims (3)

In an operating device having an operating means operated by the player, the operating device includes a first position of the operating means and a second position reached by the operating means when the player operates from the first position. A vibrating means that is configured to be movable between and has a vibrating vibrating part,
In a gaming machine provided with a receiving means arranged so as to be in contact with the vibrating portion.
When the operating means is arranged at the first position, the vibrating portion is in a separated state in which it cannot come into contact with the receiving means.
A gaming machine characterized in that when the operating means is arranged at the second position, the vibrating portion is in a contact state capable of contacting the receiving means. The vibrating means is arranged so as to project over an occupied area occupied when the operating means is arranged at the second position in the separated state, and the operating means moves to the second position to cause the vibrating means. The gaming machine according to claim 1, wherein when the machine is taken out of the occupied area, the machine changes to the contact state. The gaming machine according to claim 1 or 2, wherein the vibrating means is supported by the receiving means via a supporting means having spring elasticity.

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