JP2021065780A - Game machine - Google Patents

Abstract

To provide a game machine where a player can excellently acquire lotteries.SOLUTION: Upon entrances of a plurality of balls P1 to P3 to a first groove 311, compared to a flow down speed of the ball P1 which entered at first among the plurality of balls P1 to P3, the first groove 311 decelerates the balls P2 and P3 which entered thereafter. And thereby ball entrances of the balls P2 and P3 to a detection port 312d are prevented during a period from when the ball P1 entered the detection port 312d till a restoration period is elapsed. Accordingly, a generation of an overflow can be suppressed.SELECTED DRAWING: Figure 17

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 provided with an entrance for obtaining a lottery opportunity based on the entry of a gaming ball (Patent Document 1).

Japanese Unexamined Patent Publication No. 2011-156058

However, the above-mentioned conventional gaming machine has a problem that there is room for improvement in the method of winning a lottery. 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 a good lottery acquisition.

In order to achieve this object, the gaming machine according to claim 1 is switched between a first state in which a lottery opportunity is given when a gaming ball enters and a first state in which the gaming ball enters the ball. A second state in which a lottery opportunity is not given even if a game ball enters the ball, and a detection ball opening that can be configured are provided, and after switching to the second state, a predetermined return is performed. In a gaming machine that returns to the first state as the period elapses, when a plurality of gaming balls enter, the flow speed of the first gaming ball that enters first among the plurality of gaming balls is set. In comparison, a deceleration means for decelerating the flow speed of the second pachinko ball that has subsequently entered is provided, and the game ball thrown from the deceleration means enters the detection entry port. 2 The period from when the pachinko ball enters the deceleration means to when it enters the detection entry port is longer after the first game ball enters the deceleration means. It is configured in such a manner that it is longer than the length of the return period, which is longer than the period required to enter the ball.

The gaming machine according to claim 2 is the gaming machine according to claim 1, wherein the deceleration means intermittently applies a load in the direction opposite to the flow direction to the gaming ball to decelerate the gaming ball.

The gaming machine according to claim 3 is the gaming machine according to claim 2, wherein the deceleration means is arranged so as to be movable relative to a deceleration flow path for guiding the entering game ball and the deceleration flow path. It also includes a moving means having an action unit configured to be able to apply a load to the gaming ball, and the moving means moves relative to the first state and the deceleration flow path from the first state. The second state, which is the state of the above, can be configured, the action unit is configured to apply a load to the gaming ball flowing down the deceleration flow path in the second state, and the moving means is the first. When the gaming ball passes through the deceleration flow path, the state changes from the first state to the second state, and in the second state, the acting unit applies a load to the second gaming ball.

According to the gaming machine according to claim 1, the lottery can be successfully obtained.

According to the gaming machine according to claim 2, in addition to the effect of the gaming machine according to claim 1, by applying an intermittent load to the gaming ball, the gaming ball is decelerated and the lottery opportunity is lost. Can be prevented.

According to the gaming machine according to claim 3, in addition to the effect played by the gaming machine according to claim 2, the load applied to the gaming ball from the moving means by the passage of the gaming ball can be changed.

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 rear view exploded perspective view of a game board. It is a front view of a delay device. FIG. 6 is a cross-sectional view of the delay device in line VII-VII of FIG. FIG. 6 is a partial cross-sectional view of the delay device on line VIII-VIII of FIG. It is a front perspective view of the slide moving member. (A) is a front view of the slide moving member, (b) is a side view of the slide moving member in the direction of arrow Xb of FIG. 10 (a), and (c) is a side view of FIG. 10 (a). It is a top view of the slide moving member in the direction of arrow Xc, and FIG. 10D is a partial cross-sectional view of the slide moving member in line Xd-Xd of FIG. 10A. It is a front perspective view of the sorting device and the second adjusting device. (A) is a front view of the sorting device and the second adjusting device, (b) is a side view of the sorting device and the second adjusting device in the direction of arrow XIIb of FIG. 12 (a), and (c) is 12 (a) is a top view of the sorting device and the second adjusting device in the direction of arrow XIIc in FIG. 12 (a), and (d) is the sorting device and the second adjusting device in the XIId-XIid line of FIG. 12 (a). It is a partial sectional view. It is a front view of a delay device. It is a front view of a delay device. (A) to (c) are cross-sectional views of the second adjusting device in a plane orthogonal to the rotation axis. (A) to (d) are cross-sectional views of the functional disk device which is a cross-sectional view of the functional disk device in a plane perpendicular to the rotation axis. (A) and (b) are partial front views of the delay device. (A) and (b) are partial front views of the delay device. (A) and (b) are partial front views of the delay device. It is a partial front view of a delay device. (A) to (c) are partial front views of the delay device. It is a partial front perspective view of a game board. (A) is a top view of the fan-shaped member, (b) is a side view of the fan-shaped member in the direction of arrow XXIIIb of FIG. 23 (a), and (c) is a side view of the fan-shaped member of FIG. 23 (a). It is sectional drawing of the fan-shaped member in line XXIIIc, (d) is the bottom view of the fan-shaped member in the direction view of arrow XXIIId of FIG. 23 (b). (A) is a side view of the link member, and (b) is a bottom view of the link member in the direction of arrow XXIVb of FIG. 24 (a). (A) is a top view of a fan-shaped member and a link member, and (b) is a cross-sectional view of the fan-shaped member and the link member in line XXVb-XXVb of FIG. 25 (a). It is a top view of a fixed floor. (A) is a cross-sectional view of a fixed floor in line XXVIIa-XXVIIa of FIG. 26, and (b) is a cross-sectional view of a fixed floor in line XXVIIb-XXVIIb of FIG. 26. (A) is a partial top view of the delayed floor device, (b) is a sectional view of the delayed floor device in line XXVIIIb-XXVIIIb of FIG. 28 (a), and (c) is a portion of the delayed floor device. Top view, (d) is a cross-sectional view of the delayed floor device in line XXVIIId-XXVIIId of FIG. 28 (c). (A) is a top view of the delayed floor device, (b) is a sectional view of the delayed floor device in the line XXIXb-XXIXb of FIG. 29 (a), and (c) is a top view of the delayed floor device. (D) is a cross-sectional view of the delayed floor device in the XXIXd-XXIXd line of FIG. 29 (c). (A) is a top view of the delayed floor device, and (b) is a cross-sectional view of the delayed floor device in the line XXXb-XXXb of FIG. 30 (a). (A) is a top view of the delayed floor device, (b) is a sectional view of the delayed floor device in the line XXXIb-XXXIb of FIG. 31 (a), and (c) is a top view of the delayed floor device. (D) is a cross-sectional view of the delayed floor device on the XXXId-XXXId line of FIG. 31 (c). (A) is a top view of the delayed floor device, (b) is a sectional view of the delayed floor device in the line XXXIIb-XXXIIb of FIG. 32 (a), and (c) is a top view of the delayed floor device. (D) is a front view of the delayed floor device in the direction of arrow XXXIId in FIG. 32 (c). (A) and (b) are sectional views of the delayed floor device in the line XXXIIIa-XXXIIIa of FIG. 32 (c). (A) to (c) are partial front views of the delay device according to the second embodiment. (A) to (c) are partial front views of the delay device according to the third embodiment. (A) to (c) are partial front views of the delay device. (A) to (c) are front views of the delay device according to the fourth embodiment. (A) to (c) are front views of the delay device.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings. First, with reference to FIGS. 1 to 33, 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 a 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 keyhole 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, rental 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 of the front view (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. To.

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, which is chrome-plated, is attached to a region around the illuminated 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 balance information such as a card is displayed, and the built-in LED lights up and the balance is displayed as numerical value as balance 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 below the upper plate 17, a lower plate 50 for storing balls that could not be stored in the upper plate 17 is formed in a substantially box shape with an open upper surface in the central portion thereof. There is. On the right side of the lower plate 50, an operation handle 51 operated by a player to drive the ball into the front of the game board 13 is arranged.

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 front portion 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 53 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 cut into a substantially square shape in front view, a large number of nails and windmills (not shown) for ball guidance, rails 61 and 62, and a general prize. It is configured by assembling a mouth 63, a first winning mouth 64, a second winning mouth 640, a first variable winning device 65, a second variable winning device (not shown), a through gate 67, a variable display device unit 80, and the like. The peripheral edge portion is attached to the back surface side of the inner frame 12 (see FIG. 1). 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 rear surface 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, the first variable winning device 65, the second variable winning device (not shown), and the variable display device unit 80 are formed on the base plate 60 by router processing. It is arranged in the through hole, and is fixed by a tapping screw or the like from the front side of the game board 13.

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 circumference of the game board 13, and the game board 13 and the glass unit 16 (see FIG. 1) surround the front and back of the game board 13. 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, and the ball launched with a predetermined momentum hits the return rubber 69 and has momentum. 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 probable 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 the probability variation jackpot, a symbol corresponding to the 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. it 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 result of the lottery 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 jackpot shifts to a low probability state, and the time is shortened during a predetermined number of fluctuations (for example, 100 fluctuations). is there.

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). 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 power is applied at one time. 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 for opening the electric accessory 640a attached to the second winning opening 640 and the number of times for opening the electric accessory 640a at one time are 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 win a prize. 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 is synchronized with the variable display in the first symbol display devices 37A and 37B, and has a 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 is displayed by the control of the main control device 110 (see FIG. 4), whereas the first symbol display devices 37A and 37B display the game state. 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 the electric accessory 640a may be constant regardless of the gaming state.

The through gate 67 is assembled to the game board on the right side in the area below the variable display device unit 80, and among the balls fired on the game board, a part of the balls flowing down to the right side of the game board can pass through. It is configured in. 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 one, and may be a plurality (for example, two). Further, the assembly position of the through gate 67 is not limited to the right side of the variable display device unit 80, and may be, for example, the left side of 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, on the right side of 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 a display according to the lottery result is shown on the first symbol display device 37B.

The number of times the ball has passed through the first winning opening 64 and the second winning opening 640 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. Further, for example, the larger the number of reserved balls in the first winning opening 64, the easier it is to select a shorter period as the variable display period on the display device. Similarly, the second winning opening 640 is also controlled.

Further, each of the first winning opening 64 and the second winning opening 640 is 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 to be paid out when a prize is won may be three, and the number of prize balls to be paid out when a ball is won to the second winning opening 640 may be configured to be 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 probability 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 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 can easily 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.

As described above, the pachinko machine 10 of the present embodiment fires a ball at 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). You can change the method of "left-handed" and "right-handed". Therefore, the player can enjoy the game because the way of hitting the ball can be changed.

A first variable winning device 65 is arranged on the upper right side of 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 winning the first winning slot 64 or the second winning slot 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 gaming state transitions to a special gaming state (big hit) where 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.

Specifically, the first variable winning device 65 includes a front-view triangular opening / closing plate that covers the specific winning opening 65a, and a large opening solenoid (shown) for driving the opening / closing to the right with the lower side of the opening / closing plate as an axis. It is equipped with. The specific winning opening 65a is normally closed so that the ball cannot win or it is difficult to win. At the time of a big hit, the large opening solenoid is driven to tilt the opening / closing plate to the right to temporarily form an open state in which the ball can easily win a prize in the specific winning opening 65a. It operates so as to alternately repeat the state of.

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, an identification label, etc. is provided, and the certificate stamp, etc. attached to 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 a first out port 71. A ball that flows down the game area and does not win any of the winning openings 63, 64, 65a, 640 is guided to a ball discharge path (not shown) through the first out opening 71. The first out opening 71 is arranged below the first winning opening 64.

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. In the present embodiment, one of the wind turbines (referred to as a movable member 310) is arranged on the upper left side of the game board 13 when viewed from the front, and is shown in FIG.

As shown in FIG. 3, the control board units 90 and 91 and the back pack unit 94 are mainly provided on the rear surface 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 are 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 controller 110 to the sub controller 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 the 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 launch unit 112a includes a launch solenoid and an electromagnet (not shown), and the launch 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 on / off output 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. The other device 228 includes a drive motor 472.

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 rear surface image is an image displayed on the rear surface 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 supply 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 period of time to execute 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.

Next, the delay device 300 will be described with reference to FIGS. 5 to 21. FIG. 5 is an exploded perspective view of the back of the game board 13. FIG. 5 shows a state in which the delay device in which the ball flowing down the game area and flowing into the first winning opening 64 flows down is disassembled from the game board 13.

The ball that has flowed into the first winning opening 64 flows down the inside of the delay device 300, is thrown from the detection port 312d arranged at the lower end thereof, and passes through a detection sensor (not shown), so that a lottery is performed. That is, the lottery has not yet been performed from the time the ball enters the first winning opening 64 until it passes through the detection sensor.

Next, the delay device 300 will be described with reference to FIGS. 6 and 7. FIG. 6 is a front view of the delay device 300, and FIG. 7 is a cross-sectional view of the delay device 300 on the VII-VII line of FIG. Note that in FIG. 7, the game board 13 is partially illustrated for ease of understanding.

As shown in FIGS. 6 and 7, a groove is formed in the delay device 300, and the groove and the game board 13 that hits the surface form a path through which the ball that has entered the first winning opening 64 flows down. A speed reducing device 320 having a main body member 310 and a sliding moving member 321 that slides and moves with respect to the main body member 310, a first adjusting device 330 for adjusting the return operation of the speed reducing device 320, and rotation with respect to the main body member 310. It mainly includes a distribution device 340 that operates and distributes balls to different flow paths, and a second adjustment device 350 that is coaxial with the rotation axis of the distribution device 340 and adjusts the return operation of the distribution device 340.

The main body member 310 is a member that constitutes a groove in which the side arranged to face the game board 13 is opened, and the first groove 311 and the first groove 311 in which the ball entering from the first winning opening 64 first flows down. A path extending laterally from the connecting portion between the second groove 312 extending vertically downward from the lower end of the passage 311 and the connecting portion between the first groove 311 and the second groove 312 and longer than the extending length of the second groove 312. A third groove 313 connected to the detection port 312d and a support plate extending in a plate shape from the front side of the bottom plate opening 311b toward the lower side of the first groove 311 and supporting the slide moving member 321. A unit 314 and a section 314 are mainly provided.

The first groove 311 is a ball in the main passage 311a that lowers the ball entered from the first winning opening 64 in a straight line diagonally downward, and in the central portion of the bottom plate of the main passage 311a in the depth direction (the central portion in the depth direction of the ball). The bottom plate opening 311b, which is an opening formed with a width shorter than the radius of the above, and the top plate opening 311c, which allows the wind turbine member 322 of the speed reducer 320 to be extended inward in the top plate portion, and the top plate portion opening 311c. A pair of bearings 311d, which are arranged in pairs in the depth direction with the plate opening 311c in between, and which serve as bearings for the wind turbine member 322, and a back recessed in a size that allows the ball to roll from the main passage 311a to the back side. Mainly includes a side recessed portion 311e.

The recessed portion 311e on the back side is a recessed portion connected near the entrance of the main passage 311a, and the bottom surface is set to the same height as the bottom surface of the main passage 311a near the entrance, and the main passage 311a is directed toward the downstream side. It is configured in a manner of ascending and tilting.

The second groove 312 is a recess formed in the plate portion on the back side (back side in FIG. 6) and is divided into a contact wall 312a that gives a load to bounce the ball that has reached the lower end of the first groove 311 in the left-right direction. The recessed portion 312b, which is recessed in an arc shape so that the device 340 can be arranged, and the receiving wall portion 312c, which receives the ball flowing in from the third groove 313 and acts as a detent for the sorting device 340, and throws the ball. It mainly includes a detection port 312d and a side wall portion 312e that is arranged to face the recessed portion 312b.

The support plate portion 314 includes a pair of elongated holes 314a through which the guide rod portion 321c of the slide moving member 321 is inserted. The elongated hole 314a is configured in the same direction as the elongated hole 331a of the first adjusting device 330 (consisting of overlapping in the front-rear direction).

The speed reducing device 320 mainly includes a slide moving member 321 that slides when the ball passes through the first groove 311 and a wind turbine member 322 that is meshed with the slide moving member 321 and is brought into contact with the ball to rotate. Prepare for.

The slide moving member 321 is guided by the elongated hole 314a of the main body member 310 and the elongated hole 331a of the first adjusting device 330, which will be described later, so that the slide moving member 321 can operate linearly.

The wind turbine member 322 has a main body gear portion 322a having a gear portion that is pivotally supported by the bearing portion 311d and meshed with the slide moving member 321 at the rear end portion, and the wind turbine member 322 radially from the shaft portion of the main body gear portion 322a. It mainly includes a first extending wing portion 322b and a second extending wing portion 322c which are extended in pairs and form an angle of 90 ° with each other.

As shown in FIG. 7, the first extending vane portion 322b and the second extending vane portion 322c are configured so as to be able to project from the top plate opening 311c toward the inside of the first groove 311a, and at the same time. The first extending vane portion 322b is arranged at a position where it can come into contact with the ball in the initial state in which the slide moving member 321 is maintained at the lower end position by gravity when the slide moving member 321 is brought into contact with the ball flowing down the groove 311a.

The second extending vane portion 322c includes a convex portion 322c1 of the tip end portion in the extending direction, which is projected in a tapered shape in a direction close to the first groove 311 from the state shown in FIG. The convex portion 322c1 acts in a manner of separating the spheres when the spheres flow down the first groove in succession.

The first adjusting device 330 includes a main body plate member 331 which is a plate-shaped member sandwiching the main body member 310 between the game board 13 and a main body gear portion 322a of the wind turbine member 322 while being pivotally supported by the main body plate member 331. It mainly includes a rotary urging device 332 having a fixed gear portion 332a to be meshed with each other. The gear ratio of the fixed gear portion 332a to the main body gear portion 322a of the wind turbine member 322 is about 2. That is, as the wind turbine member 322 rotates by 90 °, the rotary urging device 332 rotates by 45 °.

The main body plate member 331 is provided with a pair of elongated holes 331a for guiding the slide moving member 321 and is also formed on the support plate portion 314 in which the elongated holes 314a having the same shape are arranged to face each other. The slide moving member 321 is configured to be slidable in the straight direction by being guided by these elongated holes 314a and 331a.

The rotary urging device 332 mainly includes a fixed gear portion 332a pivotally supported by the main body plate member 331 and a functional disk device 332b fixed to the fixed gear portion 332a at the axial end and having a recessed groove inside. Prepare for.

The sorting device 340 is a device that is pivotally supported by the central hole 345 in the main body member 310 on the right side of the second groove 312 of the main body member 310, and is a sphere that flows in from the second groove 312b in the initial state shown in FIG. The first wall portion 341 that receives the first wall portion 341, the second wall portion 342 that is arranged above the first wall portion 341 with one sphere separated from each other, and the sorting device 340 from the tip of the second wall portion 342. The arc wall portion 343 formed along the arc shape centered on the rotation axis, the concave portion 312 formed from the disk shape, and the concave portion 312 of the second groove 312 are arranged at the surface position and on the back side of the second groove 312. It mainly includes a complementary plate portion 344 formed in a manner of complementing a part of the plate portion, and a central hole 345 which is a through hole pivotally supported by the main body member 310.

The second wall portion 342 includes a tip convex portion 342a that is radially projected on the extending tip. The sphere that abuts on the arc wall portion 343 and flows down by the tip convex portion 342a can apply a load counterclockwise (counterclockwise in FIG. 6) to the sorting device 340, which is intended by the action of the sphere. It is possible to prevent the distribution device 340 from returning to the initial position side.

The initial position of the sorting device 340 is defined by the stopper portion S1 projecting rearward of the game board 13. That is, at the initial position, the tip of the arc wall portion 343 is stopped by the stopper portion S1, so that the sorting device 340 is stopped. The driving force for rotating the sorting device 340 clockwise in the front view (clockwise in FIG. 6) is generated by the second adjusting device 350.

The second adjusting device 350 is a device fixed to the complementary plate portion 344 of the sorting device 340 and has a flow path in which the pseudo center of gravity sphere GB that changes the center of gravity is movable. It will be described later in 15.

FIG. 8 is a partial cross-sectional view of the delay device 300 on line VIII-VIII of FIG. As shown in FIG. 8, the slide moving member 321 is arranged at the central portion of the main passage 311a. As a result, when the slide moving member 321 projects inside the main passage 311a, the convex portion 321a1 can be reliably brought into contact with the sphere flowing down the first groove 311.

The sphere flowing down the passage 311a may flow into the recessed portion 311e on the back side due to its shape. The recessed portion 311e on the back side has a return wall portion 311e1 configured so as to be closer to the main passage 311a side toward the downstream side (left side in FIG. 8). As a result, the ball that has flowed into the recessed portion 311e on the back side cannot be returned to the main passage 311a, and it is possible to prevent the ball from being clogged.

Next, the slide moving member 321 will be described with reference to FIGS. 9 and 10. 9 is a front perspective view of the slide moving member 321. FIG. 10A is a front view of the slide moving member 321. FIG. 10B is a view in the direction of arrow Xb in FIG. 10A. 10 (c) is a side view of the slide moving member 321, FIG. 10 (c) is a top view of the slide moving member 321 in the direction of arrow Xc of FIG. 10 (a), and FIG. 10 (d) is a view of FIG. 10 (a). It is a partial cross-sectional view of the slide moving member 321 in the Xd-Xd line of.

As shown in FIGS. 9 and 10, the slide moving member 321 includes a long plate-shaped first overhanging plate portion 321a that overhangs the central portion of the main passage 311a of the delay device 300 in a plane parallel to the main passage. The second overhanging plate portion 321b, which is continuously provided at one end of the first overhanging plate portion 321a and is extended downward with respect to the extending direction of the first overhanging plate portion 321a, and each overhanging plate portion 321b. A pair of round bar-shaped guide rods 321c extending in parallel at both ends of the protruding plates 321a and 321b in the long direction, and a depth direction with respect to the respective overhanging plates 321a and 321b (paper surface in FIG. 10A). It mainly includes a rack gear portion 321d extending in a straight line and forming rack gear teeth at a position offset in the vertical direction).

The first overhanging plate portion 321a is a plate portion extending in a direction parallel to the extending direction of the main passage 311a in the assembled state (see FIG. 6), and is arranged at intervals of the diameters of the spheres. A convex portion 321a1 is provided so as to be convex from the upper surface in a semicircular shape. When the convex portion 321a1 comes into contact with the sphere, the velocity of the sphere passing through the main passage 311a (see FIG. 8) is reduced.

The second overhanging plate portion 321b includes a convex portion 321b1 that has the same function as the convex portion 321a1, and an inclined surface 321b2 (see FIG. 10D) that inclines downward toward the back side. When the second overhanging plate portion 321b overhangs the inside of the main passage 311a, the inclined surface 321b2 makes it easy for the flowing ball to face the back side recessed portion 311e (see FIG. 8). Therefore, the passage period of the sphere can be lengthened as compared with the case where the sphere flows down in a straight line along the extending direction of the passage 311a.

Since the first overhanging plate portion 321a and the second overhanging plate portion 321b have different extension directions, the first extending plate portion 321a overhangs the inside of the main passage 311a, while the second overhanging plate portion 321b is a book. A state arranged outside the passage 311a can be formed. That is, the degree of deceleration of the sphere can be changed by arranging the slide moving member 321. The details will be described later.

The guide rod portion 321c is inserted into the elongated hole 331a of the first adjusting device 330 (see FIG. 6). As a result, the slide moving member 321 is supported so as to be slidable along the extending direction of the elongated hole 331a.

The rack gear portion 321d is extended in parallel with the extending direction of the elongated hole 331a, and the rack gear teeth are meshed with the main body gear portion 322a of the wind turbine member 322 (see FIG. 6). As a result, the wind turbine member 322 rotates, so that the rack gear portion 321d is slid in the linear direction (extending direction of the elongated hole 331a).

Next, the sorting device 340 and the second adjusting device 350 will be described with reference to FIGS. 11 and 12. 11 is a front perspective view of the sorting device 340 and the second adjusting device 350, FIG. 12A is a front view of the sorting device 340 and the second adjusting device 350, and FIG. 12B is a diagram. 12 (a) is a side view of the sorting device 340 and the second adjusting device 350 in the direction of arrow XIIb of FIG. 12 (a), and FIG. 12 (c) shows the sorting device 340 and the second adjustment in the direction of arrow XIIc of FIG. 12 (a). It is a top view of the apparatus 350, and FIG. 12D is a partial cross-sectional view of the sorting apparatus 340 and the second adjusting apparatus 350 in the XIId-XIid line of FIG. 12A. Note that FIG. 12D shows a state in which the pseudo center of gravity sphere GB is on the deceleration wall portion 351d.

As shown in FIGS. 11 and 12, the front side of the complementary plate portion 344 is opened except for the portion occupied by each wall portion 341, 342, 343, and is used as a side wall of the passage through which the ball flows down (see FIG. 6). ..

The second adjusting device 350 is a center of gravity changing device 351 fixed to the back surface side of the complementary plate portion 344 and having a recessed flow path for flowing the pseudo center of gravity sphere GB inside, and a recessed portion of the center of gravity changing device 351. A lid member 352 fixed to the center of gravity changing device 351 in a manner of covering the lid is mainly provided.

The center of gravity changing device 351 includes a disk-shaped main body member 351a having a shallow recessed portion, a recessed groove portion 351b in which the pseudo center of gravity sphere GB is recessed in the main body member 351a with a width that allows the pseudo-center of gravity sphere GB to flow down, and the recessed groove portion. A partition wall 351c that allows the passage of the pseudo-center of gravity sphere GB only at the tip, and a deceleration mechanism that extends to one side of the flow path partitioned by the partition wall 351c and decelerates the flow of the pseudo-center of gravity sphere. It is oscillatingly supported by one end (lower end of FIG. 12 (a)) of the deceleration wall portion 351d and the partition wall 351c, and is oscillatingly supported in one direction of the pseudo center of gravity sphere GB (FIG. 12 (a) rightward direction). ) Is mainly provided with a directional valve 351e that allows only passage of.

The position of the center of gravity of the second adjusting device 350 excluding the pseudo center of gravity sphere GB is set to be the same as the center of rotation. That is, the stable posture of the distribution device 340 is determined by the position where the pseudo center of gravity sphere GB is arranged with respect to the center of rotation.

Here, the pseudo-center of gravity sphere GB is composed of a sphere having a weight equal to or less than the weight of the sphere. For example, if the weight of the sphere is 5 grams, it is desirable to select a spherical object having a weight of about 2 to 4 grams as the pseudo center of gravity sphere GB. As a result, it is possible to avoid a situation in which the forces of the ball flowing into the sorting device 340 and the pseudo center of gravity sphere GB are balanced, and the sorting device 340 can be rotated by the weight of the sphere.

The deceleration mechanism of the deceleration wall portion 351d will be described with reference to FIG. 12 (d). The deceleration wall portion 351d is a portion that supports both sides of the sphere from below and rolls the sphere in that state. As shown in FIG. 12 (d), the pseudo center of gravity sphere GB does not roll at the portion (the central portion in the left-right direction in FIG. 12 (d)) where the length from the rotation axis is the maximum diameter (radius r1). At a portion where the length from the rotation axis has a radius (radius r'1) shorter than the maximum diameter, the ball comes into contact with the deceleration wall portion 351d and rolls. Therefore, when the rotation speed of the pseudo center of gravity sphere GB is the same, the speed of the pseudo center of gravity sphere GB is decelerated as compared with the speed of the pseudo center of gravity sphere GB when the pseudo center of gravity sphere GB rolls on the partition wall 351c (rolls with a radius r1). It is possible to slow down the speed of the pseudo-center of gravity sphere GB when rolling (rolling with a radius r'1) on the wall portion 351d.

That is, the translational movement distance per rotation of the pseudo-center of gravity sphere GB can be shortened. When the pseudo center of gravity sphere GB is decelerated by this method, the deceleration can be performed while maintaining the rotational energy of the pseudo center of gravity sphere GB, so that the braking is too effective and the pseudo center of gravity sphere GB stops at an unintended position. The situation can be avoided.

Further, since the degree of deceleration of the pseudo center of gravity sphere GB can be arbitrarily set by setting the contact position (rolling radius of the pseudo center of gravity sphere GB) between the deceleration wall portion 351d and the pseudo center of gravity sphere GB, a special material (high friction) can be set. The pseudo center of gravity sphere GB can be sufficiently decelerated even when the forming distance of the deceleration wall portion 351d is short.

Next, the operation of the delay device 300 will be described with reference to FIGS. 13 and 14. 13 and 14 are front views of the delay device 300. FIG. 13 shows a state immediately after the sphere has flowed through the main body member 310 in the initial state shown in FIG. 6, and FIG. 14 shows a state immediately after the sphere has flowed through the main body member 310 in the state of FIG. Is illustrated.

As shown in FIGS. 13 and 14, the sorting device 340 changes its posture between the initial state (see FIG. 6) and the changed state (see FIG. 13) due to the passage of the sphere, and the speed reducing device 320 has the number of passing spheres. The state (arrangement in the height direction) changes depending on the initial state (see FIG. 6), the intermediate state (see FIG. 13), and the ascending state (see FIG. 13).

Each state of the speed reducer 320 will be described. When the speed reducing device 320 is in the intermediate state, the slide moving member 321 moves and is arranged at a position where the convex portion 321a projects from the bottom surface of the main passage 311a. Therefore, in this state, the sphere that has flowed into the main passage 311a comes into contact with the convex portion 321a and flows down while being decelerated. In the intermediate state, the second overhang plate portion 321b is arranged outside the first groove 311.

When the speed reducing device 320 is in the raised state, the slide moving member 321 further overhangs the inside of the main passage 311a, and the second overhanging plate portion 321b is arranged above the bottom surface of the back side recessed portion 311e. Since the second overhanging plate portion 321b has an inclined surface 321b (see FIG. 10) on the upper surface, the sphere flowing into the main passage 311a in this state is a recessed portion 311e on the back side along the inclination of the inclined surface 321b. After flowing to the lower end of the recessed portion 311e on the back side, it merges with the main passage 311a again.

When the speed reducing device 320 is in the raised state, the road width (width in the height direction) of the main passage 31a is narrowed by the first overhang plate portion 321a projecting inside the main passage 311a. Further, in the present embodiment, the slide moving member 321 slides in a direction in which the slide moving member 321 is inclined with respect to the extending direction of the passage 311a, so that the contact wall 312a of the second groove 312 and the first overhanging plate portion 321a The width with the end is narrowed. Therefore, the deceleration of the ball can be performed by narrowing the road width of the main passage 311a and increasing the flow path resistance by narrowing the road width of the connecting portion between the first groove 311 and the second groove 312.

Each state of the sorting device 340 will be described. When the sorting device 340 is in the initial state (see FIG. 6), the ball flowing into the sorting device 340 is received by the first wall portion 341. Then, the distribution device 340 rotates to the changed state (see FIG. 13) due to the weight of the sphere, and the sphere flows into the detection port 312d.

Here, in the present embodiment, since the side wall portion 312e is configured to project above the first wall portion 341 (overhang at a height equal to or greater than the radius of the sphere), the sphere flows into the third groove 313 side. Is suppressed. Therefore, when the sorting device 340 is in the initial state, the sphere that has flowed into the sorting device 340 can flow down vertically with a high probability (it can flow down in the shortest period of time).

When the sorting device 340 is in a changed state (see FIG. 13), the sphere flowing into the sorting device 340 comes into contact with the arc wall portion 343 and flows into the third groove 313. Since the arc wall portion 343 is formed from an arc shape centered on the center hole 345 of the sorting device 340, a load when a sphere collides is applied in a direction toward the rotation axis of the sorting device 340. It is suppressed that a load in the rotation direction is applied to the sorting device 340.

Therefore, it is possible to avoid a situation in which the sorting device 340 unintentionally returns to the initial state due to the impact of the ball flowing into the sorting device 340 in the changing state on the sorting device 340, and the sorting device 340 changes for a predetermined period. It can be ensured that the condition is maintained.

Next, with reference to FIG. 15, adjustment of the posture change timing of the sorting device 340 will be described. 15 (a) to 15 (c) are cross-sectional views of the second adjusting device 350 in a plane orthogonal to the rotation axis. 15 (a) to 15 (c) show that the internal structure of the center of gravity changing device 351 is visible, and FIG. 15 (a) shows the case where the sorting device 340 is in the initial state (see FIG. 6). In FIG. 15B, the case where the sorting device 340 is in the changed state (see FIG. 13) is shown, and in FIG. 15C, the state immediately before the sorting device 340 returns from the changed state to the initial state. Is illustrated.

As shown in FIG. 15, in the second adjusting device 350, the pseudo center of gravity sphere GB moves inside the recessed groove portion 351b as the posture changes. As a result, the position of the center of gravity of the second adjusting device 350 changes, and the second adjusting device 350 repeats stopping and rotating.

The operation of the second adjusting device 350 will be described. As shown in FIG. 15A, when the sorting device 340 is in the initial state (see FIG. 6), the pseudo-center-of-gravity sphere GB is arranged on the right side of the central hole 345. A load is applied in the direction of rotating the second adjusting device 350 clockwise in the front view (clockwise in FIG. 15). As a result, even if the gaming machine 10 (see FIG. 1) vibrates slightly, the sorting device 340 can maintain the posture at the initial position.

As shown in FIG. 15B, when the sorting device 340 is in the changed state (see FIG. 13), the inclination formed by the partition wall 351c and the directional valve 351e is inclined downward toward the left. At the same time, the inclination formed by the deceleration wall portion 351d is set to be downwardly inclined toward the right. Therefore, the pseudo center of gravity sphere GB rolls on the upper side of the partition wall 351c and flows to the left along the arrow L1, falls on the deceleration wall portion 351d at the end, rolls on the upper side of the deceleration wall portion 351d, and the arrow L2. It operates to flow to the right along.

As a result, the pseudo center of gravity sphere GB can be sent to the left of the central hole 345, so that the second adjusting device 350 is rotated counterclockwise in front view (counterclockwise in FIG. 15) by the weight of the pseudo center of gravity sphere GB. A load is applied in the direction. As a result, the sorting device 340 can be maintained in a changed state for a certain period of time (the period until the pseudo center of gravity sphere GB passes to the right of the central hole 345).

The period for maintaining the changed state can be arbitrarily changed depending on the degree of deceleration of the pseudo center of gravity sphere GB by the deceleration wall portion 351d. For example, if the flow speed of the pseudo center of gravity sphere GB is halved by the deceleration wall portion 351d, the period for maintaining the distribution device 340 in the changed state can be doubled.

As the mode of the deceleration wall portion 351d, various modes are exemplified. For example, a method of decelerating the translational movement speed of the pseudo center of gravity sphere GB by reducing the radius of gyration at the point where the pseudo center of gravity sphere GB comes into contact with the deceleration wall portion 351d is exemplified (see FIG. 12 (d)). That is, by receiving the rotation of the pseudo-center of gravity sphere GB not at the maximum diameter portion (center portion) but at the portion where the diameter becomes smaller (near the end portion), the translational movement distance per rotation of the pseudo-center-of-gravity sphere GB is obtained. This is a method of shortening and decelerating the pseudo center of gravity sphere GB without reducing the number of rotations. According to this method, the translational speed of the pseudo-center-of-gravity sphere GB after passing through the deceleration wall portion 351d can be increased as compared with the case of reducing the rotation speed of the pseudo-center-of-gravity sphere GB.

Therefore, immediately after reaching the right end of the deceleration wall portion 351d, the pseudo center of gravity sphere GB can be thrown to the right at a large speed, and immediately after the pseudo center of gravity sphere GB reaches the right end of the deceleration wall portion 351d, FIG. It is possible to shorten the period until the state changes to the state shown in (c).

As shown in FIG. 15 (c), the pseudo center of gravity sphere GB passes through the directional valve 351e before and after the state of the distribution device 340 changes from the changed state to the initial state. As shown in FIG. 15C, the directional valve 351e is configured to allow the pseudo-center-of-gravity sphere GB to flow to the right, while preventing the pseudo-center-of-gravity sphere GB from flowing to the left. This makes it possible to prevent the pseudo-center of gravity sphere GB from bouncing back to the left of the central hole 345.

In the present embodiment, the period from when the sorting device 340 changes to the changed state to when it returns to the initial state is a variable period which is easily selected when the number of reserved balls in the winning opening 64 (see FIG. 2) is four. It is set to a longer period than (shortest fluctuation period).

Therefore, when a ball is inserted into the distribution device when the distribution device 340 is in the initial state, and the ball enters the detection port 312d (see FIG. 6), the number of reserved balls in the winning port 64 becomes four. In addition, the balls that have entered the distribution device 340 before the end of the fluctuation that is started after that (before the number of reserved balls in the winning opening 64 is vacant) are all distributed to the third groove 313 (see FIG. 13). Then, while the ball passes through the third groove 313, the fluctuation of 1 of the winning opening 64 ends, and the number of reserved balls in the winning opening 64 becomes vacant, so that the winning opening 64 overflows (the state in which the number of reserved balls is the maximum). By entering the ball into the detection port 312d, it is possible to prevent the occurrence of a state in which a lottery opportunity cannot be obtained even though the ball has entered.

The degree of deceleration of the ball in the third groove 313 can be set by various methods. For example, the ball may be decelerated by attaching a high-friction sheet to the bottom wall on which the ball rolls.

Here, as a first setting example, the period until the ball passes through the third groove 313 is easily selected, for example, when the number of reserved balls in the winning opening 64 is four (the shortest variation period). By setting the period longer than that, when two balls enter the sorting device 340 in succession, the second ball enters the detection port 312d and the second ball enters the third groove. The period from passing through 313 to entering the detection port 312d can be made longer than the fluctuation period (shortest fluctuation period) that is likely to be selected when the number of reserved balls in the winning opening 64 is four. As a result, it is possible to prevent overflow from occurring at the winning opening 64.

Further, as a second setting example, the period until the ball passes through the third groove 313 is divided into, for example, a variable period that is easily selected when the number of reserved balls in the winning opening 64 is 3, and the number of reserved balls is 4. By setting the period longer than the total period of the fluctuation period (shortest fluctuation period) that is likely to be selected in the case of individual balls, even if two balls are continuously inserted into the third groove 313, one ball is inserted. Since the two fluctuations are digested in the period from when the eyeball enters the detection port 312d until the second ball passes through the third groove 313 and enters the detection port 312d, after that, Even if two balls enter the detection port 312d, it is possible to suppress the occurrence of overflow.

Next, the functional disk device 332b will be described with reference to FIG. In the functional disk device 332b, the position of the center of gravity changes as in the case of the second adjusting device 350 by moving the pseudo center of gravity sphere GB arranged between the functional disk device 332b and the main body plate member 331 (see FIG. 7). It is a device that changes the direction of the load applied to the 332b.

16 (a) to 16 (d) are cross-sectional views of the functional disk device 332b, which is a cross-sectional view of the functional disk device 332b in a plane perpendicular to the rotation axis. FIG. 16A shows the case where the speed reducer 320 is in the initial state (see FIG. 6), and FIG. 16B shows immediately after the speed reducer 320 changes from the initial state to the intermediate state (see FIG. 13). 16 (c) shows immediately after the speed reducer 320 changes its state from the intermediate state to the ascending state (see FIG. 14), and FIG. 16 (d) shows the speed reducer 320 from the intermediate state to the initial state. The state immediately after the state change is shown in the figure.

As shown in FIG. 16, the functional disk device 332b is a partition that limits the portion through which the sphere can pass from the recessed groove portion 332b1 that is recessed from the back side at a depth at which the pseudo-center of gravity sphere GB can move. The wall 332b2 and the partition wall 332b2 are arranged as a rollable plate portion on the lower side of the partition wall 332b2, and are formed so as to project a predetermined width from the end of the partition wall 332b2 and slow down the flow of the pseudo center of gravity sphere GB. The first deceleration wall portion 332b3, the second deceleration wall portion 332b4 that is arranged on the opposite side of the partition wall 332b2 with the first deceleration wall portion 332b3 sandwiched between them and decelerates the flow of the pseudo center of gravity sphere GB, and the pseudo center of gravity sphere GB. It is mainly provided with a directional valve 332b5 that limits the passage of the vehicle in one direction from the left side to the right side.

For convenience, the pseudo center of gravity sphere GB uses the same reference numerals as the pseudo center of gravity sphere GB accommodated in the second adjusting device 350, and is limited to those having the same shape and weight as the pseudo center of gravity sphere GB. Not the purpose.

The functional disk device 332b can allow the pseudo center of gravity sphere GB to flow down at the first deceleration wall portion 332b3 to pass through the directional valve 332b5, or can pass through the directional valve 332b5 to flow down at the second deceleration wall portion 332b4. .. Hereinafter, the operation of the functional disk device 332b will be described in detail. In addition, FIG. 6, FIG. 13 and FIG. 14 are referred to as appropriate.

As shown in FIG. 16A, when the speed reducer 3420 is in the initial state (see FIG. 6), the partition plate 332b is tilted downward to the right, and the pseudo center of gravity sphere GB is a functional disk device. It is maintained on the right side of 332b. As a result, a load for maintaining the slide moving member 321 downward is applied from the rotary urging device 332 to the slide moving member 321 (see FIG. 6). Therefore, when the gaming machine 10 (see FIG. 1) vibrates, it is possible to prevent the slide moving member 321 from moving up and down.

As shown in FIG. 16B, when the reduction gear 3420 is in the intermediate state (see FIG. 13), the partition plate 332b2 is in a mode of inclining downward to the left, while the first reduction wall portion 332b3 is It is considered to be a downward slope to the right. Therefore, the pseudo center of gravity sphere GB rolls the upper surface of the partition plate 332b2 to the left along the arrow L3, and then rolls to the right on the upper surface of the first deceleration wall portion 332b3 along the arrow L4. The center of gravity sphere GB is sent to the right side of the rotation center of the functional disk device 332b, and a load is applied in the direction of returning the functional disk device 332b to the initial state (direction of rotating clockwise in FIG. 16).

In the middle of the flow of the pseudo center of gravity sphere GB, as shown in FIG. 16 (b), in a state where the pseudo center of gravity sphere GB is arranged on the left side of the center of rotation, yesterday the disk device 332b was counterclockwise in FIG. 16 (b). Since the load is applied in the direction of rotating the slide moving member 321 due to gravity, the lowering of the slide moving member 321 can be stopped. Further, the weight of the sphere can prevent the slide moving member 321 from descending (even if the sphere descends, it is possible to form a state in which the slide moving member 321 immediately rises when the sphere arrives).

As shown in FIG. 16 (c), when the speed reducer 3420 is in the ascending state (see FIG. 14), the first deceleration wall portion 332b3 is in a mode of descending and tilting to the left, while the second deceleration wall. The portion 332b4 is in a mode of inclining downward to the right. Therefore, the pseudo-center of gravity sphere GB rolls the upper surface of the first deceleration wall portion 332b3 to the left along the arrow L5, and then rolls to the right on the upper surface of the second deceleration wall portion 332b4 along the arrow L6. As a result, the pseudo center of gravity sphere GB is sent to the right side of the rotation center of the functional disk device 332b, and a load is applied in the direction of returning the functional disk device 332b to the initial state (direction of rotating clockwise in FIG. 16).

When the pseudo center of gravity sphere GB is rolling on the upper surface of the first deceleration wall portion 332b3, the sphere passes through the main passage 311a and the deceleration device 320 moves to the ascending state, and the functional disk device 332b is shown in FIG. 16 (c). In the posture shown in the above, the pseudo center of gravity sphere GB is subsequently decelerated by the first deceleration wall portion 332b3 and further decelerated by the second deceleration wall portion 332b4, so that the reduction gear 320 is placed in the intermediate state. Compared with the case (see FIG. 13), the period until the pseudo-center of gravity sphere GB is arranged to the right of the center of rotation is lengthened. Therefore, the speed reducer 320 can be maintained in the ascending state (see FIG. 14) longer than the period in which it is maintained in the intermediate state (see FIG. 13).

As shown in FIG. 16D, when the pseudo center of gravity sphere GB arranged on the first deceleration wall portion 332b3 or the second deceleration wall portion 332b4 is arranged to the right of the center of the functional circle device 332b, the slide moving member The reduction device 320 operates due to the weight of 321 to bring the functional disk device 332b into the same posture as the initial state, and the pseudo center of gravity sphere GB is discharged from the first reduction wall portion 332b3 or the second reduction wall portion 332b4 and is recessed. Roll 332b1. When the pseudo center of gravity sphere GB passes through the directional valve 332b5, the functional disk device 332b returns to the initial state (see FIG. 16A).

A flow pattern of a sphere flowing down inside the delay device 300 will be described with reference to FIGS. 17 and 18. 17 (a), 17 (b), 18 (a) and 18 (b) are partial front views of the delay device 300. 17 (a), 17 (b), 18 (a) and 18 (b) show a case where three balls P1 to P3 are inserted in a row from the winning opening 64, and FIG. In a), a state in which the spheres P1 to P3 are arranged in front of the wind turbine member 322 is shown, and in FIG. 18 (b), the sphere P1 and the sphere P2 are separated from the second extending vane portion 322c of the wind turbine member 322. In FIG. 18 (c), the state in which the sphere P2 pushed the second extending wing portion 322c and reached the sorting device 340 is illustrated, and in FIG. 18 (d), the sphere P3 is the first. The state in which the two grooves 312 begin to invade is illustrated.

In addition, in FIG. 17 (a), FIG. 17 (b), FIG. 18 (a) and FIG. 18 (b), after the balls P1 to P3 enter the winning opening 64 in the lower right space of the structural drawing. A graph showing the situation of is illustrated. In addition, the timing at which the balls P1 to P3 enter the winning opening 64 actually deviates slightly (about 0.2 seconds), but in the graph, the balls P1 to P3 win the prize in order to facilitate understanding. It is illustrated as having entered the mouth 64 at the same time, and the horizontal axis is configured as the elapsed time T.

In the graph, the timing when the spheres P1 to P3 enter the winning opening 64 (“IN”) and the timing when the spheres P1 to P3 enter the detection opening 312d (“OUT”) are shown, and when the spheres P1 to P3 enter the winning opening 64 (“OUT”). Which section is flowing down is illustrated by a code. Further, in the corresponding drawing, which timing of the graph the state shown in FIGS. 17 (a), 17 (b), 18 (a) and 18 (b) represents is indicated by a triangular mark.

As shown in FIG. 17A, the spheres P1 to P3 flow down the first groove 311 under the same conditions until they reach the wind turbine member 322, and there is no difference in their velocities.

As shown in FIG. 17B, the first ball P1 pushes forward the first extending blade portion 322b of the wind turbine member 322, and the second ball P2 is separated from the second extending blade portion 322c. Then, the preceding sphere P1 flows down to the convex portion 321a1 without being decelerated, while the convex portion 321a1 projects into the main passage 311a on the downstream side of the sphere P2. Therefore, when the sphere P2 and the sphere P3 come into contact with the convex portion 321a1, a load in the direction opposite to the flow direction is intermittently applied and the sphere P3 decelerates. As a result, a space can be provided between the spheres P1 and the spheres P2. Therefore, for example, it is possible to prevent the spheres from being clogged and malfunctioning due to the two spheres being simultaneously entered into the sorting device 340. be able to.

In the present embodiment, the first period of passing through the first groove required for the ball P1 to pass through the first groove 311 is set to 2 seconds (T11 = 2s), and after the ball P1 has passed, the speed reducer 320 ( The deceleration return first start period, which is the period from the intermediate state to the start of returning to the initial state, is set to 5 seconds, and the speed reducer is set to return to the initial state 1 second after the start of return.

Further, the second period T2, which is the period from when the ball P1 enters the second groove 312 to when it enters the detection port 312d, is 1.5 seconds (T2 = 1.5s). The second period T2 is the first half T2a (T2a = 1s) of the second period, which is one second before reaching the sorting device 340, and the second half of the second period, which is 0.5 seconds after passing through the sorting device 340. It is divided into T2b (T2b = 0.5s), and the period during which the ball passes through the second groove 312 is invariant regardless of the state of the sorting device 340.

As shown in FIG. 18A, when the second ball P2 pushes the second extending blade portion 322c of the wind turbine member 322, the preceding ball P2 flows into the second groove, while the ball P3 , Flows into the recessed portion 311e on the back side along the inclined surface 321b2 of the slide moving member 321. As a result, in addition to being decelerated by the convex portion 321a1, the flow path of the sphere P3 is extended by the amount passing through the inner recessed portion 311e, so that the sphere P2 and the sphere P3 can be spaced apart from each other.

In the present embodiment, the first groove passage second period T12 required for the sphere P2 to pass through the first groove 311 is set to 3 seconds (T12 = 3s), and the sphere P3 passes through the first groove 311. The third period T13 required for passing through the first groove is set to 6 seconds (T13 = 6s). Further, the deceleration return second start period, which is the period from the passage of the ball P2 to the start of the deceleration device 320 returning to the initial state (from the ascending state), is set to 7 seconds, and the deceleration device is set to 2 seconds after the start of the return. It is set to return to the initial state.

Further, since the sphere P2 comes into contact with the arc wall portion 343 of the sorting device 340 and flows into the third groove 313, the path to the detection port 312d is extended as compared with the sphere P1. Therefore, the distance between the sphere P1 and the sphere P2 can be widened.

In the present embodiment, the third period T3 required for the balls P2 and P3 to pass through the third groove 313 is set to 3 seconds (T3 = 3s). Further, the speed of the pseudo center of gravity sphere GB of the second adjusting device 350 is set in such a manner that the distribution maintenance period BT1 which is the period from the change of the state of the distribution device 340 to the change state to the start of returning to the initial state is 4 seconds. It is set (BT1 = 4s).

As shown in FIG. 18B, when the speed reducer 320 is in the raised state, the distance between the end of the first overhanging plate portion 321a and the contact wall 312a is about the same as the diameter of the sphere. Will be done. Therefore, the spheres P2 and P3 are subjected to a large resistance when passing between the end portion of the first overhanging plate portion 321a and the contact wall 312a, and the momentum is reduced. Thereby, the distance between the spheres P1 and the spheres P2 and P3 can be widened.

As shown in FIG. 18B, the sphere P2 flows down the third groove 313 and receives the first wall portion 341 and presses it against the wall portion 312c, so that the sorting device 340 can be easily maintained in the changed state. it can.

As shown in the graph, the distribution device 340 is maintained in the changed state even at the timing when the sphere P3 flows into the distribution device 340 (at the timing when only the distribution maintenance period BT1 has elapsed after the state of the distribution device 340 changes to the changed state. The sphere P3 reaches the sorting device 340). Therefore, the ball P3 flows into the third groove 313. As a result, it is possible to prevent the distance between the sphere P2 and the sphere P3 from being shortened.

As shown in the graph, according to the present embodiment, when the spheres P1 to P3 enter the winning opening 64 in succession, the spheres P1 and P2 enter the detection opening 312d at intervals of 4 seconds, and the spheres P2 And the ball P3 enter at intervals of 3 seconds. In the present embodiment, the fluctuation period of 1 selected after the maximum number of reserved balls in the winning opening 64 is set to 3 seconds. Therefore, in the case of FIGS. 17 and 18, an overflow occurs in the winning opening 64. Can be prevented.

Further, in the present embodiment, the period during which the sorting device 340 is maintained in the changed state is one variable period selected after the number of reserved balls in the winning opening 64 is maximized when the balls flow into the detection port 312d. As shown in FIG. 18A, when the ball P2 enters the sorting device 340 during the fluctuation period, the ball P2 is surely flowed into the third groove 313. be able to. As a result, it is possible to prevent overflow from occurring when the balls continuously enter the sorting device 340.

Therefore, even when three balls P1 to P3 are continuously entered into the winning opening 64, the timing at which they are entered into the detection opening 312d can be shifted, and overflow at the winning opening 64 can be suppressed. Can be done. As a result, even if the player does not pay special attention, it is possible to avoid a situation in which the ball enters the winning opening 64 but cannot receive the lottery, and the game can be performed comfortably.

In the present embodiment, when another ball is connected to the rear of the ball P3 and another ball enters the winning opening 64 (when four balls are continuously entered), the fourth ball and the ball P3 are connected. The timing of entering the detection port 312d cannot be shifted. Therefore, it is desirable to recommend a stop hit so as not to play a game in which four balls are inserted into the winning opening 64 while the number of reserved balls in the winning opening 64 is three.

Further, as shown in the graph, when the balls P1 to P3 continuously enter the winning opening 64, for example, the ball P3 wins a prize at an interval of 1 second or more after entering the winning opening 64 of the ball P1. When entering the mouth 64, by the time the ball P3 reaches the sorting device 340, the sorting device 340 has been returned to the initial state, so that the ball P3 flows down the second groove 312 in the vertical direction and the detection port 312d. Enter the ball. In this case, the delay period of the ball P3 is not sufficient, and the overflow at the winning opening 64 cannot be suppressed.

Therefore, the effect of suppressing overflow when the third ball enters the winning opening 64 is limited to a limited situation (after the ball P1 and the ball P2 continuously enter the winning opening 64, the ball P1 enters the ball. Since it can be played only in the situation where the ball P3 enters the winning opening 64 within 1 second from the above, it happens to be stopped (holding the winning opening 64) while leaving the need for the player to make a stop. If you forget to stop launching the ball when the number of balls is 3, you can fortunately create a situation where the winning opening 64 does not overflow if the situation is met.

This makes it possible to form a clear difference in the number of lottery opportunities for the number of balls entered into the winning opening 64 between the player who makes a stop and the player who does not make a stop. In a rare situation where three balls enter the winning opening 64 in a row when the number of reserved balls in the opening 64 is 3, the third ball P3 does not overflow at the winning opening 64. It is possible to make the conditions strict (limit the ball entry interval) and produce the value when overflow does not occur.

As a result, it is possible to make the player who makes a stop hit more carefully (because it is possible to pay attention to the number of reserved balls and stop the launch at an early stage), so there is an opportunity for a lottery. It is possible to enthusiastically operate the handle 51 (see FIG. 1) in order to acquire more of the above, and it is possible to improve the interest of the player.

Next, a case where the balls P4 and P5 enter the delay device 300 at intervals will be described with reference to FIGS. 19 and 20. 19 (a), 19 (b) and 20 are partial front views of the delay device 300. FIG. 19 (a) shows a state in which the ball P4 reaches the wind turbine member 322 when the speed reducer 320 is in the initial state, and FIG. 19 (b) shows the speed reducer 320 in the intermediate state and the distribution device 340. The case where the ball P5 enters the winning opening 64 0.5 seconds after the ball P4 enters the detection port 312d (4 seconds after the ball P4 enters) is shown in the figure. In 20, the state immediately before the ball P5 is entered into the sorting device 340 is illustrated. In FIGS. 19 (a), 19 (b), and 20, in the lower right space of the structural drawing, a graph showing the situation after the balls P4 and P5 enter the winning opening 64 has a horizontal axis. It is shown as an elapsed time T.

In the graph, the timing when the spheres P4 and P5 enter the winning opening 64 (“IN”) and the timing when the spheres P4 and P5 enter the detection opening 312d (“OUT”) are shown, and when and which of the spheres P4 and P5 Whether it flows down the section is indicated by a symbol. Further, which timing of the graph the state shown in FIGS. 19A, 19B, and 20 represents is indicated by a triangular mark in the corresponding drawing.

In the state shown in FIG. 20, the ball P5 does not enter the third groove 313, flows vertically downward through the second groove 312, and enters the detection port 312d. Here, if the ball P5 enters the detection port 312d before the fluctuation immediately after the ball P4 enters the detection port 312d is completed, overflow may occur.

Therefore, in the present embodiment, the first groove passage second period T12 required for the ball P5 to pass through the speed reducer 320 in the intermediate state is the period of fluctuation when the number of reserved balls in the winning opening 64 is four (3). The mode is set to be longer than (seconds) (the first groove passage second period T12 is set to 3 seconds). In this case, even if the sphere P5 does not flow into the third groove 313 (flows down the second groove 312 in the vertical direction), the fluctuation ends before the sphere P5 passes over the slide moving member 321. It is possible to prevent the overflow from occurring at the winning opening 64. In this case, since the ball P5 does not flow down the third groove 313, the timing of the lottery by the ball P5 can be advanced, and the player can be prevented from getting bored.

Further, since the distribution maintenance period BT1 from the state change of the distribution device 340 to the start of returning to the initial state is set to 4 seconds, it is 3 seconds after the ball P4 enters the winning opening 64 (winning opening). It is possible to reliably enter the ball that has entered the third groove 313 (the period of fluctuation when the number of reserved balls of 64 is four). Further, since the ball can be entered into the third groove 313 until immediately before the sorting device 340 returns to the initial state, the ball P4 enters within less than 4 seconds after entering the winning opening 64. The ball can be reliably entered into the third groove 313. As a result, even when the balls P4 and P5 enter the winning opening 64 at intervals of 3 seconds or less, it is possible to prevent overflow from occurring at the winning opening 64.

Next, with reference to FIG. 21, a case where balls continuously enter the sorting device 340 will be described. In the present embodiment, for example, when the speed reducer 320 is in the ascending state (see FIG. 14), it is a state that occurs when two additional balls enter the winning opening 64 in succession (for example, FIG. 17 (see FIG. 14). This is a state that occurs when the balls P1 and P2 shown in a) are inserted, and after the balls P2 enter the second groove 312, two balls continuously enter the winning opening 64). 21 (a) to 21 (c) are partial front views of the delay device 300. FIG. 21 (a) shows a state in which the sorting device 340 is in the initial state and the ball P6 enters the sorting device 340. In FIG. 21 (b), the sorting device 340 is rotated by the weight of the ball P6 to rotate the ball. The state in which P7 is extruded is illustrated, and in FIG. 21 (c), the state in which the sphere P6 flows down the second groove 312 and the sphere P7 flows down the third groove 313 is shown.

As shown in FIG. 21A, the sorting device 340 is provided with a space capable of accommodating only one ball between the first wall portion 341 and the second wall portion 342. Therefore, when two balls reach the sorting device 340 in a row, the first ball P6 is housed in the sorting device 340, but the second ball P7 remains without being housed. Therefore, only the sphere P6 can flow down to the detection port 312d alone.

The tip convex portion 342a arranged at the tip of the second wall portion 342 of the sorting device 340 moves the sphere P7 to the entrance of the third groove 313 in a posture in which the sphere P7 remains outside (see FIG. 21B). It is formed in a manner of pushing out toward the tip (the entrance of the third groove 313 is formed at a position facing the tip convex portion 342a). Therefore, the ball P7 can be pushed out to the inner side of the third groove 313, and it is possible to prevent the ball P7 from staying near the entrance of the third groove 313. Thereby, for example, even if the sorting device 340 is set to return to the initial state immediately from the changed state, the ball P7 is prevented from entering the sorting device 340 (not properly pushed into the third groove 313). be able to.

As shown in FIG. 21 (c), the ball P6 enters the detection port 312d with the sorting device 340 as a boundary, and the ball P7 enters the detection port 312d after flowing down the third groove 313. Here, as described above, the third period T3, which is the period during which the balls P7 flow down the third groove 313, is set to 3 seconds, and that period is selected after the number of reserved balls in the winning opening 64 is maximized. Since the fluctuation period (3 seconds) of 1 or more is set, even if the ball P6 enters the detection port 312d when the number of reserved balls in the winning opening 64 is 3, the ball P7 enters the detection port 312d. By this time, one fluctuation will end. Therefore, when the ball P7 enters the detection port 312d, it is possible to prevent overflow from occurring at the winning port 64.

In the present embodiment, if another ball enters the detection port 312d within 3 seconds after the ball P7 enters the detection port 312d, the ball is configured to overflow at the winning port 64. To. As a result, it is possible to construct a flow path in which overflow can be suppressed when the number of balls entering in a short period of time is up to two, while overflow occurs when the number of balls entering in a short period of time is three. Therefore, it is possible to make the player carefully consider the firing intensity of the ball and the firing frequency of the ball in order to obtain more chances of lottery at the winning opening 64, and improve the playability regarding the mode of launching the ball. Can be made to.

Since the sorting device 340 rotates from the initial state to the changing state only by the weight of the sphere, the sphere P6 and the sphere P7 are arranged between the side wall portion 312e and the tip convex portion 342a. It is possible to solve the problem that occurs only when the sorting device 340 operates electrically, such as the sorting device 340 operating and causing ball clogging.

In the present embodiment, in the state of FIG. 21C, for example, the ball reaches the sorting device 340 at the timing when the sorting device 340 returns to the initial state within 1 second after reaching, and the next ball further reaches the sorting device 340. If the 340 reaches the sorting device 340 one second after returning to the initial state, there is a risk that the ball that arrived earlier and the ball that arrived later may collide at the confluence position of the first groove 311 and the third groove 313. Yes, in that case, two balls enter the detection port 312d at intervals of 3 seconds or less. Therefore, if the number of reserved balls in the winning opening 64 (see FIG. 20) is three while the preceding ball passes through the third groove 313, the overflow in the winning opening 64 cannot be avoided.

This is significantly different from the case where the two balls reach the sorting device 340 when the sorting device 340 is in the initial state. That is, when the two balls reach the distribution device 340 at 2-second intervals when the distribution device 340 is in the initial state, the latter balls are guided to the third groove 313 and therefore enter the detection port 312d. It is possible to secure an interval of 3 seconds or more (see FIG. 21). On the other hand, when the distribution device 340 is in a changing state and the spheres reach the distribution device 340 at 2-second intervals, the front sphere is guided to the third groove 313, and the rear sphere vertically downwards the second groove 312. There is a possibility that the ball may flow down, and the interval at which the ball enters the detection port 312d may be shorter than 3 seconds.

As a result, it is possible to form a flow path that cannot always suppress overflow when two balls enter the ball entry port 64 in succession. Therefore, while providing a mechanism that can suppress overflow, basically, it is assumed that the maximum number of lottery can be obtained by performing a game of stopping when the number of reserved balls in the winning opening 64 reaches three. The significance of hitting can be improved.

Next, the delayed floor device 400 will be described with reference to FIGS. 22 to 33. FIG. 22 is a partial front perspective view of the game board 13. As shown in FIG. 22, in the delay floor device 400, a part of the spheres flowing down to the left of the center frame 86 flows in (through a so-called “warp flow path”), and the sphere rolls on the upper part. A movable device that is configured to be possible and that repeatedly reciprocates to drop a sphere whose velocity in the left-right direction has converged to 0 toward the front side. And a link member 420 (see FIG. 24) that matches the movements of the pair of fan-shaped members 410, and a fixed floor that tiltably supports the fan-shaped member 410 and allows the ball to pass through before flowing into the fan-shaped member 410. It mainly comprises a fixed floor 430.

In the initial state (see FIG. 22), the delayed floor device 400 is configured in such a manner that the sphere can be easily converged at the center position in the left-right direction (the left-right peripheral portion of the fixed floor 430 is inclined downward toward the center position). The fan-shaped member 410 is arranged in a positional relationship in which the center position in the left-right direction and the center position of the winning opening 64 coincide with each other in the vertical direction. That is, the arrangement is such that the ball can be easily inserted from the delayed floor device 400 into the winning opening 64.

Among the fan-shaped members 410 arranged in pairs in the front-rear direction, the fan-shaped member 410 on the front side tilts forward in a manner of tilting forward toward the front side, so that the ball can easily enter the winning opening 64.

The fan-shaped member 410 will be described with reference to FIG. 23. Since the pair of fan-shaped members 410 are composed of the same members, one fan-shaped member 410 will be described, and the other fan-shaped member 410 will be omitted.

23 (a) is a top view of the fan-shaped member 410, FIG. 23 (b) is a side view of the fan-shaped member 410 in the direction of arrow XXIIIb of FIG. 23 (a), and FIG. 23 (c) is a side view of the fan-shaped member 410. FIG. 23 (a) is a cross-sectional view of the fan-shaped member 410 taken along the line XXIIIc-XXIIIc of FIG. 23 (a), and FIG. 23 (d) is a bottom view of the fan-shaped member 410 in the direction of arrow XXIIId of FIG. 23 (b).

As shown in FIG. 23, the fan-shaped member 410 includes a main body member 411 composed of a fan-shaped plate member and an extended arm portion 412 extending coaxially in the left-right direction from an intermediate position of the main body member 411. A convex fixing portion 413 having an insertion hole which is projected from the bottom surface of the main body member 411 in a pair and has an insertion hole through which the connecting rod 414 is inserted and fixed, and a connecting rod 414 which is inserted and fixed to the convex fixing portion 413. Mainly prepare.

The width of the main body member 411 is about the diameter of a sphere on the tapered side (lower side in FIG. 23A). Further, on the tapered side thereof, there is a chamfered portion 411a that is inclined downward, and an opening 411b that is formed between the convex fixing portions 413.

The connecting rod 414 is configured as a separate member from the main body member 411. When assembling, the link member 420 (see FIG. 24) is arranged between the convex fixing portions 413, and the connecting rod 414 is inserted into the adjusting elongated hole 422 of the link member 420, and the connecting rod is inserted. The 414 is fixed to the convex fixing portion 413. As a result, the fan-shaped member 410 and the link member 420 can be connected (see FIG. 25).

Next, the link member 420 will be described with reference to FIG. 24. The link member 420 is a member that connects a pair of fan-shaped members 410 and has a role of determining the operating direction thereof.

24 (a) is a side view of the link member 420, and FIG. 24 (b) is a bottom view of the link member 420 in the direction of arrow XXIVb of FIG. 24 (a). As shown in FIG. 24, the link member 420 has a main body member 421 formed of a plate-shaped member having an L-shaped cross section and a constant thickness (see FIG. 24 (b)), and a pair of front and rear members on the upper portion of the main body member 421. It mainly includes an adjustment elongated hole 422 drilled in the thickness direction and extended in the front-rear direction, and a support elongated hole 423 drilled in the thickness direction and extended in the vertical direction at the lower part of the main body member 421. ..

The adjustment elongated hole 422 is a hole through which the connecting rod 414 (see FIG. 23) of the fan-shaped member 410 is inserted. That is, the link member 420 and the pair of fan-shaped members 410 are connected via the adjustment elongated hole 422. The support elongated hole 423 is an elongated hole through which the support convex portion 434 (see FIG. 26) of the fixed floor 430 is inserted, and acts in a manner of designating the moving direction of the link member 420 in one direction (vertical direction).

The fan-shaped member 410 and the link member 420 in the pre-assembled state will be described with reference to FIG. 25. 25 (a) is a top view of the fan-shaped member 410 and the link member 420, and FIG. 25 (b) is a cross-sectional view of the fan-shaped member 410 and the link member 420 in the XXVb-XXVb line of FIG. 25 (a). .. The pre-assembled state shown in FIG. 25 refers to the sub-assembled state before assembling to the fixed floor 430. In the manufacturing process, the fan-shaped member 410 and the link member 420 are assembled to the fixed floor 430 after the pre-assembled state is configured.

In the pre-assembled state, the connecting rod 414 of the fan-shaped member 410 is fixed to the convex fixing portion 413 in a state of being inserted into the adjusting elongated hole 422 of the link member 420, whereby the fan-shaped member 410 and the link member 420 are connected to each other. Will be done.

As shown in FIG. 25, since the pair of fan-shaped members 410 are connected by the link member 420, when one fan-shaped member 410 operates, the operation is transmitted to the other fan-shaped member 410 via the link member 420. Consists of aspects.

Next, the fixed floor 430 will be described with reference to FIGS. 26 and 27. 26 is a top view of the fixed floor 430, FIG. 27 (a) is a cross-sectional view of the fixed floor 430 in line XXVIIa-XXVIIa of FIG. 26, and FIG. 27 (b) is XXVIIb-XXVIIb of FIG. It is sectional drawing of the fixed floor 430 in line. Note that FIGS. 26 and 27 show a state in which the fan-shaped member 410 and the link member 420 are removed. Further, in FIG. 26, the support portion 432 is partially cross-sectionally viewed.

As shown in FIGS. 26, 27 (a) and 27 (b), in the fixed floor 430, the fan-shaped member 410 is arranged in the assembled state (see FIG. 22), and the upper surface of the fan-shaped member 410 and the fixed floor 430 are formed. The portion between the rotating shafts of the fan-shaped member 410 is recessed corresponding to the thickness of the fan-shaped member 410 so as to be formed at the surface position, and the outer portion thereof is recessed in such a manner that it does not interfere with the movement of the fan-shaped member 410. The recessed floor 431 to be formed, the support portion 432 on which the extension arm portion 412 of the fan-shaped member 410 is supported when the recessed floor 431 is arranged, and the central portion of the recessed floor 431 are opened in the vertical direction. At the hollow portion 433, which is a cavity, the support convex portion 434 which is projected from the side wall forming the hollow portion 433 in the left-right direction, and the position where the fan-shaped member 410 is deviated from the closest position to the left and right in the assembled state. It mainly includes an inflow port 435 that is recessed with a size that allows the ball to flow in, and a delay flow path 436 that communicates from the inflow port 435 and allows the ball to flow down.

The support portion 432 includes a support groove portion 432a having a groove shape for supporting the extended arm portion 412 of the fan-shaped member 410, and a support lid portion 432b that covers the support groove portion 432a from above and covers the support groove portion 432a.

The hollow portion 433 is a cavity in which the link member 420 is housed, and the support convex portion 434 is a protrusion inserted into the support elongated hole 423 of the link member 420. When assembling the link member 420, the link member 420 is inserted into the gap between the hollow portion 433 and the tip of the support convex portion 434, and then the link member 420 is slid in the left-right direction to support the convex portion. The portion 434 can be inserted through the support elongated hole 423.

The inflow port 435 is composed of a diameter slightly larger than the diameter of the sphere. Therefore, when the member is covered above the inflow port 435 in a manner of blocking a part of the inflow port 435, it is impossible for the ball to flow into the inflow port 435.

The delay flow path 436 is a flow path for delaying the entry of the ball into the winning opening 64 with respect to the ball directly entering the winning opening 64 from the fan-shaped member 410. For example, by making the period required for the ball to pass through the delay flow path 436 longer than the fluctuation period of 1 that occurs when the ball enters the winning opening 64, an overflow occurs at the winning opening 64. It can be suppressed.

For example, by setting the period required for the balls to pass through the delay flow path 436 to be longer than the variable period that is easily selected when the number of reserved balls in the winning opening 64 is 4, the number of reserved balls in the winning opening 64 can be increased. Even if the first ball that has fallen from the fan-shaped member 410 directly enters the winning opening 64 and the second ball enters the inflow port 435 in the three states, the two balls Since the fluctuation of 1 is completed by the time the eye ball enters the winning opening 64, it is possible to suppress the overflow at the winning opening 64 due to the second ball entering the winning opening 64. it can.

A method of assembling the fan-shaped member 410 and the link member 420 (see FIG. 25) to the fixed floor 430 will be described. First, of the fan-shaped member 410 and the link member 420 in the pre-assembled state described above, the link member 420 is inserted into the cavity portion 433, and the support elongated hole 423 (see FIG. 25) is inserted into the support convex portion 434 by the above method. After fitting, the extended arm portion 412 (see FIG. 25) of the fan-shaped member 410 is placed on the support groove portion 432a, and the support lid portion 432b is covered and fitted over the support groove portion 432a, whereby the fan-shaped member 410 is fitted with the support portion of the fixed floor 430. The link member 420 is supported by the 432 so as to be tiltable, and the link member 420 is supported so as to be movable up and down (along the extending direction of the support elongated hole 423). As a result, the fan-shaped member 410 and the link member 420 are assembled to the fixed floor 430 to form the delayed floor device 400.

The state change of the delayed floor device 400 will be described with reference to FIG. 28. 28 (a) is a partial top view of the delayed floor device 400, FIG. 28 (b) is a cross-sectional view of the delayed floor device 400 in line XXVIIIb-XXVIIIb of FIG. 28 (a), and FIG. 28 (c). ) Is a partial top view of the delayed floor device 400, and FIG. 28 (d) is a cross-sectional view of the delayed floor device 400 on the line XXVIIId-XXVIIId of FIG. 28 (c).

In the initial state shown in FIGS. 28 (a) and 28 (b), the pair of fan-shaped members 410 are in a parallel posture, and in the tilted state shown in FIGS. 28 (c) and 28 (d), the fan-shaped members are in a parallel posture. It is assumed that 410 is tilted by about 45 ° from the initial state.

The major difference between the initial state and the tilted state is whether or not the ball can enter the inflow port 435 and whether or not the ball can pass through the intermediate position of the pair of fan-shaped members 410. Regarding the former, in the initial state, a part of the fan-shaped member 410 is covered on the upper part of the inflow port 435, so that the ball cannot enter the inflow port 435. Since the fan-shaped member 410 retreats from the upper part of the inflow port 435 (because it is tilted to the retreating position), the ball can enter the inflow port 435.

Regarding the latter, in the initial state, the fan-shaped member 410 is in a parallel posture so that the sphere can pass through the upper part between the fan-shaped members 410, but in the tilted state, the fan-shaped member 410 is at a position where the sphere passes. The ball that has flowed into the portion between the fan-shaped members 410 collides with the fan-shaped member 410 and is prevented from passing through. Since the inflow port 435 is arranged between the fan-shaped members 410 in the tilted state, the ball colliding with the fan-shaped member 410 does not bounce (such as when it vibrates in the vertical direction) and stays above the inflow port 435. In this case, it is possible to drop the ball directly into the inflow port 435.

With reference to FIG. 29, the operation mode of the delay floor device 400 due to the difference in position when the ball falls from the fixed floor 430 to the front side will be described. 29 (a) is a top view of the delayed floor device 400, and FIG. 29 (b) is a cross-sectional view of the delayed floor device 400 in line XXIXb-XXIXb of FIG. 29 (a), FIG. 29 (c). Is a top view of the delayed floor device 400, and FIG. 29 (d) is a cross-sectional view of the delayed floor device 400 on the XXIXd-XXIXd line of FIG. 29 (c).

As shown in FIGS. 29 (c) and 29 (d), the delay floor device 400 is used to move the ball when the ball P11 previously on the delay floor device 400 falls to the front side of the fixed floor 430. Along (using the weight of the sphere), the fan-shaped member 410 operates. Therefore, a drive source such as a motor for operating the delay floor device 400 can be eliminated.

29 (a) and 29 (b) show a state in which the sphere P11 is about to fall from a position away from the fan-shaped member 410, and in FIGS. 29 (c) and 29 (d), the sphere P11 is fan-shaped. A state in which the member 410 is about to fall from the center position to the front side of the fixed floor 430 is shown.

Here, it is possible to configure the delay floor device 400 to move each time the ball passes over the delay floor device 400, but in that case, the delay floor device 400 does not depend on how the ball passes. There is a risk that the entry into the winning opening 64 will be unnecessarily delayed due to the influence of. In that case, the start of the fluctuation triggered by the entry of the ball into the winning opening 64 is delayed, which causes dissatisfaction of the player.

On the other hand, in the present embodiment, as shown in FIG. 29, the ball P11 falls from the state where the ball P11 is on the fan-shaped member 410, which is a position where the ball P11 can easily enter the winning opening 64 as it is, to the front side of the fixed floor 430. When the delay floor device 400 is tilted in the leaning state, while the ball P11 falls from a position away from the fan-shaped member 410, which is a position unlikely to enter the winning opening 64 even if the ball P11 falls. The delayed floor device 400 is configured to maintain the initial state. Therefore, the delayed floor device 400 can be operated only when the falling ball P11 is likely to enter the winning opening 64.

As a result, the delayed floor device 400 operates even when it is not necessary, and it is possible to prevent the ball from entering the winning opening 64 from being unnecessarily delayed. It is possible to avoid delaying the start of the fluctuation, and it is possible to improve the interest of the player.

As shown in FIG. 29 (d), the chamfered portion 411a is formed at the tip of the fan-shaped member 410, so that the tip of the fan-shaped member 410 is inclined while protruding from the front surface of the game board 13 in the initial state. In the state, it can be configured to be pulled backward from the front surface of the game board 13. As a result, the ball can be rolled to a position where it can easily fall into the winning opening 64 (front side of the front surface of the game board 13) and then dropped. Therefore, the ball falling from the state shown in FIG. 29 (d) can be dropped. It is possible to improve the probability of entering the winning opening 64.

With reference to FIG. 30, the relationship between the ball P11 previously on the delayed floor device 400 and the ball P12 newly entered in the delayed floor device 400 will be described. 30 (a) is a top view of the delayed floor device 400, and FIG. 30 (b) is a cross-sectional view of the delayed floor device 400 in the line XXXb-XXXb of FIG. 30 (a).

30 (a) and 30 (b) show a state in which the sphere P11 flows down to the front side of the fan-shaped member 410, the fan-shaped member 410 is tilted, and then the sphere P12 is inserted from the left-right direction. To.

A predetermined ball reaches the center of the floor portion arranged above the winning opening 64, and another ball rolls on the floor portion from the left-right direction at the timing when it is about to fall to the winning opening 64 and collides with the predetermined ball. However, the predetermined ball may come off from the winning opening 64, which has been a source of deteriorating the player's interest.

On the other hand, in the present embodiment, as shown in FIG. 30, when the sphere P21 rolls at the timing when the sphere P11 falls from the front side of the fan-shaped member 410, the delay floor device 400 is tilted and the delay floor device 400 is tilted. By colliding the sphere P12 with the fan-shaped member 410, it is possible to prevent the sphere P11 from colliding with the sphere P12.

At this time, as shown in FIG. 30A, the gap formed by the tip portions of the pair of fan-shaped members 410 is tapered toward the traveling direction of the sphere P12 (to the right in FIG. 30A). Therefore, even if the sphere P12 rolls at a position slightly deviated from the intermediate portion of the pair of fan-shaped members 410 in the front-rear direction and collides with the fan-shaped member 410, the speed direction of the spheres P12 is paired along the tapered shape of the gap. It can be modified in the direction toward the intermediate position of the fan-shaped member 410. Therefore, the rolling path of the sphere P12 can be limited, and it is possible to easily avoid the collision between the sphere P12 and the sphere P11.

Next, with reference to FIG. 31, two balls P11 and P12 enter the delayed floor device 400 at intervals, and the delayed floor device 400 in a state where the reciprocating motion is repeated and the velocity in the left-right direction converges to 0. The action of is described.

31 (a) is a top view of the delayed floor device 400, and FIG. 31 (b) is a cross-sectional view of the delayed floor device 400 in the line XXXIb-XXXIb of FIG. 31 (a). Is a top view of the delayed floor device 400, and FIG. 31 (d) is a cross-sectional view of the delayed floor device 400 on the line XXXId-XXXId of FIG. 31 (c).

In FIGS. 31 (a) and 31 (b), the delayed floor device 400 is in the initial state, and the sphere P11 rides on the fan-shaped member 410 on the front side and the sphere P12 rides on the fan-shaped member 410 on the back side. Illustrated, in FIGS. 31 (c) and 31 (d), the sphere P11 flows down to the front side from the state shown in FIGS. 31 (a) and 31 (b), and the delayed floor device 400 is tilted. ..

As shown in FIGS. 31 (a) to 31 (d), in the sphere P12 on the fan-shaped member 410 on the back side, the sphere P11 flows down from the fan-shaped member 410 on the front side, and the delay floor device 400 is in an inclined state. As a result, the fan-shaped member 410 on the back side is pushed back in the back direction (to the right in FIG. 31B) along the inclination of the fan-shaped member 410.

After that, the ball P11 falls and the delay floor device 400 returns to the initial state, so that the ball P12 can pass over the delay floor device 400 again and roll above the fan-shaped member 410 on the front side. .. That is, from the state shown in FIG. 31 (a), as compared with the case where the sphere P11 and the sphere P12 continuously enter the winning opening 64, the sphere P11 is pushed back by the amount that the sphere P11 and the sphere P12 enter. The intervals can be separated. As a result, it is possible to prevent the ball P11 and the ball P12 from entering the winning opening 64 and causing an overflow at the winning opening 64.

Next, referring to FIG. 32, two spheres P11 and P12 enter the delay floor device 400, and the spheres P11 and P12 move in the front-rear direction in a state where the reciprocating motion is repeated and the velocity in the left-right direction converges to 0. The operation of the delayed floor device 400 when arranged in a row will be described.

32 (a) is a top view of the delayed floor device 400, and FIG. 32 (b) is a cross-sectional view of the delayed floor device 400 in the line XXXIIb-XXXIIb of FIG. 32 (a). Is a top view of the delayed floor device 400, and FIG. 32 (d) is a front view of the delayed floor device 400 in the direction of arrow XXXIId of FIG. 32 (c).

As shown in FIGS. 32 (a) and 32 (b), when the two spheres P11 and P12 are arranged in a row, the spheres P11 are on the front side (front side) of the extended arm portion 412 of the fan-shaped member 410 on the front side. In the state of being arranged on the left side of FIG. 32 (b), the sphere P12 is arranged near the intermediate position of the pair of front and rear fan-shaped members 410 (see FIG. 32 (b)).

From this state, when the sphere P11 falls from the front side of the delay floor device 400 and the delay floor device 400 is tilted, the sphere P12 is attached to the tip portion of the fan-shaped member 410 when the tip portion (arc portion) is raised. Can be lifted. In the present embodiment, since the tip portion of the fan-shaped member 410 has an arc shape, the tip portion of the fan-shaped member 410 supporting the sphere P12 tilts downward as it goes outward in the left-right direction in the tilted state (FIG. 32 (d)). reference). Therefore, the sphere P12 does not continue to be maintained at the center of the left and right sides of the fan-shaped member 410, but flows down to the left and right outside along the shape of the tip portion of the fan-shaped member 410. As a result, the sphere P12 flows from the fan-shaped member 410 into the inflow port 435. Therefore, it is possible to prevent the ball P12 from entering the winning opening 64 in succession with the ball P11.

33 (a) and 33 (b) are cross-sectional views of the delayed floor device 400 on line XXXIIIa-XXXIIIa of FIG. 32 (c). In FIG. 33 (a), the state in which the spheres P11 and P12 are flowing down from the state shown in FIG. 32 (c) is in the process of flowing down, and in FIG. 33 (b), the spheres P11 and P11 are further changed from the state shown in FIG. 33 (a). The state in which P12 flows down and the ball P11 enters the winning opening 64 is shown in the figure.

As shown in FIGS. 33 (a) and 33 (b), when the spheres P11 and P12 flow down in succession on the delayed floor device 400, the sphere P11 falls on the front side of the game board 13 and the sphere P12 is delayed. It flows down the flow path 436. That is, since the flow paths of the two balls P11 and P12 are separated and the delayed floor device 400 is composed of a long flow path, the timing at which the two balls P11 and P12 win the winning opening 64 is shifted. Can be done.

Therefore, for example, even if the information is acquired immediately after entering the winning opening 64 and the fluctuation is started by the third symbol display device 81 (see FIG. 2), the winning opening 64 may overflow. Can be suppressed.

That is, the number of reserved balls in the winning opening 64 is 4 during the period from the position of the sphere P12 shown in FIG. 33 (b) until the sphere P12 flows down to the winning opening 64 by flowing down the remaining portion of the delay flow path 436. By setting a period longer than the fluctuation period (shortest fluctuation period) that is likely to be selected in the case of individual pieces, it is possible to suppress the occurrence of overflow at the winning opening 64.

Next, the second embodiment will be described with reference to FIG. 34. In the first embodiment, the case where the sorting device 340 changes the posture only by moving the center of gravity has been described, but in the delay device 2300 in the second embodiment, the locking device 2315 arranged in the main body member 2310 has a long hole. It is supported by 2316 and is configured to maintain the posture of the sorting device 2340. The same parts as those of the above-described embodiments are designated by the same reference numerals, and the description thereof will be omitted.

34 (a) to 34 (c) are partial front views of the delay device 2300 according to the second embodiment. Note that FIG. 34 (a) shows a state in which the spheres P21 and P22 reach the sorting device 2340 in the initial state in a row, and FIG. 34 (b) shows a state in which the sorting device 2340 changes depending on the weight of the spheres P21. The state in which the sphere P22 flows down the third groove 313 is shown as the state changes to, and in FIG. 34 (c), the sphere P22 is released from the locking device 2315, and the sorting device 2340 returns to the initial state. The state in which the movement is started is shown in the figure. In the present embodiment, the second adjusting device 350 is not arranged in the sorting device 2340, and the sorting device 2340 is urged toward the initial state by a spring mechanism (not shown).

In the sorting device 2340, the first wall portion 2341 is composed of about half the length of the second wall portion 342. As a result, it is possible to prevent the ball P22 flowing down from the third groove 313 from colliding with the first wall portion 2341, and to prevent the ball P22 from interfering with the return operation of the sorting device 2340.

As shown in FIG. 34 (a), the locking device 2315 has a length extending in the left-right direction on the wall portion on the back side (back side in the vertical direction of the paper surface of FIG. 34) of the main body member 2310 at the lower end portion of the side wall portion 312e. A hook member 2315a that is slidably and rotatably supported by a long hole 2316, which is a hole, and a torsion spring 2315b that generates an elastic force that urges the hook member 2315a to the right and clockwise in the front view. , Equipped with. In the present embodiment, a space is formed in the lower end portion of the side wall portion 312e so that the hook member 2315a can pass through the space.

The hook member 2315a includes a shaft portion 2315a1 supported by an elongated hole 2316 extending in the left-right direction in a wall portion formed between a pair of upper and lower third grooves 313, and a shaft portion 2315a1 thereof. The contact portion 2315a2 is integrally formed with the shaft portion 2315a1 and is formed so as to penetrate the side wall portion 312e and project to the upper right side (upper right side of FIG. 34) of the shaft portion 2315a1. It mainly includes a release portion 2315a3 formed by projecting inward of the third groove 313 on the side.

The contact portion 2315a2 is arranged at a position where it interferes with the movement locus of the tip convex portion 342a of the sorting device 2340. The shape of the abutting portion 2315a2 is such that the upper surface portion suddenly descends and inclines toward the right, and the lower surface portion has a shape along the left-right direction (a shape that makes surface contact with the tip convex portion 342a). When the state changes from the initial state to the changing state, the resistance applied to the sorting device 2340 can be suppressed and the moving speed thereof can be improved, while when the sorting device 2340 changes from the changed state to the initial state, the state changes. , The resistance applied to the sorting device 2340 can be increased to facilitate locking of the sorting device 2340 in a changed state.

Further, since the shaft portion 2315a1 is configured to be slidable in the left-right direction along the elongated hole 2316, the hook member 2315a can be moved in a state immediately before the sorting device 2340 changes (immediately before FIG. 34B). You can escape to the left. As a result, as compared with the case where the hook member 2315a is pivotally supported, it is possible to prevent the sorting device 2340 from colliding with the locking device 2315 and engaging with the locking device 2315, resulting in malfunction.

In the torsion spring 2315b, the torsion portion is wound around the shaft portion 2315a1, one end portion (the left end portion in FIG. 34 (a)) is locked to the main body member 2310, and the other end portion (FIG. 34 (a)). ) The right end) is configured to be locked to the hook member 2315a.

As shown in FIG. 34 (b), when the distribution device 2340 is changed by the weight of the sphere P21, the tip convex portion 342a is locked to the contact portion 2315a2. As a result, the sorting device 2340 is maintained in a changed state. In the present embodiment, as long as the locking device 2315 does not change its posture, the sorting device 2340 maintains the changed state.

As shown in FIG. 34 (c), when the sphere P22 flowing down the third groove 313 comes into contact with the release portion 2315a and the hook member 2315a changes its posture counterclockwise when viewed from the front, the distribution device 2340 by the hook member 2315a (The contact portion 2315a2 is arranged outside the movement locus of the sorting device 2340), and the sorting device 2340 can be returned to the initial state.

According to this, in a state where the urging force in the front-view clockwise direction is always applied to the distribution device 2340, a time delay is formed from the state change of the distribution device 2340 to the change state to the start of movement toward the initial state. can do. Therefore, with a simple configuration, the spheres P21 and P22 can be reliably distributed to separate flow paths.

Although the case where the spheres P21 and P22 flow down in succession is described in FIG. 34, the effect of the present embodiment is that the spheres P21 and P22 are effective in light of the fact that the locking device 2315a is released by the flow of the spheres P22. It is exhibited regardless of the arrival interval of the sorting device 2340.

Next, a third embodiment will be described with reference to FIGS. 35 and 36. In the first embodiment, the case where the state of the delay device 300 is changed by the action of a sphere flowing down the upstream side of the detection port 312d has been described, but the delay device 3300 in the third embodiment has a downstream side of the detection port 312d. It is composed of a mode in which the state changes due to the action of a flowing sphere. The same parts as those of the above-described embodiments are designated by the same reference numerals, and the description thereof will be omitted. Further, in the present embodiment, the detection port 312d is arranged so as to have an opening facing in the left-right direction.

35 (a), 35 (b), 35 (c), 36 (a), 36 (b) and 36 (c) show the time in which the spheres P31 and P32 flow through the delay device 3300. It is a partial front view of the delay device 3300 in the third embodiment illustrated in series.

In addition, in FIG. 35A, a state in which the stop device 3340 is set to the initial state and the balls P31 and P32 continuously enter the winning opening 64 and reach the stop device 3340 is shown in FIG. 35B. In FIG. 35 (a), a state in which the stop device 3340 is rotated by a predetermined amount from the state of FIG. 35 (a) is shown, and in FIG. 35 (c), a state in which the stop device 3340 is in a changed state is shown.

Further, FIG. 36 (a) shows a state in which the preceding sphere P31 passes through the detection port 312d in the left-right direction and abuts on the maintenance device 3360 to change the posture of the maintenance device 3360, and FIG. 36 (b) shows a state in which the posture of the maintenance device 3360 is changed. , The state in which the stop device 3340 is changed in posture from the changed state to the initial state and a gap is provided between the stop device 3340 and the second groove 3312 so that one sphere can pass through is illustrated. In FIG. 36 (c), the rear sphere is shown. The state in which P32 flows down toward the detection port 312d is illustrated.

As shown in FIG. 35 (a), the delay device 3300 includes a main body member 3310 having a flow path for guiding a ball that has entered the winning opening 64 to the detection port 312d, and a ball that flows down inside the main body member 3310. When the stop device 3340 whose state changes due to the action and the stop device 3340 are in the changed state (see FIG. 35 (c)), the state is maintained and the posture changes due to the action of the ball passing through the detection port 312d. Along with this, a maintenance device 3360 for releasing the maintenance of the state of the stop device 3340 is mainly provided.

As shown in FIG. 35 (a), the main body member 3310 constitutes a flow path that inclines downward, and guides a ball that has entered from the winning opening 64 to a vertically upward position of the detection opening 312d, and a first groove 3311 thereof. It mainly includes a second groove 3312 extending vertically from the lower end portion of the first groove 3311 to the detection port 312d, and a post-detection flow path 3313 in which a ball passing through the detection port 312d is guided. The first groove 3311 and the second groove 3312 have a groove shape having an open portion on the game board 13 side, and in the assembled state, the open portion is closed by the game board 13 to provide a passage through which the ball flows down. It is formed.

The second groove 3312 has an accommodating recess 3312f in which the side wall portion 312e extends to the detection port 312d and is formed as a recess having a size capable of accommodating half of the balls between the contact wall 312a and the side wall portion 312e. Be prepared.

Further, a receiving wall portion 3312c is provided on the opposite side of the side wall portion 312e, and a housing recess 3312c1 is recessed in the receiving wall portion 3312c toward the rear. The accommodating recess 3312c1 is arranged in a positional relationship in which the magnet portion 3346 can be accommodated when the stopping device 3340 is in a changed state (see FIG. 35A).

The accommodating recess 3312f extends along a straight line on which the lower wall surface for receiving the ball passes through the central hole 345 of the stopping device 3340. As a result, the direction in which the ball P32 waiting in the accommodating recess 3312f starts to flow down due to gravity can be set to the direction toward the stop device 3340. Therefore, when the sphere P32 is in a state where it can flow down, the sphere P32 can be smoothly flowed down.

The post-detection flow path 3313 is a flow path through which the ball passing through the detection port 312d flows down, is arranged directly under the contact portion 3363 of the maintenance device 3360, and is a bearing portion 3313a that pivotally supports the shaft portion 3361a of the maintenance device 3360. The opening 3133b, which is an opening that allows the contact portion 3363 to enter and exit, and the main body rod are projected from the upper wall of the flow path 3313 after detection toward the lower side surface of the main body rod 3361 of the maintenance device 3360. It includes a locking portion 3313c that locks the movement of the 3361, and a delay flow path 3313d that extends from the detection port 312d to the opening 3313b.

The stop device 3340 does not include the second adjusting device 350 configured to be movable at the position of the center of gravity described in the first embodiment, and the center of gravity G3 is a line extending the second wall portion 342 and the stop device 3340. It is fixedly placed at the intersection with the circumference of. In the second wall portion 342, the formation of the tip convex portion 342a is omitted.

Further, the stop device 3340 includes a magnet portion 3346 that extends from the first wall portion 341 of the stop device 3340 toward the opposite side of the second wall portion 342 and is made of a magnetic material.

The maintenance device 3360 is a pendulum-shaped device rotatably supported by the bearing portion 3313a, and is a rod-shaped member having a shaft portion 3361a pivotally supported by the bearing portion 3313a at an intermediate position, and a main body rod 3361 thereof. The posture of the main body rod 3361, which is arranged at the end of the main body rod 3361 on the side close to the receiving wall portion 312c and is arranged at the end of the magnet portion 3362 made of a magnetic material and the magnet portion 3362 on the opposite side. It mainly includes a contact portion 3363 that is arranged at a position where it can enter the inside of the flow path 3313 after detection due to a change and is arranged so that it can come into contact with a ball that flows down.

In the present embodiment, as shown in FIG. 35A, the posture in which the main body rod 3361 is supported by the locking portion 3313c is the initial state of the maintenance device 3360. That is, in the initial state, the magnet portion 3362 is arranged so as to face the accommodating recess 3312c1, the contact portion 3363 projects inward of the flow path 3313 after detection, and the weight of the contact portion 3363 causes the maintenance device 3360 to extend. Posture is maintained.

The end face of the magnet portion 3362 is a straight line drawn vertically from the end face, and the upper portion of the straight line is omitted with the straight line passing through the shaft portion 3361a as a boundary.

That is, the end face portion that is drawn vertically from the end face and through which the straight line passing through the shaft portion 3361a passes is closest to the receiving wall portion 3312c in the initial state, and the upper portion (main body rod 3361 is viewed from the front). Since the portion that moves closer to the receiving wall portion 3312c by rotating counterclockwise) is omitted, the same portion is closest to the receiving wall portion 3312c even after the maintenance device 3360 changes its posture from the initial state. (All portions of the end face of the magnet portion 3362 are configured to be away from the receiving wall portion 3312c).

Therefore, as shown in FIG. 35 (c), the maintenance device 3360 is changed in posture by the action of a sphere from the state where the magnet portion 3346 of the stop device 3340 is close to the magnet portion 3362 of the maintenance device 3360 and a magnetic force in the attraction direction is generated. As a result, the end face of the magnet portion 3362 can be separated from the magnet portion 3346 of the stop device 3340.

Further, since the magnet portion 3362 is not moved in the direction perpendicular to the suction surface, but is separated while tilting the posture with respect to the suction surface, the magnet portions 3346 and 3362 can be attracted by a weak force. It can be released.

The change in the state of the delay device 3300 when the spheres P31 and P32 pass through the main body member 3310 will be described in chronological order.

As shown in FIG. 35A, when the balls P31 and P32 enter the winning opening 64, the balls P31 and P32 reach the stop device 3340 through the first groove 3311 and the second groove 3312. In the present embodiment, the space between the first wall portion 341 and the second wall portion 342 of the stop device 3340 is set to a size capable of accommodating one sphere, so that only the former sphere P31 is accommodated and the latter sphere P31 is accommodated. The sphere P32 is maintained outside the stop device 3340.

As shown in FIG. 35 (b), the stop device 3340 is rotated from the initial state by the weight of the front sphere P31, and the rear sphere P32 is pushed by the outer end portion of the second wall portion 342 into the accommodating recess 3312f. The left part is housed. Since the position accommodated in the accommodating recess 3312f is the lowermost position on the upstream side of the stop device 3340 of the second groove 3312, the sphere P32 is maintained at the position shown in FIG. 35 (b) by the action of gravity. To.

As shown in FIG. 35 (c), in a state where the sphere P31 flows down to the detection port 312d, the first wall portion 341 of the stop device 3340 and the receiving wall portion 3312c come into contact with each other, and the magnet portion 3346 is accommodated in the accommodating recess 3312c1. Will be done. In this state, the magnet portion 3346 is close to the magnet portion 3362 of the maintenance device 3360 and a magnetic force in the suction direction is generated, so that the state of the stop device 3340 is maintained in the changed state. Therefore, even if the ball P31 flows down to the outside of the stop device 3340, the ball P32 remains stopped.

As shown in FIG. 36 (a), after the previous sphere P31 has passed through the delay flow path 3313d, it comes into contact with the contact portion 3363, whereby the main body rod 3361 of the maintenance device 3360 rotates, and the magnet portion 3362 becomes It is separated from the magnet portion 3346.

As a result, the magnetic force acting on the stop device 3340 is sharply reduced, and the force for stopping the rotation of the stop device 3340 is released. Therefore, the center of gravity G3 of the stop device 3340 is moved downward by the action of gravity. , The stop device 3340 starts rotating counterclockwise when viewed from the front.

In the present embodiment, the distance between the shaft portion 3361a and the contact portion 3363 is several times (about 5 times) longer than the distance between the shaft portion 3361a and the magnet portion 3362. The maintenance device 3360 can be rotated with a small load of the weight of the sphere P31.

Further, since the moving width on the magnet portion 3362 side is smaller than the moving width on the contact portion 3363 side with respect to the shaft portion 3361a, the magnet portion 3362 is positioned by the vibration transmitted to the game board 13. It is possible to prevent the posture of the stop device 3340 from changing due to insufficient magnetic force applied to the stop device 3340 due to the deviation.

As shown in FIG. 36B, when the sphere P31 passes through and the sphere P31 and the abutting portion 3363 are separated from each other, the maintenance device 3360 returns to the initial state due to the weight of the abutting portion 3363.

As shown in FIG. 36B, the stop device 3340 rotates in such a manner that the opening area of the portion facing the sphere P32 housed in the housing recess 3312f gradually increases in the operation of returning from the changed state to the initial state. To do. That is, the sphere P32 can be accommodated in the stop device 3340 before the stop device 3340 returns to the initial state. Thereby, for example, when two balls are deposited on the upstream side of the stop device 3340, it is possible to prevent both of the two balls from flowing into the stop device 3340. Therefore, it is possible to prevent the stop device 3340 from being clogged and causing an operation failure or a slowdown in the operation speed.

As shown in FIG. 36 (c), the ball P32 housed in the storage recess 3312f is housed in the stop device 3340, the stop device 3340 is rotated by the weight of the ball P32, and the ball P32 flows down to the detection port 312d. Will be done.

In this way, even when a plurality of balls P31 and P32 enter the winning opening 64 in a row, until the previous ball P31 changes the posture of the maintenance device 3360 and passes through the position where the state maintenance of the stop device 3340 is released. , The flow of the later sphere P32 can be stopped. In the present embodiment, since the sphere P31 is designed to pass through the delay flow path 3313d for 3 seconds, the sphere P32 for at least 3 seconds after the sphere P31 passes through the detection port 312d and the fluctuation starts. However, it can be prevented from passing through the detection port 312d.

Therefore, when the shortest period of fluctuation that can be obtained by entering the winning opening 64 (the fluctuation period that is easily selected when the number of reserved balls is four) is 3 seconds, it is shown in FIG. 35 (a). Even if the balls P31 and P32 enter the winning opening 64 in succession (the balls enter at intervals shorter than 3 seconds), after the fluctuation started by the ball P31 passing through the detection opening 312d is completed. , The state in which the sphere P32 passes through the detection port 312d can be configured. As a result, it is possible to prevent overflow from occurring when balls enter the winning opening 64 in a row.

Further, since the period from when the ball P31 passes through the detection port 312d to when the maintenance device 3360 changes its posture can be secured, overflow occurs as compared with the case where the posture maintenance of the stop device 3340 is released upstream of the detection port 312d. Can be reliably prevented from occurring.

For example, when the posture of the maintenance device 3360 is changed by using the ball before passing through the detection port 312d, the operation of the stop device 3340 is performed in order to secure the distance between the ball passing through the detection port 312d and the ball after that. It should be designed to be slow. That is, it is necessary to leave a space between the balls during the period from the change state to the return of the stop device 3340, and if the operation speed of the stop device 3340 changes due to aged deterioration or the like, there is a risk that overflow cannot be prevented.

On the other hand, according to the present embodiment, only the sphere operates in the delay device 3300 after the sphere passes through the detection port 312d until the sphere comes into contact with the maintenance device 3360. Therefore, the operation timing of the stop device 3340 can be managed in relation to the sphere and the fixed flow path.

In the present embodiment, since the period required for fluctuation (3 seconds) has elapsed before the ball reaches the maintenance device 3360, the overflow occurs regardless of the period until the stop device 3340 returns to the initial state. Can be prevented. That is, regardless of whether the stop device 3340 returns to the initial state in 10 seconds or returns to the initial state in 0.5 seconds, it is possible to prevent an overflow from occurring at the winning opening 64 regardless of that.

Further, as compared with the case where the stop device 3340 is electrically operated constantly, the period from when the ball P31 passes through the winning opening 64 to when it passes through the detection port 312d is secured to be shorter, and after the ball P31. Only the ball P32 that enters the ball can be stopped, and it is possible to prevent the period from the time when the previous ball P31 passes through the winning opening 64 to the start of the fluctuation is extended. This can prevent the player from feeling uncomfortable (for example, the feeling that the ball has entered the winning opening 64 but the fluctuation does not start, so that the player may be doing something wrong). it can.

Next, a fourth embodiment will be described with reference to FIGS. 37 and 38. In the first embodiment, the case where the ball is decelerated by the action of the convex portion 321a1 of the delay device 300 has been described, but the delay device 4300 in the fourth embodiment decelerates the ball by the sprocket 4340 that separates the balls at equal intervals. .. The same parts as those of the above-described embodiments are designated by the same reference numerals, and the description thereof will be omitted.

37 (a), 37 (b), 37 (c), 38 (a), 38 (b) and 38 (c) show how the spheres P41, P42 and the like flow through the delay device 4300. It is a front view of the delay device 4300 in the 4th Embodiment illustrated in chronological order. Note that FIG. 37 (a) shows a state in which the sprocket 4340 is in the initial state and the balls P41 and 42 continuously enter the winning opening 64 and reach the sprocket 4340. FIG. 37 (b) shows the state. A state in which the sprocket 4340 is rotated by a predetermined amount from the state of FIG. 37 (a) is shown, and a state in which the magnet member 4351 of the magnet device 4350 is arranged at the locking position is shown in FIG. 38 (c). In a), the state in which the sprocket 4340 is rotating due to the weight of the sphere P42 is shown, and in FIG. 38 (b), the state immediately before the sphere P42 enters the detection port 312d is shown. The state in which the sprocket 4340 rotates clockwise in the front view and the magnet member 4351 of the magnet device 4350 is moving toward the initial position is illustrated.

As shown in FIG. 37 (a), the delay device 4300 includes a main body member 4310 having a flow path for guiding a ball that has entered the winning opening 64 to the detection port 312d, and a ball that flows down inside the main body member 4310. It mainly includes a sprocket 4340 whose state changes by action, and a magnet device 4350 having a magnet member 4351 configured to be relatively movable along a rotation locus of the sprocket 4340.

As shown in FIG. 37 (a), the main body member 4310 includes a first groove 3311, a second groove 4312 extending vertically from the lower end portion of the first groove 3311 to the detection port 312d, and a second groove 4312 thereof. A cylindrical shaft rod 4313 extending in the front-rear direction in the right portion of the groove 4312 is mainly provided. The first groove 3311 and the second groove 4312 have a groove shape having an open portion on the game board 13 side, and in the assembled state, the open portion is closed by the game board 13 to provide a passage through which the ball flows down. It is formed.

The second groove 4312 has a configuration in which the receiving wall portion 3312c (see FIG. 35 (a)) is removed from the second groove 3312 in the third embodiment. Therefore, the contact wall 312a, the recessed portion 312b, the detection port 312d, the side wall portion 312e, and the accommodating recess 3312f are designated by the same reference numerals, and the description thereof will be omitted.

The sprocket 4340 is a gear-shaped member that rotates by the weight of a sphere flowing down the main body member 4310, and is a disk-shaped disk member 4341 whose center position is rotatably supported by a shaft rod 4313, and a circle thereof. It mainly includes a storage wall portion 4342 which is extended to the front side of the plate member 4341 and is formed so as to be able to store a sphere in a gap between the walls.

Since the disc member 4341 is arranged at a position that is in a surface position with the wall portion on the back side of the main body member 4310 (the wall portion on the back side in the vertical direction of the paper surface in FIG. 37 (a)), it flows down the inside of the disc member 4341. The sphere passes through the front side of the disk member 4341.

Further, the disk member 4341 divides the striped magnetic poles (the region between each plate-shaped portion 4342a to 4342e into three equal parts along the outer peripheral surface, the central portion thereof is the north pole, and the outer portion is the south pole. It is provided with a magnet portion 4341a having a striped magnetic pole). The rotation speed of the sprocket 4340 is adjusted by the interaction between the magnet portion 4341a and the magnet device 4350.

In order to make it easy to determine that the disk member 4341 and the magnet member 4351 have moved relative to each other, a triangular mark M is formed near the outer peripheral position of the disk member 4341.

The accommodating wall portion 4342 is a plate-shaped portion extending radially outward from the center of the disk member 4341 to prevent the passage of a sphere in the circumferential direction, and is at equal intervals (72 °). It is composed of five plate-shaped portions 4342a to 4342e arranged at intervals). Each gap between the plate-shaped portions 4342a to 4342e is configured to have a width capable of accommodating only one sphere. Further, the outer peripheral surfaces of the plate-shaped portions 4342a to 4342e (the radial outer peripheral surfaces of the sprocket 4340) are formed from an arc shape formed coaxially with the central axis of the disk member 4341.

As shown as an example in FIG. 37 (a), the first plate-shaped portion 4342a is arranged at a position on which the sphere P41 rides, and from there, the second plate-shaped portion 4342b and the third plate-shaped portion are arranged in the clockwise direction in the front view. 4342c, the fourth plate-shaped portion 4342d, and the fifth plate-shaped portion 4342e are arranged.

The magnet device 4350 is formed of a magnetic material and is formed in an arc shape having a diameter slightly longer than the diameter of the outer peripheral surface of the disk member 4341 of the sprocket 4340, and the shaft rod 4313 is formed via a rotating arm (not shown). A magnet member 4351 axially supported by the magnet member and an arc wall portion extending from the main body member 4310 at a position separated by a predetermined distance below the disk member 4341 as an arc-shaped wall surface along the shape of the lower surface of the magnet member 4351. It mainly includes a 4352 and a stopper portion 4353 that projects toward the magnet member 4351 at an end portion of the arc wall portion 4352 that is opposite to the side close to the main body member 4310.

The magnet member 4351 has striped magnetic poles (striped magnetic poles in which the arc region is divided into three equal parts, the central portion thereof is the south pole, and the outer portion is the north pole) on the inner peripheral side of the arc shape. The sprocket 4340 is arranged with a slight gap from the outer peripheral surface of the disk member 4341, and the position is corrected in relation to the magnetic poles of the disk member 4341.

That is, in the state shown in FIG. 37 (a) (the state before the weight of the sphere P41 is applied to the sprocket 4340), the central position of the region between each plate-shaped portion 4342a to 4342e and the central position of the arc of the magnet member 4351. Is maintained at a position that matches.

One end (the left end of FIG. 37 (a)) of the magnet member 4351 abuts on the outer surface of the main body member 4310 at the initial position shown in FIG. 37 (a), and the magnet member 4351 is engaged as shown in FIG. 37 (c). At the stop position (the position rotated counterclockwise by 72 ° from the initial position about the shaft rod 4313), the other end (the upper end in FIG. 37 (c)) comes into contact with the stopper 4353.

The arc wall portion 4352 is a wall portion arranged outside the magnet member 4351, and is arranged at a position where a gap is left between the arc wall portion 4352 and the magnet member 4351 when the magnet member 4351 is attracted to the disk member 4341. Will be done.

For example, even if for some reason the game board 13 vibrates and an impact is applied to the magnet member 4351 and the attraction between the disk member 4341 and the magnet member 4351 is temporarily released, the magnet member 4351 has an arc. Since it is supported by the wall portion 4352, it is possible to prevent the magnet member 4351 from being largely displaced.

The stopper portion 4353 is arranged at a position that blocks the movement of the magnet member 4351. In the present embodiment, the magnet member 4351 and the stopper portion 4353 come into contact with each other in a locked state in which the magnet member 4351 is rotated by a predetermined angle (72 ° in the present embodiment) from the initial position shown in FIG. 37 (a). It is configured in an embodiment (see FIG. 37 (c)), and in this locked state, the sphere P41 flows down to the detection port 312d.

The change in the state of the delay device 4300 when the spheres P41 and P42 pass through the main body member 4310 will be described in chronological order.

As shown in FIG. 37 (a), when the balls P41 and P42 enter the winning opening 64, the balls P41 and P42 reach the sprocket 4340 through the first groove 3311 and the second groove 4312. In the present embodiment, the space between the first plate-shaped portion 4342a and the second plate-shaped portion 4342b of the sprocket 4340 is set to a size capable of accommodating one sphere, so that only the front sphere P41 is accommodated and the rear sprocket 4340 is accommodated. Ball P42 is maintained on the outside of the sprocket 4340.

As shown in FIG. 37 (b), the sprocket 4340 is rotated from the initial state (see FIG. 37 (a)) by the weight of the front sphere P41, and the rear sphere P42 is pushed to the tip of the second plate-shaped portion 4342b. The left side portion is accommodated in the accommodating recess 3312f. Since the position accommodated in the accommodating recess 3312f is the lowermost position of the second groove 4312 on the upstream side of the sprocket 4340, the sphere P42 is maintained at the position shown in FIG. 37 (b) by the action of gravity. ..

In the state shown in FIG. 37 (b), the magnet member 4351 moves integrally with the disk member 4341 of the sprocket 4340. Therefore, the weight of the magnet member 4351 is loaded on the disk member 4341 as a rotation resistance.

As shown in FIG. 37 (c), in a state where the sprocket 4340 is rotated 72 ° counterclockwise from the initial state (a state in which the sphere P31 can flow down to the detection port 312d), the magnet member 4351 and the stopper portion 4353 (The magnet member 4351 is arranged at the locking position).

Therefore, when the sprocket 4340 further rotates counterclockwise when viewed from the front, the magnet member 4351 is maintained in the locked position, and only the sprocket 4340 rotates. In this case, a magnetic force acts between the sprocket 4340 and the magnet member 4351, and the magnetic force is applied to the resistance to rotation of the sprocket 4340.

As shown in FIG. 37 (c), the sprocket 4340 is rotated 72 ° from the initial state in a state where the sphere P41 flows down to the detection port 312d while rubbing against the side wall portion 312e and the first plate-shaped portion 4342a. It becomes. That is, the passage of the ball causes the sprocket 4340 to be adjusted to a predetermined posture. Since the shape of the sphere is precisely made, it is possible to reliably rotate the sprocket 4340 by 72 ° by utilizing the precision of the shape of the sphere.

At this time, as shown in FIG. 37 (c), the first plate-shaped portion 4342a inclines downward in the direction of pressing the sphere P41 against the side wall portion 312e, so that the velocity of the sphere P41 is directed toward the side wall portion 312e. It is possible to prevent the first plate-shaped portion 4342a from rotating too much due to the momentum of the ball P41.

In the state shown in FIG. 37 (c), the ball P42 enters the sprocket 4340, and after the ball P41 is thrown toward the detection port 312d, the sprocket 4340 is rotated by the weight of the ball P42.

As shown in FIG. 38 (a), when the sprocket 4340 is rotated by the weight of the sphere P42, the disk member 4341 and the magnet member 4351 of the sprocket 4340 move relative to each other as shown by the position of the mark M. Therefore, the magnetic force generated between the sprocket 4340 and the magnet member 4351 is applied to the sprocket 4340 as a rotation resistance.

Further, in FIG. 38 (a), following the ball P42, the ball P43 and the ball P44 enter the winning opening 64 and stay on the upstream side of the sprocket 4340.

In the present embodiment, the rotational resistance applied to the sprocket 4340 by the magnetic force applied between the magnet member 4351 and the sprocket 4340 is much larger than the rotational resistance applied to the sprocket 4340 by the weight of the magnet member 4351. It is configured in a mode (the magnet member 4351 is configured in a mode in which the weight is reduced while the generated magnetic force is increased).

As a result, for example, the period from the state shown in FIG. 37 (a) to the state shown in FIG. 37 (c) is set to 0.5 seconds, while the period shown in FIG. 37 (c) is set to FIG. 38 (a). ) Can be set to 5 seconds (the period required to rotate the sprocket 4340 by a predetermined angle can be changed).

In the present embodiment, the period from the state shown in FIG. 37 (c) to the state shown in FIG. 38 (a) is set to 5 seconds, so that, for example, the ball P41 passes through the detection port 312d. As a result, the number of reserved balls in the winning opening 64 becomes 4, and if the fluctuation selected at that time is a fluctuation of 3 seconds, the ball P42 passes through the detection port 312d after the fluctuation is completed. Therefore, it is possible to prevent the ball P42 from overflowing at the winning opening 64 when passing through the detection opening 312d.

As shown in FIG. 38A, when a plurality of balls P43 and balls P44 stay on the upstream side of the sprocket 4340, the load applied from the balls P43 and the balls P44 to the sprocket 4340 is the outer circumference of the accommodating wall portion 4342. Due to the effect of the shape of the surface (arc), the load is applied in the direction (diameter direction) toward the shaft rod 4313.

Therefore, the load applied from the spheres P43 and the spheres P44 in the rotational direction of the sprocket 4340 can be limited to the load generated by the rubbing between the spheres P43 and the sprocket 4340, and is compared with the weights of the spheres P43 and P44 that stay. Therefore, the rotational resistance applied to the sprocket 4340 can be reduced.

38 (b) shows a state in which the ball P42 is sent to the detection port 312d and the ball P43 enters the sprocket 4340 (from the initial state shown in FIG. 37 (a), the sprocket 4340 is 144 counterclockwise when viewed from the front. ° Rotated state) is shown.

When the sprocket 4340 rotates from the state shown in FIG. 38 (b), the relative movement between the sprocket 4340 and the magnet member 4351 is accompanied by the relative movement of the sprocket 4340 and the magnet member 4351 as in the case where the sprocket 4340 is rotated by the weight of the ball P42. This also applies when the sphere P44 after the sphere P43 is housed in the sprocket 4340 and the sprocket 4340 rotates.

That is, according to the present embodiment, even if the number of balls entering the winning opening 64 in succession is 4 or more (regardless of the number of balls), the interval at which each ball is sent to the detection opening 312d is constant. The interval is maintained, and the period until the ball P41, which is entered into the winning opening 64 as the first ball, passes through the detection opening 312d is compared with the throwing interval between the balls opened by the sprocket 4340. Can be shortened.

Therefore, it is possible to suppress the player from feeling uncomfortable (for example, the feeling that the ball has entered the winning opening 64 but the fluctuation does not start, so that the player thinks that he / she is doing something wrong). ..

As shown in FIG. 38 (c), after the ball P44 (see FIG. 38 (b)) is thrown toward the detection port 312d, the next ball (the ball entered into the winning opening 64) becomes the sprocket 4340. When not riding, the sprocket 4340 rotates clockwise in the front view due to the weight of the magnet member 4351.

In the present embodiment, since the magnet member 4351 is composed of a light member, the rotation speed of the sprocket 4340 is reduced, and the period until the magnet member 4351 returns from the locked position to the initial position is set to 5 seconds.

Therefore, the sprocket 4340 is further rotated from the timing when the sphere P41 shown in FIG. 37 (a) passes through the detection port 312d and the state shown in FIG. 38 (c), and immediately after the magnet member 4351 is arranged in the initial position, the sprocket 4340 is used. There is a gap of 5 seconds or more between the timing at which the ball to be entered passes through the detection port 312d. The 5 seconds is a period longer than the shortest fluctuation period (3 seconds) that is likely to be selected when the number of reserved balls in the winning opening 64 is 4.

Therefore, when the ball passes through the sprocket 4340 immediately after the sprocket 4340 returns to the initial state, it is possible to easily prevent an overflow from occurring at the winning opening 64.

In the state shown in FIG. 38 (c), the relative positions of the sprocket 4340 and the magnet member 4351 do not change in appearance from the state shown in FIG. 37 (a), but as shown in the mark M, in reality, FIG. 37 Compared to the state shown in (a), the magnet member 4351 is arranged at a position relative to the shaft rod 4313 by 72 °.

In the present embodiment, in a state where the magnet member 4351 is arranged at the locking position, the sprocket 4340 is placed between the plate-shaped portions of the accommodating wall portion 4342 with respect to the magnet member 4351 each time the ball passes through the second groove 4312. It is configured so that the position is displaced by an angle of one gap (that is, 72 °).

Therefore, the relative movement of the sprocket 4340 and the magnet member 4351 is limited to a relative movement such that, for example, the first plate-shaped portion 4342a moves to the position of the second plate state 4342b, and after the relative movement, the sprocket 4340 and the sprocket 4340 The overall shape of the magnet member 4351 and the magnet member 4351 does not change from that before the relative movement.

Therefore, regardless of the number of balls passing through the second groove 4312, the overall shape of the sprocket 4340 and the magnet member 4351 after the balls are discharged from the sprocket 4340 can be made unchanged, and thus the winning opening 64 It is possible to eliminate the need to dispose a device for moving the magnet member 4351 at the position of the mark M of the sprocket 4340 when the inflow of the sphere to the sprocket 4340 disappears for a certain period of time (Fig. 38 (c)). As described above, even if the relative positional relationship between the mark M and the magnet member 4351 has changed from the state shown in FIG. 37 (a), it can be left as it is).

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 convex portion 321a1 is convexly provided on the slide moving member 321 and the projecting portion 321a1 projects inward of the first groove 311 has been described, but the present invention is not necessarily limited to this. For example, a pair of wall portions forming an S-shaped path are arranged on the slide moving member 321 and the slide moving member 321 moves to complete an S-shaped path in which a sphere flows down inside the first groove 311. It may be composed of. In this case, since the path itself through which the sphere flows can be lengthened by the pair of wall portions, the deceleration effect can be maintained for a long period of time as compared with the case where the convex portion 321a1 reduces the deceleration effect due to wear. .. Further, the slide moving member 321 may be configured in such a manner that the region where the convex portion 321a1 is formed and the region where the S-shaped path is formed are continuously provided.

In the first embodiment, the case where the convex portion 321a1 of the speed reducing device 320 projects upward has been described, but the present invention is not necessarily limited to this. For example, the convex portion 321a1 may project downward into the first groove 311 or the convex portion 311a1 may project downward into the first groove 311. In this case, it is possible to prevent the slide moving member 321 from moving to the outside of the first groove 311 due to the weight of the sphere.

In the first embodiment, the case where the balls P1 and P2 can be distributed even when the balls P1 and P2 enter the distribution device 340 in the initial state in succession has been described, but the present invention is not necessarily limited to this. It's not a thing. For example, before the spheres reach the allocating device 340, after arranging an interval load means for surely spacing the connected spheres, the spheres enter the allocating device 340 and a while later, the state of the allocating device 340. May be configured in such a manner that In this case, since it is not necessary to strictly control the timing of the state change of the distribution device 340, the distribution device 340 can be loosely supported and the load required for the state change can be reduced.

In the first embodiment, the case where the portion of the sorting device 340 where the spheres collide is formed of an arc shape (arc wall portion 343) is described, but the present invention is not necessarily limited to this. For example, it may be composed of a flat plate-like portion of a portion corresponding to the arc wall portion 343. In this case, if a ball enters the sorting device 340 while the sorting device 340 is returning to the initial state, the sorting device 340 is rotated by the load given from the ball and returned to the changed state. As a result, the period during which the sorting device 340 is maintained in the changed state can be extended.

In the first embodiment, the case where the sorting device 340 is operated to return by changing the center of gravity has been described, but the present invention is not necessarily limited to this. For example, the sorting device 340 is returned by using a product whose urging force changes depending on the moving direction (moving resistance is applied only in one direction) or a cylinder product that changes the moving resistance in each direction using an orifice. It may be operated. In this case, maintainability can be improved by using a commercially available product. Further, by configuring the rotation resistance of the rotation shaft of the distribution device 340 to be small in the forward rotation and large in the reverse rotation, a constant urging force is applied to the distribution device 340, so that the return operation of the distribution device 340 takes time. Delays can occur.

In the first embodiment, the case where the sphere flowing from the fan-shaped member 410 to the inflow port 435 is guided through the delay flow path 436 has been described, but the present invention is not necessarily limited to this. For example, by forming another floor surface below the inflow port 435 (by forming a floor on which the sphere can roll in two stages), the sphere that has flowed into the inflow port 435 from the fan-shaped member 410 is again in the floor. The surface may be rolled to enter the winning opening 64. In this case, since the period during which the ball rolls on the floor surface can be extended, the player can pay attention to the movement of the ball and extend the period during which the launch of the ball is stopped. Therefore, the fluctuation of the winning amount held during that period can be digested, and the occurrence of overflow can be suppressed.

In the first embodiment, the case where the fan-shaped member 410 is tilted with the rotation axis aligned in the left-right direction has been described, but the present invention is not necessarily limited to this. For example, the rotation axis may be tilted along the front-rear direction. In this case, the ball can be dropped toward the winning opening 64 along the inclination of the arc portion of the fan-shaped member 410 (the position in the left-right direction can be corrected).

In the first embodiment, the case where the fan-shaped member 410 operates under the weight of a sphere has been described, but the present invention is not necessarily limited to this. For example, the fan-shaped member 410 may be electrically operated in a constant repetitive operation mode. In this case, a plurality of types of combinations of operations of the pair of fan-shaped members 410 can be configured. For example, the front side fan-shaped member 410 is in a raised position and the back side fan-shaped member 410 is in a lying position, and the front side fan-shaped member 410 is in a raised position and the back side fan-shaped member 410. The member 410 is in a raised position, the fan-shaped member 410 on the front side is in a lying position, and the fan-shaped member 410 on the back side is in a lying position, and the fan-shaped member 410 on the front side is lying down. It is possible to configure a posture in which the fan-shaped member 410 on the back side is in a raised posture and a posture in which the fan-shaped member 410 on the back side is raised, and it is possible to increase the combination of the states of the pair of fan-shaped members 410.

In the first embodiment, the case where the pair of fan-shaped members 410 are formed of the same shape has been described, but the present invention is not necessarily limited to this. For example, the fan-shaped member on the back side may be configured to have a longer width in the left-right direction as compared with the fan-shaped member 410 on the front side. In this case, even for a sphere located at a position away from the center position in the left-right direction of the fan-shaped member 410 and above the fan-shaped member on the back side, an action (push-back action) associated with the inclination of the fan-shaped member is exerted. Can be caused.

In the first embodiment, the case where the outlet of the delay flow path 436 is displaced in the left-right direction with respect to the winning opening 64 has been described, but the present invention is not necessarily limited to this. For example, the delay flow paths 436 below the pair of left and right inlets 435 may merge at the center of the left and right, and the outlets thereof may be arranged directly above the winning opening 64. In this case, it is possible to improve the rate at which the balls discharged from the exit of the delay flow path 436 into the game area enter the winning opening 64.

In the third embodiment, the case where the stop device 3340 is maintained in the posture by the magnetic force has been described, but the present invention is not necessarily limited to this. For example, the locking member projects from the lower surface of the first wall portion 341, the overhanging tip is bent toward the center hole 345, and the tip of the main body rod 3361 of the maintenance device 3360 is bent downward. The posture of the stop device 3340 may be maintained by hooking the bent portions to each other. In this case, the stop device 3340 can be maintained in the changed state regardless of the magnitude of the load applied to the stop device 3340.

In the fourth embodiment, the case where the second groove 4312 is extended in the vertical direction has been described, but the present invention is not necessarily limited to this. For example, the second groove 4312 may be inclined along the front-rear direction immediately before the sprocket 4340 (immediately before the upstream side). In this case, even if the number of balls staying above the sprocket 4340 increases, the load applied to the sprocket from the balls can be reduced, and problems such as poor rotation of the sprocket 4340 can be suppressed. ..

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 including that. 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 for displaying 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 the operation of the starting operation means (for example, the operation lever) is caused. 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 consisting 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 due to, for example, 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.

<Suppress overflow by turning the second and subsequent balls to another route and delaying them>
Opportunity for lottery even if the game ball enters in the first state where the opportunity for lottery is given when the game ball enters and the state where the game ball is switched by entering the ball in the first state. In a gaming machine provided with a detection slot that can be configured with a second state in which is not given, and after switching to the second state, a predetermined return period elapses to return to the first state. , When a plurality of gaming balls are inserted, the period from when the first gaming ball, which is one of the plurality of gaming balls, is entered to when the ball is thrown into the detection slot is compared. Then, a delay means for delaying the period from when the second game ball, which is another game ball, enters the ball to when the ball is thrown to the detection entry port is provided, and the period delayed by the delay means is equal to or longer than the return period. A game machine A1 characterized by being said to be.

Here, in a gaming machine such as a pachinko machine, information is acquired based on the entrance of the game ball and the entry of the game ball into the entrance, and the display means based on the information. There is a gaming machine that dynamically displays the machine (see, for example, Japanese Patent Application Laid-Open No. 2011-156058). However, in the above-mentioned conventional gaming machine, it is possible to store up to a predetermined number (for example, 4) of information acquired based on the fact that the gaming ball has entered the ball entrance, and it is impossible to store any more information. Although it is configured, if multiple gaming balls enter the entrance in succession at short intervals, the upper limit of the number of memorable balls will be reached (the second state), and there is a risk of so-called overflow. There was a problem. Therefore, it is necessary for the player to make a self-judgment to reduce the number of balls to be continuously launched, or to play while checking the number of balls that constantly store information, which puts a burden on the player.

On the other hand, according to the gaming machine A1, the period from when the first gaming ball enters the detection entry slot to when the second gaming ball enters the detection entry slot by the delay means is longer than the return period. Since the length is increased and the second game ball is prevented from entering the detection entry port in the second state, the detection entry port is in the second state when the first game ball enters the detection entry port. Even in the case of, it is possible to form a memorable number of vacant spaces before the second game ball enters the detection entrance, and it is possible to suppress the occurrence of overflow.

The period delayed by the delay means is at least longer than the period of one dynamic display mode performed by the dynamic display means such as a liquid crystal device, and is the longest when the number of stored information storage means is the upper limit. It is desirable that the period is longer than the period of the dynamic display mode of.

The configuration of the delay means is not particularly limited, and various modes can be considered. For example, the flow path of the game ball may be distributed by a movable member, or the flow path of the game ball may be distributed according to the relationship between the shape of the flow path and the collision of the ball.

In the game machine A1, the delay means distributes the game ball to a plurality of paths and changes the posture from the first posture to the second posture by passing the game ball, and the distribution means thereof. The urging means that generates an urging force that changes the posture from the second posture to the first posture and the first game ball that has passed through the sorting means when the sorting means is in the first posture are guided and the detection is entered. The first guide flow path for throwing balls to the ball mouth and the second game ball that has passed through the distribution means between the time when the distribution means returns from the second posture to the time immediately before returning to the first posture are guided to the detection entry port. A second guide flow path for throwing balls to the ball is provided, and the period during which the second game ball passes through the second guide flow path is compared with the period during which the first game ball passes through the first guide flow path. The gaming machine A2 is characterized in that the delay period is configured as a difference between the delay periods.

According to the gaming machine A2, in addition to the effect of the gaming machine A1, the delay means includes the sorting means, the first guide flow path in which the game ball is sorted by the sorting means, the second guide flow path, and the sorting means. It is equipped with an urging means for returning the posture, and is compared with the period until the first gaming ball, which first passes through the sorting means and is guided through the first guide flow path, reaches the detection entry port, and then after that. It is possible to prolong the period until the second gaming ball that has passed through the sorting means and is guided through the second guide flow path reaches the detection entry port by the time immediately before the sorting means returns to the first posture by the urging means. Since the delay period is configured as the difference between these periods, the period during which the game ball flows down is assured as compared with the case where the flow path of the game ball is randomly determined as in the case where the game ball collides with a nail. It can be lengthened to, and the timing at which the game ball reaches the detection entrance can be reliably shifted.

In addition, since the posture of the sorting means is restored by the urging means, the game balls are sorted even when the game balls reach the sorting means at intervals (when it is not necessary to delay the game ball that came later). It is possible to prevent the second guide flow path from being distributed by the means.

In the gaming machine A2, the sorting means uses the first wall portion facing the gaming ball in the flow direction and the gaming ball in contact with the first wall portion in the case of the first posture. A second wall portion is provided at a sandwiched position, and the second wall portion receives a load along the flow direction from the game ball, so that the first one from the second posture of the sorting means. A gaming machine A3 characterized in that a change in posture in a direction toward a posture is suppressed.

According to the gaming machine A3, in addition to the effect of the gaming machine A2, the second wall portion arranged at a position sandwiching the gaming ball colliding with the sorting means with the first wall portion is along the flow direction from the gaming ball. By receiving the load, it is suppressed that the sorting means changes its posture from the second posture to the first posture. Therefore, the game ball that has passed through the sorting means first passes through the sorting means later. The action of the sphere can prevent the flow from being hindered and the flow from being delayed.

In the gaming machines A2 or A3, the sorting means includes a dividing means for dividing the gaming balls flowing down in a row and guiding only one ball to the first guide flow path, and the posture changes depending on the weight of the gaming balls. The gaming machine A4 having a configuration, wherein the dividing means functions by changing the posture of the sorting means.

According to the gaming machine A4, in addition to the effect of the gaming machine A2 or A3, the dividing means of the sorting means divides the spheres flowing down in succession, and a plurality of spheres are guided to the first guide flow path. This can be prevented without the addition of a drive source.

As the dividing means, a means for pushing the game balls toward the second guide flow path by projecting inward of the flow path, or a means for pushing the game balls in a row by projecting toward the inside of the flow path. An example is a means of inserting the game balls in between and separating the game balls from each other.

In the gaming machine A4, the sorting means uses the first wall portion facing the gaming ball in the flow direction and the gaming ball in contact with the first wall portion in the first posture. It is provided with a second wall portion arranged at a sandwiched position, and when the sorting means changes its posture from the first posture to the second posture, the second wall portion becomes the second gaming ball in the moving direction. The gaming machine A5 is characterized in that the gaming ball is introduced into the second guide flow path by colliding with the gaming ball.

According to the gaming machine A5, in addition to the effect of the gaming machine A4, when the sorting means collides with the second game ball in the moving direction during the posture change, the game is played between the sorting means and the first guide flow path. It is possible to prevent the ball from being pinched and causing the sorting means to malfunction.

Here, for example, when the sorting means operates electrically, the sorting means operates regardless of the position of the game ball, so that the game ball is at a position away from the entrance of the second guide flow path and also with the sorting means. When the sorting means operates in a direction in which the distance between the sorting means and the side wall of the first guide flow path is narrowed in a state of being arranged at a position between the side wall of the first guide flow path, the sorting means and the first The game ball may be caught between the guide flow path and the sorting means may malfunction.

On the other hand, according to the gaming machine A5, since the operation of the sorting device is generated by the weight of the game ball instead of being electric, the sorting means does not operate in a state where the sorting means malfunctions due to the arrangement of the game ball. The positional relationship and the shape relationship can be designed in advance. As a result, it is possible to prevent malfunction of the sorting means.

In the gaming machine A5, a position where a plurality of gaming balls reach the sorting means, one gaming ball abuts on the first wall portion, and the other gaming ball abuts in the moving direction of the second wall portion. In the connected ball introduction state in which the distribution means has changed its posture, it is a side surface forming the inlet of the one game ball and the second guide flow path from the first guide flow path, and is the first guide flow. The gaming machine A6, which is the distance between the end faces with the side surface on the downstream side of the road, and the distance along the extending direction of the first guide flow path is equal to or less than the radius of the gaming ball.

According to the gaming machine A6, in addition to the effect of the gaming machine A5, when the other gaming ball is connected to one gaming ball and reaches the sorting means in the connected ball introduction state, the center of the other gaming ball is the second. Since it is arranged in the area inside the second guide flow path when the guide flow path is extended, the game ball can be pushed along the side surface of the second guide flow path, and the game ball can be used as the second guide flow path. Can be introduced.

A7, wherein in the gaming machines A4 to A6, the sorting means performs a returning operation from the second posture to the first posture over a period longer than the returning period.

According to the gaming machine A7, in addition to the effects of the gaming machines A4 to A6, it is surely prevented that the second gaming ball is entered into the detection entry slot during the period when the entry detection port is in the second state. be able to.

When the dynamic display mode of the display device is such that the larger the number of memory of the detection entry port is, the easier it is to select a short-term display mode, the length of the predetermined dynamic display mode is at least the detection input. It is desirable that the length of the shortest dynamic display mode or more when the memory number of the ball mouth is the upper limit value or more.

<Overflow suppression by making the stage movable by the weight of the sphere>
Opportunity for lottery even if the game ball enters in the first state where the opportunity for lottery is given when the game ball enters and the state where the game ball is switched by entering the ball in the first state. In a gaming machine provided with a detection inlet that can be configured with a second state in which is not given, and returns to the first state after a predetermined return period elapses after being switched to the second state. , A rolling means configured to have an optimum drop portion, which is a descending start position at which the game ball can easily enter the detection entry port, and to roll on the upper surface in a manner in which the game ball passes through the optimum drop portion. The gaming machine B1 is characterized in that the rolling means operates in a mode in which the gaming ball is started to descend from the optimum falling portion at intervals equal to or longer than the return period.

Here, in a game machine such as a pachinko machine, the game ball has an optimum drop portion arranged as a descent start portion where the game ball can easily enter the detection entry port, and the game ball arranged on the upper surface provides the optimum drop portion. There are gaming machines provided with rolling means (so-called "stages") that are configured to be rollable in a passing manner (see, for example, Japanese Patent Application Laid-Open No. 2011-156508). However, in the conventional gaming machine described above, the second gaming ball rides on the rolling means before the first gaming ball on the rolling means first descends from the rolling means, and the first gaming ball and the first gaming ball are on the rolling means. The two gaming balls may descend from the optimum drop portion in a short period of time, and in that case, there is a problem that an overflow may occur at the detection entry port.

This is different from the state in which the game balls flow down while colliding with the nails, and when the game balls reciprocate in the left-right direction in a manner of passing the optimum drop portion (the game balls reciprocate on a specific path), the game balls are reciprocated with each other. Is a problem peculiar to the rolling means that tends to collide frequently.

On the other hand, according to the gaming machine B1, the rolling means operates in such a manner that the gaming balls are started to descend one by one at intervals from the optimum falling portion, so that the gaming machines can be played at the detection slot in a short period of time. It is possible to prevent the balls from entering all at once. Therefore, even when a plurality of game balls are placed on the rolling means, it is possible to prevent overflow from occurring at the detection entry port.

The gaming machine B1 includes an introduction flow path for introducing the game ball into the rolling means, and the rolling means guides the game ball to the optimum falling portion while the game ball is introduced from the introduction flow path. A floor member is provided, and the first floor member is formed to be movable by the weight of a rolling game ball, and the movement reduces the speed of the game ball arriving later toward the first floor member. A gaming machine B2 characterized in that it operates in a mode.

According to the gaming machine B2, in addition to the effect of the gaming machine B1, when the gaming ball rides on the first floor member of the rolling means, the first floor member operates by the weight of the gaming ball, so that the game is played. Since the speed of the ball toward the first floor member can be reduced, the distance between the game ball on the first floor member and the game ball toward the first floor member can be widened. As a result, it is possible to prevent overflow from occurring at the detection entry port.

The speed of the game ball toward the first floor member may be reduced, for example, the speed of the game ball toward the first floor member may be reduced (braking), or the game ball may be stopped. , The case where the game ball is moved (runs in the opposite direction) in the direction opposite to the direction toward the first floor member is exemplified.

Further, as a method of reducing the speed of the game ball toward the first floor member, for example, a method of making the first floor member descend and incline in a direction away from the first floor member, or an upper surface of the first floor member. Examples thereof include a method of projecting a deceleration protrusion and a method of projecting a magnet at a position where a magnetic force can act on a game ball on the first floor member.

In the gaming machine B2, the optimum falling portion is arranged on the first floor member, and the first floor member is configured to operate when the game ball is dropped from the optimum falling portion. The moving means is placed in the vicinity of the first floor member before and after the game ball falls from the optimum drop portion, and the optimum drop of another game ball heading toward the optimum drop portion within a predetermined period of time. The gaming machine B3, which is provided with a preventive means for preventing the player from reaching the unit.

According to the gaming machine B3, in addition to the effect of the gaming machine B2, the first floor member operates when the gaming ball falls from the optimum falling portion, and the rolling means is the gaming ball from the optimum falling portion. Is placed on the first floor member before and after the fall, and other game balls heading toward the optimum drop portion are prevented by the preventive means within a predetermined period, so that a plurality of game balls are continuously introduced into the optimum drop portion. Even in this case, it is possible to prevent other gaming balls from continuously falling from the optimum falling portion after the earliest gaming ball has fallen from the optimum falling portion. As a result, it is possible to prevent overflow from occurring at the detection entry port.

In the game machine B3, the prevention means can configure a preventive state in which the game ball can be prevented and a passing state in which the game ball cannot be prevented, and the optimum immediately after the game ball falls from the optimum drop portion. As the state of the falling portion, a preferable falling state in which the game ball has fallen in a manner in which the game ball can be easily entered into the detection entry port, and a game ball being inserted into the detection entry port as compared with the preferable falling state. A normal falling state in which the game ball has fallen in a mode that is difficult to cause is configured, and the preventing means is set to the preventing state when the suitable falling state is set, and the preventing means is set to the preventing state when the game ball is set to the normal falling state. The gaming machine B4, which is characterized in that the player is in a passing state.

According to the gaming machine B4, in addition to the effect of the gaming machine B3, when the optimum falling portion is in a suitable falling state, the preventive means is set in a preventive state, and the optimum falling portion is set in a normal falling state. Since the prevention means is passed through the ball, it is possible to suppress the prevention of the game ball even when the game ball falling from the optimum drop portion does not enter the detection entry port, and the game ball is placed at the detection entry port. It is possible to prevent the timing of entering the ball from being unnecessarily delayed.

The gaming machine B3 or B4 is provided with a throwing means for throwing a game ball prevented by the preventing means in a direction away from the optimum falling portion.

According to the gaming machine B5, in addition to the effect of the gaming machine B3 or B4, the gaming ball prevented by the preventing means by the throwing means is thrown in the direction away from the optimum falling portion, thereby intensifying the movement of the gaming ball. Since it is possible to increase the period until the game ball reaches the optimum drop portion again, it is possible to suppress the occurrence of overflow at the detection entrance while improving the interest of the player.

In any of the gaming machines B2 to B5, an intermediate floor member for introducing a game ball into the first floor member is provided, the intermediate floor member is made operable, and the operation causes the player to descend in a direction away from the first floor member. A gaming machine B6 characterized in that the intermediate floor member changes state in an inclined state.

According to the gaming machine B6, in addition to the effect of any of the gaming machines B2 to B5, the intermediate floor member inclines downward in the direction away from the first floor member, so that the gaming ball reaches the intermediate floor member. , The gravitational acceleration can be generated in the direction away from the first floor member. Therefore, it is possible to prevent the gap between the game ball arranged on the first floor member and the game ball that will reach the intermediate floor member from being reduced.

The gaming machine B6 is characterized in that the intermediate floor members are arranged in pairs on both sides of the first floor member, and the posture changes of the intermediate floor members occur alternately in the pair of intermediate floor members.

According to the gaming machine B7, in addition to the effect of the gaming machine B6, the intermediate floor members are arranged in pairs on both sides of the first floor member, and the posture changes of the intermediate floor members occur alternately in the pair of intermediate floor members. When the gaming balls are directed toward both of the pair of intermediate floor members, the timing at which the gaming balls are decelerated can be shifted, and the timing at which the gaming balls reach the first floor member can be shifted. Therefore, it is possible to prevent the game ball from being congested in the vicinity of the optimum drop portion.

In any of the gaming machines B2 to B7, in the rolling means, the gaming ball that has reached the optimum drop portion after the reciprocating motion in the left-right direction has converged, and the gaming ball that has passed through the introduction flow path to the first floor member. The gaming machine B8 is characterized in that it is configured in a manner of preventing a collision with a gaming ball flowing down toward it.

According to the gaming machine B8, in addition to the effect of any of the gaming machines B2 to B7, in the rolling means, the reciprocating motion in the left-right direction is completed and the gaming ball reaches the optimum drop portion and passes through the introduction flow path. Since it is configured to prevent a collision with a game ball flowing down toward the first floor member, the game ball immediately before falling from the optimum drop portion collides with another game ball and is detected as a ball entry port. It is possible to prevent the pachinko balls from falling in a direction away from the ball and from passing the colliding game balls in a row and passing through the detection entry port.

<Overflow suppression by decelerating the second and subsequent balls and shifting the winning timing>
Opportunity for lottery even if the game ball enters in the first state where the opportunity for lottery is given when the game ball enters and the state where the game ball is switched by entering the ball in the first state. In a gaming machine provided with a detection inlet that can be configured with a second state in which is not given, and after switching to the second state, the game returns to the first state after a predetermined return period elapses. , When a plurality of game balls enter, the flow speed of the second game ball that enters after that is compared with the flow speed of the first game ball that enters first among the plurality of game balls. The pachinko ball is provided with a deceleration means for decelerating the speed, and the game ball thrown from the deceleration means enters the detection entry port. The period required for the ball to enter the ball opening is longer than the period required for the first gaming ball to enter the detection entry port after the first gaming ball enters the deceleration means. A gaming machine C1 characterized in that it is configured to be longer than that.

Here, in a gaming machine such as a pachinko machine, information is acquired based on the entrance of the game ball and the entry of the game ball into the entrance, and the display means based on the information. There is a gaming machine that dynamically displays the machine (see, for example, Japanese Patent Application Laid-Open No. 2011-156058). However, in the above-mentioned conventional gaming machine, it is possible to store up to a predetermined number (for example, 4) of information acquired based on the fact that the gaming ball has entered the ball entrance, and it is impossible to store any more information. However, there is a problem that if a plurality of game balls continuously enter the ball entrance at short intervals, the upper limit of the number of memorable balls may be reached and a so-called overflow may occur. Therefore, it is necessary for the player to make a self-judgment to reduce the number of balls to be continuously launched, or to play while checking the number of balls that constantly store information, which puts a burden on the player.

On the other hand, according to the gaming machine C1, when a plurality of gaming balls enter the deceleration means, the speed is compared with the flow speed of the first gaming ball in which the deceleration means enters the first of the plurality of gaming balls. Then, the second gaming ball that has entered after that is decelerated, and the second gaming ball is placed in the detection entry slot until the return period elapses after the first gaming ball enters the detection entry slot. Since the ball is prevented from entering, it is possible to suppress the occurrence of overflow.

The period from when the second game ball enters the deceleration means to when the ball enters the detection entry port is the period from when the first game ball enters the deceleration means to when the ball enters the detection entry port. The length is at least longer than the length of the period (return period) of one dynamic display mode performed by the dynamic display means, and in particular, the detection entrance is set to the second state. It is desirable that the period be longer than the period of the longest dynamic display mode in the case of.

Further, the deceleration of the game ball means that the velocity component along the path toward the detection entry port is reduced. For example, the game ball flows in the direction away from the detection entry port (negative speed). The deceleration means has a preventive means for temporarily preventing the ball from being thrown, such as when the ball is reciprocated (moves in a zigzag pattern) in a direction perpendicular to the direction toward the detection entry port, and the ball is thrown by the preventive means. Until the prevention is released, the case where the game ball reciprocates in front of the prevention means, the case where the game ball temporarily stops, and the like are included.

As means for decelerating the game ball, a method of projecting an abutting member which faces and abuts in the flow direction of the game ball into the flow path, a method of applying a magnetic force to the flowing game ball, or a game ball. An example is a method of arranging a sprocket in a passage through which the sprocket passes and rotating the sprocket on a game ball.

In the gaming machine C1, the deceleration means decelerates the gaming ball by intermittently applying a load in the direction opposite to the flow direction to the gaming ball.

According to the gaming machine C2, in addition to the effect of the gaming machine C1, the deceleration means intermittently applies a load in the opposite direction of the flow direction to the gaming ball to reduce the rotation speed of the gaming ball, and as a result. Since the game ball is decelerated, the game ball can be effectively decelerated.

When decelerating by friction with the wall surface, it is necessary to increase the contact area in order to improve the deceleration efficiency, but if the target is a sphere such as a game ball, it is difficult to sufficiently increase the contact area. Is. On the other hand, in the mode in which the load is intermittently applied in the direction opposite to the flow direction, the deceleration efficiency does not depend on the target shape, so that the game ball can be effectively decelerated.

In the gaming machine C2, the deceleration means is arranged so as to be relatively movable with respect to the deceleration flow path for guiding the entering game ball and the deceleration flow path, and is configured to be able to apply a load to the game ball. It is provided with a moving means having an acting portion, and the moving means can configure a first state and a second state which is a state after relative movement from the first state to the deceleration flow path. The action unit is configured to apply a load to the gaming ball flowing down the deceleration flow path in the second state, and the moving means is such that the first game ball passes through the deceleration flow path. The gaming machine C3 is characterized in that the state changes from the first state to the second state, and in the second state, the acting unit applies a load to the second gaming ball.

According to the gaming machine C3, in addition to the effect of the gaming machine C2, the moving means having the acting portion can configure the first state and the second state, and the moving means is the first gaming ball passing through the deceleration flow path. The state is changed to the second state by the action of, and the second game ball is given a load from the action part in the second state, so that the second game ball can be decelerated without separately preparing a drive device. The distance between the first game ball and the second game ball can be separated.

Examples of the acting portion include a rib portion extending in a direction perpendicular to the extending direction of the deceleration flow path and projecting into the deceleration flow path, a magnet portion for applying a magnetic force to the game ball, and the like. When the acting part is a rib part, there are a mode in which the speed of the game ball is gradually reduced so that the game ball can pass through, a mode in which the game ball overhangs so as not to pass, and a mode in which the game ball is stopped. Illustrated.

In the gaming machine C3, the moving means is configured in such a manner that the deceleration degree of the second gaming ball is increased as the number of balls that the acting unit enters the deceleration means within a predetermined period increases. Characteristic gaming machine C4.

According to the gaming machine C4, in addition to the effect of the gaming machine C3, as the number of balls entering the deceleration means within a predetermined period increases, the acting unit increases the deceleration degree of the second gaming ball. When the number of balls flowing in the deceleration flow path becomes three within the period, the third game ball can be decelerated more than the second game ball, so that the second game ball can be decelerated more. And the third game ball can be widened. As a result, even when the second game ball enters the detection entry port and the detection entry port is in the second state, before the third game ball enters the ball. It is possible to earn a period (return period) in which the dynamic display of 1 is executed, and it is possible to suppress the occurrence of overflow due to the passage of the third game ball through the detection means.

In addition, as a mode in which the action unit increases the deceleration degree of the second game ball, for example, a mode in which the load acting on the second game ball increases and a length (duration) in which the load acts on the second game ball are used. An embodiment in which the amount of work applied to the second game ball increases due to the expansion is exemplified.

In any of the gaming machines C1 to C4, the deceleration means includes a miniaturization means configured to be movable relative to the flow path through which the game ball flows, and the miniaturization means is the first game ball. The gaming machine C5, characterized in that, upon passing, the second gaming ball moves in a direction that narrows the inner peripheral shape of the flow path before the second gaming ball passes through.

According to the gaming machine C5, in addition to the effect of any of the gaming machines C1 to C4, the miniaturization means changes the shape of the inner circumference of the flow path before the second gaming ball passes by the passage of the first gaming ball. Since it moves in the narrowing direction, it is possible to increase the resistance of the flow path when the second game ball passes through. As a result, the second game ball can be decelerated.

By matching the position where the inner peripheral shape of the flow path is narrowed with the position where the flow path changes direction (the position where the velocity component in the direction in which the game ball has flowed down disappears), the game ball flows down until then. It is possible to apply a large resistance at the timing of stopping along the direction in which the game ball was in place, to prevent the game ball from passing by with force, and to increase the action of decelerating the game ball.

In any of the gaming machines C1 to C5, a release means for releasing the deceleration effect generated on the second game ball by the deceleration means by changing the state is provided, and the state change of the release means is a game that has passed through the deceleration means. A gaming machine C6, characterized in that the ball passes through a predetermined position.

According to the gaming machine C6, in addition to the effect of any of the gaming machines C1 to C5, a releasing means for canceling the deceleration effect is provided, and the releasing by the releasing means causes the gaming ball that has passed through the deceleration means to pass through a predetermined position. Since it is performed by doing so, it is possible to eliminate the need for another driving means for changing the state of the releasing means.

In the gaming machine C6, the gaming machine C7 is characterized in that the releasing by the releasing means is performed by the gaming ball after passing through the detection entrance.

According to the game machine C7, in addition to the effect of the game machine C6, the release by the release means is performed by the game ball after passing through the detection entrance, so that it is easy to manage the release timing by the release means. Can be.

In any of the gaming machines C1 to C7, the deceleration means is configured in a mode in which the state changes between an initial state and a change state different from the initial state, and in the initial state, the deceleration means is used by the gaming ball. It changes to the changed state by passing through, and in the changed state, it is configured to change to the initial state by not passing the deceleration means through the deceleration means for a predetermined period, and the game ball passes through the deceleration means. The gaming machine C8 is characterized in that the period of passing through the decelerating means in the changing state is set longer than the period of passing through the decelerating means in the initial state.

According to the gaming machine C8, in addition to the effect of any of the gaming machines C1 to C7, the passing period of the gaming ball passing through the deceleration means in the initial state is shortened, and then the deceleration means is passed. As long as the interval between the gaming balls does not become longer than a predetermined period, the deceleration means can always be maintained in a changing state, and the period during which the gaming balls pass through the deceleration means can be maintained for a long time.

In the gaming machine C8, when the gaming balls enter the deceleration means at intervals shorter than the predetermined interval while the deceleration means is in the changing state, the number of the entering game balls does not matter. The gaming machine C9, wherein the deceleration means throws a gaming ball at a constant interval longer than the predetermined interval.

According to the gaming machine C9, in addition to the effect of the gaming machine C8, when the deceleration means is in a changing state, even if a plurality of game balls are entered into the deceleration means, the number of balls is constant regardless of the number of balls entered. Since the game balls can be thrown at intervals, it is possible to prevent overflow from occurring at the detected ball entry port regardless of the number of balls entered.

As the deceleration means, a sprocket-shaped device configured to accommodate a game ball in a recess on the peripheral surface is exemplified.

A gaming machine F1 in any of the gaming machines A1 to A9, B1 to B8, and C1 to C9, wherein the gaming machine 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.

A gaming machine F2 characterized in that, in any one of the gaming machines A1 to A9, B1 to B8, and C1 to C9, the gaming machine is a pachinko gaming machine. 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).

A gaming machine F3 characterized in that, in any one of the gaming machines A1 to A9, B1 to B8, and C1 to C9, the gaming machine is a fusion of a pachinko gaming machine and a slot machine. 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)
64 Winning slot (part of the detection slot)
300, 2300 Delay device (delay means)
311 1st groove (part of deceleration flow path)
312 2nd groove (part of the 1st guide flow path)
312d Detection port (part of detection entry port)
313 Third groove (part of the second guide flow path)
321 Slide moving member (moving means, miniaturizing means)
321a1 Convex part (acting part)
340, 2340 Sorting device (sorting means)
341, 2341 1st wall part (1st wall part)
342 2nd wall (2nd wall)
342a Convex tip (part of dividing means)
350 2nd adjustment device (urging means)
400 Delayed floor device (rolling means)
410 Fan-shaped member (first floor member, part of prevention means, part of ball throwing means, intermediate floor member)
411a Chamfered part (optimal falling part)
436 Delayed flow path (part of throwing means)
3340 Stop device (part of deceleration means)
3360 Maintenance device (release means)
4340 sprocket (part of deceleration means)
P1, P4, P6, P21, P31, P41 balls (first game ball)
P2, P5, P7, P22, P32, P42 balls (second game ball)
P11, P12 balls (game balls, other game balls)

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 entrance for obtaining a lottery opportunity based on the entry of a gaming ball (Patent Document 1).

Japanese Unexamined Patent Publication No. 2011-156058

However, the above-mentioned conventional gaming machine has a problem that there is room for improvement in the method of winning a lottery. 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 a good lottery acquisition.

In order to achieve this object, the gaming machine according to claim 1 is switched between a first state in which a lottery opportunity is given when a gaming ball enters and a first state in which the gaming ball enters the ball. A second state in which a lottery opportunity is not given even if a game ball enters the ball, and a detection ball opening that can be configured are provided, and after switching to the second state, a predetermined return is performed. In a gaming machine that returns to the first state as the period elapses, when a plurality of gaming balls enter, the flow speed of the first gaming ball that enters first among the plurality of gaming balls is set. In comparison, a deceleration means for decelerating the flow speed of the second pachinko ball that has subsequently entered is provided, and the game ball thrown from the deceleration means enters the detection entry port. 2 The period from when the pachinko ball enters the deceleration means to when it enters the detection entry port is longer after the first game ball enters the deceleration means. It is configured in such a manner that it is longer than the length of the return period, which is longer than the period required to enter the ball.

According to the gaming machine according to claim 1, the lottery can be successfully obtained.

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 rear view exploded perspective view of a game board. It is a front view of a delay device. FIG. 6 is a cross-sectional view of the delay device in line VII-VII of FIG. FIG. 6 is a partial cross-sectional view of the delay device on line VIII-VIII of FIG. It is a front perspective view of the slide moving member. (A) is a front view of the slide moving member, (b) is a side view of the slide moving member in the direction of arrow Xb of FIG. 10 (a), and (c) is a side view of FIG. 10 (a). It is a top view of the slide moving member in the direction of arrow Xc, and FIG. 10D is a partial cross-sectional view of the slide moving member in line Xd-Xd of FIG. 10A. It is a front perspective view of the sorting device and the second adjusting device. (A) is a front view of the sorting device and the second adjusting device, (b) is a side view of the sorting device and the second adjusting device in the direction of arrow XIIb of FIG. 12 (a), and (c) is 12 (a) is a top view of the sorting device and the second adjusting device in the direction of arrow XIIc in FIG. 12 (a), and (d) is the sorting device and the second adjusting device in the XIId-XIid line of FIG. 12 (a). It is a partial sectional view. It is a front view of a delay device. It is a front view of a delay device. (A) to (c) are cross-sectional views of the second adjusting device in a plane orthogonal to the rotation axis. (A) to (d) are cross-sectional views of the functional disk device which is a cross-sectional view of the functional disk device in a plane perpendicular to the rotation axis. (A) and (b) are partial front views of the delay device. (A) and (b) are partial front views of the delay device. (A) and (b) are partial front views of the delay device. It is a partial front view of a delay device. (A) to (c) are partial front views of the delay device. It is a partial front perspective view of a game board. (A) is a top view of the fan-shaped member, (b) is a side view of the fan-shaped member in the direction of arrow XXIIIb of FIG. 23 (a), and (c) is a side view of the fan-shaped member of FIG. 23 (a). It is sectional drawing of the fan-shaped member in line XXIIIc, (d) is the bottom view of the fan-shaped member in the direction view of arrow XXIIId of FIG. 23 (b). (A) is a side view of the link member, and (b) is a bottom view of the link member in the direction of arrow XXIVb of FIG. 24 (a). (A) is a top view of a fan-shaped member and a link member, and (b) is a cross-sectional view of the fan-shaped member and the link member in line XXVb-XXVb of FIG. 25 (a). It is a top view of a fixed floor. (A) is a cross-sectional view of a fixed floor in line XXVIIa-XXVIIa of FIG. 26, and (b) is a cross-sectional view of a fixed floor in line XXVIIb-XXVIIb of FIG. 26. (A) is a partial top view of the delayed floor device, (b) is a sectional view of the delayed floor device in line XXVIIIb-XXVIIIb of FIG. 28 (a), and (c) is a portion of the delayed floor device. Top view, (d) is a cross-sectional view of the delayed floor device in line XXVIIId-XXVIIId of FIG. 28 (c). (A) is a top view of the delayed floor device, (b) is a sectional view of the delayed floor device in the line XXIXb-XXIXb of FIG. 29 (a), and (c) is a top view of the delayed floor device. (D) is a cross-sectional view of the delayed floor device in the XXIXd-XXIXd line of FIG. 29 (c). (A) is a top view of the delayed floor device, and (b) is a cross-sectional view of the delayed floor device in the line XXXb-XXXb of FIG. 30 (a). (A) is a top view of the delayed floor device, (b) is a sectional view of the delayed floor device in the line XXXIb-XXXIb of FIG. 31 (a), and (c) is a top view of the delayed floor device. (D) is a cross-sectional view of the delayed floor device on the XXXId-XXXId line of FIG. 31 (c). (A) is a top view of the delayed floor device, (b) is a sectional view of the delayed floor device in the line XXXIIb-XXXIIb of FIG. 32 (a), and (c) is a top view of the delayed floor device. (D) is a front view of the delayed floor device in the direction of arrow XXXIId in FIG. 32 (c). (A) and (b) are sectional views of the delayed floor device in the line XXXIIIa-XXXIIIa of FIG. 32 (c). (A) to (c) are partial front views of the delay device according to the second embodiment. (A) to (c) are partial front views of the delay device according to the third embodiment. (A) to (c) are partial front views of the delay device. (A) to (c) are front views of the delay device according to the fourth embodiment. (A) to (c) are front views of the delay device.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings. First, with reference to FIGS. 1 to 33, 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 a 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 keyhole 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, rental 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 of the front view (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. To.

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, which is chrome-plated, is attached to a region around the illuminated 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 balance information such as a card is displayed, and the built-in LED lights up and the balance is displayed as numerical value as balance 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 below the upper plate 17, a lower plate 50 for storing balls that could not be stored in the upper plate 17 is formed in a substantially box shape with an open upper surface in the central portion thereof. There is. On the right side of the lower plate 50, an operation handle 51 operated by a player to drive the ball into the front of the game board 13 is arranged.

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 front portion 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 53 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 cut into a substantially square shape in front view, a large number of nails and windmills (not shown) for ball guidance, rails 61 and 62, and a general prize. It is configured by assembling a mouth 63, a first winning mouth 64, a second winning mouth 640, a first variable winning device 65, a second variable winning device (not shown), a through gate 67, a variable display device unit 80, and the like. The peripheral edge portion is attached to the back surface side of the inner frame 12 (see FIG. 1). 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 rear surface 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, the first variable winning device 65, the second variable winning device (not shown), and the variable display device unit 80 are formed on the base plate 60 by router processing. It is arranged in the through hole, and is fixed by a tapping screw or the like from the front side of the game board 13.

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 circumference of the game board 13, and the game board 13 and the glass unit 16 (see FIG. 1) surround the front and back of the game board 13. 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, and the ball launched with a predetermined momentum hits the return rubber 69 and has momentum. 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 probable 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 the probability variation jackpot, a symbol corresponding to the 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. it 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 result of the lottery 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 jackpot shifts to a low probability state, and the time is shortened during a predetermined number of fluctuations (for example, 100 fluctuations). is there.

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). 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 power is applied at one time. 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 for opening the electric accessory 640a attached to the second winning opening 640 and the number of times for opening the electric accessory 640a at one time are 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 win a prize. 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 is synchronized with the variable display in the first symbol display devices 37A and 37B, and has a 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 is displayed by the control of the main control device 110 (see FIG. 4), whereas the first symbol display devices 37A and 37B display the game state. 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 the electric accessory 640a may be constant regardless of the gaming state.

The through gate 67 is assembled to the game board on the right side in the area below the variable display device unit 80, and among the balls fired on the game board, a part of the balls flowing down to the right side of the game board can pass through. It is configured in. 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 one, and may be a plurality (for example, two). Further, the assembly position of the through gate 67 is not limited to the right side of the variable display device unit 80, and may be, for example, the left side of 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, on the right side of 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 a display according to the lottery result is shown on the first symbol display device 37B.

The number of times the ball has passed through the first winning opening 64 and the second winning opening 640 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. Further, for example, the larger the number of reserved balls in the first winning opening 64, the easier it is to select a shorter period as the variable display period on the display device. Similarly, the second winning opening 640 is also controlled.

Further, each of the first winning opening 64 and the second winning opening 640 is 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 to be paid out when a prize is won may be three, and the number of prize balls to be paid out when a ball is won to the second winning opening 640 may be configured to be 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 probability 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 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 can easily 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.

As described above, the pachinko machine 10 of the present embodiment fires a ball at 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). You can change the method of "left-handed" and "right-handed". Therefore, the player can enjoy the game because the way of hitting the ball can be changed.

A first variable winning device 65 is arranged on the upper right side of 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 winning the first winning slot 64 or the second winning slot 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 gaming state transitions to a special gaming state (big hit) where 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.

Specifically, the first variable winning device 65 includes a front-view triangular opening / closing plate that covers the specific winning opening 65a, and a large opening solenoid (shown) for driving the opening / closing to the right with the lower side of the opening / closing plate as an axis. It is equipped with. The specific winning opening 65a is normally closed so that the ball cannot win or it is difficult to win. At the time of a big hit, the large opening solenoid is driven to tilt the opening / closing plate to the right to temporarily form an open state in which the ball can easily win a prize in the specific winning opening 65a. It operates so as to alternately repeat the state of.

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, an identification label, etc. is provided, and the certificate stamp, etc. attached to 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 a first out port 71. A ball that flows down the game area and does not win any of the winning openings 63, 64, 65a, 640 is guided to a ball discharge path (not shown) through the first out opening 71. The first out opening 71 is arranged below the first winning opening 64.

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. In the present embodiment, one of the wind turbines (referred to as a movable member 310) is arranged on the upper left side of the game board 13 when viewed from the front, and is shown in FIG.

As shown in FIG. 3, the control board units 90 and 91 and the back pack unit 94 are mainly provided on the rear surface 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 are 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 controller 110 to the sub controller 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 the 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 launch unit 112a includes a launch solenoid and an electromagnet (not shown), and the launch 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 on / off output 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. The other device 228 includes a drive motor 472.

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 rear surface image is an image displayed on the rear surface 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 supply 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 period of time to execute 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.

Next, the delay device 300 will be described with reference to FIGS. 5 to 21. FIG. 5 is an exploded perspective view of the back of the game board 13. FIG. 5 shows a state in which the delay device in which the ball flowing down the game area and flowing into the first winning opening 64 flows down is disassembled from the game board 13.

The ball that has flowed into the first winning opening 64 flows down the inside of the delay device 300, is thrown from the detection port 312d arranged at the lower end thereof, and passes through a detection sensor (not shown), so that a lottery is performed. That is, the lottery has not yet been performed from the time the ball enters the first winning opening 64 until it passes through the detection sensor.

Next, the delay device 300 will be described with reference to FIGS. 6 and 7. FIG. 6 is a front view of the delay device 300, and FIG. 7 is a cross-sectional view of the delay device 300 on the VII-VII line of FIG. Note that in FIG. 7, the game board 13 is partially illustrated for ease of understanding.

As shown in FIGS. 6 and 7, a groove is formed in the delay device 300, and the groove and the game board 13 that hits the surface form a path through which the ball that has entered the first winning opening 64 flows down. A speed reducing device 320 having a main body member 310 and a sliding moving member 321 that slides and moves with respect to the main body member 310, a first adjusting device 330 for adjusting the return operation of the speed reducing device 320, and rotation with respect to the main body member 310. It mainly includes a distribution device 340 that operates and distributes balls to different flow paths, and a second adjustment device 350 that is coaxial with the rotation axis of the distribution device 340 and adjusts the return operation of the distribution device 340.

The main body member 310 is a member that constitutes a groove in which the side arranged to face the game board 13 is opened, and the first groove 311 and the first groove 311 in which the ball entering from the first winning opening 64 first flows down. A path extending laterally from the connecting portion between the second groove 312 extending vertically downward from the lower end of the passage 311 and the connecting portion between the first groove 311 and the second groove 312 and longer than the extending length of the second groove 312. A third groove 313 connected to the detection port 312d and a support plate extending in a plate shape from the front side of the bottom plate opening 311b toward the lower side of the first groove 311 and supporting the slide moving member 321. A unit 314 and a section 314 are mainly provided.

The first groove 311 is a ball in the main passage 311a that lowers the ball entered from the first winning opening 64 in a straight line diagonally downward, and in the central portion of the bottom plate of the main passage 311a in the depth direction (the central portion in the depth direction of the ball). The bottom plate opening 311b, which is an opening formed with a width shorter than the radius of the above, and the top plate opening 311c, which allows the wind turbine member 322 of the speed reducer 320 to be extended inward in the top plate portion, and the top plate portion opening 311c. A pair of bearings 311d, which are arranged in pairs in the depth direction with the plate opening 311c in between, and which serve as bearings for the wind turbine member 322, and a back recessed in a size that allows the ball to roll from the main passage 311a to the back side. Mainly includes a side recessed portion 311e.

The recessed portion 311e on the back side is a recessed portion connected near the entrance of the main passage 311a, and the bottom surface is set to the same height as the bottom surface of the main passage 311a near the entrance, and the main passage 311a is directed toward the downstream side. It is configured in a manner of ascending and tilting.

The second groove 312 is a recess formed in the plate portion on the back side (back side in FIG. 6) and is divided into a contact wall 312a that gives a load to bounce the ball that has reached the lower end of the first groove 311 in the left-right direction. The recessed portion 312b, which is recessed in an arc shape so that the device 340 can be arranged, and the receiving wall portion 312c, which receives the ball flowing in from the third groove 313 and acts as a detent for the sorting device 340, and throws the ball. It mainly includes a detection port 312d and a side wall portion 312e that is arranged to face the recessed portion 312b.

The support plate portion 314 includes a pair of elongated holes 314a through which the guide rod portion 321c of the slide moving member 321 is inserted. The elongated hole 314a is configured in the same direction as the elongated hole 331a of the first adjusting device 330 (consisting of overlapping in the front-rear direction).

The speed reducing device 320 mainly includes a slide moving member 321 that slides when the ball passes through the first groove 311 and a wind turbine member 322 that is meshed with the slide moving member 321 and is brought into contact with the ball to rotate. Prepare for.

The slide moving member 321 is guided by the elongated hole 314a of the main body member 310 and the elongated hole 331a of the first adjusting device 330, which will be described later, so that the slide moving member 321 can operate linearly.

The wind turbine member 322 has a main body gear portion 322a having a gear portion that is pivotally supported by the bearing portion 311d and meshed with the slide moving member 321 at the rear end portion, and the wind turbine member 322 radially from the shaft portion of the main body gear portion 322a. It mainly includes a first extending wing portion 322b and a second extending wing portion 322c which are extended in pairs and form an angle of 90 ° with each other.

As shown in FIG. 7, the first extending vane portion 322b and the second extending vane portion 322c are configured so as to be able to project from the top plate opening 311c toward the inside of the first groove 311a, and at the same time. The first extending vane portion 322b is arranged at a position where it can come into contact with the ball in the initial state in which the slide moving member 321 is maintained at the lower end position by gravity when the slide moving member 321 is brought into contact with the ball flowing down the groove 311a.

The second extending vane portion 322c includes a convex portion 322c1 of the tip end portion in the extending direction, which is projected in a tapered shape in a direction close to the first groove 311 from the state shown in FIG. The convex portion 322c1 acts in a manner of separating the spheres when the spheres flow down the first groove in succession.

The first adjusting device 330 includes a main body plate member 331 which is a plate-shaped member sandwiching the main body member 310 between the game board 13 and a main body gear portion 322a of the wind turbine member 322 while being pivotally supported by the main body plate member 331. It mainly includes a rotary urging device 332 having a fixed gear portion 332a to be meshed with each other. The gear ratio of the fixed gear portion 332a to the main body gear portion 322a of the wind turbine member 322 is about 2. That is, as the wind turbine member 322 rotates by 90 °, the rotary urging device 332 rotates by 45 °.

The main body plate member 331 is provided with a pair of elongated holes 331a for guiding the slide moving member 321 and is also formed on the support plate portion 314 in which the elongated holes 314a having the same shape are arranged to face each other. The slide moving member 321 is configured to be slidable in the straight direction by being guided by these elongated holes 314a and 331a.

The rotary urging device 332 mainly includes a fixed gear portion 332a pivotally supported by the main body plate member 331 and a functional disk device 332b fixed to the fixed gear portion 332a at the axial end and having a recessed groove inside. Prepare for.

The sorting device 340 is a device that is pivotally supported by the central hole 345 in the main body member 310 on the right side of the second groove 312 of the main body member 310, and is a sphere that flows in from the second groove 312b in the initial state shown in FIG. The first wall portion 341 that receives the first wall portion 341, the second wall portion 342 that is arranged above the first wall portion 341 with one sphere separated from each other, and the sorting device 340 from the tip of the second wall portion 342. The arc wall portion 343 formed along the arc shape centered on the rotation axis, the concave portion 312 formed from the disk shape, and the concave portion 312 of the second groove 312 are arranged at the surface position and on the back side of the second groove 312. It mainly includes a complementary plate portion 344 formed in a manner of complementing a part of the plate portion, and a central hole 345 which is a through hole pivotally supported by the main body member 310.

The second wall portion 342 includes a tip convex portion 342a that is radially projected on the extending tip. The sphere that abuts on the arc wall portion 343 and flows down by the tip convex portion 342a can apply a load counterclockwise (counterclockwise in FIG. 6) to the sorting device 340, which is intended by the action of the sphere. It is possible to prevent the distribution device 340 from returning to the initial position side.

The initial position of the sorting device 340 is defined by the stopper portion S1 projecting rearward of the game board 13. That is, at the initial position, the tip of the arc wall portion 343 is stopped by the stopper portion S1, so that the sorting device 340 is stopped. The driving force for rotating the sorting device 340 clockwise in the front view (clockwise in FIG. 6) is generated by the second adjusting device 350.

The second adjusting device 350 is a device fixed to the complementary plate portion 344 of the sorting device 340 and has a flow path in which the pseudo center of gravity sphere GB that changes the center of gravity is movable. It will be described later in 15.

FIG. 8 is a partial cross-sectional view of the delay device 300 on line VIII-VIII of FIG. As shown in FIG. 8, the slide moving member 321 is arranged at the central portion of the main passage 311a. As a result, when the slide moving member 321 projects inside the main passage 311a, the convex portion 321a1 can be reliably brought into contact with the sphere flowing down the first groove 311.

The sphere flowing down the passage 311a may flow into the recessed portion 311e on the back side due to its shape. The recessed portion 311e on the back side has a return wall portion 311e1 configured so as to be closer to the main passage 311a side toward the downstream side (left side in FIG. 8). As a result, the ball that has flowed into the recessed portion 311e on the back side cannot be returned to the main passage 311a, and it is possible to prevent the ball from being clogged.

Next, the slide moving member 321 will be described with reference to FIGS. 9 and 10. 9 is a front perspective view of the slide moving member 321. FIG. 10A is a front view of the slide moving member 321. FIG. 10B is a view in the direction of arrow Xb in FIG. 10A. 10 (c) is a side view of the slide moving member 321, FIG. 10 (c) is a top view of the slide moving member 321 in the direction of arrow Xc of FIG. 10 (a), and FIG. 10 (d) is a view of FIG. 10 (a). It is a partial cross-sectional view of the slide moving member 321 in the Xd-Xd line of.

As shown in FIGS. 9 and 10, the slide moving member 321 includes a long plate-shaped first overhanging plate portion 321a that overhangs the central portion of the main passage 311a of the delay device 300 in a plane parallel to the main passage. The second overhanging plate portion 321b, which is continuously provided at one end of the first overhanging plate portion 321a and is extended downward with respect to the extending direction of the first overhanging plate portion 321a, and each overhanging plate portion 321b. A pair of round bar-shaped guide rods 321c extending in parallel at both ends of the protruding plates 321a and 321b in the long direction, and a depth direction with respect to the respective overhanging plates 321a and 321b (paper surface in FIG. 10A). It mainly includes a rack gear portion 321d extending in a straight line and forming rack gear teeth at a position offset in the vertical direction).

The first overhanging plate portion 321a is a plate portion extending in a direction parallel to the extending direction of the main passage 311a in the assembled state (see FIG. 6), and is arranged at intervals of the diameters of the spheres. A convex portion 321a1 is provided so as to be convex from the upper surface in a semicircular shape. When the convex portion 321a1 comes into contact with the sphere, the velocity of the sphere passing through the main passage 311a (see FIG. 8) is reduced.

The second overhanging plate portion 321b includes a convex portion 321b1 that has the same function as the convex portion 321a1, and an inclined surface 321b2 (see FIG. 10D) that inclines downward toward the back side. When the second overhanging plate portion 321b overhangs the inside of the main passage 311a, the inclined surface 321b2 makes it easy for the flowing ball to face the back side recessed portion 311e (see FIG. 8). Therefore, the passage period of the sphere can be lengthened as compared with the case where the sphere flows down in a straight line along the extending direction of the passage 311a.

Since the first overhanging plate portion 321a and the second overhanging plate portion 321b have different extension directions, the first extending plate portion 321a overhangs the inside of the main passage 311a, while the second overhanging plate portion 321b is a book. A state arranged outside the passage 311a can be formed. That is, the degree of deceleration of the sphere can be changed by arranging the slide moving member 321. The details will be described later.

The guide rod portion 321c is inserted into the elongated hole 331a of the first adjusting device 330 (see FIG. 6). As a result, the slide moving member 321 is supported so as to be slidable along the extending direction of the elongated hole 331a.

The rack gear portion 321d is extended in parallel with the extending direction of the elongated hole 331a, and the rack gear teeth are meshed with the main body gear portion 322a of the wind turbine member 322 (see FIG. 6). As a result, the wind turbine member 322 rotates, so that the rack gear portion 321d is slid in the linear direction (extending direction of the elongated hole 331a).

Next, the sorting device 340 and the second adjusting device 350 will be described with reference to FIGS. 11 and 12. 11 is a front perspective view of the sorting device 340 and the second adjusting device 350, FIG. 12A is a front view of the sorting device 340 and the second adjusting device 350, and FIG. 12B is a diagram. 12 (a) is a side view of the sorting device 340 and the second adjusting device 350 in the direction of arrow XIIb of FIG. 12 (a), and FIG. 12 (c) shows the sorting device 340 and the second adjustment in the direction of arrow XIIc of FIG. 12 (a). It is a top view of the apparatus 350, and FIG. 12D is a partial cross-sectional view of the sorting apparatus 340 and the second adjusting apparatus 350 in the XIId-XIid line of FIG. 12A. Note that FIG. 12D shows a state in which the pseudo center of gravity sphere GB is on the deceleration wall portion 351d.

As shown in FIGS. 11 and 12, the front side of the complementary plate portion 344 is opened except for the portion occupied by each wall portion 341, 342, 343, and is used as a side wall of the passage through which the ball flows down (see FIG. 6). ..

The second adjusting device 350 is a center of gravity changing device 351 fixed to the back surface side of the complementary plate portion 344 and having a recessed flow path for flowing the pseudo center of gravity sphere GB inside, and a recessed portion of the center of gravity changing device 351. A lid member 352 fixed to the center of gravity changing device 351 in a manner of covering the lid is mainly provided.

The center of gravity changing device 351 includes a disk-shaped main body member 351a having a shallow recessed portion, a recessed groove portion 351b in which the pseudo center of gravity sphere GB is recessed in the main body member 351a with a width that allows the pseudo-center of gravity sphere GB to flow down, and the recessed groove portion. A partition wall 351c that allows the passage of the pseudo-center of gravity sphere GB only at the tip, and a deceleration mechanism that extends to one side of the flow path partitioned by the partition wall 351c and decelerates the flow of the pseudo-center of gravity sphere. It is oscillatingly supported by one end (lower end of FIG. 12 (a)) of the deceleration wall portion 351d and the partition wall 351c, and is oscillatingly supported in one direction of the pseudo center of gravity sphere GB (FIG. 12 (a) rightward direction). ) Is mainly provided with a directional valve 351e that allows only passage of.

The position of the center of gravity of the second adjusting device 350 excluding the pseudo center of gravity sphere GB is set to be the same as the center of rotation. That is, the stable posture of the distribution device 340 is determined by the position where the pseudo center of gravity sphere GB is arranged with respect to the center of rotation.

Here, the pseudo-center of gravity sphere GB is composed of a sphere having a weight equal to or less than the weight of the sphere. For example, if the weight of the sphere is 5 grams, it is desirable to select a spherical object having a weight of about 2 to 4 grams as the pseudo center of gravity sphere GB. As a result, it is possible to avoid a situation in which the forces of the ball flowing into the sorting device 340 and the pseudo center of gravity sphere GB are balanced, and the sorting device 340 can be rotated by the weight of the sphere.

The deceleration mechanism of the deceleration wall portion 351d will be described with reference to FIG. 12 (d). The deceleration wall portion 351d is a portion that supports both sides of the sphere from below and rolls the sphere in that state. As shown in FIG. 12 (d), the pseudo center of gravity sphere GB does not roll at the portion (the central portion in the left-right direction in FIG. 12 (d)) where the length from the rotation axis is the maximum diameter (radius r1). At a portion where the length from the rotation axis has a radius (radius r'1) shorter than the maximum diameter, the ball comes into contact with the deceleration wall portion 351d and rolls. Therefore, when the rotation speed of the pseudo center of gravity sphere GB is the same, the speed of the pseudo center of gravity sphere GB is decelerated as compared with the speed of the pseudo center of gravity sphere GB when the pseudo center of gravity sphere GB rolls on the partition wall 351c (rolls with a radius r1). It is possible to slow down the speed of the pseudo-center of gravity sphere GB when rolling (rolling with a radius r'1) on the wall portion 351d.

That is, the translational movement distance per rotation of the pseudo-center of gravity sphere GB can be shortened. When the pseudo center of gravity sphere GB is decelerated by this method, the deceleration can be performed while maintaining the rotational energy of the pseudo center of gravity sphere GB, so that the braking is too effective and the pseudo center of gravity sphere GB stops at an unintended position. The situation can be avoided.

Further, since the degree of deceleration of the pseudo center of gravity sphere GB can be arbitrarily set by setting the contact position (rolling radius of the pseudo center of gravity sphere GB) between the deceleration wall portion 351d and the pseudo center of gravity sphere GB, a special material (high friction) can be set. The pseudo center of gravity sphere GB can be sufficiently decelerated even when the forming distance of the deceleration wall portion 351d is short.

Next, the operation of the delay device 300 will be described with reference to FIGS. 13 and 14. 13 and 14 are front views of the delay device 300. FIG. 13 shows a state immediately after the sphere has flowed through the main body member 310 in the initial state shown in FIG. 6, and FIG. 14 shows a state immediately after the sphere has flowed through the main body member 310 in the state of FIG. Is illustrated.

As shown in FIGS. 13 and 14, the sorting device 340 changes its posture between the initial state (see FIG. 6) and the changed state (see FIG. 13) due to the passage of the sphere, and the speed reducing device 320 has the number of passing spheres. The state (arrangement in the height direction) changes depending on the initial state (see FIG. 6), the intermediate state (see FIG. 13), and the ascending state (see FIG. 13).

Each state of the speed reducer 320 will be described. When the speed reducing device 320 is in the intermediate state, the slide moving member 321 moves and is arranged at a position where the convex portion 321a projects from the bottom surface of the main passage 311a. Therefore, in this state, the sphere that has flowed into the main passage 311a comes into contact with the convex portion 321a and flows down while being decelerated. In the intermediate state, the second overhang plate portion 321b is arranged outside the first groove 311.

When the speed reducing device 320 is in the raised state, the slide moving member 321 further overhangs the inside of the main passage 311a, and the second overhanging plate portion 321b is arranged above the bottom surface of the back side recessed portion 311e. Since the second overhanging plate portion 321b has an inclined surface 321b (see FIG. 10) on the upper surface, the sphere flowing into the main passage 311a in this state is a recessed portion 311e on the back side along the inclination of the inclined surface 321b. After flowing to the lower end of the recessed portion 311e on the back side, it merges with the main passage 311a again.

When the speed reducing device 320 is in the raised state, the road width (width in the height direction) of the main passage 31a is narrowed by the first overhang plate portion 321a projecting inside the main passage 311a. Further, in the present embodiment, the slide moving member 321 slides in a direction in which the slide moving member 321 is inclined with respect to the extending direction of the passage 311a, so that the contact wall 312a of the second groove 312 and the first overhanging plate portion 321a The width with the end is narrowed. Therefore, the deceleration of the ball can be performed by narrowing the road width of the main passage 311a and increasing the flow path resistance by narrowing the road width of the connecting portion between the first groove 311 and the second groove 312.

Each state of the sorting device 340 will be described. When the sorting device 340 is in the initial state (see FIG. 6), the ball flowing into the sorting device 340 is received by the first wall portion 341. Then, the distribution device 340 rotates to the changed state (see FIG. 13) due to the weight of the sphere, and the sphere flows into the detection port 312d.

Here, in the present embodiment, since the side wall portion 312e is configured to project above the first wall portion 341 (overhang at a height equal to or greater than the radius of the sphere), the sphere flows into the third groove 313 side. Is suppressed. Therefore, when the sorting device 340 is in the initial state, the sphere that has flowed into the sorting device 340 can flow down vertically with a high probability (it can flow down in the shortest period of time).

When the sorting device 340 is in a changed state (see FIG. 13), the sphere flowing into the sorting device 340 comes into contact with the arc wall portion 343 and flows into the third groove 313. Since the arc wall portion 343 is formed from an arc shape centered on the center hole 345 of the sorting device 340, a load when a sphere collides is applied in a direction toward the rotation axis of the sorting device 340. It is suppressed that a load in the rotation direction is applied to the sorting device 340.

Therefore, it is possible to avoid a situation in which the sorting device 340 unintentionally returns to the initial state due to the impact of the ball flowing into the sorting device 340 in the changing state on the sorting device 340, and the sorting device 340 changes for a predetermined period. It can be ensured that the condition is maintained.

Next, with reference to FIG. 15, adjustment of the posture change timing of the sorting device 340 will be described. 15 (a) to 15 (c) are cross-sectional views of the second adjusting device 350 in a plane orthogonal to the rotation axis. 15 (a) to 15 (c) show that the internal structure of the center of gravity changing device 351 is visible, and FIG. 15 (a) shows the case where the sorting device 340 is in the initial state (see FIG. 6). In FIG. 15B, the case where the sorting device 340 is in the changed state (see FIG. 13) is shown, and in FIG. 15C, the state immediately before the sorting device 340 returns from the changed state to the initial state. Is illustrated.

As shown in FIG. 15, in the second adjusting device 350, the pseudo center of gravity sphere GB moves inside the recessed groove portion 351b as the posture changes. As a result, the position of the center of gravity of the second adjusting device 350 changes, and the second adjusting device 350 repeats stopping and rotating.

The operation of the second adjusting device 350 will be described. As shown in FIG. 15A, when the sorting device 340 is in the initial state (see FIG. 6), the pseudo-center-of-gravity sphere GB is arranged on the right side of the central hole 345. A load is applied in the direction of rotating the second adjusting device 350 clockwise in the front view (clockwise in FIG. 15). As a result, even if the gaming machine 10 (see FIG. 1) vibrates slightly, the sorting device 340 can maintain the posture at the initial position.

As shown in FIG. 15B, when the sorting device 340 is in the changed state (see FIG. 13), the inclination formed by the partition wall 351c and the directional valve 351e is inclined downward toward the left. At the same time, the inclination formed by the deceleration wall portion 351d is set to be downwardly inclined toward the right. Therefore, the pseudo center of gravity sphere GB rolls on the upper side of the partition wall 351c and flows to the left along the arrow L1, falls on the deceleration wall portion 351d at the end, rolls on the upper side of the deceleration wall portion 351d, and the arrow L2. It operates to flow to the right along.

As a result, the pseudo center of gravity sphere GB can be sent to the left of the central hole 345, so that the second adjusting device 350 is rotated counterclockwise in front view (counterclockwise in FIG. 15) by the weight of the pseudo center of gravity sphere GB. A load is applied in the direction. As a result, the sorting device 340 can be maintained in a changed state for a certain period of time (the period until the pseudo center of gravity sphere GB passes to the right of the central hole 345).

The period for maintaining the changed state can be arbitrarily changed depending on the degree of deceleration of the pseudo center of gravity sphere GB by the deceleration wall portion 351d. For example, if the flow speed of the pseudo center of gravity sphere GB is halved by the deceleration wall portion 351d, the period for maintaining the distribution device 340 in the changed state can be doubled.

As the mode of the deceleration wall portion 351d, various modes are exemplified. For example, a method of decelerating the translational movement speed of the pseudo center of gravity sphere GB by reducing the radius of gyration at the point where the pseudo center of gravity sphere GB comes into contact with the deceleration wall portion 351d is exemplified (see FIG. 12 (d)). That is, by receiving the rotation of the pseudo-center of gravity sphere GB not at the maximum diameter portion (center portion) but at the portion where the diameter becomes smaller (near the end portion), the translational movement distance per rotation of the pseudo-center-of-gravity sphere GB is obtained. This is a method of shortening and decelerating the pseudo center of gravity sphere GB without reducing the number of rotations. According to this method, the translational speed of the pseudo-center-of-gravity sphere GB after passing through the deceleration wall portion 351d can be increased as compared with the case of reducing the rotation speed of the pseudo-center-of-gravity sphere GB.

Therefore, immediately after reaching the right end of the deceleration wall portion 351d, the pseudo center of gravity sphere GB can be thrown to the right at a large speed, and immediately after the pseudo center of gravity sphere GB reaches the right end of the deceleration wall portion 351d, FIG. It is possible to shorten the period until the state changes to the state shown in (c).

As shown in FIG. 15 (c), the pseudo center of gravity sphere GB passes through the directional valve 351e before and after the state of the distribution device 340 changes from the changed state to the initial state. As shown in FIG. 15C, the directional valve 351e is configured to allow the pseudo-center-of-gravity sphere GB to flow to the right, while preventing the pseudo-center-of-gravity sphere GB from flowing to the left. This makes it possible to prevent the pseudo-center of gravity sphere GB from bouncing back to the left of the central hole 345.

In the present embodiment, the period from when the sorting device 340 changes to the changed state to when it returns to the initial state is a variable period which is easily selected when the number of reserved balls in the winning opening 64 (see FIG. 2) is four. It is set to a longer period than (shortest fluctuation period).

Therefore, when a ball is inserted into the distribution device when the distribution device 340 is in the initial state, and the ball enters the detection port 312d (see FIG. 6), the number of reserved balls in the winning port 64 becomes four. In addition, the balls that have entered the distribution device 340 before the end of the fluctuation that is started after that (before the number of reserved balls in the winning opening 64 is vacant) are all distributed to the third groove 313 (see FIG. 13). Then, while the ball passes through the third groove 313, the fluctuation of 1 of the winning opening 64 ends, and the number of reserved balls in the winning opening 64 becomes vacant, so that the winning opening 64 overflows (the state in which the number of reserved balls is the maximum). By entering the ball into the detection port 312d, it is possible to prevent the occurrence of a state in which a lottery opportunity cannot be obtained even though the ball has entered.

The degree of deceleration of the ball in the third groove 313 can be set by various methods. For example, the ball may be decelerated by attaching a high-friction sheet to the bottom wall on which the ball rolls.

Here, as a first setting example, the period until the ball passes through the third groove 313 is easily selected, for example, when the number of reserved balls in the winning opening 64 is four (the shortest variation period). By setting the period longer than that, when two balls enter the sorting device 340 in succession, the second ball enters the detection port 312d and the second ball enters the third groove. The period from passing through 313 to entering the detection port 312d can be made longer than the fluctuation period (shortest fluctuation period) that is likely to be selected when the number of reserved balls in the winning opening 64 is four. As a result, it is possible to prevent overflow from occurring at the winning opening 64.

Further, as a second setting example, the period until the ball passes through the third groove 313 is divided into, for example, a variable period that is easily selected when the number of reserved balls in the winning opening 64 is 3, and the number of reserved balls is 4. By setting the period longer than the total period of the fluctuation period (shortest fluctuation period) that is likely to be selected in the case of individual balls, even if two balls are continuously inserted into the third groove 313, one ball is inserted. Since the two fluctuations are digested in the period from when the eyeball enters the detection port 312d until the second ball passes through the third groove 313 and enters the detection port 312d, after that, Even if two balls enter the detection port 312d, it is possible to suppress the occurrence of overflow.

Next, the functional disk device 332b will be described with reference to FIG. In the functional disk device 332b, the position of the center of gravity changes as in the case of the second adjusting device 350 by moving the pseudo center of gravity sphere GB arranged between the functional disk device 332b and the main body plate member 331 (see FIG. 7). It is a device that changes the direction of the load applied to the 332b.

16 (a) to 16 (d) are cross-sectional views of the functional disk device 332b, which is a cross-sectional view of the functional disk device 332b in a plane perpendicular to the rotation axis. FIG. 16A shows the case where the speed reducer 320 is in the initial state (see FIG. 6), and FIG. 16B shows immediately after the speed reducer 320 changes from the initial state to the intermediate state (see FIG. 13). 16 (c) shows immediately after the speed reducer 320 changes its state from the intermediate state to the ascending state (see FIG. 14), and FIG. 16 (d) shows the speed reducer 320 from the intermediate state to the initial state. The state immediately after the state change is shown in the figure.

As shown in FIG. 16, the functional disk device 332b is a partition that limits the portion through which the sphere can pass from the recessed groove portion 332b1 that is recessed from the back side at a depth at which the pseudo-center of gravity sphere GB can move. The wall 332b2 and the partition wall 332b2 are arranged as a rollable plate portion on the lower side of the partition wall 332b2, and are formed so as to project a predetermined width from the end of the partition wall 332b2 and slow down the flow of the pseudo center of gravity sphere GB. The first deceleration wall portion 332b3, the second deceleration wall portion 332b4 that is arranged on the opposite side of the partition wall 332b2 with the first deceleration wall portion 332b3 sandwiched between them and decelerates the flow of the pseudo center of gravity sphere GB, and the pseudo center of gravity sphere GB. It is mainly provided with a directional valve 332b5 that limits the passage of the vehicle in one direction from the left side to the right side.

For convenience, the pseudo center of gravity sphere GB uses the same reference numerals as the pseudo center of gravity sphere GB accommodated in the second adjusting device 350, and is limited to those having the same shape and weight as the pseudo center of gravity sphere GB. Not the purpose.

The functional disk device 332b can allow the pseudo center of gravity sphere GB to flow down at the first deceleration wall portion 332b3 to pass through the directional valve 332b5, or can pass through the directional valve 332b5 to flow down at the second deceleration wall portion 332b4. .. Hereinafter, the operation of the functional disk device 332b will be described in detail. In addition, FIG. 6, FIG. 13 and FIG. 14 are referred to as appropriate.

As shown in FIG. 16A, when the speed reducer 3420 is in the initial state (see FIG. 6), the partition plate 332b is tilted downward to the right, and the pseudo center of gravity sphere GB is a functional disk device. It is maintained on the right side of 332b. As a result, a load for maintaining the slide moving member 321 downward is applied from the rotary urging device 332 to the slide moving member 321 (see FIG. 6). Therefore, when the gaming machine 10 (see FIG. 1) vibrates, it is possible to prevent the slide moving member 321 from moving up and down.

As shown in FIG. 16B, when the reduction gear 3420 is in the intermediate state (see FIG. 13), the partition plate 332b2 is in a mode of inclining downward to the left, while the first reduction wall portion 332b3 is It is considered to be a downward slope to the right. Therefore, the pseudo center of gravity sphere GB rolls the upper surface of the partition plate 332b2 to the left along the arrow L3, and then rolls to the right on the upper surface of the first deceleration wall portion 332b3 along the arrow L4. The center of gravity sphere GB is sent to the right side of the rotation center of the functional disk device 332b, and a load is applied in the direction of returning the functional disk device 332b to the initial state (direction of rotating clockwise in FIG. 16).

In the middle of the flow of the pseudo center of gravity sphere GB, as shown in FIG. 16 (b), in a state where the pseudo center of gravity sphere GB is arranged on the left side of the center of rotation, yesterday the disk device 332b was counterclockwise in FIG. 16 (b). Since the load is applied in the direction of rotating the slide moving member 321 due to gravity, the lowering of the slide moving member 321 can be stopped. Further, the weight of the sphere can prevent the slide moving member 321 from descending (even if the sphere descends, it is possible to form a state in which the slide moving member 321 immediately rises when the sphere arrives).

As shown in FIG. 16 (c), when the speed reducer 3420 is in the ascending state (see FIG. 14), the first deceleration wall portion 332b3 is in a mode of descending and tilting to the left, while the second deceleration wall. The portion 332b4 is in a mode of inclining downward to the right. Therefore, the pseudo-center of gravity sphere GB rolls the upper surface of the first deceleration wall portion 332b3 to the left along the arrow L5, and then rolls to the right on the upper surface of the second deceleration wall portion 332b4 along the arrow L6. As a result, the pseudo center of gravity sphere GB is sent to the right side of the rotation center of the functional disk device 332b, and a load is applied in the direction of returning the functional disk device 332b to the initial state (direction of rotating clockwise in FIG. 16).

When the pseudo center of gravity sphere GB is rolling on the upper surface of the first deceleration wall portion 332b3, the sphere passes through the main passage 311a and the deceleration device 320 moves to the ascending state, and the functional disk device 332b is shown in FIG. 16 (c). In the posture shown in the above, the pseudo center of gravity sphere GB is subsequently decelerated by the first deceleration wall portion 332b3 and further decelerated by the second deceleration wall portion 332b4, so that the reduction gear 320 is placed in the intermediate state. Compared with the case (see FIG. 13), the period until the pseudo-center of gravity sphere GB is arranged to the right of the center of rotation is lengthened. Therefore, the speed reducer 320 can be maintained in the ascending state (see FIG. 14) longer than the period in which it is maintained in the intermediate state (see FIG. 13).

As shown in FIG. 16D, when the pseudo center of gravity sphere GB arranged on the first deceleration wall portion 332b3 or the second deceleration wall portion 332b4 is arranged to the right of the center of the functional circle device 332b, the slide moving member The reduction device 320 operates due to the weight of 321 to bring the functional disk device 332b into the same posture as the initial state, and the pseudo center of gravity sphere GB is discharged from the first reduction wall portion 332b3 or the second reduction wall portion 332b4 and is recessed. Roll 332b1. When the pseudo center of gravity sphere GB passes through the directional valve 332b5, the functional disk device 332b returns to the initial state (see FIG. 16A).

A flow pattern of a sphere flowing down inside the delay device 300 will be described with reference to FIGS. 17 and 18. 17 (a), 17 (b), 18 (a) and 18 (b) are partial front views of the delay device 300. 17 (a), 17 (b), 18 (a) and 18 (b) show a case where three balls P1 to P3 are inserted in a row from the winning opening 64, and FIG. In a), a state in which the spheres P1 to P3 are arranged in front of the wind turbine member 322 is shown, and in FIG. 18 (b), the sphere P1 and the sphere P2 are separated from the second extending vane portion 322c of the wind turbine member 322. In FIG. 18 (c), the state in which the sphere P2 pushed the second extending wing portion 322c and reached the sorting device 340 is illustrated, and in FIG. 18 (d), the sphere P3 is the first. The state in which the two grooves 312 begin to invade is illustrated.

In addition, in FIG. 17 (a), FIG. 17 (b), FIG. 18 (a) and FIG. 18 (b), after the balls P1 to P3 enter the winning opening 64 in the lower right space of the structural drawing. A graph showing the situation of is illustrated. In addition, the timing at which the balls P1 to P3 enter the winning opening 64 actually deviates slightly (about 0.2 seconds), but in the graph, the balls P1 to P3 win the prize in order to facilitate understanding. It is illustrated as having entered the mouth 64 at the same time, and the horizontal axis is configured as the elapsed time T.

In the graph, the timing when the spheres P1 to P3 enter the winning opening 64 (“IN”) and the timing when the spheres P1 to P3 enter the detection opening 312d (“OUT”) are shown, and when the spheres P1 to P3 enter the winning opening 64 (“OUT”). Which section is flowing down is illustrated by a code. Further, in the corresponding drawing, which timing of the graph the state shown in FIGS. 17 (a), 17 (b), 18 (a) and 18 (b) represents is indicated by a triangular mark.

As shown in FIG. 17A, the spheres P1 to P3 flow down the first groove 311 under the same conditions until they reach the wind turbine member 322, and there is no difference in their velocities.

As shown in FIG. 17B, the first ball P1 pushes forward the first extending blade portion 322b of the wind turbine member 322, and the second ball P2 is separated from the second extending blade portion 322c. Then, the preceding sphere P1 flows down to the convex portion 321a1 without being decelerated, while the convex portion 321a1 projects into the main passage 311a on the downstream side of the sphere P2. Therefore, when the sphere P2 and the sphere P3 come into contact with the convex portion 321a1, a load in the direction opposite to the flow direction is intermittently applied and the sphere P3 decelerates. As a result, a space can be provided between the spheres P1 and the spheres P2. Therefore, for example, it is possible to prevent the spheres from being clogged and malfunctioning due to the two spheres being simultaneously entered into the sorting device 340. be able to.

In the present embodiment, the first period of passing through the first groove required for the ball P1 to pass through the first groove 311 is set to 2 seconds (T11 = 2s), and after the ball P1 has passed, the speed reducer 320 ( The deceleration return first start period, which is the period from the intermediate state to the start of returning to the initial state, is set to 5 seconds, and the speed reducer is set to return to the initial state 1 second after the start of return.

Further, the second period T2, which is the period from when the ball P1 enters the second groove 312 to when it enters the detection port 312d, is 1.5 seconds (T2 = 1.5s). The second period T2 is the first half T2a (T2a = 1s) of the second period, which is one second before reaching the sorting device 340, and the second half of the second period, which is 0.5 seconds after passing through the sorting device 340. It is divided into T2b (T2b = 0.5s), and the period during which the ball passes through the second groove 312 is invariant regardless of the state of the sorting device 340.

As shown in FIG. 18A, when the second ball P2 pushes the second extending blade portion 322c of the wind turbine member 322, the preceding ball P2 flows into the second groove, while the ball P3 , Flows into the recessed portion 311e on the back side along the inclined surface 321b2 of the slide moving member 321. As a result, in addition to being decelerated by the convex portion 321a1, the flow path of the sphere P3 is extended by the amount passing through the inner recessed portion 311e, so that the sphere P2 and the sphere P3 can be spaced apart from each other.

In the present embodiment, the first groove passage second period T12 required for the sphere P2 to pass through the first groove 311 is set to 3 seconds (T12 = 3s), and the sphere P3 passes through the first groove 311. The third period T13 required for passing through the first groove is set to 6 seconds (T13 = 6s). Further, the deceleration return second start period, which is the period from the passage of the ball P2 to the start of the deceleration device 320 returning to the initial state (from the ascending state), is set to 7 seconds, and the deceleration device is set to 2 seconds after the start of the return. It is set to return to the initial state.

Further, since the sphere P2 comes into contact with the arc wall portion 343 of the sorting device 340 and flows into the third groove 313, the path to the detection port 312d is extended as compared with the sphere P1. Therefore, the distance between the sphere P1 and the sphere P2 can be widened.

In the present embodiment, the third period T3 required for the balls P2 and P3 to pass through the third groove 313 is set to 3 seconds (T3 = 3s). Further, the speed of the pseudo center of gravity sphere GB of the second adjusting device 350 is set in such a manner that the distribution maintenance period BT1 which is the period from the change of the state of the distribution device 340 to the change state to the start of returning to the initial state is 4 seconds. It is set (BT1 = 4s).

As shown in FIG. 18B, when the speed reducer 320 is in the raised state, the distance between the end of the first overhanging plate portion 321a and the contact wall 312a is about the same as the diameter of the sphere. Will be done. Therefore, the spheres P2 and P3 are subjected to a large resistance when passing between the end portion of the first overhanging plate portion 321a and the contact wall 312a, and the momentum is reduced. Thereby, the distance between the spheres P1 and the spheres P2 and P3 can be widened.

As shown in FIG. 18B, the sphere P2 flows down the third groove 313 and receives the first wall portion 341 and presses it against the wall portion 312c, so that the sorting device 340 can be easily maintained in the changed state. it can.

As shown in the graph, the distribution device 340 is maintained in the changed state even at the timing when the sphere P3 flows into the distribution device 340 (at the timing when only the distribution maintenance period BT1 has elapsed after the state of the distribution device 340 changes to the changed state. The sphere P3 reaches the sorting device 340). Therefore, the ball P3 flows into the third groove 313. As a result, it is possible to prevent the distance between the sphere P2 and the sphere P3 from being shortened.

As shown in the graph, according to the present embodiment, when the spheres P1 to P3 enter the winning opening 64 in succession, the spheres P1 and P2 enter the detection opening 312d at intervals of 4 seconds, and the spheres P2 And the ball P3 enter at intervals of 3 seconds. In the present embodiment, the fluctuation period of 1 selected after the maximum number of reserved balls in the winning opening 64 is set to 3 seconds. Therefore, in the case of FIGS. 17 and 18, an overflow occurs in the winning opening 64. Can be prevented.

Further, in the present embodiment, the period during which the sorting device 340 is maintained in the changed state is one variable period selected after the number of reserved balls in the winning opening 64 is maximized when the balls flow into the detection port 312d. As shown in FIG. 18A, when the ball P2 enters the sorting device 340 during the fluctuation period, the ball P2 is surely flowed into the third groove 313. be able to. As a result, it is possible to prevent overflow from occurring when the balls continuously enter the sorting device 340.

Therefore, even when three balls P1 to P3 are continuously entered into the winning opening 64, the timing at which they are entered into the detection opening 312d can be shifted, and overflow at the winning opening 64 can be suppressed. Can be done. As a result, even if the player does not pay special attention, it is possible to avoid a situation in which the ball enters the winning opening 64 but cannot receive the lottery, and the game can be performed comfortably.

In the present embodiment, when another ball is connected to the rear of the ball P3 and another ball enters the winning opening 64 (when four balls are continuously entered), the fourth ball and the ball P3 are connected. The timing of entering the detection port 312d cannot be shifted. Therefore, it is desirable to recommend a stop hit so as not to play a game in which four balls are inserted into the winning opening 64 while the number of reserved balls in the winning opening 64 is three.

Further, as shown in the graph, when the balls P1 to P3 continuously enter the winning opening 64, for example, the ball P3 wins a prize at an interval of 1 second or more after entering the winning opening 64 of the ball P1. When entering the mouth 64, by the time the ball P3 reaches the sorting device 340, the sorting device 340 has been returned to the initial state, so that the ball P3 flows down the second groove 312 in the vertical direction and the detection port 312d. Enter the ball. In this case, the delay period of the ball P3 is not sufficient, and the overflow at the winning opening 64 cannot be suppressed.

Therefore, the effect of suppressing overflow when the third ball enters the winning opening 64 is limited to a limited situation (after the ball P1 and the ball P2 continuously enter the winning opening 64, the ball P1 enters the ball. Since it can be played only in the situation where the ball P3 enters the winning opening 64 within 1 second from the above, it happens to be stopped (holding the winning opening 64) while leaving the need for the player to make a stop. If you forget to stop launching the ball when the number of balls is 3, you can fortunately create a situation where the winning opening 64 does not overflow if the situation is met.

This makes it possible to form a clear difference in the number of lottery opportunities for the number of balls entered into the winning opening 64 between the player who makes a stop and the player who does not make a stop. In a rare situation where three balls enter the winning opening 64 in a row when the number of reserved balls in the opening 64 is 3, the third ball P3 does not overflow at the winning opening 64. It is possible to make the conditions strict (limit the ball entry interval) and produce the value when overflow does not occur.

As a result, it is possible to make the player who makes a stop hit more carefully (because it is possible to pay attention to the number of reserved balls and stop the launch at an early stage), so there is an opportunity for a lottery. It is possible to enthusiastically operate the handle 51 (see FIG. 1) in order to acquire more of the above, and it is possible to improve the interest of the player.

Next, a case where the balls P4 and P5 enter the delay device 300 at intervals will be described with reference to FIGS. 19 and 20. 19 (a), 19 (b) and 20 are partial front views of the delay device 300. FIG. 19 (a) shows a state in which the ball P4 reaches the wind turbine member 322 when the speed reducer 320 is in the initial state, and FIG. 19 (b) shows the speed reducer 320 in the intermediate state and the distribution device 340. The case where the ball P5 enters the winning opening 64 0.5 seconds after the ball P4 enters the detection port 312d (4 seconds after the ball P4 enters) is shown in the figure. In 20, the state immediately before the ball P5 is entered into the sorting device 340 is illustrated. In FIGS. 19 (a), 19 (b), and 20, in the lower right space of the structural drawing, a graph showing the situation after the balls P4 and P5 enter the winning opening 64 has a horizontal axis. It is shown as an elapsed time T.

In the graph, the timing when the spheres P4 and P5 enter the winning opening 64 (“IN”) and the timing when the spheres P4 and P5 enter the detection opening 312d (“OUT”) are shown, and when and which of the spheres P4 and P5 Whether it flows down the section is indicated by a symbol. Further, which timing of the graph the state shown in FIGS. 19A, 19B, and 20 represents is indicated by a triangular mark in the corresponding drawing.

In the state shown in FIG. 20, the ball P5 does not enter the third groove 313, flows vertically downward through the second groove 312, and enters the detection port 312d. Here, if the ball P5 enters the detection port 312d before the fluctuation immediately after the ball P4 enters the detection port 312d is completed, overflow may occur.

Therefore, in the present embodiment, the first groove passage second period T12 required for the ball P5 to pass through the speed reducer 320 in the intermediate state is the period of fluctuation when the number of reserved balls in the winning opening 64 is four (3). The mode is set to be longer than (seconds) (the first groove passage second period T12 is set to 3 seconds). In this case, even if the sphere P5 does not flow into the third groove 313 (flows down the second groove 312 in the vertical direction), the fluctuation ends before the sphere P5 passes over the slide moving member 321. It is possible to prevent the overflow from occurring at the winning opening 64. In this case, since the ball P5 does not flow down the third groove 313, the timing of the lottery by the ball P5 can be advanced, and the player can be prevented from getting bored.

Further, since the distribution maintenance period BT1 from the state change of the distribution device 340 to the start of returning to the initial state is set to 4 seconds, it is 3 seconds after the ball P4 enters the winning opening 64 (winning opening). It is possible to reliably enter the ball that has entered the third groove 313 (the period of fluctuation when the number of reserved balls of 64 is four). Further, since the ball can be entered into the third groove 313 until immediately before the sorting device 340 returns to the initial state, the ball P4 enters within less than 4 seconds after entering the winning opening 64. The ball can be reliably entered into the third groove 313. As a result, even when the balls P4 and P5 enter the winning opening 64 at intervals of 3 seconds or less, it is possible to prevent overflow from occurring at the winning opening 64.

Next, with reference to FIG. 21, a case where balls continuously enter the sorting device 340 will be described. In the present embodiment, for example, when the speed reducer 320 is in the ascending state (see FIG. 14), it is a state that occurs when two additional balls enter the winning opening 64 in succession (for example, FIG. 17 (see FIG. 14). This is a state that occurs when the balls P1 and P2 shown in a) are inserted, and after the balls P2 enter the second groove 312, two balls continuously enter the winning opening 64). 21 (a) to 21 (c) are partial front views of the delay device 300. FIG. 21 (a) shows a state in which the sorting device 340 is in the initial state and the ball P6 enters the sorting device 340. In FIG. 21 (b), the sorting device 340 is rotated by the weight of the ball P6 to rotate the ball. The state in which P7 is extruded is illustrated, and in FIG. 21 (c), the state in which the sphere P6 flows down the second groove 312 and the sphere P7 flows down the third groove 313 is shown.

As shown in FIG. 21A, the sorting device 340 is provided with a space capable of accommodating only one ball between the first wall portion 341 and the second wall portion 342. Therefore, when two balls reach the sorting device 340 in a row, the first ball P6 is housed in the sorting device 340, but the second ball P7 remains without being housed. Therefore, only the sphere P6 can flow down to the detection port 312d alone.

The tip convex portion 342a arranged at the tip of the second wall portion 342 of the sorting device 340 moves the sphere P7 to the entrance of the third groove 313 in a posture in which the sphere P7 remains outside (see FIG. 21B). It is formed in a manner of pushing out toward the tip (the entrance of the third groove 313 is formed at a position facing the tip convex portion 342a). Therefore, the ball P7 can be pushed out to the inner side of the third groove 313, and it is possible to prevent the ball P7 from staying near the entrance of the third groove 313. Thereby, for example, even if the sorting device 340 is set to return to the initial state immediately from the changed state, the ball P7 is prevented from entering the sorting device 340 (not properly pushed into the third groove 313). be able to.

As shown in FIG. 21 (c), the ball P6 enters the detection port 312d with the sorting device 340 as a boundary, and the ball P7 enters the detection port 312d after flowing down the third groove 313. Here, as described above, the third period T3, which is the period during which the balls P7 flow down the third groove 313, is set to 3 seconds, and that period is selected after the number of reserved balls in the winning opening 64 is maximized. Since the fluctuation period (3 seconds) of 1 or more is set, even if the ball P6 enters the detection port 312d when the number of reserved balls in the winning opening 64 is 3, the ball P7 enters the detection port 312d. By this time, one fluctuation will end. Therefore, when the ball P7 enters the detection port 312d, it is possible to prevent overflow from occurring at the winning port 64.

In the present embodiment, if another ball enters the detection port 312d within 3 seconds after the ball P7 enters the detection port 312d, the ball is configured to overflow at the winning port 64. To. As a result, it is possible to construct a flow path in which overflow can be suppressed when the number of balls entering in a short period of time is up to two, while overflow occurs when the number of balls entering in a short period of time is three. Therefore, it is possible to make the player carefully consider the firing intensity of the ball and the firing frequency of the ball in order to obtain more chances of lottery at the winning opening 64, and improve the playability regarding the mode of launching the ball. Can be made to.

Since the sorting device 340 rotates from the initial state to the changing state only by the weight of the sphere, the sphere P6 and the sphere P7 are arranged between the side wall portion 312e and the tip convex portion 342a. It is possible to solve the problem that occurs only when the sorting device 340 operates electrically, such as the sorting device 340 operating and causing ball clogging.

In the present embodiment, in the state of FIG. 21C, for example, the ball reaches the sorting device 340 at the timing when the sorting device 340 returns to the initial state within 1 second after reaching, and the next ball further reaches the sorting device 340. If the 340 reaches the sorting device 340 one second after returning to the initial state, there is a risk that the ball that arrived earlier and the ball that arrived later may collide at the confluence position of the first groove 311 and the third groove 313. Yes, in that case, two balls enter the detection port 312d at intervals of 3 seconds or less. Therefore, if the number of reserved balls in the winning opening 64 (see FIG. 20) is three while the preceding ball passes through the third groove 313, the overflow in the winning opening 64 cannot be avoided.

This is significantly different from the case where the two balls reach the sorting device 340 when the sorting device 340 is in the initial state. That is, when the two balls reach the distribution device 340 at 2-second intervals when the distribution device 340 is in the initial state, the latter balls are guided to the third groove 313 and therefore enter the detection port 312d. It is possible to secure an interval of 3 seconds or more (see FIG. 21). On the other hand, when the distribution device 340 is in a changing state and the spheres reach the distribution device 340 at 2-second intervals, the front sphere is guided to the third groove 313, and the rear sphere vertically downwards the second groove 312. There is a possibility that the ball may flow down, and the interval at which the ball enters the detection port 312d may be shorter than 3 seconds.

As a result, it is possible to form a flow path that cannot always suppress overflow when two balls enter the ball entry port 64 in succession. Therefore, while providing a mechanism that can suppress overflow, basically, it is assumed that the maximum number of lottery can be obtained by performing a game of stopping when the number of reserved balls in the winning opening 64 reaches three. The significance of hitting can be improved.

Next, the delayed floor device 400 will be described with reference to FIGS. 22 to 33. FIG. 22 is a partial front perspective view of the game board 13. As shown in FIG. 22, in the delay floor device 400, a part of the spheres flowing down to the left of the center frame 86 flows in (through a so-called “warp flow path”), and the sphere rolls on the upper part. A movable device that is configured to be possible and that repeatedly reciprocates to drop a sphere whose velocity in the left-right direction has converged to 0 toward the front side. And a link member 420 (see FIG. 24) that matches the movements of the pair of fan-shaped members 410, and a fixed floor that tiltably supports the fan-shaped member 410 and allows the ball to pass through before flowing into the fan-shaped member 410. It mainly comprises a fixed floor 430.

In the initial state (see FIG. 22), the delayed floor device 400 is configured in such a manner that the sphere can be easily converged at the center position in the left-right direction (the left-right peripheral portion of the fixed floor 430 is inclined downward toward the center position). The fan-shaped member 410 is arranged in a positional relationship in which the center position in the left-right direction and the center position of the winning opening 64 coincide with each other in the vertical direction. That is, the arrangement is such that the ball can be easily inserted from the delayed floor device 400 into the winning opening 64.

Among the fan-shaped members 410 arranged in pairs in the front-rear direction, the fan-shaped member 410 on the front side tilts forward in a manner of tilting forward toward the front side, so that the ball can easily enter the winning opening 64.

The fan-shaped member 410 will be described with reference to FIG. 23. Since the pair of fan-shaped members 410 are composed of the same members, one fan-shaped member 410 will be described, and the other fan-shaped member 410 will be omitted.

23 (a) is a top view of the fan-shaped member 410, FIG. 23 (b) is a side view of the fan-shaped member 410 in the direction of arrow XXIIIb of FIG. 23 (a), and FIG. 23 (c) is a side view of the fan-shaped member 410. FIG. 23 (a) is a cross-sectional view of the fan-shaped member 410 taken along the line XXIIIc-XXIIIc of FIG. 23 (a), and FIG. 23 (d) is a bottom view of the fan-shaped member 410 in the direction of arrow XXIIId of FIG. 23 (b).

As shown in FIG. 23, the fan-shaped member 410 includes a main body member 411 composed of a fan-shaped plate member and an extended arm portion 412 extending coaxially in the left-right direction from an intermediate position of the main body member 411. A convex fixing portion 413 having an insertion hole which is projected from the bottom surface of the main body member 411 in a pair and has an insertion hole through which the connecting rod 414 is inserted and fixed, and a connecting rod 414 which is inserted and fixed to the convex fixing portion 413. Mainly prepare.

The width of the main body member 411 is about the diameter of a sphere on the tapered side (lower side in FIG. 23A). Further, on the tapered side thereof, there is a chamfered portion 411a that is inclined downward, and an opening 411b that is formed between the convex fixing portions 413.

The connecting rod 414 is configured as a separate member from the main body member 411. When assembling, the link member 420 (see FIG. 24) is arranged between the convex fixing portions 413, and the connecting rod 414 is inserted into the adjusting elongated hole 422 of the link member 420, and the connecting rod is inserted. The 414 is fixed to the convex fixing portion 413. As a result, the fan-shaped member 410 and the link member 420 can be connected (see FIG. 25).

Next, the link member 420 will be described with reference to FIG. 24. The link member 420 is a member that connects a pair of fan-shaped members 410 and has a role of determining the operating direction thereof.

24 (a) is a side view of the link member 420, and FIG. 24 (b) is a bottom view of the link member 420 in the direction of arrow XXIVb of FIG. 24 (a). As shown in FIG. 24, the link member 420 has a main body member 421 formed of a plate-shaped member having an L-shaped cross section and a constant thickness (see FIG. 24 (b)), and a pair of front and rear members on the upper portion of the main body member 421. It mainly includes an adjustment elongated hole 422 drilled in the thickness direction and extended in the front-rear direction, and a support elongated hole 423 drilled in the thickness direction and extended in the vertical direction at the lower part of the main body member 421. ..

The adjustment elongated hole 422 is a hole through which the connecting rod 414 (see FIG. 23) of the fan-shaped member 410 is inserted. That is, the link member 420 and the pair of fan-shaped members 410 are connected via the adjustment elongated hole 422. The support elongated hole 423 is an elongated hole through which the support convex portion 434 (see FIG. 26) of the fixed floor 430 is inserted, and acts in a manner of designating the moving direction of the link member 420 in one direction (vertical direction).

The fan-shaped member 410 and the link member 420 in the pre-assembled state will be described with reference to FIG. 25. 25 (a) is a top view of the fan-shaped member 410 and the link member 420, and FIG. 25 (b) is a cross-sectional view of the fan-shaped member 410 and the link member 420 in the XXVb-XXVb line of FIG. 25 (a). .. The pre-assembled state shown in FIG. 25 refers to the sub-assembled state before assembling to the fixed floor 430. In the manufacturing process, the fan-shaped member 410 and the link member 420 are assembled to the fixed floor 430 after the pre-assembled state is configured.

In the pre-assembled state, the connecting rod 414 of the fan-shaped member 410 is fixed to the convex fixing portion 413 in a state of being inserted into the adjusting elongated hole 422 of the link member 420, whereby the fan-shaped member 410 and the link member 420 are connected to each other. Will be done.

As shown in FIG. 25, since the pair of fan-shaped members 410 are connected by the link member 420, when one fan-shaped member 410 operates, the operation is transmitted to the other fan-shaped member 410 via the link member 420. Consists of aspects.

Next, the fixed floor 430 will be described with reference to FIGS. 26 and 27. 26 is a top view of the fixed floor 430, FIG. 27 (a) is a cross-sectional view of the fixed floor 430 in line XXVIIa-XXVIIa of FIG. 26, and FIG. 27 (b) is XXVIIb-XXVIIb of FIG. It is sectional drawing of the fixed floor 430 in line. Note that FIGS. 26 and 27 show a state in which the fan-shaped member 410 and the link member 420 are removed. Further, in FIG. 26, the support portion 432 is partially cross-sectionally viewed.

As shown in FIGS. 26, 27 (a) and 27 (b), in the fixed floor 430, the fan-shaped member 410 is arranged in the assembled state (see FIG. 22), and the upper surface of the fan-shaped member 410 and the fixed floor 430 are formed. The portion between the rotating shafts of the fan-shaped member 410 is recessed corresponding to the thickness of the fan-shaped member 410 so as to be formed at the surface position, and the outer portion thereof is recessed in such a manner that it does not interfere with the movement of the fan-shaped member 410. The recessed floor 431 to be formed, the support portion 432 on which the extension arm portion 412 of the fan-shaped member 410 is supported when the recessed floor 431 is arranged, and the central portion of the recessed floor 431 are opened in the vertical direction. At the hollow portion 433, which is a cavity, the support convex portion 434 which is projected from the side wall forming the hollow portion 433 in the left-right direction, and the position where the fan-shaped member 410 is deviated from the closest position to the left and right in the assembled state. It mainly includes an inflow port 435 that is recessed with a size that allows the ball to flow in, and a delay flow path 436 that communicates from the inflow port 435 and allows the ball to flow down.

The support portion 432 includes a support groove portion 432a having a groove shape for supporting the extended arm portion 412 of the fan-shaped member 410, and a support lid portion 432b that covers the support groove portion 432a from above and covers the support groove portion 432a.

The hollow portion 433 is a cavity in which the link member 420 is housed, and the support convex portion 434 is a protrusion inserted into the support elongated hole 423 of the link member 420. When assembling the link member 420, the link member 420 is inserted into the gap between the hollow portion 433 and the tip of the support convex portion 434, and then the link member 420 is slid in the left-right direction to support the convex portion. The portion 434 can be inserted through the support elongated hole 423.

The inflow port 435 is composed of a diameter slightly larger than the diameter of the sphere. Therefore, when the member is covered above the inflow port 435 in a manner of blocking a part of the inflow port 435, it is impossible for the ball to flow into the inflow port 435.

The delay flow path 436 is a flow path for delaying the entry of the ball into the winning opening 64 with respect to the ball directly entering the winning opening 64 from the fan-shaped member 410. For example, by making the period required for the ball to pass through the delay flow path 436 longer than the fluctuation period of 1 that occurs when the ball enters the winning opening 64, an overflow occurs at the winning opening 64. It can be suppressed.

For example, by setting the period required for the balls to pass through the delay flow path 436 to be longer than the variable period that is easily selected when the number of reserved balls in the winning opening 64 is 4, the number of reserved balls in the winning opening 64 can be increased. Even if the first ball that has fallen from the fan-shaped member 410 directly enters the winning opening 64 and the second ball enters the inflow port 435 in the three states, the two balls Since the fluctuation of 1 is completed by the time the eye ball enters the winning opening 64, it is possible to suppress the overflow at the winning opening 64 due to the second ball entering the winning opening 64. it can.

A method of assembling the fan-shaped member 410 and the link member 420 (see FIG. 25) to the fixed floor 430 will be described. First, of the fan-shaped member 410 and the link member 420 in the pre-assembled state described above, the link member 420 is inserted into the cavity portion 433, and the support elongated hole 423 (see FIG. 25) is inserted into the support convex portion 434 by the above method. After fitting, the extended arm portion 412 (see FIG. 25) of the fan-shaped member 410 is placed on the support groove portion 432a, and the support lid portion 432b is covered and fitted over the support groove portion 432a, whereby the fan-shaped member 410 is fitted with the support portion of the fixed floor 430. The link member 420 is supported by the 432 so as to be tiltable, and the link member 420 is supported so as to be movable up and down (along the extending direction of the support elongated hole 423). As a result, the fan-shaped member 410 and the link member 420 are assembled to the fixed floor 430 to form the delayed floor device 400.

The state change of the delayed floor device 400 will be described with reference to FIG. 28. 28 (a) is a partial top view of the delayed floor device 400, FIG. 28 (b) is a cross-sectional view of the delayed floor device 400 in line XXVIIIb-XXVIIIb of FIG. 28 (a), and FIG. 28 (c). ) Is a partial top view of the delayed floor device 400, and FIG. 28 (d) is a cross-sectional view of the delayed floor device 400 on the line XXVIIId-XXVIIId of FIG. 28 (c).

In the initial state shown in FIGS. 28 (a) and 28 (b), the pair of fan-shaped members 410 are in a parallel posture, and in the tilted state shown in FIGS. 28 (c) and 28 (d), the fan-shaped members are in a parallel posture. It is assumed that 410 is tilted by about 45 ° from the initial state.

The major difference between the initial state and the tilted state is whether or not the ball can enter the inflow port 435 and whether or not the ball can pass through the intermediate position of the pair of fan-shaped members 410. Regarding the former, in the initial state, a part of the fan-shaped member 410 is covered on the upper part of the inflow port 435, so that the ball cannot enter the inflow port 435. Since the fan-shaped member 410 retreats from the upper part of the inflow port 435 (because it is tilted to the retreating position), the ball can enter the inflow port 435.

Regarding the latter, in the initial state, the fan-shaped member 410 is in a parallel posture so that the sphere can pass through the upper part between the fan-shaped members 410, but in the tilted state, the fan-shaped member 410 is at a position where the sphere passes. The ball that has flowed into the portion between the fan-shaped members 410 collides with the fan-shaped member 410 and is prevented from passing through. Since the inflow port 435 is arranged between the fan-shaped members 410 in the tilted state, the ball colliding with the fan-shaped member 410 does not bounce (such as when it vibrates in the vertical direction) and stays above the inflow port 435. In this case, it is possible to drop the ball directly into the inflow port 435.

With reference to FIG. 29, the operation mode of the delay floor device 400 due to the difference in position when the ball falls from the fixed floor 430 to the front side will be described. 29 (a) is a top view of the delayed floor device 400, and FIG. 29 (b) is a cross-sectional view of the delayed floor device 400 in line XXIXb-XXIXb of FIG. 29 (a), FIG. 29 (c). Is a top view of the delayed floor device 400, and FIG. 29 (d) is a cross-sectional view of the delayed floor device 400 on the XXIXd-XXIXd line of FIG. 29 (c).

As shown in FIGS. 29 (c) and 29 (d), the delay floor device 400 is used to move the ball when the ball P11 previously on the delay floor device 400 falls to the front side of the fixed floor 430. Along (using the weight of the sphere), the fan-shaped member 410 operates. Therefore, a drive source such as a motor for operating the delay floor device 400 can be eliminated.

29 (a) and 29 (b) show a state in which the sphere P11 is about to fall from a position away from the fan-shaped member 410, and in FIGS. 29 (c) and 29 (d), the sphere P11 is fan-shaped. A state in which the member 410 is about to fall from the center position to the front side of the fixed floor 430 is shown.

Here, it is possible to configure the delay floor device 400 to move each time the ball passes over the delay floor device 400, but in that case, the delay floor device 400 does not depend on how the ball passes. There is a risk that the entry into the winning opening 64 will be unnecessarily delayed due to the influence of. In that case, the start of the fluctuation triggered by the entry of the ball into the winning opening 64 is delayed, which causes dissatisfaction of the player.

On the other hand, in the present embodiment, as shown in FIG. 29, the ball P11 falls from the state where the ball P11 is on the fan-shaped member 410, which is a position where the ball P11 can easily enter the winning opening 64 as it is, to the front side of the fixed floor 430. When the delay floor device 400 is tilted in the leaning state, while the ball P11 falls from a position away from the fan-shaped member 410, which is a position unlikely to enter the winning opening 64 even if the ball P11 falls. The delayed floor device 400 is configured to maintain the initial state. Therefore, the delayed floor device 400 can be operated only when the falling ball P11 is likely to enter the winning opening 64.

As a result, the delayed floor device 400 operates even when it is not necessary, and it is possible to prevent the ball from entering the winning opening 64 from being unnecessarily delayed. It is possible to avoid delaying the start of the fluctuation, and it is possible to improve the interest of the player.

As shown in FIG. 29 (d), the chamfered portion 411a is formed at the tip of the fan-shaped member 410, so that the tip of the fan-shaped member 410 is inclined while protruding from the front surface of the game board 13 in the initial state. In the state, it can be configured to be pulled backward from the front surface of the game board 13. As a result, the ball can be rolled to a position where it can easily fall into the winning opening 64 (front side of the front surface of the game board 13) and then dropped. Therefore, the ball falling from the state shown in FIG. 29 (d) can be dropped. It is possible to improve the probability of entering the winning opening 64.

With reference to FIG. 30, the relationship between the ball P11 previously on the delayed floor device 400 and the ball P12 newly entered in the delayed floor device 400 will be described. 30 (a) is a top view of the delayed floor device 400, and FIG. 30 (b) is a cross-sectional view of the delayed floor device 400 in the line XXXb-XXXb of FIG. 30 (a).

30 (a) and 30 (b) show a state in which the sphere P11 flows down to the front side of the fan-shaped member 410, the fan-shaped member 410 is tilted, and then the sphere P12 is inserted from the left-right direction. To.

A predetermined ball reaches the center of the floor portion arranged above the winning opening 64, and another ball rolls on the floor portion from the left-right direction at the timing when it is about to fall to the winning opening 64 and collides with the predetermined ball. However, the predetermined ball may come off from the winning opening 64, which has been a source of deteriorating the player's interest.

On the other hand, in the present embodiment, as shown in FIG. 30, when the sphere P21 rolls at the timing when the sphere P11 falls from the front side of the fan-shaped member 410, the delay floor device 400 is tilted and the delay floor device 400 is tilted. By colliding the sphere P12 with the fan-shaped member 410, it is possible to prevent the sphere P11 from colliding with the sphere P12.

At this time, as shown in FIG. 30A, the gap formed by the tip portions of the pair of fan-shaped members 410 is tapered toward the traveling direction of the sphere P12 (to the right in FIG. 30A). Therefore, even if the sphere P12 rolls at a position slightly deviated from the intermediate portion of the pair of fan-shaped members 410 in the front-rear direction and collides with the fan-shaped member 410, the speed direction of the spheres P12 is paired along the tapered shape of the gap. It can be modified in the direction toward the intermediate position of the fan-shaped member 410. Therefore, the rolling path of the sphere P12 can be limited, and it is possible to easily avoid the collision between the sphere P12 and the sphere P11.

Next, with reference to FIG. 31, two balls P11 and P12 enter the delayed floor device 400 at intervals, and the delayed floor device 400 in a state where the reciprocating motion is repeated and the velocity in the left-right direction converges to 0. The action of is described.

31 (a) is a top view of the delayed floor device 400, and FIG. 31 (b) is a cross-sectional view of the delayed floor device 400 in the line XXXIb-XXXIb of FIG. 31 (a). Is a top view of the delayed floor device 400, and FIG. 31 (d) is a cross-sectional view of the delayed floor device 400 on the line XXXId-XXXId of FIG. 31 (c).

In FIGS. 31 (a) and 31 (b), the delayed floor device 400 is in the initial state, and the sphere P11 rides on the fan-shaped member 410 on the front side and the sphere P12 rides on the fan-shaped member 410 on the back side. Illustrated, in FIGS. 31 (c) and 31 (d), the sphere P11 flows down to the front side from the state shown in FIGS. 31 (a) and 31 (b), and the delayed floor device 400 is tilted. ..

As shown in FIGS. 31 (a) to 31 (d), in the sphere P12 on the fan-shaped member 410 on the back side, the sphere P11 flows down from the fan-shaped member 410 on the front side, and the delay floor device 400 is in an inclined state. As a result, the fan-shaped member 410 on the back side is pushed back in the back direction (to the right in FIG. 31B) along the inclination of the fan-shaped member 410.

After that, the ball P11 falls and the delay floor device 400 returns to the initial state, so that the ball P12 can pass over the delay floor device 400 again and roll above the fan-shaped member 410 on the front side. .. That is, from the state shown in FIG. 31 (a), as compared with the case where the sphere P11 and the sphere P12 continuously enter the winning opening 64, the sphere P11 is pushed back by the amount that the sphere P11 and the sphere P12 enter. The intervals can be separated. As a result, it is possible to prevent the ball P11 and the ball P12 from entering the winning opening 64 and causing an overflow at the winning opening 64.

Next, referring to FIG. 32, two spheres P11 and P12 enter the delay floor device 400, and the spheres P11 and P12 move in the front-rear direction in a state where the reciprocating motion is repeated and the velocity in the left-right direction converges to 0. The operation of the delayed floor device 400 when arranged in a row will be described.

32 (a) is a top view of the delayed floor device 400, and FIG. 32 (b) is a cross-sectional view of the delayed floor device 400 in the line XXXIIb-XXXIIb of FIG. 32 (a). Is a top view of the delayed floor device 400, and FIG. 32 (d) is a front view of the delayed floor device 400 in the direction of arrow XXXIId of FIG. 32 (c).

As shown in FIGS. 32 (a) and 32 (b), when the two spheres P11 and P12 are arranged in a row, the spheres P11 are on the front side (front side) of the extended arm portion 412 of the fan-shaped member 410 on the front side. In the state of being arranged on the left side of FIG. 32 (b), the sphere P12 is arranged near the intermediate position of the pair of front and rear fan-shaped members 410 (see FIG. 32 (b)).

From this state, when the sphere P11 falls from the front side of the delay floor device 400 and the delay floor device 400 is tilted, the sphere P12 is attached to the tip portion of the fan-shaped member 410 when the tip portion (arc portion) is raised. Can be lifted. In the present embodiment, since the tip portion of the fan-shaped member 410 has an arc shape, the tip portion of the fan-shaped member 410 supporting the sphere P12 tilts downward as it goes outward in the left-right direction in the tilted state (FIG. 32 (d)). reference). Therefore, the sphere P12 does not continue to be maintained at the center of the left and right sides of the fan-shaped member 410, but flows down to the left and right outside along the shape of the tip portion of the fan-shaped member 410. As a result, the sphere P12 flows from the fan-shaped member 410 into the inflow port 435. Therefore, it is possible to prevent the ball P12 from entering the winning opening 64 in succession with the ball P11.

33 (a) and 33 (b) are cross-sectional views of the delayed floor device 400 on line XXXIIIa-XXXIIIa of FIG. 32 (c). In FIG. 33 (a), the state in which the spheres P11 and P12 are flowing down from the state shown in FIG. 32 (c) is in the process of flowing down, and in FIG. 33 (b), the spheres P11 and P11 are further changed from the state shown in FIG. 33 (a). The state in which P12 flows down and the ball P11 enters the winning opening 64 is shown in the figure.

As shown in FIGS. 33 (a) and 33 (b), when the spheres P11 and P12 flow down in succession on the delayed floor device 400, the sphere P11 falls on the front side of the game board 13 and the sphere P12 is delayed. It flows down the flow path 436. That is, since the flow paths of the two balls P11 and P12 are separated and the delayed floor device 400 is composed of a long flow path, the timing at which the two balls P11 and P12 win the winning opening 64 is shifted. Can be done.

Therefore, for example, even if the information is acquired immediately after entering the winning opening 64 and the fluctuation is started by the third symbol display device 81 (see FIG. 2), the winning opening 64 may overflow. Can be suppressed.

That is, the number of reserved balls in the winning opening 64 is 4 during the period from the position of the sphere P12 shown in FIG. 33 (b) until the sphere P12 flows down to the winning opening 64 by flowing down the remaining portion of the delay flow path 436. By setting a period longer than the fluctuation period (shortest fluctuation period) that is likely to be selected in the case of individual pieces, it is possible to suppress the occurrence of overflow at the winning opening 64.

Next, the second embodiment will be described with reference to FIG. 34. In the first embodiment, the case where the sorting device 340 changes the posture only by moving the center of gravity has been described, but in the delay device 2300 in the second embodiment, the locking device 2315 arranged in the main body member 2310 has a long hole. It is supported by 2316 and is configured to maintain the posture of the sorting device 2340. The same parts as those of the above-described embodiments are designated by the same reference numerals, and the description thereof will be omitted.

34 (a) to 34 (c) are partial front views of the delay device 2300 according to the second embodiment. Note that FIG. 34 (a) shows a state in which the spheres P21 and P22 reach the sorting device 2340 in the initial state in a row, and FIG. 34 (b) shows a state in which the sorting device 2340 changes depending on the weight of the spheres P21. The state in which the sphere P22 flows down the third groove 313 is shown as the state changes to, and in FIG. 34 (c), the sphere P22 is released from the locking device 2315, and the sorting device 2340 returns to the initial state. The state in which the movement is started is shown in the figure. In the present embodiment, the second adjusting device 350 is not arranged in the sorting device 2340, and the sorting device 2340 is urged toward the initial state by a spring mechanism (not shown).

In the sorting device 2340, the first wall portion 2341 is composed of about half the length of the second wall portion 342. As a result, it is possible to prevent the ball P22 flowing down from the third groove 313 from colliding with the first wall portion 2341, and to prevent the ball P22 from interfering with the return operation of the sorting device 2340.

As shown in FIG. 34 (a), the locking device 2315 has a length extending in the left-right direction on the wall portion on the back side (back side in the vertical direction of the paper surface of FIG. 34) of the main body member 2310 at the lower end portion of the side wall portion 312e. A hook member 2315a that is slidably and rotatably supported by a long hole 2316, which is a hole, and a torsion spring 2315b that generates an elastic force that urges the hook member 2315a to the right and clockwise in the front view. , Equipped with. In the present embodiment, a space is formed in the lower end portion of the side wall portion 312e so that the hook member 2315a can pass through the space.

The hook member 2315a includes a shaft portion 2315a1 supported by an elongated hole 2316 extending in the left-right direction in a wall portion formed between a pair of upper and lower third grooves 313, and a shaft portion 2315a1 thereof. The contact portion 2315a2 is integrally formed with the shaft portion 2315a1 and is formed so as to penetrate the side wall portion 312e and project to the upper right side (upper right side of FIG. 34) of the shaft portion 2315a1. It mainly includes a release portion 2315a3 formed by projecting inward of the third groove 313 on the side.

The contact portion 2315a2 is arranged at a position where it interferes with the movement locus of the tip convex portion 342a of the sorting device 2340. The shape of the abutting portion 2315a2 is such that the upper surface portion suddenly descends and inclines toward the right, and the lower surface portion has a shape along the left-right direction (a shape that makes surface contact with the tip convex portion 342a). When the state changes from the initial state to the changing state, the resistance applied to the sorting device 2340 can be suppressed and the moving speed thereof can be improved, while when the sorting device 2340 changes from the changed state to the initial state, the state changes. , The resistance applied to the sorting device 2340 can be increased to facilitate locking of the sorting device 2340 in a changed state.

Further, since the shaft portion 2315a1 is configured to be slidable in the left-right direction along the elongated hole 2316, the hook member 2315a can be moved in a state immediately before the sorting device 2340 changes (immediately before FIG. 34B). You can escape to the left. As a result, as compared with the case where the hook member 2315a is pivotally supported, it is possible to prevent the sorting device 2340 from colliding with the locking device 2315 and engaging with the locking device 2315, resulting in malfunction.

In the torsion spring 2315b, the torsion portion is wound around the shaft portion 2315a1, one end portion (the left end portion in FIG. 34 (a)) is locked to the main body member 2310, and the other end portion (FIG. 34 (a)). ) The right end) is configured to be locked to the hook member 2315a.

As shown in FIG. 34 (b), when the distribution device 2340 is changed by the weight of the sphere P21, the tip convex portion 342a is locked to the contact portion 2315a2. As a result, the sorting device 2340 is maintained in a changed state. In the present embodiment, as long as the locking device 2315 does not change its posture, the sorting device 2340 maintains the changed state.

As shown in FIG. 34 (c), when the sphere P22 flowing down the third groove 313 comes into contact with the release portion 2315a and the hook member 2315a changes its posture counterclockwise when viewed from the front, the distribution device 2340 by the hook member 2315a (The contact portion 2315a2 is arranged outside the movement locus of the sorting device 2340), and the sorting device 2340 can be returned to the initial state.

According to this, in a state where the urging force in the front-view clockwise direction is always applied to the distribution device 2340, a time delay is formed from the state change of the distribution device 2340 to the change state to the start of movement toward the initial state. can do. Therefore, with a simple configuration, the spheres P21 and P22 can be reliably distributed to separate flow paths.

Although the case where the spheres P21 and P22 flow down in succession is described in FIG. 34, the effect of the present embodiment is that the spheres P21 and P22 are effective in light of the fact that the locking device 2315a is released by the flow of the spheres P22. It is exhibited regardless of the arrival interval of the sorting device 2340.

Next, a third embodiment will be described with reference to FIGS. 35 and 36. In the first embodiment, the case where the state of the delay device 300 is changed by the action of a sphere flowing down the upstream side of the detection port 312d has been described, but the delay device 3300 in the third embodiment has a downstream side of the detection port 312d. It is composed of a mode in which the state changes due to the action of a flowing sphere. The same parts as those of the above-described embodiments are designated by the same reference numerals, and the description thereof will be omitted. Further, in the present embodiment, the detection port 312d is arranged so as to have an opening facing in the left-right direction.

35 (a), 35 (b), 35 (c), 36 (a), 36 (b) and 36 (c) show the time in which the spheres P31 and P32 flow through the delay device 3300. It is a partial front view of the delay device 3300 in the third embodiment illustrated in series.

In addition, in FIG. 35A, a state in which the stop device 3340 is set to the initial state and the balls P31 and P32 continuously enter the winning opening 64 and reach the stop device 3340 is shown in FIG. 35B. In FIG. 35 (a), a state in which the stop device 3340 is rotated by a predetermined amount from the state of FIG. 35 (a) is shown, and in FIG. 35 (c), a state in which the stop device 3340 is in a changed state is shown.

Further, FIG. 36 (a) shows a state in which the preceding sphere P31 passes through the detection port 312d in the left-right direction and abuts on the maintenance device 3360 to change the posture of the maintenance device 3360, and FIG. 36 (b) shows a state in which the posture of the maintenance device 3360 is changed. , The state in which the stop device 3340 is changed in posture from the changed state to the initial state and a gap is provided between the stop device 3340 and the second groove 3312 so that one sphere can pass through is illustrated. In FIG. 36 (c), the rear sphere is shown. The state in which P32 flows down toward the detection port 312d is illustrated.

As shown in FIG. 35 (a), the delay device 3300 includes a main body member 3310 having a flow path for guiding a ball that has entered the winning opening 64 to the detection port 312d, and a ball that flows down inside the main body member 3310. When the stop device 3340 whose state changes due to the action and the stop device 3340 are in the changed state (see FIG. 35 (c)), the state is maintained and the posture changes due to the action of the ball passing through the detection port 312d. Along with this, a maintenance device 3360 for releasing the maintenance of the state of the stop device 3340 is mainly provided.

As shown in FIG. 35 (a), the main body member 3310 constitutes a flow path that inclines downward, and guides a ball that has entered from the winning opening 64 to a vertically upward position of the detection opening 312d, and a first groove 3311 thereof. It mainly includes a second groove 3312 extending vertically from the lower end portion of the first groove 3311 to the detection port 312d, and a post-detection flow path 3313 in which a ball passing through the detection port 312d is guided. The first groove 3311 and the second groove 3312 have a groove shape having an open portion on the game board 13 side, and in the assembled state, the open portion is closed by the game board 13 to provide a passage through which the ball flows down. It is formed.

The second groove 3312 has an accommodating recess 3312f in which the side wall portion 312e extends to the detection port 312d and is formed as a recess having a size capable of accommodating half of the balls between the contact wall 312a and the side wall portion 312e. Be prepared.

Further, a receiving wall portion 3312c is provided on the opposite side of the side wall portion 312e, and a housing recess 3312c1 is recessed in the receiving wall portion 3312c toward the rear. The accommodating recess 3312c1 is arranged in a positional relationship in which the magnet portion 3346 can be accommodated when the stopping device 3340 is in a changed state (see FIG. 35A).

The accommodating recess 3312f extends along a straight line on which the lower wall surface for receiving the ball passes through the central hole 345 of the stopping device 3340. As a result, the direction in which the ball P32 waiting in the accommodating recess 3312f starts to flow down due to gravity can be set to the direction toward the stop device 3340. Therefore, when the sphere P32 is in a state where it can flow down, the sphere P32 can be smoothly flowed down.

The post-detection flow path 3313 is a flow path through which the ball passing through the detection port 312d flows down, is arranged directly under the contact portion 3363 of the maintenance device 3360, and is a bearing portion 3313a that pivotally supports the shaft portion 3361a of the maintenance device 3360. The opening 3133b, which is an opening that allows the contact portion 3363 to enter and exit, and the main body rod are projected from the upper wall of the flow path 3313 after detection toward the lower side surface of the main body rod 3361 of the maintenance device 3360. It includes a locking portion 3313c that locks the movement of the 3361, and a delay flow path 3313d that extends from the detection port 312d to the opening 3313b.

The stop device 3340 does not include the second adjusting device 350 configured to be movable at the position of the center of gravity described in the first embodiment, and the center of gravity G3 is a line extending the second wall portion 342 and the stop device 3340. It is fixedly placed at the intersection with the circumference of. In the second wall portion 342, the formation of the tip convex portion 342a is omitted.

Further, the stop device 3340 includes a magnet portion 3346 that extends from the first wall portion 341 of the stop device 3340 toward the opposite side of the second wall portion 342 and is made of a magnetic material.

The maintenance device 3360 is a pendulum-shaped device rotatably supported by the bearing portion 3313a, and is a rod-shaped member having a shaft portion 3361a pivotally supported by the bearing portion 3313a at an intermediate position, and a main body rod 3361 thereof. The posture of the main body rod 3361, which is arranged at the end of the main body rod 3361 on the side close to the receiving wall portion 312c and is arranged at the end of the magnet portion 3362 made of a magnetic material and the magnet portion 3362 on the opposite side. It mainly includes a contact portion 3363 that is arranged at a position where it can enter the inside of the flow path 3313 after detection due to a change and is arranged so that it can come into contact with a ball that flows down.

In the present embodiment, as shown in FIG. 35A, the posture in which the main body rod 3361 is supported by the locking portion 3313c is the initial state of the maintenance device 3360. That is, in the initial state, the magnet portion 3362 is arranged so as to face the accommodating recess 3312c1, the contact portion 3363 projects inward of the flow path 3313 after detection, and the weight of the contact portion 3363 causes the maintenance device 3360 to extend. Posture is maintained.

The end face of the magnet portion 3362 is a straight line drawn vertically from the end face, and the upper portion of the straight line is omitted with the straight line passing through the shaft portion 3361a as a boundary.

That is, the end face portion that is drawn vertically from the end face and through which the straight line passing through the shaft portion 3361a passes is closest to the receiving wall portion 3312c in the initial state, and the upper portion (main body rod 3361 is viewed from the front). Since the portion that moves closer to the receiving wall portion 3312c by rotating counterclockwise) is omitted, the same portion is closest to the receiving wall portion 3312c even after the maintenance device 3360 changes its posture from the initial state. (All portions of the end face of the magnet portion 3362 are configured to be away from the receiving wall portion 3312c).

Therefore, as shown in FIG. 35 (c), the maintenance device 3360 is changed in posture by the action of a sphere from the state where the magnet portion 3346 of the stop device 3340 is close to the magnet portion 3362 of the maintenance device 3360 and a magnetic force in the attraction direction is generated. As a result, the end face of the magnet portion 3362 can be separated from the magnet portion 3346 of the stop device 3340.

Further, since the magnet portion 3362 is not moved in the direction perpendicular to the suction surface, but is separated while tilting the posture with respect to the suction surface, the magnet portions 3346 and 3362 can be attracted by a weak force. It can be released.

The change in the state of the delay device 3300 when the spheres P31 and P32 pass through the main body member 3310 will be described in chronological order.

As shown in FIG. 35A, when the balls P31 and P32 enter the winning opening 64, the balls P31 and P32 reach the stop device 3340 through the first groove 3311 and the second groove 3312. In the present embodiment, the space between the first wall portion 341 and the second wall portion 342 of the stop device 3340 is set to a size capable of accommodating one sphere, so that only the former sphere P31 is accommodated and the latter sphere P31 is accommodated. The sphere P32 is maintained outside the stop device 3340.

As shown in FIG. 35 (b), the stop device 3340 is rotated from the initial state by the weight of the front sphere P31, and the rear sphere P32 is pushed by the outer end portion of the second wall portion 342 into the accommodating recess 3312f. The left part is housed. Since the position accommodated in the accommodating recess 3312f is the lowermost position on the upstream side of the stop device 3340 of the second groove 3312, the sphere P32 is maintained at the position shown in FIG. 35 (b) by the action of gravity. To.

As shown in FIG. 35 (c), in a state where the sphere P31 flows down to the detection port 312d, the first wall portion 341 of the stop device 3340 and the receiving wall portion 3312c come into contact with each other, and the magnet portion 3346 is accommodated in the accommodating recess 3312c1. Will be done. In this state, the magnet portion 3346 is close to the magnet portion 3362 of the maintenance device 3360 and a magnetic force in the suction direction is generated, so that the state of the stop device 3340 is maintained in the changed state. Therefore, even if the ball P31 flows down to the outside of the stop device 3340, the ball P32 remains stopped.

As shown in FIG. 36 (a), after the previous sphere P31 has passed through the delay flow path 3313d, it comes into contact with the contact portion 3363, whereby the main body rod 3361 of the maintenance device 3360 rotates, and the magnet portion 3362 becomes It is separated from the magnet portion 3346.

As a result, the magnetic force acting on the stop device 3340 is sharply reduced, and the force for stopping the rotation of the stop device 3340 is released. Therefore, the center of gravity G3 of the stop device 3340 is moved downward by the action of gravity. , The stop device 3340 starts rotating counterclockwise when viewed from the front.

In the present embodiment, the distance between the shaft portion 3361a and the contact portion 3363 is several times (about 5 times) longer than the distance between the shaft portion 3361a and the magnet portion 3362. The maintenance device 3360 can be rotated with a small load of the weight of the sphere P31.

Further, since the moving width on the magnet portion 3362 side is smaller than the moving width on the contact portion 3363 side with respect to the shaft portion 3361a, the magnet portion 3362 is positioned by the vibration transmitted to the game board 13. It is possible to prevent the posture of the stop device 3340 from changing due to insufficient magnetic force applied to the stop device 3340 due to the deviation.

As shown in FIG. 36B, when the sphere P31 passes through and the sphere P31 and the abutting portion 3363 are separated from each other, the maintenance device 3360 returns to the initial state due to the weight of the abutting portion 3363.

As shown in FIG. 36B, the stop device 3340 rotates in such a manner that the opening area of the portion facing the sphere P32 housed in the housing recess 3312f gradually increases in the operation of returning from the changed state to the initial state. To do. That is, the sphere P32 can be accommodated in the stop device 3340 before the stop device 3340 returns to the initial state. Thereby, for example, when two balls are deposited on the upstream side of the stop device 3340, it is possible to prevent both of the two balls from flowing into the stop device 3340. Therefore, it is possible to prevent the stop device 3340 from being clogged and causing an operation failure or a slowdown in the operation speed.

As shown in FIG. 36 (c), the ball P32 housed in the storage recess 3312f is housed in the stop device 3340, the stop device 3340 is rotated by the weight of the ball P32, and the ball P32 flows down to the detection port 312d. Will be done.

In this way, even when a plurality of balls P31 and P32 enter the winning opening 64 in a row, until the previous ball P31 changes the posture of the maintenance device 3360 and passes through the position where the state maintenance of the stop device 3340 is released. , The flow of the later sphere P32 can be stopped. In the present embodiment, since the sphere P31 is designed to pass through the delay flow path 3313d for 3 seconds, the sphere P32 for at least 3 seconds after the sphere P31 passes through the detection port 312d and the fluctuation starts. However, it can be prevented from passing through the detection port 312d.

Therefore, when the shortest period of fluctuation that can be obtained by entering the winning opening 64 (the fluctuation period that is easily selected when the number of reserved balls is four) is 3 seconds, it is shown in FIG. 35 (a). Even if the balls P31 and P32 enter the winning opening 64 in succession (the balls enter at intervals shorter than 3 seconds), after the fluctuation started by the ball P31 passing through the detection opening 312d is completed. , The state in which the sphere P32 passes through the detection port 312d can be configured. As a result, it is possible to prevent overflow from occurring when balls enter the winning opening 64 in a row.

Further, since the period from when the ball P31 passes through the detection port 312d to when the maintenance device 3360 changes its posture can be secured, overflow occurs as compared with the case where the posture maintenance of the stop device 3340 is released upstream of the detection port 312d. Can be reliably prevented from occurring.

For example, when the posture of the maintenance device 3360 is changed by using the ball before passing through the detection port 312d, the operation of the stop device 3340 is performed in order to secure the distance between the ball passing through the detection port 312d and the ball after that. It should be designed to be slow. That is, it is necessary to leave a space between the balls during the period from the change state to the return of the stop device 3340, and if the operation speed of the stop device 3340 changes due to aged deterioration or the like, there is a risk that overflow cannot be prevented.

On the other hand, according to the present embodiment, only the sphere operates in the delay device 3300 after the sphere passes through the detection port 312d until the sphere comes into contact with the maintenance device 3360. Therefore, the operation timing of the stop device 3340 can be managed in relation to the sphere and the fixed flow path.

In the present embodiment, since the period required for fluctuation (3 seconds) has elapsed before the ball reaches the maintenance device 3360, the overflow occurs regardless of the period until the stop device 3340 returns to the initial state. Can be prevented. That is, regardless of whether the stop device 3340 returns to the initial state in 10 seconds or returns to the initial state in 0.5 seconds, it is possible to prevent an overflow from occurring at the winning opening 64 regardless of that.

Further, as compared with the case where the stop device 3340 is electrically operated constantly, the period from when the ball P31 passes through the winning opening 64 to when it passes through the detection port 312d is secured to be shorter, and after the ball P31. Only the ball P32 that enters the ball can be stopped, and it is possible to prevent the period from the time when the previous ball P31 passes through the winning opening 64 to the start of the fluctuation is extended. This can prevent the player from feeling uncomfortable (for example, the feeling that the ball has entered the winning opening 64 but the fluctuation does not start, so that the player may be doing something wrong). it can.

Next, a fourth embodiment will be described with reference to FIGS. 37 and 38. In the first embodiment, the case where the ball is decelerated by the action of the convex portion 321a1 of the delay device 300 has been described, but the delay device 4300 in the fourth embodiment decelerates the ball by the sprocket 4340 that separates the balls at equal intervals. .. The same parts as those of the above-described embodiments are designated by the same reference numerals, and the description thereof will be omitted.

37 (a), 37 (b), 37 (c), 38 (a), 38 (b) and 38 (c) show how the spheres P41, P42 and the like flow through the delay device 4300. It is a front view of the delay device 4300 in the 4th Embodiment illustrated in chronological order. Note that FIG. 37 (a) shows a state in which the sprocket 4340 is in the initial state and the balls P41 and 42 continuously enter the winning opening 64 and reach the sprocket 4340. FIG. 37 (b) shows the state. A state in which the sprocket 4340 is rotated by a predetermined amount from the state of FIG. 37 (a) is shown, and a state in which the magnet member 4351 of the magnet device 4350 is arranged at the locking position is shown in FIG. 38 (c). In a), the state in which the sprocket 4340 is rotating due to the weight of the sphere P42 is shown, and in FIG. 38 (b), the state immediately before the sphere P42 enters the detection port 312d is shown. The state in which the sprocket 4340 rotates clockwise in the front view and the magnet member 4351 of the magnet device 4350 is moving toward the initial position is illustrated.

As shown in FIG. 37 (a), the delay device 4300 includes a main body member 4310 having a flow path for guiding a ball that has entered the winning opening 64 to the detection port 312d, and a ball that flows down inside the main body member 4310. It mainly includes a sprocket 4340 whose state changes by action, and a magnet device 4350 having a magnet member 4351 configured to be relatively movable along a rotation locus of the sprocket 4340.

As shown in FIG. 37 (a), the main body member 4310 includes a first groove 3311, a second groove 4312 extending vertically from the lower end portion of the first groove 3311 to the detection port 312d, and a second groove 4312 thereof. A cylindrical shaft rod 4313 extending in the front-rear direction in the right portion of the groove 4312 is mainly provided. The first groove 3311 and the second groove 4312 have a groove shape having an open portion on the game board 13 side, and in the assembled state, the open portion is closed by the game board 13 to provide a passage through which the ball flows down. It is formed.

The second groove 4312 has a configuration in which the receiving wall portion 3312c (see FIG. 35 (a)) is removed from the second groove 3312 in the third embodiment. Therefore, the contact wall 312a, the recessed portion 312b, the detection port 312d, the side wall portion 312e, and the accommodating recess 3312f are designated by the same reference numerals, and the description thereof will be omitted.

The sprocket 4340 is a gear-shaped member that rotates by the weight of a sphere flowing down the main body member 4310, and is a disk-shaped disk member 4341 whose center position is rotatably supported by a shaft rod 4313, and a circle thereof. It mainly includes a storage wall portion 4342 which is extended to the front side of the plate member 4341 and is formed so as to be able to store a sphere in a gap between the walls.

Since the disc member 4341 is arranged at a position that is in a surface position with the wall portion on the back side of the main body member 4310 (the wall portion on the back side in the vertical direction of the paper surface in FIG. 37 (a)), it flows down the inside of the disc member 4341. The sphere passes through the front side of the disk member 4341.

Further, the disk member 4341 divides the striped magnetic poles (the region between each plate-shaped portion 4342a to 4342e into three equal parts along the outer peripheral surface, the central portion thereof is the north pole, and the outer portion is the south pole. It is provided with a magnet portion 4341a having a striped magnetic pole). The rotation speed of the sprocket 4340 is adjusted by the interaction between the magnet portion 4341a and the magnet device 4350.

In order to make it easy to determine that the disk member 4341 and the magnet member 4351 have moved relative to each other, a triangular mark M is formed near the outer peripheral position of the disk member 4341.

The accommodating wall portion 4342 is a plate-shaped portion extending radially outward from the center of the disk member 4341 to prevent the passage of a sphere in the circumferential direction, and is at equal intervals (72 °). It is composed of five plate-shaped portions 4342a to 4342e arranged at intervals). Each gap between the plate-shaped portions 4342a to 4342e is configured to have a width capable of accommodating only one sphere. Further, the outer peripheral surfaces of the plate-shaped portions 4342a to 4342e (the radial outer peripheral surfaces of the sprocket 4340) are formed from an arc shape formed coaxially with the central axis of the disk member 4341.

As shown as an example in FIG. 37 (a), the first plate-shaped portion 4342a is arranged at a position on which the sphere P41 rides, and from there, the second plate-shaped portion 4342b and the third plate-shaped portion are arranged in the clockwise direction in the front view. 4342c, the fourth plate-shaped portion 4342d, and the fifth plate-shaped portion 4342e are arranged.

The magnet device 4350 is formed of a magnetic material and is formed in an arc shape having a diameter slightly longer than the diameter of the outer peripheral surface of the disk member 4341 of the sprocket 4340, and the shaft rod 4313 is formed via a rotating arm (not shown). A magnet member 4351 axially supported by the magnet member and an arc wall portion extending from the main body member 4310 at a position separated by a predetermined distance below the disk member 4341 as an arc-shaped wall surface along the shape of the lower surface of the magnet member 4351. It mainly includes a 4352 and a stopper portion 4353 that projects toward the magnet member 4351 at an end portion of the arc wall portion 4352 that is opposite to the side close to the main body member 4310.

The magnet member 4351 has striped magnetic poles (striped magnetic poles in which the arc region is divided into three equal parts, the central portion thereof is the south pole, and the outer portion is the north pole) on the inner peripheral side of the arc shape. The sprocket 4340 is arranged with a slight gap from the outer peripheral surface of the disk member 4341, and the position is corrected in relation to the magnetic poles of the disk member 4341.

That is, in the state shown in FIG. 37 (a) (the state before the weight of the sphere P41 is applied to the sprocket 4340), the central position of the region between each plate-shaped portion 4342a to 4342e and the central position of the arc of the magnet member 4351. Is maintained at a position that matches.

One end (the left end of FIG. 37 (a)) of the magnet member 4351 abuts on the outer surface of the main body member 4310 at the initial position shown in FIG. 37 (a), and the magnet member 4351 is engaged as shown in FIG. 37 (c). At the stop position (the position rotated counterclockwise by 72 ° from the initial position about the shaft rod 4313), the other end (the upper end in FIG. 37 (c)) comes into contact with the stopper 4353.

The arc wall portion 4352 is a wall portion arranged outside the magnet member 4351, and is arranged at a position where a gap is left between the arc wall portion 4352 and the magnet member 4351 when the magnet member 4351 is attracted to the disk member 4341. Will be done.

For example, even if for some reason the game board 13 vibrates and an impact is applied to the magnet member 4351 and the attraction between the disk member 4341 and the magnet member 4351 is temporarily released, the magnet member 4351 has an arc. Since it is supported by the wall portion 4352, it is possible to prevent the magnet member 4351 from being largely displaced.

The stopper portion 4353 is arranged at a position that blocks the movement of the magnet member 4351. In the present embodiment, the magnet member 4351 and the stopper portion 4353 come into contact with each other in a locked state in which the magnet member 4351 is rotated by a predetermined angle (72 ° in the present embodiment) from the initial position shown in FIG. 37 (a). It is configured in an embodiment (see FIG. 37 (c)), and in this locked state, the sphere P41 flows down to the detection port 312d.

The change in the state of the delay device 4300 when the spheres P41 and P42 pass through the main body member 4310 will be described in chronological order.

As shown in FIG. 37 (a), when the balls P41 and P42 enter the winning opening 64, the balls P41 and P42 reach the sprocket 4340 through the first groove 3311 and the second groove 4312. In the present embodiment, the space between the first plate-shaped portion 4342a and the second plate-shaped portion 4342b of the sprocket 4340 is set to a size capable of accommodating one sphere, so that only the front sphere P41 is accommodated and the rear sprocket 4340 is accommodated. Ball P42 is maintained on the outside of the sprocket 4340.

As shown in FIG. 37 (b), the sprocket 4340 is rotated from the initial state (see FIG. 37 (a)) by the weight of the front sphere P41, and the rear sphere P42 is pushed to the tip of the second plate-shaped portion 4342b. The left side portion is accommodated in the accommodating recess 3312f. Since the position accommodated in the accommodating recess 3312f is the lowermost position of the second groove 4312 on the upstream side of the sprocket 4340, the sphere P42 is maintained at the position shown in FIG. 37 (b) by the action of gravity. ..

In the state shown in FIG. 37 (b), the magnet member 4351 moves integrally with the disk member 4341 of the sprocket 4340. Therefore, the weight of the magnet member 4351 is loaded on the disk member 4341 as a rotation resistance.

As shown in FIG. 37 (c), in a state where the sprocket 4340 is rotated 72 ° counterclockwise from the initial state (a state in which the sphere P31 can flow down to the detection port 312d), the magnet member 4351 and the stopper portion 4353 (The magnet member 4351 is arranged at the locking position).

Therefore, when the sprocket 4340 further rotates counterclockwise when viewed from the front, the magnet member 4351 is maintained in the locked position, and only the sprocket 4340 rotates. In this case, a magnetic force acts between the sprocket 4340 and the magnet member 4351, and the magnetic force is applied to the resistance to rotation of the sprocket 4340.

As shown in FIG. 37 (c), the sprocket 4340 is rotated 72 ° from the initial state in a state where the sphere P41 flows down to the detection port 312d while rubbing against the side wall portion 312e and the first plate-shaped portion 4342a. It becomes. That is, the passage of the ball causes the sprocket 4340 to be adjusted to a predetermined posture. Since the shape of the sphere is precisely made, it is possible to reliably rotate the sprocket 4340 by 72 ° by utilizing the precision of the shape of the sphere.

At this time, as shown in FIG. 37 (c), the first plate-shaped portion 4342a inclines downward in the direction of pressing the sphere P41 against the side wall portion 312e, so that the velocity of the sphere P41 is directed toward the side wall portion 312e. It is possible to prevent the first plate-shaped portion 4342a from rotating too much due to the momentum of the ball P41.

In the state shown in FIG. 37 (c), the ball P42 enters the sprocket 4340, and after the ball P41 is thrown toward the detection port 312d, the sprocket 4340 is rotated by the weight of the ball P42.

As shown in FIG. 38 (a), when the sprocket 4340 is rotated by the weight of the sphere P42, the disk member 4341 and the magnet member 4351 of the sprocket 4340 move relative to each other as shown by the position of the mark M. Therefore, the magnetic force generated between the sprocket 4340 and the magnet member 4351 is applied to the sprocket 4340 as a rotation resistance.

Further, in FIG. 38 (a), following the ball P42, the ball P43 and the ball P44 enter the winning opening 64 and stay on the upstream side of the sprocket 4340.

In the present embodiment, the rotational resistance applied to the sprocket 4340 by the magnetic force applied between the magnet member 4351 and the sprocket 4340 is much larger than the rotational resistance applied to the sprocket 4340 by the weight of the magnet member 4351. It is configured in a mode (the magnet member 4351 is configured in a mode in which the weight is reduced while the generated magnetic force is increased).

As a result, for example, the period from the state shown in FIG. 37 (a) to the state shown in FIG. 37 (c) is set to 0.5 seconds, while the period shown in FIG. 37 (c) is set to FIG. 38 (a). ) Can be set to 5 seconds (the period required to rotate the sprocket 4340 by a predetermined angle can be changed).

In the present embodiment, the period from the state shown in FIG. 37 (c) to the state shown in FIG. 38 (a) is set to 5 seconds, so that, for example, the ball P41 passes through the detection port 312d. As a result, the number of reserved balls in the winning opening 64 becomes 4, and if the fluctuation selected at that time is a fluctuation of 3 seconds, the ball P42 passes through the detection port 312d after the fluctuation is completed. Therefore, it is possible to prevent the ball P42 from overflowing at the winning opening 64 when passing through the detection opening 312d.

As shown in FIG. 38A, when a plurality of balls P43 and balls P44 stay on the upstream side of the sprocket 4340, the load applied from the balls P43 and the balls P44 to the sprocket 4340 is the outer circumference of the accommodating wall portion 4342. Due to the effect of the shape of the surface (arc), the load is applied in the direction (diameter direction) toward the shaft rod 4313.

Therefore, the load applied from the spheres P43 and the spheres P44 in the rotational direction of the sprocket 4340 can be limited to the load generated by the rubbing between the spheres P43 and the sprocket 4340, and is compared with the weights of the spheres P43 and P44 that stay. Therefore, the rotational resistance applied to the sprocket 4340 can be reduced.

38 (b) shows a state in which the ball P42 is sent to the detection port 312d and the ball P43 enters the sprocket 4340 (from the initial state shown in FIG. 37 (a), the sprocket 4340 is 144 counterclockwise when viewed from the front. ° Rotated state) is shown.

When the sprocket 4340 rotates from the state shown in FIG. 38 (b), the relative movement between the sprocket 4340 and the magnet member 4351 is accompanied by the relative movement of the sprocket 4340 and the magnet member 4351 as in the case where the sprocket 4340 is rotated by the weight of the ball P42. This also applies when the sphere P44 after the sphere P43 is housed in the sprocket 4340 and the sprocket 4340 rotates.

That is, according to the present embodiment, even if the number of balls entering the winning opening 64 in succession is 4 or more (regardless of the number of balls), the interval at which each ball is sent to the detection opening 312d is constant. The interval is maintained, and the period until the ball P41, which is entered into the winning opening 64 as the first ball, passes through the detection opening 312d is compared with the throwing interval between the balls opened by the sprocket 4340. Can be shortened.

Therefore, it is possible to suppress the player from feeling uncomfortable (for example, the feeling that the ball has entered the winning opening 64 but the fluctuation does not start, so that the player thinks that he / she is doing something wrong). ..

As shown in FIG. 38 (c), after the ball P44 (see FIG. 38 (b)) is thrown toward the detection port 312d, the next ball (the ball entered into the winning opening 64) becomes the sprocket 4340. When not riding, the sprocket 4340 rotates clockwise in the front view due to the weight of the magnet member 4351.

In the present embodiment, since the magnet member 4351 is composed of a light member, the rotation speed of the sprocket 4340 is reduced, and the period until the magnet member 4351 returns from the locked position to the initial position is set to 5 seconds.

Therefore, the sprocket 4340 is further rotated from the timing when the sphere P41 shown in FIG. 37 (a) passes through the detection port 312d and the state shown in FIG. 38 (c), and immediately after the magnet member 4351 is arranged in the initial position, the sprocket 4340 is used. There is a gap of 5 seconds or more between the timing at which the ball to be entered passes through the detection port 312d. The 5 seconds is a period longer than the shortest fluctuation period (3 seconds) that is likely to be selected when the number of reserved balls in the winning opening 64 is 4.

Therefore, when the ball passes through the sprocket 4340 immediately after the sprocket 4340 returns to the initial state, it is possible to easily prevent an overflow from occurring at the winning opening 64.

In the state shown in FIG. 38 (c), the relative positions of the sprocket 4340 and the magnet member 4351 do not change in appearance from the state shown in FIG. 37 (a), but as shown in the mark M, in reality, FIG. 37 Compared to the state shown in (a), the magnet member 4351 is arranged at a position relative to the shaft rod 4313 by 72 °.

In the present embodiment, in a state where the magnet member 4351 is arranged at the locking position, the sprocket 4340 is placed between the plate-shaped portions of the accommodating wall portion 4342 with respect to the magnet member 4351 each time the ball passes through the second groove 4312. It is configured so that the position is displaced by an angle of one gap (that is, 72 °).

Therefore, the relative movement of the sprocket 4340 and the magnet member 4351 is limited to a relative movement such that, for example, the first plate-shaped portion 4342a moves to the position of the second plate state 4342b, and after the relative movement, the sprocket 4340 and the sprocket 4340 The overall shape of the magnet member 4351 and the magnet member 4351 does not change from that before the relative movement.

Therefore, regardless of the number of balls passing through the second groove 4312, the overall shape of the sprocket 4340 and the magnet member 4351 after the balls are discharged from the sprocket 4340 can be made unchanged, and thus the winning opening 64 It is possible to eliminate the need to dispose a device for moving the magnet member 4351 at the position of the mark M of the sprocket 4340 when the inflow of the sphere to the sprocket 4340 disappears for a certain period of time (Fig. 38 (c)). As described above, even if the relative positional relationship between the mark M and the magnet member 4351 has changed from the state shown in FIG. 37 (a), it can be left as it is).

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 convex portion 321a1 is convexly provided on the slide moving member 321 and the projecting portion 321a1 projects inward of the first groove 311 has been described, but the present invention is not necessarily limited to this. For example, a pair of wall portions forming an S-shaped path are arranged on the slide moving member 321 and the slide moving member 321 moves to complete an S-shaped path in which a sphere flows down inside the first groove 311. It may be composed of. In this case, since the path itself through which the sphere flows can be lengthened by the pair of wall portions, the deceleration effect can be maintained for a long period of time as compared with the case where the convex portion 321a1 reduces the deceleration effect due to wear. .. Further, the slide moving member 321 may be configured in such a manner that the region where the convex portion 321a1 is formed and the region where the S-shaped path is formed are continuously provided.

In the first embodiment, the case where the convex portion 321a1 of the speed reducing device 320 projects upward has been described, but the present invention is not necessarily limited to this. For example, the convex portion 321a1 may project downward into the first groove 311 or the convex portion 311a1 may project downward into the first groove 311. In this case, it is possible to prevent the slide moving member 321 from moving to the outside of the first groove 311 due to the weight of the sphere.

In the first embodiment, the case where the balls P1 and P2 can be distributed even when the balls P1 and P2 enter the distribution device 340 in the initial state in succession has been described, but the present invention is not necessarily limited to this. It's not a thing. For example, before the spheres reach the allocating device 340, after arranging an interval load means for surely spacing the connected spheres, the spheres enter the allocating device 340 and a while later, the state of the allocating device 340. May be configured in such a manner that In this case, since it is not necessary to strictly control the timing of the state change of the distribution device 340, the distribution device 340 can be loosely supported and the load required for the state change can be reduced.

In the first embodiment, the case where the portion of the sorting device 340 where the spheres collide is formed of an arc shape (arc wall portion 343) is described, but the present invention is not necessarily limited to this. For example, it may be composed of a flat plate-like portion of a portion corresponding to the arc wall portion 343. In this case, if a ball enters the sorting device 340 while the sorting device 340 is returning to the initial state, the sorting device 340 is rotated by the load given from the ball and returned to the changed state. As a result, the period during which the sorting device 340 is maintained in the changed state can be extended.

In the first embodiment, the case where the sorting device 340 is operated to return by changing the center of gravity has been described, but the present invention is not necessarily limited to this. For example, the sorting device 340 is returned by using a product whose urging force changes depending on the moving direction (moving resistance is applied only in one direction) or a cylinder product that changes the moving resistance in each direction using an orifice. It may be operated. In this case, maintainability can be improved by using a commercially available product. Further, by configuring the rotation resistance of the rotation shaft of the distribution device 340 to be small in the forward rotation and large in the reverse rotation, a constant urging force is applied to the distribution device 340, so that the return operation of the distribution device 340 takes time. Delays can occur.

In the first embodiment, the case where the sphere flowing from the fan-shaped member 410 to the inflow port 435 is guided through the delay flow path 436 has been described, but the present invention is not necessarily limited to this. For example, by forming another floor surface below the inflow port 435 (by forming a floor on which the sphere can roll in two stages), the sphere that has flowed into the inflow port 435 from the fan-shaped member 410 is again in the floor. The surface may be rolled to enter the winning opening 64. In this case, since the period during which the ball rolls on the floor surface can be extended, the player can pay attention to the movement of the ball and extend the period during which the launch of the ball is stopped. Therefore, the fluctuation of the winning amount held during that period can be digested, and the occurrence of overflow can be suppressed.

In the first embodiment, the case where the fan-shaped member 410 is tilted with the rotation axis aligned in the left-right direction has been described, but the present invention is not necessarily limited to this. For example, the rotation axis may be tilted along the front-rear direction. In this case, the ball can be dropped toward the winning opening 64 along the inclination of the arc portion of the fan-shaped member 410 (the position in the left-right direction can be corrected).

In the first embodiment, the case where the fan-shaped member 410 operates under the weight of a sphere has been described, but the present invention is not necessarily limited to this. For example, the fan-shaped member 410 may be electrically operated in a constant repetitive operation mode. In this case, a plurality of types of combinations of operations of the pair of fan-shaped members 410 can be configured. For example, the front side fan-shaped member 410 is in a raised position and the back side fan-shaped member 410 is in a lying position, and the front side fan-shaped member 410 is in a raised position and the back side fan-shaped member 410. The member 410 is in a raised position, the fan-shaped member 410 on the front side is in a lying position, and the fan-shaped member 410 on the back side is in a lying position, and the fan-shaped member 410 on the front side is lying down. It is possible to configure a posture in which the fan-shaped member 410 on the back side is in a raised posture and a posture in which the fan-shaped member 410 on the back side is raised, and it is possible to increase the combination of the states of the pair of fan-shaped members 410.

In the first embodiment, the case where the pair of fan-shaped members 410 are formed of the same shape has been described, but the present invention is not necessarily limited to this. For example, the fan-shaped member on the back side may be configured to have a longer width in the left-right direction as compared with the fan-shaped member 410 on the front side. In this case, even for a sphere located at a position away from the center position in the left-right direction of the fan-shaped member 410 and above the fan-shaped member on the back side, an action (push-back action) associated with the inclination of the fan-shaped member is exerted. Can be caused.

In the first embodiment, the case where the outlet of the delay flow path 436 is displaced in the left-right direction with respect to the winning opening 64 has been described, but the present invention is not necessarily limited to this. For example, the delay flow paths 436 below the pair of left and right inlets 435 may merge at the center of the left and right, and the outlets thereof may be arranged directly above the winning opening 64. In this case, it is possible to improve the rate at which the balls discharged from the exit of the delay flow path 436 into the game area enter the winning opening 64.

In the third embodiment, the case where the stop device 3340 is maintained in the posture by the magnetic force has been described, but the present invention is not necessarily limited to this. For example, the locking member projects from the lower surface of the first wall portion 341, the overhanging tip is bent toward the center hole 345, and the tip of the main body rod 3361 of the maintenance device 3360 is bent downward. The posture of the stop device 3340 may be maintained by hooking the bent portions to each other. In this case, the stop device 3340 can be maintained in the changed state regardless of the magnitude of the load applied to the stop device 3340.

In the fourth embodiment, the case where the second groove 4312 is extended in the vertical direction has been described, but the present invention is not necessarily limited to this. For example, the second groove 4312 may be inclined along the front-rear direction immediately before the sprocket 4340 (immediately before the upstream side). In this case, even if the number of balls staying above the sprocket 4340 increases, the load applied to the sprocket from the balls can be reduced, and problems such as poor rotation of the sprocket 4340 can be suppressed. ..

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 including that. 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 for displaying 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 the operation of the starting operation means (for example, the operation lever) is caused. 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 consisting 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 due to, for example, 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.

<Suppress overflow by turning the second and subsequent balls to another route and delaying them>
Opportunity for lottery even if the game ball enters in the first state where the opportunity for lottery is given when the game ball enters and the state where the game ball is switched by entering the ball in the first state. In a gaming machine provided with a detection slot that can be configured with a second state in which is not given, and after switching to the second state, a predetermined return period elapses to return to the first state. , When a plurality of gaming balls are inserted, the period from when the first gaming ball, which is one of the plurality of gaming balls, is entered to when the ball is thrown into the detection slot is compared. Then, a delay means for delaying the period from when the second game ball, which is another game ball, enters the ball to when the ball is thrown to the detection entry port is provided, and the period delayed by the delay means is equal to or longer than the return period. A game machine A1 characterized by being said to be.

Here, in a gaming machine such as a pachinko machine, information is acquired based on the entrance of the game ball and the entry of the game ball into the entrance, and the display means based on the information. There is a gaming machine that dynamically displays the machine (see, for example, Japanese Patent Application Laid-Open No. 2011-156058). However, in the above-mentioned conventional gaming machine, it is possible to store up to a predetermined number (for example, 4) of information acquired based on the fact that the gaming ball has entered the ball entrance, and it is impossible to store any more information. Although it is configured, if multiple gaming balls enter the entrance in succession at short intervals, the upper limit of the number of memorable balls will be reached (the second state), and there is a risk of so-called overflow. There was a problem. Therefore, it is necessary for the player to make a self-judgment to reduce the number of balls to be continuously launched, or to play while checking the number of balls that constantly store information, which puts a burden on the player.

On the other hand, according to the gaming machine A1, the period from when the first gaming ball enters the detection entry slot to when the second gaming ball enters the detection entry slot by the delay means is longer than the return period. Since the length is increased and the second game ball is prevented from entering the detection entry port in the second state, the detection entry port is in the second state when the first game ball enters the detection entry port. Even in the case of, it is possible to form a memorable number of vacant spaces before the second game ball enters the detection entrance, and it is possible to suppress the occurrence of overflow.

The period delayed by the delay means is at least longer than the period of one dynamic display mode performed by the dynamic display means such as a liquid crystal device, and is the longest when the number of stored information storage means is the upper limit. It is desirable that the period is longer than the period of the dynamic display mode of.

The configuration of the delay means is not particularly limited, and various modes can be considered. For example, the flow path of the game ball may be distributed by a movable member, or the flow path of the game ball may be distributed according to the relationship between the shape of the flow path and the collision of the ball.

In the game machine A1, the delay means distributes the game ball to a plurality of paths and changes the posture from the first posture to the second posture by passing the game ball, and the distribution means thereof. The urging means that generates an urging force that changes the posture from the second posture to the first posture and the first game ball that has passed through the sorting means when the sorting means is in the first posture are guided and the detection is entered. The first guide flow path for throwing balls to the ball mouth and the second game ball that has passed through the distribution means between the time when the distribution means returns from the second posture to the time immediately before returning to the first posture are guided to the detection entry port. A second guide flow path for throwing balls to the ball is provided, and the period during which the second game ball passes through the second guide flow path is compared with the period during which the first game ball passes through the first guide flow path. The gaming machine A2 is characterized in that the delay period is configured as a difference between the delay periods.

According to the gaming machine A2, in addition to the effect of the gaming machine A1, the delay means includes the sorting means, the first guide flow path in which the game ball is sorted by the sorting means, the second guide flow path, and the sorting means. It is equipped with an urging means for returning the posture, and is compared with the period until the first gaming ball, which first passes through the sorting means and is guided through the first guide flow path, reaches the detection entry port, and then after that. It is possible to prolong the period until the second gaming ball that has passed through the sorting means and is guided through the second guide flow path reaches the detection entry port by the time immediately before the sorting means returns to the first posture by the urging means. Since the delay period is configured as the difference between these periods, the period during which the game ball flows down is assured as compared with the case where the flow path of the game ball is randomly determined as in the case where the game ball collides with a nail. It can be lengthened to, and the timing at which the game ball reaches the detection entrance can be reliably shifted.

In addition, since the posture of the sorting means is restored by the urging means, the game balls are sorted even when the game balls reach the sorting means at intervals (when it is not necessary to delay the game ball that came later). It is possible to prevent the second guide flow path from being distributed by the means.

In the gaming machine A2, the sorting means uses the first wall portion facing the gaming ball in the flow direction and the gaming ball in contact with the first wall portion in the case of the first posture. A second wall portion is provided at a sandwiched position, and the second wall portion receives a load along the flow direction from the game ball, so that the first one from the second posture of the sorting means. A gaming machine A3 characterized in that a change in posture in a direction toward a posture is suppressed.

According to the gaming machine A3, in addition to the effect of the gaming machine A2, the second wall portion arranged at a position sandwiching the gaming ball colliding with the sorting means with the first wall portion is along the flow direction from the gaming ball. By receiving the load, it is suppressed that the sorting means changes its posture from the second posture to the first posture. Therefore, the game ball that has passed through the sorting means first passes through the sorting means later. The action of the sphere can prevent the flow from being hindered and the flow from being delayed.

In the gaming machines A2 or A3, the sorting means includes a dividing means for dividing the gaming balls flowing down in a row and guiding only one ball to the first guide flow path, and the posture changes depending on the weight of the gaming balls. The gaming machine A4 having a configuration, wherein the dividing means functions by changing the posture of the sorting means.

According to the gaming machine A4, in addition to the effect of the gaming machine A2 or A3, the dividing means of the sorting means divides the spheres flowing down in succession, and a plurality of spheres are guided to the first guide flow path. This can be prevented without the addition of a drive source.

As the dividing means, a means for pushing the game balls toward the second guide flow path by projecting inward of the flow path, or a means for pushing the game balls in a row by projecting toward the inside of the flow path. An example is a means of inserting the game balls in between and separating the game balls from each other.

In the gaming machine A4, the sorting means uses the first wall portion facing the gaming ball in the flow direction and the gaming ball in contact with the first wall portion in the first posture. It is provided with a second wall portion arranged at a sandwiched position, and when the sorting means changes its posture from the first posture to the second posture, the second wall portion becomes the second gaming ball in the moving direction. The gaming machine A5 is characterized in that the gaming ball is introduced into the second guide flow path by colliding with the gaming ball.

According to the gaming machine A5, in addition to the effect of the gaming machine A4, when the sorting means collides with the second game ball in the moving direction during the posture change, the game is played between the sorting means and the first guide flow path. It is possible to prevent the ball from being pinched and causing the sorting means to malfunction.

Here, for example, when the sorting means operates electrically, the sorting means operates regardless of the position of the game ball, so that the game ball is at a position away from the entrance of the second guide flow path and also with the sorting means. When the sorting means operates in a direction in which the distance between the sorting means and the side wall of the first guide flow path is narrowed in a state of being arranged at a position between the side wall of the first guide flow path, the sorting means and the first The game ball may be caught between the guide flow path and the sorting means may malfunction.

On the other hand, according to the gaming machine A5, since the operation of the sorting device is generated by the weight of the game ball instead of being electric, the sorting means does not operate in a state where the sorting means malfunctions due to the arrangement of the game ball. The positional relationship and the shape relationship can be designed in advance. As a result, it is possible to prevent malfunction of the sorting means.

In the gaming machine A5, a position where a plurality of gaming balls reach the sorting means, one gaming ball abuts on the first wall portion, and the other gaming ball abuts in the moving direction of the second wall portion. In the connected ball introduction state in which the distribution means has changed its posture, it is a side surface forming the inlet of the one game ball and the second guide flow path from the first guide flow path, and is the first guide flow. The gaming machine A6, which is the distance between the end faces with the side surface on the downstream side of the road, and the distance along the extending direction of the first guide flow path is equal to or less than the radius of the gaming ball.

According to the gaming machine A6, in addition to the effect of the gaming machine A5, when the other gaming ball is connected to one gaming ball and reaches the sorting means in the connected ball introduction state, the center of the other gaming ball is the second. Since it is arranged in the area inside the second guide flow path when the guide flow path is extended, the game ball can be pushed along the side surface of the second guide flow path, and the game ball can be used as the second guide flow path. Can be introduced.

A7, wherein in the gaming machines A4 to A6, the sorting means performs a returning operation from the second posture to the first posture over a period longer than the returning period.

According to the gaming machine A7, in addition to the effects of the gaming machines A4 to A6, it is surely prevented that the second gaming ball is entered into the detection entry slot during the period when the entry detection port is in the second state. be able to.

When the dynamic display mode of the display device is such that the larger the number of memory of the detection entry port is, the easier it is to select a short-term display mode, the length of the predetermined dynamic display mode is at least the detection input. It is desirable that the length of the shortest dynamic display mode or more when the memory number of the ball mouth is the upper limit value or more.

<Overflow suppression by making the stage movable by the weight of the sphere>
Opportunity for lottery even if the game ball enters in the first state where the opportunity for lottery is given when the game ball enters and the state where the game ball is switched by entering the ball in the first state. In a gaming machine provided with a detection inlet that can be configured with a second state in which is not given, and returns to the first state after a predetermined return period elapses after being switched to the second state. , A rolling means configured to have an optimum drop portion, which is a descending start position at which the game ball can easily enter the detection entry port, and to roll on the upper surface in a manner in which the game ball passes through the optimum drop portion. The gaming machine B1 is characterized in that the rolling means operates in a mode in which the gaming ball is started to descend from the optimum falling portion at intervals equal to or longer than the return period.

Here, in a game machine such as a pachinko machine, the game ball has an optimum drop portion arranged as a descent start portion where the game ball can easily enter the detection entry port, and the game ball arranged on the upper surface provides the optimum drop portion. There are gaming machines provided with rolling means (so-called "stages") that are configured to be rollable in a passing manner (see, for example, Japanese Patent Application Laid-Open No. 2011-156508). However, in the conventional gaming machine described above, the second gaming ball rides on the rolling means before the first gaming ball on the rolling means first descends from the rolling means, and the first gaming ball and the first gaming ball are on the rolling means. The two gaming balls may descend from the optimum drop portion in a short period of time, and in that case, there is a problem that an overflow may occur at the detection entry port.

This is different from the state in which the game balls flow down while colliding with the nails, and when the game balls reciprocate in the left-right direction in a manner of passing the optimum drop portion (the game balls reciprocate on a specific path), the game balls are reciprocated with each other. Is a problem peculiar to the rolling means that tends to collide frequently.

On the other hand, according to the gaming machine B1, the rolling means operates in such a manner that the gaming balls are started to descend one by one at intervals from the optimum falling portion, so that the gaming machines can be played at the detection slot in a short period of time. It is possible to prevent the balls from entering all at once. Therefore, even when a plurality of game balls are placed on the rolling means, it is possible to prevent overflow from occurring at the detection entry port.

The gaming machine B1 includes an introduction flow path for introducing the game ball into the rolling means, and the rolling means guides the game ball to the optimum falling portion while the game ball is introduced from the introduction flow path. A floor member is provided, and the first floor member is formed to be movable by the weight of a rolling game ball, and the movement reduces the speed of the game ball arriving later toward the first floor member. A gaming machine B2 characterized in that it operates in a mode.

According to the gaming machine B2, in addition to the effect of the gaming machine B1, when the gaming ball rides on the first floor member of the rolling means, the first floor member operates by the weight of the gaming ball, so that the game is played. Since the speed of the ball toward the first floor member can be reduced, the distance between the game ball on the first floor member and the game ball toward the first floor member can be widened. As a result, it is possible to prevent overflow from occurring at the detection entry port.

The speed of the game ball toward the first floor member may be reduced, for example, the speed of the game ball toward the first floor member may be reduced (braking), or the game ball may be stopped. , The case where the game ball is moved (runs in the opposite direction) in the direction opposite to the direction toward the first floor member is exemplified.

Further, as a method of reducing the speed of the game ball toward the first floor member, for example, a method of making the first floor member descend and incline in a direction away from the first floor member, or an upper surface of the first floor member. Examples thereof include a method of projecting a deceleration protrusion and a method of projecting a magnet at a position where a magnetic force can act on a game ball on the first floor member.

In the gaming machine B2, the optimum falling portion is arranged on the first floor member, and the first floor member is configured to operate when the game ball is dropped from the optimum falling portion. The moving means is placed in the vicinity of the first floor member before and after the game ball falls from the optimum drop portion, and the optimum drop of another game ball heading toward the optimum drop portion within a predetermined period of time. The gaming machine B3, which is provided with a preventive means for preventing the player from reaching the unit.

According to the gaming machine B3, in addition to the effect of the gaming machine B2, the first floor member operates when the gaming ball falls from the optimum falling portion, and the rolling means is the gaming ball from the optimum falling portion. Is placed on the first floor member before and after the fall, and other game balls heading toward the optimum drop portion are prevented by the preventive means within a predetermined period, so that a plurality of game balls are continuously introduced into the optimum drop portion. Even in this case, it is possible to prevent other gaming balls from continuously falling from the optimum falling portion after the earliest gaming ball has fallen from the optimum falling portion. As a result, it is possible to prevent overflow from occurring at the detection entry port.

In the game machine B3, the prevention means can configure a preventive state in which the game ball can be prevented and a passing state in which the game ball cannot be prevented, and the optimum immediately after the game ball falls from the optimum drop portion. As the state of the falling portion, a preferable falling state in which the game ball has fallen in a manner in which the game ball can be easily entered into the detection entry port, and a game ball being inserted into the detection entry port as compared with the preferable falling state. A normal falling state in which the game ball has fallen in a mode that is difficult to cause is configured, and the preventing means is set to the preventing state when the suitable falling state is set, and the preventing means is set to the preventing state when the game ball is set to the normal falling state. The gaming machine B4, which is characterized in that the player is in a passing state.

According to the gaming machine B4, in addition to the effect of the gaming machine B3, when the optimum falling portion is in a suitable falling state, the preventive means is set in a preventive state, and the optimum falling portion is set in a normal falling state. Since the prevention means is passed through the ball, it is possible to suppress the prevention of the game ball even when the game ball falling from the optimum drop portion does not enter the detection entry port, and the game ball is placed at the detection entry port. It is possible to prevent the timing of entering the ball from being unnecessarily delayed.

The gaming machine B3 or B4 is provided with a throwing means for throwing a game ball prevented by the preventing means in a direction away from the optimum falling portion.

According to the gaming machine B5, in addition to the effect of the gaming machine B3 or B4, the gaming ball prevented by the preventing means by the throwing means is thrown in the direction away from the optimum falling portion, thereby intensifying the movement of the gaming ball. Since it is possible to increase the period until the game ball reaches the optimum drop portion again, it is possible to suppress the occurrence of overflow at the detection entrance while improving the interest of the player.

In any of the gaming machines B2 to B5, an intermediate floor member for introducing a game ball into the first floor member is provided, the intermediate floor member is made operable, and the operation causes the player to descend in a direction away from the first floor member. A gaming machine B6 characterized in that the intermediate floor member changes state in an inclined state.

According to the gaming machine B6, in addition to the effect of any of the gaming machines B2 to B5, the intermediate floor member inclines downward in the direction away from the first floor member, so that the gaming ball reaches the intermediate floor member. , The gravitational acceleration can be generated in the direction away from the first floor member. Therefore, it is possible to prevent the gap between the game ball arranged on the first floor member and the game ball that will reach the intermediate floor member from being reduced.

The gaming machine B6 is characterized in that the intermediate floor members are arranged in pairs on both sides of the first floor member, and the posture changes of the intermediate floor members occur alternately in the pair of intermediate floor members.

According to the gaming machine B7, in addition to the effect of the gaming machine B6, the intermediate floor members are arranged in pairs on both sides of the first floor member, and the posture changes of the intermediate floor members occur alternately in the pair of intermediate floor members. When the gaming balls are directed toward both of the pair of intermediate floor members, the timing at which the gaming balls are decelerated can be shifted, and the timing at which the gaming balls reach the first floor member can be shifted. Therefore, it is possible to prevent the game ball from being congested in the vicinity of the optimum drop portion.

In any of the gaming machines B2 to B7, in the rolling means, the gaming ball that has reached the optimum drop portion after the reciprocating motion in the left-right direction has converged, and the gaming ball that has passed through the introduction flow path to the first floor member. The gaming machine B8 is characterized in that it is configured in a manner of preventing a collision with a gaming ball flowing down toward it.

According to the gaming machine B8, in addition to the effect of any of the gaming machines B2 to B7, in the rolling means, the reciprocating motion in the left-right direction is completed and the gaming ball reaches the optimum drop portion and passes through the introduction flow path. Since it is configured to prevent a collision with a game ball flowing down toward the first floor member, the game ball immediately before falling from the optimum drop portion collides with another game ball and is detected as a ball entry port. It is possible to prevent the pachinko balls from falling in a direction away from the ball and from passing the colliding game balls in a row and passing through the detection entry port.

<Overflow suppression by decelerating the second and subsequent balls and shifting the winning timing>
Opportunity for lottery even if the game ball enters in the first state where the opportunity for lottery is given when the game ball enters and the state where the game ball is switched by entering the ball in the first state. In a gaming machine provided with a detection inlet that can be configured with a second state in which is not given, and after switching to the second state, the game returns to the first state after a predetermined return period elapses. , When a plurality of game balls enter, the flow speed of the second game ball that enters after that is compared with the flow speed of the first game ball that enters first among the plurality of game balls. The pachinko ball is provided with a deceleration means for decelerating the speed, and the game ball thrown from the deceleration means enters the detection entry port. The period required for the ball to enter the ball opening is longer than the period required for the first gaming ball to enter the detection entry port after the first gaming ball enters the deceleration means. A gaming machine C1 characterized in that it is configured to be longer than that.

Here, in a gaming machine such as a pachinko machine, information is acquired based on the entrance of the game ball and the entry of the game ball into the entrance, and the display means based on the information. There is a gaming machine that dynamically displays the machine (see, for example, Japanese Patent Application Laid-Open No. 2011-156058). However, in the above-mentioned conventional gaming machine, it is possible to store up to a predetermined number (for example, 4) of information acquired based on the fact that the gaming ball has entered the ball entrance, and it is impossible to store any more information. However, there is a problem that if a plurality of game balls continuously enter the ball entrance at short intervals, the upper limit of the number of memorable balls may be reached and a so-called overflow may occur. Therefore, it is necessary for the player to make a self-judgment to reduce the number of balls to be continuously launched, or to play while checking the number of balls that constantly store information, which puts a burden on the player.

On the other hand, according to the gaming machine C1, when a plurality of gaming balls enter the deceleration means, the speed is compared with the flow speed of the first gaming ball in which the deceleration means enters the first of the plurality of gaming balls. Then, the second gaming ball that has entered after that is decelerated, and the second gaming ball is placed in the detection entry slot until the return period elapses after the first gaming ball enters the detection entry slot. Since the ball is prevented from entering, it is possible to suppress the occurrence of overflow.

The period from when the second game ball enters the deceleration means to when the ball enters the detection entry port is the period from when the first game ball enters the deceleration means to when the ball enters the detection entry port. The length is at least longer than the length of the period (return period) of one dynamic display mode performed by the dynamic display means, and in particular, the detection entrance is set to the second state. It is desirable that the period be longer than the period of the longest dynamic display mode in the case of.

Further, the deceleration of the game ball means that the velocity component along the path toward the detection entry port is reduced. For example, the game ball flows in the direction away from the detection entry port (negative speed). The deceleration means has a preventive means for temporarily preventing the ball from being thrown, such as when the ball is reciprocated (moves in a zigzag pattern) in a direction perpendicular to the direction toward the detection entry port, and the ball is thrown by the preventive means. Until the prevention is released, the case where the game ball reciprocates in front of the prevention means, the case where the game ball temporarily stops, and the like are included.

As means for decelerating the game ball, a method of projecting an abutting member which faces and abuts in the flow direction of the game ball into the flow path, a method of applying a magnetic force to the flowing game ball, or a game ball. An example is a method of arranging a sprocket in a passage through which the sprocket passes and rotating the sprocket on a game ball.

In the gaming machine C1, the deceleration means decelerates the gaming ball by intermittently applying a load in the direction opposite to the flow direction to the gaming ball.

According to the gaming machine C2, in addition to the effect of the gaming machine C1, the deceleration means intermittently applies a load in the opposite direction of the flow direction to the gaming ball to reduce the rotation speed of the gaming ball, and as a result. Since the game ball is decelerated, the game ball can be effectively decelerated.

When decelerating by friction with the wall surface, it is necessary to increase the contact area in order to improve the deceleration efficiency, but if the target is a sphere such as a game ball, it is difficult to sufficiently increase the contact area. Is. On the other hand, in the mode in which the load is intermittently applied in the direction opposite to the flow direction, the deceleration efficiency does not depend on the target shape, so that the game ball can be effectively decelerated.

In the gaming machine C2, the deceleration means is arranged so as to be relatively movable with respect to the deceleration flow path for guiding the entering game ball and the deceleration flow path, and is configured to be able to apply a load to the game ball. It is provided with a moving means having an acting portion, and the moving means can configure a first state and a second state which is a state after relative movement from the first state to the deceleration flow path. The action unit is configured to apply a load to the gaming ball flowing down the deceleration flow path in the second state, and the moving means is such that the first game ball passes through the deceleration flow path. The gaming machine C3 is characterized in that the state changes from the first state to the second state, and in the second state, the acting unit applies a load to the second gaming ball.

According to the gaming machine C3, in addition to the effect of the gaming machine C2, the moving means having the acting portion can configure the first state and the second state, and the moving means is the first gaming ball passing through the deceleration flow path. The state is changed to the second state by the action of, and the second game ball is given a load from the action part in the second state, so that the second game ball can be decelerated without separately preparing a drive device. The distance between the first game ball and the second game ball can be separated.

Examples of the acting portion include a rib portion extending in a direction perpendicular to the extending direction of the deceleration flow path and projecting into the deceleration flow path, a magnet portion for applying a magnetic force to the game ball, and the like. When the acting part is a rib part, there are a mode in which the speed of the game ball is gradually reduced so that the game ball can pass through, a mode in which the game ball overhangs so as not to pass, and a mode in which the game ball is stopped. Illustrated.

In the gaming machine C3, the moving means is configured in such a manner that the deceleration degree of the second gaming ball is increased as the number of balls that the acting unit enters the deceleration means within a predetermined period increases. Characteristic gaming machine C4.

According to the gaming machine C4, in addition to the effect of the gaming machine C3, as the number of balls entering the deceleration means within a predetermined period increases, the acting unit increases the deceleration degree of the second gaming ball. When the number of balls flowing in the deceleration flow path becomes three within the period, the third game ball can be decelerated more than the second game ball, so that the second game ball can be decelerated more. And the third game ball can be widened. As a result, even when the second game ball enters the detection entry port and the detection entry port is in the second state, before the third game ball enters the ball. It is possible to earn a period (return period) in which the dynamic display of 1 is executed, and it is possible to suppress the occurrence of overflow due to the passage of the third game ball through the detection means.

In addition, as a mode in which the action unit increases the deceleration degree of the second game ball, for example, a mode in which the load acting on the second game ball increases and a length (duration) in which the load acts on the second game ball are used. An embodiment in which the amount of work applied to the second game ball increases due to the expansion is exemplified.

In any of the gaming machines C1 to C4, the deceleration means includes a miniaturization means configured to be movable relative to the flow path through which the game ball flows, and the miniaturization means is the first game ball. The gaming machine C5, characterized in that, upon passing, the second gaming ball moves in a direction that narrows the inner peripheral shape of the flow path before the second gaming ball passes through.

According to the gaming machine C5, in addition to the effect of any of the gaming machines C1 to C4, the miniaturization means changes the shape of the inner circumference of the flow path before the second gaming ball passes by the passage of the first gaming ball. Since it moves in the narrowing direction, it is possible to increase the resistance of the flow path when the second game ball passes through. As a result, the second game ball can be decelerated.

By matching the position where the inner peripheral shape of the flow path is narrowed with the position where the flow path changes direction (the position where the velocity component in the direction in which the game ball has flowed down disappears), the game ball flows down until then. It is possible to apply a large resistance at the timing of stopping along the direction in which the game ball was in place, to prevent the game ball from passing by with force, and to increase the action of decelerating the game ball.

In any of the gaming machines C1 to C5, a release means for releasing the deceleration effect generated on the second game ball by the deceleration means by changing the state is provided, and the state change of the release means is a game that has passed through the deceleration means. A gaming machine C6, characterized in that the ball passes through a predetermined position.

According to the gaming machine C6, in addition to the effect of any of the gaming machines C1 to C5, a releasing means for canceling the deceleration effect is provided, and the releasing by the releasing means causes the gaming ball that has passed through the deceleration means to pass through a predetermined position. Since it is performed by doing so, it is possible to eliminate the need for another driving means for changing the state of the releasing means.

In the gaming machine C6, the gaming machine C7 is characterized in that the releasing by the releasing means is performed by the gaming ball after passing through the detection entrance.

According to the game machine C7, in addition to the effect of the game machine C6, the release by the release means is performed by the game ball after passing through the detection entrance, so that it is easy to manage the release timing by the release means. Can be.

In any of the gaming machines C1 to C7, the deceleration means is configured in a mode in which the state changes between an initial state and a change state different from the initial state, and in the initial state, the deceleration means is used by the gaming ball. It changes to the changed state by passing through, and in the changed state, it is configured to change to the initial state by not passing the deceleration means through the deceleration means for a predetermined period, and the game ball passes through the deceleration means. The gaming machine C8 is characterized in that the period of passing through the decelerating means in the changing state is set longer than the period of passing through the decelerating means in the initial state.

According to the gaming machine C8, in addition to the effect of any of the gaming machines C1 to C7, the passing period of the gaming ball passing through the deceleration means in the initial state is shortened, and then the deceleration means is passed. As long as the interval between the gaming balls does not become longer than a predetermined period, the deceleration means can always be maintained in a changing state, and the period during which the gaming balls pass through the deceleration means can be maintained for a long time.

In the gaming machine C8, when the gaming balls enter the deceleration means at intervals shorter than the predetermined interval while the deceleration means is in the changing state, the number of the entering game balls does not matter. The gaming machine C9, wherein the deceleration means throws a gaming ball at a constant interval longer than the predetermined interval.

According to the gaming machine C9, in addition to the effect of the gaming machine C8, when the deceleration means is in a changing state, even if a plurality of game balls are entered into the deceleration means, the number of balls is constant regardless of the number of balls entered. Since the game balls can be thrown at intervals, it is possible to prevent overflow from occurring at the detected ball entry port regardless of the number of balls entered.

As the deceleration means, a sprocket-shaped device configured to accommodate a game ball in a recess on the peripheral surface is exemplified.

A gaming machine F1 in any of the gaming machines A1 to A9, B1 to B8, and C1 to C9, wherein the gaming machine 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.

A gaming machine F2 characterized in that, in any one of the gaming machines A1 to A9, B1 to B8, and C1 to C9, the gaming machine is a pachinko gaming machine. 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).

A gaming machine F3 characterized in that, in any one of the gaming machines A1 to A9, B1 to B8, and C1 to C9, the gaming machine is a fusion of a pachinko gaming machine and a slot machine. 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 provided with an entrance for obtaining a lottery opportunity based on the entry of a gaming ball (for example, Patent Document 1: Japanese Patent Application Laid-Open No. 2011-156058).
However, the above-mentioned conventional gaming machine has a problem that there is room for improvement in the method of winning a lottery. The technical idea is to solve the above-exemplified problems and the like, and aims to provide a gaming machine with good lottery acquisition.
<Means>
In order to achieve this purpose, the gaming machine of the technical idea 1 is switched between the first state in which the opportunity of lottery is given when the gaming ball enters and the first state in which the gaming ball enters in the first state. A second state in which a lottery opportunity is not given even if a game ball enters the ball, and a detection ball opening that can be configured are provided, and after switching to the second state, a predetermined return is performed. In a gaming machine that returns to the first state as the period elapses, when a plurality of gaming balls enter, the flow speed of the first gaming ball that enters first among the plurality of gaming balls is set. In comparison, a deceleration means for decelerating the flow speed of the second pachinko ball that has subsequently entered is provided, and the game ball thrown from the deceleration means enters the detection entry port. 2 The period from when the gaming ball enters the deceleration means to when the ball enters the detection entry port is longer after the first game ball enters the deceleration means. It is configured in such a manner that the length of the return period is longer than the period required to enter the ball.
The gaming machine of the technical idea 2 is the gaming machine described in the technical idea 1, in which the deceleration means intermittently applies a load in the direction opposite to the flow direction to the gaming ball to decelerate the gaming ball.
The gaming machine of the technical idea 3 is the gaming machine described in the technical idea 2, and the deceleration means is arranged so as to be movable relative to the deceleration flow path for guiding the entering game ball and the deceleration flow path. It is provided with a moving means having an action unit configured to be able to apply a load to the game ball, and the moving means moves relative to the first state and the deceleration flow path from the first state. The second state, which is a later state, can be configured, the action unit is configured to apply a load to the gaming ball flowing down the deceleration flow path in the second state, and the moving means is the first state. When one game ball passes through the deceleration flow path, the state changes from the first state to the second state, and in the second state, the acting unit applies a load to the second game ball.
<Effect>
According to the gaming machine described in Technical Thought 1, it is possible to improve the acquisition of lottery.
According to the gaming machine described in Technical Thought 2, in addition to the effect of the gaming machine described in Technical Thought 1, the gaming ball is decelerated by applying an intermittent load to the gaming ball, and the chance of lottery is lost. Can be prevented.
According to the gaming machine described in the technical idea 3, in addition to the effect of the gaming machine described in the technical idea 2, the load applied to the gaming ball from the moving means can be changed by the passage of the gaming ball.

10 Pachinko machine (game machine)
64 Winning slot (part of the detection slot)
300, 2300 Delay device (delay means)
311 1st groove (part of deceleration flow path)
312 2nd groove (part of the 1st guide flow path)
312d Detection port (part of detection entry port)
313 Third groove (part of the second guide flow path)
321 Slide moving member (moving means, miniaturizing means)
321a1 Convex part (acting part)
340, 2340 Sorting device (sorting means)
341, 2341 1st wall part (1st wall part)
342 2nd wall (2nd wall)
342a Convex tip (part of dividing means)
350 2nd adjustment device (urging means)
400 Delayed floor device (rolling means)
410 Fan-shaped member (first floor member, part of prevention means, part of ball throwing means, intermediate floor member)
411a Chamfered part (optimal falling part)
436 Delayed flow path (part of throwing means)
3340 Stop device (part of deceleration means)
3360 Maintenance device (release means)
4340 sprocket (part of deceleration means)
P1, P4, P6, P21, P31, P41 balls (first game ball)
P2, P5, P7, P22, P32, P42 balls (second game ball)
P11, P12 balls (game balls, other game balls)

Claims (3)

Opportunity for lottery even if the game ball enters in the first state where the opportunity for lottery is given when the game ball enters and the state where the game ball is switched by entering the ball in the first state. In a gaming machine provided with a detection inlet that can be configured with a second state in which is not given, and returns to the first state after a predetermined return period elapses after being switched to the second state. ,
When a plurality of game balls enter, the flow velocity of the second game ball that enters after that is compared with the flow velocity of the first game ball that enters first among the plurality of game balls. Equipped with deceleration means to decelerate
The game ball thrown from the deceleration means is configured to enter the detection entry port.
The period from when the second gaming ball enters the deceleration means to when the second gaming ball enters the detection entry port is longer after the first gaming ball enters the deceleration means. A gaming machine characterized in that it is configured to be longer than the length of the return period, which is longer than the period required to enter the ball mouth. The gaming machine according to claim 1, wherein the decelerating means decelerates the gaming ball by intermittently applying a load in the direction opposite to the flow direction to the gaming ball. The deceleration means has a deceleration flow path that guides the game ball that has entered the ball, and an action unit that is arranged so as to be relatively movable with respect to the deceleration flow path and is configured to be able to apply a load to the game ball. With means,
The moving means can be configured with a first state and a second state which is a state after the first state moves relative to the deceleration flow path.
The action unit is configured to apply a load to a game ball flowing down the deceleration flow path in the second state.
The moving means changes its state from the first state to the second state when the first game ball passes through the deceleration flow path.
The gaming machine according to claim 2, wherein in the second state, the acting unit applies a load to the second gaming ball.

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