JP7050626B2 - Pachinko machine - Google Patents

Description

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

For gaming machines such as pachinko machines, it is obligatory to install a performance display function (Patent Document 1) that calculates a so-called base value as an example of performance information and displays it on a display device (performance display monitor) arranged on the back side of the gaming machine. It was decided to be. This base value is calculated as the ratio of the number of payouts to the number of outs, but the period for counting the number of outs and the number of payouts (winning number) used for calculating the base value is a specific period, for example, a period with low probability and no time reduction. Limited to.

Japanese Unexamined Patent Publication No. 2018-061825

INDUSTRIAL APPLICABILITY The present invention is a game capable of minimizing an adverse effect on the calculated performance information even though there is a time difference between the timing of entering a ball into a winning means or the like and the timing of detecting a ball by an out-ball detecting means. The purpose is to provide an opportunity.

In the present invention, a symbol display means capable of variablely displaying a symbol according to any of a plurality of types of variable patterns based on a winning of a game ball to the symbol starting means, and a stop symbol after the change by the symbol display means are specific embodiments. A special game execution means for executing a special game in the case of A normal out counter that counts the number of outs during a specific period based on the detection by the detection means, a specific number counter that counts a specific number during the specific period based on the detection by the winning detection means, and the normal outs. A specific value calculation means for calculating a specific value based on each count value by the counter and the specific number counter is provided, and a predetermined start condition is satisfied for the specific period at least after the end of the symbol variation by the symbol display means. In the gaming machine which starts when the above is performed and ends when the predetermined end condition is satisfied after the end of the symbol change by the symbol display means, the last time before the end condition is satisfied during the specific period. The predetermined period of the symbol variation is set to a time shorter than the specific time required for the gaming ball detected by the winning detection means to be subsequently detected by the out ball detecting means, and the predetermined period is the said period. It is started at a predetermined timing after the end of the winning effect of whether or not the symbol has the specific mode .

According to the present invention, it is possible to minimize the adverse effect on the calculated performance information even though there is a time difference between the timing of entering the ball into the winning means and the like and the timing of detecting the ball by the out-ball detecting means. Will be.

It is a front view of the pachinko machine which concerns on 1st Embodiment of this invention. It is a side view of the pachinko machine. It is a rear view of the pachinko machine. It is a perspective view of the outer frame and the front frame in the pachinko machine. It is a partial front view of the front frame in the pachinko machine. It is a perspective view of the front door in the pachinko machine. It is a rear view of the front door in the pachinko machine. It is a plan sectional view of the front door in the pachinko machine. It is a cross-sectional view of a main part of a front door in the pachinko machine. It is a front sectional view of the main part of the front door in the pachinko machine. It is an exploded perspective view of the ball feed unit in the pachinko machine. It is a side sectional view of the main part of the pachinko machine, (a) shows a state in which a ball feed part is raised, and (b) is a state in which a ball feed part is lowered. It is a partially broken plan view of the launch handle in the pachinko machine. It is an exploded perspective view of the launch handle in the pachinko machine. It is a front sectional view of the launch handle in the pachinko machine. It is explanatory drawing of the firing operation in the pachinko machine, (a) is the relationship between the operation amount of the rotation operation part and the firing intensity, (b) is the operation of the rotation operation part and the operation lever when the rotation operation part is operated, (C) is the operation of the rotation operation unit and the operation lever when the operation of the rotation operation unit is stopped and returned to the non-operation state, and (d) is the rotation operation when the operation lever is operated from the second position to the first position. The operation of the part and the operation lever is shown. It is an exploded perspective view of the front door in the pachinko machine. It is a front view of the pachinko machine with the second upper unit removed from the front door. It is a cross-sectional view of a main part of a front door in the pachinko machine. It is a front view of the main part of the front door in the pachinko machine. It is a front sectional view of the main part of the front door in the pachinko machine. It is a cross-sectional view of a main part of a front door in the pachinko machine. It is a front sectional view of the main part of the front door in the pachinko machine. It is a side sectional view of the main part of the front door in the pachinko machine. It is a cross-sectional view of a main part of a front door in the pachinko machine. It is a front view of the 2nd upper unit in the pachinko machine. It is a side view of the 2nd upper unit in the pachinko machine. It is a rear view of the 2nd upper unit in the pachinko machine. It is an exploded perspective view of the frame movable effect means in the pachinko machine. It is a side sectional view of the movable part which constitutes the frame movable production means in the pachinko machine. It is sectional drawing in the axial direction of the movable part which constitutes the frame movable effect effect | mouth in the pachinko machine. It is a side sectional view of the frame movable production means in the pachinko machine. It is an exploded perspective view of the drive mechanism which constitutes the frame movable production means in the pachinko machine. It is a top view at the origin drive position of the drive mechanism which constitutes the frame movable production means in the pachinko machine. It is a top view at the forward drive position of the drive mechanism which constitutes the frame movable production means in the pachinko machine. It is explanatory drawing of the rotation operation of the frame movable body in the pachinko machine. It is an exploded perspective view of the operation effect means in the pachinko machine. It is a side sectional view at the origin position of the operation effect means in the pachinko machine. It is a side sectional view at the front end position of the operation effect means in the pachinko machine. It is a side sectional view at the origin position of the slide support means constituting the operation effect means in the pachinko machine. It is a side sectional view at the front end position of the slide support means constituting the operation effect means in the pachinko machine. It is a side sectional view of the main part at the pushing position of the operation effect means in the pachinko machine. It is a plan sectional view (a) and a side sectional view (b) of the 2nd positioning means of the 2nd upper unit in the pachinko machine. It is a side sectional view of the 1st locking means of the 2nd upper unit in the pachinko machine. It is a side sectional view (a) and a plan sectional view (b) of the 3rd locking means of the 2nd upper unit in the pachinko machine. It is a side sectional view (a) and the rear view (b) of the 2nd locking means of the 2nd upper unit in the pachinko machine. It is a side sectional view of the 2nd and 3rd fixing means of the 2nd upper unit in the pachinko machine. It is a plan sectional view of the 2nd fixing means of the 2nd upper unit in the pachinko machine, FIG. It is a rear view of the main part of the front door in the pachinko machine. It is sectional drawing of the main part of the front frame tail and the front door in the pachinko machine. It is a front view of the game board in the pachinko machine. It is an exploded perspective view of the base plate, the rail member and the upper constituent member of the game board in the pachinko machine. It is a front view of the game information display means in the pachinko machine. It is a front view of the liquid crystal display means, the board movable effect means, the back mounting base and the ball collecting case in the pachinko machine. It is sectional drawing of the main part of the game board in the pachinko machine. It is a side sectional view of the lower part of the game board in the pachinko machine. It is a side sectional view of the upper part of the game board in the pachinko machine. It is an exploded perspective view of the board movable body and the board movable body base which constitute the board movable effect means in the pachinko machine. It is an exploded perspective view of the elevating drive unit constituting the board movable effect means in the pachinko machine. It is a front view of the elevating drive unit constituting the board movable effect means in the pachinko machine, (a) shows a state in which a guide member, a base cover, etc. are removed, and (b) shows a state in which a guide member is removed. It is explanatory drawing which shows the relationship between the operation of the movable board, and the movable frame in the pachinko machine. It is a block diagram of the control system in the pachinko machine. It is a figure which shows the connection relationship between the LED common port and the LED data port in the pachinko machine, a game information display means, and a performance information display means (setting display means, performance display means). It is a figure which shows the flowchart (first half) of the power-on process in the pachinko machine. It is a figure which shows the flowchart (the latter half) of the power-on process in the pachinko machine. It is a figure which shows the source program corresponding to the partial processing of the power-on processing in the pachinko machine, and the processing order for each processing mode. It is a figure which shows the source program corresponding to the partial processing of the power-on processing in the pachinko machine, and the processing order for each processing mode. It is a figure which shows the correspondence relationship between the 0th to 7th bits of the input port 1 and an input signal in the pachinko machine. It is a figure which shows the correspondence relationship between the input information of a setting change operation means, a door and a game information clearing means, and the value of A register in the pachinko machine, and the correspondence relationship between them and a transition branch destination. It is a figure which shows the flowchart of the setting change processing in the pachinko machine. It is a figure which shows the source program (a), the flowchart (b) of the system input / output management processing in the pachinko machine, and the correspondence relation (c) between the LED output counter and the display state of a setting display means. It is a figure which shows the 7-segment decoding table for numerical values in the pachinko machine. It is a figure which shows the source program (a) and the flowchart (b) of the processing during system confirmation in the pachinko machine. It is a figure which shows the flowchart of the power supply abnormality check process in the pachinko machine. It is a figure which shows the flowchart of the RAM clear process in the pachinko machine. It is a figure which shows the flowchart of the common processing in the pachinko machine. It is a figure which shows the flowchart of the power-on-waiting process in the pachinko machine. It is a figure which shows the flowchart of the setting confirmation processing in the pachinko machine. It is a figure which shows the flowchart of the out-of-region processing in the pachinko machine. It is a figure which shows the flowchart of the out-of-region RAM check processing in the pachinko machine. It is a figure which shows the addition / non-addition period of each counter in the pachinko machine. It is a figure which shows the minimum value and the maximum value of the specific elapsed time for each of the winning means and the out port in the pachinko machine. It is a figure which shows the start winning timing and the passing timing of the out ball detection means in the pachinko machine, (a) shows the case of the final change of the addition period, and (b) shows the case of the final change of the non-addition period. There is. It is a figure which shows the entry timing for various winning means and the passing timing of the out-ball detecting means when the effect symbol fluctuates in the SP reach 1 jackpot fluctuation pattern in the normal gaming state (addition period) in the same pachinko machine. .. It is a figure which shows the entry timing for various winning means and the passing timing of the out ball detecting means when the effect symbol fluctuates in the SP reach 2 jackpot fluctuation pattern in the normal gaming state (addition period) in the same pachinko machine. .. It is a figure which shows the entry timing for various prize-winning means and the passage timing of the out-ball detection means when the effect symbol usually fluctuates in one variation pattern which is out of order during the time saving state (non-addition period) in the pachinko machine. It is a figure which shows the entry timing for various prize-winning means and the passage timing of the out-ball detection means when the effect symbol usually fluctuates in the out-of-order 2 fluctuation pattern in the pachinko machine in the time saving state (non-addition period). It is a figure which showed the main transmission command from the main control board to the effect control board in the power-on processing of the pachinko machine for each processing mode. It is a figure which shows the flowchart of the timer interrupt processing in the pachinko machine. It is a figure which shows the flowchart of the LED management process in the pachinko machine. It is a figure which shows the LED common output selection table (a) and LED data output information table (b) in the pachinko machine. It is a figure which shows the flowchart of the performance display update process in the pachinko machine. It is a figure which shows the flowchart of the display update process (the first half) in the pachinko machine. It is a figure which shows the flowchart of the display update process (the latter half: when the lighting / extinguishing switching counter is an even number) in the pachinko machine. It is a figure which shows the flowchart of the display update process (the latter half: when the lighting / extinguishing switching counter is an odd number) in the pachinko machine. It is a figure which shows the identification display part LED data table (a) and the decimal value LED data table (b) in the pachinko machine. It is a figure which shows the display mode of the identification display part and the numerical value display part corresponding to the display content pointer and the section pointer in the pachinko machine. It is a time chart showing the display mode during the operation confirmation display of the performance display means in the pachinko machine and the change state with each value of the blinking cycle timer, the operation confirmation timer, the on / off switching counter, and the display content pointer. Display mode and blinking cycle timer from the real-time base value display period to the first cumulative base value display period (pre-measurement period) of the performance display means in the pachinko machine, operation confirmation timer, lighting / extinguishing switching counter, display content pointer It is a time chart which shows the change state with a value. Display mode and blinking cycle timer from the first cumulative base value display period to the second cumulative base value display period (second unit measurement period) of the performance display means in the pachinko machine, operation confirmation timer, lighting / extinguishing switching counter, display It is a time chart which shows the change state with each value of a content pointer. It is a figure which shows the operation content of the effect means at the time of command reception at the time of clearing RAM and at the time of setting change of the pachinko machine. It is a figure which shows the operation content of the effect means at the time of the backup restoration of the pachinko machine, at the time of setting confirmation, and at the time of command reception at the time of RAM abnormality. It is explanatory drawing which shows one scene of the production by the frame movable body, the board movable body, and the operation handle of the pachinko machine. It is explanatory drawing which shows one scene of the production by the frame movable body, the board movable body, and the operation handle of the pachinko machine. It is explanatory drawing which shows one scene of the production by the frame movable body, the board movable body, and the operation handle of the pachinko machine. It is a figure which shows the relationship between the display pattern of the base value in the pachinko machine, and the error notification in the case of a door opening error. It is schematic front view (a) and side view (b) of the pachinko machine which concerns on 2nd Embodiment of this invention. It is schematic front view (a) and side view (b) of the pachinko machine which concerns on 3rd Embodiment of this invention. It is a figure which shows the relationship between the display pattern of the base value in the pachinko machine which concerns on 4th Embodiment of this invention, and the length of a jackpot start / end interval. It is a front sectional view of the rear part of the game board in the pachinko machine which concerns on 5th Embodiment of this invention. It is a plan sectional view of the rear part of the game board in the pachinko machine.

Hereinafter, embodiments of the invention will be described in detail with reference to the drawings. 1 to 106 exemplify the first embodiment in which the present invention is adopted for a pachinko machine. In FIGS. 1 to 8, the gaming machine main body 1 includes an outer frame 2, a front frame 3 arranged on the front side of the outer frame 2, and a front door 4 arranged on the front side of the front frame 3. There is.

As shown in FIGS. 2 to 4, the outer frame 2 is formed in a rectangular shape by a pair of left and right vertical frame members 5 and 6 and a pair of upper and lower horizontal frame members 7 and 8. A front cover member 9 is mounted on the front side of the lower horizontal frame member 8 so as to connect the left and right vertical frame members 5 and 6, and the front frame 3 is arranged on the upper side of the front cover member 9. There is.

As shown in FIG. 4 and the like, the front frame 3 is provided on the upper side of the front cover member 9 and on the upper side of the frame portion 10 and the rectangular frame portion 10 capable of substantially contacting the front edge side of the outer frame 2. The game board mounting portion 11 and the lower mounting portion 12 provided on the lower side in the frame portion 10 are provided integrally, for example, via a first hinge 13 arranged on one end side in the left-right direction, for example, the left end side. It is pivotally attached to the outer frame 2 so as to be openable and detachable, and can be locked to the outer frame 2 in a closed state by the locking means 14 on the opposite side in the left-right direction with respect to the first hinge 13, for example, the right end side. The game board 15 is detachably mounted on the game board mounting portion 11, for example, from the front side, and the launching means 16 is arranged on the front side thereof, for example, substantially in the center in the left-right direction, and the lower speaker 17 is arranged on the right side thereof. Has been done.

As shown in FIG. 5, the launching means 16 includes, for example, a launch rail 18 arranged in an inclined shape rising to the left, and a launch ball stopper 19 that supports a game ball supplied on the launch rail 18 at a launch standby position. , A striking mallet 20 that is arranged corresponding to the launch standby position on the launch rail 18 and can swing around the drive shaft 20a in the front-rear direction, a rotary solenoid that swings and drives the striking mallet 20 via the drive shaft 20a, etc. When the launch handle 22, which will be described later, is rotationally operated, the launch drive means 21 continuously pushes the striking mallet 20 in the striking direction (clockwise) with a firing intensity according to the operation amount. It is designed to be driven. As a result, the game balls supplied one by one on the launch rail 18 are sequentially launched toward the game area 15a of the game board 15 along the launch rail 18. A sheet metal launch base plate 23 is mounted on the front side of the lower mounting portion 12, and the launch rail 18, the launch ball stopper 19, and the hammer 20 are each arranged on the front side of the launch base plate 23 to drive the launch. The means 21 is arranged on the back side of the launch base plate 23.

As shown in FIGS. 6 to 8 and the like, the front door 4 is a synthetic resin door base 25 formed in a rectangular shape corresponding to the front surface of the front frame 3 and having a window hole 24a of the viewing window 24 substantially in the center. Is pivotally attached to the front frame 3 via a second hinge 26 arranged on the left end side, which is the same as the first hinge 13, and is closed to the front frame 3 by the locking means 14. It can be locked in the state.

The door base 25 is provided on the upper side of the window hole 24a in the left-right direction, the pair of vertical base portions 28a and 28b arranged on the left and right sides of the window hole 24a, and the lower side of the window hole 24a. For example, the lower base portion 29 in the left-right direction is integrally provided, and the lower base portion 29 is formed in a wide shape in the vertical direction corresponding to the front side of the lower mounting portion 12 of the front frame 3. Around the window hole 24a, for example, a pair of upper speakers 30a and 30b are arranged on the left and right ends of the upper base portion 27, and a pair of intermediate speakers 31a and 31b are arranged on the lower ends of the left and right vertical base portions 28a and 28b, respectively. ing.

Further, on the back side of the door base 25, the horizontal reinforcing members 32 in the left-right direction are on the upper end side of the upper base portion 27, and the vertical reinforcing members 33a, 33b in the vertical direction are on the outside of the left and right vertical base portions 28a, 28b. The lower reinforcing member 34 is attached to the base portion 29, respectively. The lower reinforcing member 34 has a wide shape corresponding to substantially the entire lower base portion 29, and the lower end sides of the vertical reinforcing members 33a and 33b are polymerized back and forth at both left and right ends and connected by screws or the like, and are connected to the upper edge side rearward. A receiving frame 34a that bends is provided. The reinforcing members 32, 33a, 33b, 34 are made of sheet metal.

The inner peripheral side of the joint portion between the upper base portion 27 of the door base 25 and the left and right vertical base portions 28a and 28b and the joint portion between the lower base portion 29 and the left and right vertical base portions 28a and 28b corresponds to the window hole 24a. The upper speakers 30a and 30b and the intermediate speakers 31a and 31b are mounted forward on each of the joints thereof via a speaker mounting portion.

The window hole 24a is provided corresponding to the front side of the game area 15a, and is closed by a transparent plate unit 35 detachably attached to the back side of the door base 25. As shown in FIGS. 2, 7 and the like, the transparent plate unit 35 is a connecting frame 36b that connects two front and rear transparent plates 36a that can see through the game area 15a and the two front and rear transparent plates 36a on the outer peripheral side. It is mounted on the receiving frame 34a via the engaging means 37 (see FIG. 6), and the upper side is detachably fixed to the back side of the door base 25 by a plurality of fixing means 39. Although it is desirable to use a glass plate for the transparent plate 36a, a synthetic resin plate or the like may be used.

Further, a lower unit 41 is provided on the front side of the lower base portion 29, and an upper unit 42 is provided on the front side of the upper base portion 27 and the vertical base portions 28a and 28b, respectively. The upper unit 42 is divided into two, for example, a first upper unit 42a on the left side and a second upper unit 42b on the right side.

As shown in FIGS. 1, 6, 8, 10 and the like, the lower unit 41 includes, for example, a push button type effect operating means 43 that can be operated by the player, and an upper plate that stores the game ball for launching. 44, a lower plate 45 for storing surplus balls, a launch ball guide passage 46 for guiding the game ball in the upper plate 44 to the launch means 16, a ball pulling operation means 47 that can be operated by the player, and a ball pulling operation. A ball removal guide passage 48 that guides the game ball on the upper plate 44 side to the lower plate 45 side when the means 47 is operated, an upper plate 44, a lower plate 45, a launch ball guide passage 46, a ball removal guide passage 48, etc. It is provided with a decorative cover 49 that covers the front side.

As shown in FIG. 8, the upper plate 44 is connected to a dish-shaped storage portion 51 extending forward from the back wall 50 integrated with the door base 25, and to the left and right sides, for example, the right side of the storage portion 51. It is provided with an alignment portion 52 and is provided on a dish member 53 mounted on the front side of the back wall 50. The back wall 50 is provided with a payout port 50a on the opposite side of the storage section 51 from the alignment section 52, for example, on the left side, and prize balls and the like are paid out from the payout port 50a to the storage section 51.

The storage portion 51 is gradually narrowed toward the alignment portion 52, and its bottom surface is formed in a gently inclined shape with the alignment portion 52 side being low, so that the alignment portion 52 is aligned while the internal game balls are aligned in a row. It is designed to guide you to. The alignment portion 52 has a groove shape having a width that allows the game balls to be aligned in a row, and is formed in a gently inclined shape with a low downstream side thereof. It is connected to the upstream end side of.

As shown in FIGS. 8 to 10, the launch ball guide passage 46 is arranged in an inclined shape that descends to the left along the front side of the back wall 50, for example, and the downstream end side (left end side) is the lower base portion 29. And is connected to a launch ball supply hole 54 that penetrates the lower reinforcing member 34 back and forth. The lower base portion 29 and the lower reinforcing member 34 on the rear side are formed with a passage opening 55 corresponding to the rear side of the launch ball guide passage 46. The passage opening 55 is for maintenance and is closed by an opening / closing lid 56 so as to be openable / closable. The passage opening 55 is integrally formed with the launch ball supply hole 54, for example, on the upstream side of the launch ball supply hole 54.

Further, on the bottom wall 46a of the launch ball guide passage 46, for example, a ball extraction hole 57 is formed in the vicinity of the upstream side of the launch ball supply hole 54, and the ball extraction guide passage 48 communicates under the ball extraction hole 57. are doing. The ball removal guide passage 48 has a downstream end opening toward the lower plate 45, and guides the game ball that has fallen into the ball extraction hole 57 to the lower plate 45.

Further, for example, on the lower side of the launch ball guide passage 46, a ball pulling opening / closing means 58 capable of opening / closing the ball pulling hole 57 in conjunction with the ball pulling operating means 47 is arranged. The ball-extracting opening / closing means 58 is supported so as to be slidable in the left-right direction along the bottom wall 46a of the launch ball guide passage 46, so that the opening / closing portion 58a projects toward the ball-extracting hole 57 and closes the ball-extracting hole 57. It is possible to change between a closed state (shown by a solid line in FIG. 10) and an open state in which the opening / closing portion 58a opens the ball punching hole 57 (shown by a two-dot chain line in FIG. 10) by means of urging means (not shown). It is urged to the closed side.

Further, the ball removing operation means 47 is supported so as to be vertically movable in a state of protruding upward from the decorative cover 49, for example, the vertical operation of the ball removing operating means 47 and the left and right direction of the ball removing opening / closing means 58. Is interlocked with the operation of the above by an interlocking mechanism 59 including a swing arm or the like. When the ball pulling operation means 47 moves downward from the non-operating position to the operating position by the pressing operation of the player operation, the ball pulling opening / closing means 58 moves from the closed state against the urging force of the urging means via the interlocking mechanism 59. The state shifts to the open state, and the ball extraction hole 57 is opened. As a result, the game balls on the upstream side of the ball pulling hole 57 sequentially fall into the ball pulling hole 57, and are guided to the lower plate 45 by the ball pulling guide passage 48.

Then, when the player who has pressed the ball removing operation means 47 stops the pressing operation, the ball removing opening / closing means 58 returns from the open state to the closed state due to the urging force of the urging means, and the ball removing hole 57 is closed. At the same time, the ball pulling operation means 47 returns to the non-operation position via the interlocking mechanism 59. When the ball extraction hole 57 is closed, the game ball flowing down in the launch ball guide passage 46 is guided to the launch ball supply hole 54 side without falling into the ball extraction hole 57.

Further, as shown in FIGS. 6 to 9, the ball feed unit 61 and the lower plate guide unit 62 are detachably mounted on the back surface side of the lower reinforcing member 34. The ball feeding unit 61 is for supplying the game ball guided from the upper plate 44 through the launching ball guide passage 46 to the launching means 16, and is behind the launching ball supply hole 54 and of the launching means 16. It is located on the front side. The ball feed unit 61 is integrally provided with an opening / closing lid 56 on the front side thereof, for example, and is opened from the normal position where the opening / closing lid 56 closes the passage opening 55 by a hinge 63 in the left-right direction provided on the lower side. It is rotatably supported between the open position and is held in the normal position by the holding means 64.

As shown in FIGS. 9, 11, 12, 12 and the like, the ball feed unit 61 includes a front and rear flat ball feed case 65 arranged along the rear side of the lower reinforcing member 34, and the inside of the ball feed case 65. It has a ball feed member 66 provided so as to be swingable, and a ball feed drive means 67 such as an electromagnetic solenoid that drives the ball feed member 66 in the ball feed case 65, and is synchronized with the launch operation of the launch means 16. The game balls are fed out one by one on the launch rail 18.

The ball feed case 65 is provided at a ball receiving port 68 that opens to the front side corresponding to the launch ball supply hole 54, and is provided at a position lower than the ball receiving port 68 and opens to the rear side corresponding to the launch rail 18. The ball feed port 69 is provided in the front and rear, and the pivot 63a of the hinge 63 is provided on the lower side. The ball feed member 66 is provided with a support shaft 70 in the front-rear direction on one end side thereof and a ball feed portion 71 on the other end side thereof, and is driven by the ball feed drive means 67 around the support shaft 70 with respect to the ball feed case 65. The ball feeding portion 71 moves up and down by swinging.

The ball feeding portion 71 is provided vertically with a gap of about one game ball between the blocking portion 71a and the ball receiving portion 71b, and when ascending, the blocking portion 71a receives the ball as shown in FIG. 12 (a). While retracting to the upper side of the entrance 68, the ball receiving portion 71b receives and holds one game ball, and when descending, the blocking portion 71a blocks the subsequent entry of the game ball and receives the ball as shown in FIG. 12 (b). The game ball held on the portion 71b is made to flow down from the ball feeding port 69 onto the launch rail 18.

In the case of the present embodiment, since there is a slight distance between the ball extraction hole 57 and the ball feed unit 61 on the downstream side thereof, the ball is launched by the launching means 16 with the game ball remaining in the upper plate 44. Even if the operation is stopped and the ball pulling operation means 47 is operated, not all the game balls can be pulled out, and as shown in FIG. 9, about several pieces (here, two pieces) are on the upstream side of the ball feeding unit 61. The game ball of is left. In order for the player to collect these few remaining balls, it is necessary to intentionally make a foul ball by operating the launching means 16 with a firing intensity that does not reach the game area 15a.

The lower plate guide unit 62 guides the surplus ball when the upper plate 44 is full and the foul ball that has returned without reaching the game area 15a even though it was launched by the launching means 16 to the lower plate 45. A foul ball receiving portion 72 that receives a surplus ball on the upstream side of the payout port 50a, a foul ball receiving portion 74 that receives a foul ball that has flowed back through the launch ball guide passage 73 of the game board 15, and a surplus ball. It is provided with a lower plate guide passage (return passage) 75 for guiding the surplus ball received by the receiving portion 72 and the foul ball received by the foul ball receiving portion 74 to the lower plate 45.

As shown in FIGS. 1, 2, 13 to 15, the launch handle 22, the launch handle base 81 projects substantially forward from the decorative cover 49, and the launch handle base 81 is around the axis in the substantially front-rear direction on the front side of the launch handle base 81. Rotational operation unit (first operating means) 82 rotatably supported, a return spring (urging means) 83 that urges the rotation operation unit 82 in the opposite direction, and a handle covering the front side of the rotation operation unit 82. It is equipped with a cap 84 and the like.

The launch handle base 81 is made of, for example, synthetic resin, and integrates a substantially cylindrical support leg portion 85 arranged in the front-rear direction and a bowl-shaped mechanism accommodating portion 86 provided on the front end side of the support leg portion 85. The rear end side of the support leg 85 is fixed to the door base 25, the lower reinforcing member 34, and the like in preparation for the above.

In the mechanism accommodating portion 86, a bearing portion 87 in a substantially front-rear direction is provided in the central portion, and for example, a tubular portion 88 having a forward protruding shape is provided at a plurality of locations in the peripheral portion integrally with the launch handle base 81, and a variable resistance is provided. A device 89, a touch sensor 90, an operation switch 91, an operation lever (second operating means) 92, and the like are housed.

The variable resistor 89 is for detecting the rotation angle (operation amount) of the rotation operation unit 82, and the detection side gear 93 is mounted on the detection shaft 89a projecting forward. The touch sensor 90 is for detecting contact of a finger or the like with the rotation operation unit 82, and is arranged, for example, on the rear side of the bearing unit 87.

The operation lever 92 performs a launch stop operation for stopping the launch operation by the launch means 16 and a foul ball launch operation for intentionally launching a foul ball by the launch means 16, and is an operation unit on one end side. With the 92a protruding outward from a predetermined location on the outer peripheral side of the mechanism accommodating portion 86, for example, the notch 86a provided at the lower left, on the other end side around the rotation axis 94 in the front-rear direction with respect to the launch handle base 81. It is supported swingably. The operating lever 92 is, for example, a first position (shown by a two-dot chain line in FIG. 15A) having a large protrusion amount and a second position (shown by a solid line in FIG. 15A) having a small protrusion amount. It is swingable between the two and is urged toward the first position, and when it is in the first position, the operation switch 91 is turned on and the firing operation by the launching means 16 is allowed, and it is in the second position. Occasionally, the operation switch 91 is turned off to stop the firing operation by the firing means 16.

Further, the operating lever 92 is provided with a second engaging portion 96 that can be engaged with the first engaging portion 95 on the rotation operating portion 82 side. The second engaging portion 96 is arranged at a position where the rotation operating portion 82 moves in the rotational direction as the operating lever 92 swings, and is formed, for example, in the shape of a forward protrusion.

The rotation operation unit 82 is made of, for example, a synthetic resin, and has an operation ring unit 101 formed in a short cylindrical shape corresponding to the front edge side of the mechanism accommodating unit 86, and a plurality of operation ring units 101 projecting from the outer peripheral side of the operation ring unit 101. For example, three finger hook portions 102, an operation shaft 103 in a substantially front-rear direction arranged at the center of the operation ring portion 101, and a connecting plate 104 connecting the inner peripheral side of the operation ring portion 101 and the outer peripheral side of the operation shaft 103. Is integrally provided, and the rear end side of the operation shaft 103 is inserted into the bearing portion 87 so as to be rotatably supported by the launch handle base 81.

An operation-side gear 105 is integrally rotatable on the operation shaft 103 of the rotation operation unit 82, and the operation-side gear 105 meshes with the detection-side gear 93. As a result, the rotation operation unit 82 and the detection shaft 89a of the variable resistor 89 are interlocked with each other, and the rotation angle (displacement amount) of the rotation operation unit 82 can be detected by the variable resistor 89. Further, the rotation operation unit 82 functions as an electrode of the touch sensor 90, for example, by applying conductive plating to the entire outer surface thereof.

For example, a plurality of arcuate guide holes 104a are provided in the connecting plate 104 of the rotation operation unit 82, and the tubular portion 88 on the launch handle base 81 side is inserted forward into the guide holes 104a. As a result, the operable range of the rotation operating unit (first operating means) 82 is restricted between the predetermined non-operating position and the operating upper limit position rotated clockwise by a predetermined angle from the non-operating position.

Further, the rotation operation unit 82 is urged toward a non-operation position by a return spring (urging means) 83. The return spring 83 is attached to the operation shaft 103 of the rotation operation unit 82 from the front side, one end of which is engaged with the engagement portion 106 of the rotation operation unit 82 side, and the other end side of the engagement portion 107 of the firing handle base 81 side. The rotation operation unit 82 is urged in the counter-operation direction (counterclockwise direction), and the rotation operation unit 82 and the touch sensor 90 are made conductive.

Further, the rotation operation unit 82 is integrally provided with a first engagement portion 95, for example, on the back surface side of the connecting plate 104. The first engaging portion 95 is, for example, a radial ridge, and when the rotation operating portion 82 returns to the non-operating position side by the return spring 83, the first engaging portion 95 is a first at a specific position before a predetermined angle of the non-operating position. It is adapted to engage with the second engaging portion 96 of the operating lever 92 at the position. Since the urging force of the return spring 83 on the rotation operation unit 82 side is larger than the urging force on the operation lever 92 side, the second engagement is performed while the rotation operation unit 82 further moves from the specific position to the non-operation position. When the part 96 is pushed by the first engaging part 95 and the operation lever 92 moves to the second position side and the rotation operation part 82 reaches the non-operation position, the operation lever 92 reaches the second position. ing. That is, when the rotation operation unit 82 is in the non-operation position, the operation lever 92 is held in the second position.

The handle cap 84 is formed in a substantially hemispherical shape by using synthetic resin, and a plurality of fixing bases 108 are projected backward corresponding to the tubular portion 88 on the launch handle base 81 side on the inner surface side thereof, and the trailing edge side thereof. Is detachably attached to and detachable from the launch handle base 81 by screwing the fixing base 108 from the rear side of the launch handle base 81 via the tubular portion 88 in a state of being fitted to the inner peripheral side of the operation ring portion 101 from the front side. It is fixed. At least a part of the handle cap 84 constitutes a light emitting lens portion, and the LED substrate 109 is arranged inside the handle cap 84.

As shown in FIGS. 16A and 16B, when the player grips the rotation operation unit 82 and rotates it clockwise, the operation lever 92 moves from the second position to the first position side accordingly. The operation switch 91 is turned on, and the firing operation by the firing means 16 is permitted. After that, the firing operation by the firing means 16 is performed with the firing intensity according to the operation amount (displacement amount) of the rotation operation unit 82. At this time, the game ball launched by the launching means 16 does not reach the game area 15a when the operation amount of the rotation operation unit 82 is equal to or less than a predetermined foul threshold value (specific threshold value), and the rotation operation amount of the rotation operation unit 82. Will reach the game area 15a (pass through the return prevention valve 337 described later) when the foul threshold value is exceeded (FIG. 16A). Further, when the player presses the operation lever 92 from the first position to the second position (first operation) in this state, the operation switch 91 is turned off and the firing operation by the firing means 16 is stopped.

As shown in FIG. 16C, when the player stops the operation of the rotation operation unit 82 to stop the firing operation and returns the rotation operation unit 82 to the non-operation position, the operation lever 92 is moved to the first position accordingly. Moves from to the second position. As a result, the operation switch 91 is turned off, and the firing operation by the firing means 16 is stopped. When the rotation operation unit 82 is in the non-operation position, the operation lever 92 is held in the second position, and the player can operate the rotation operation unit 82 toward the first position side (second operation).

In this way, when the rotation operating portion 82 returns to the non-operating position, the first engaging portion 95 comes into contact with the second engaging portion 96, and the operating lever 92 moves from the first position to the second position. When the rotation operation unit 82 reaches the non-operation position, for example, the impact caused by the collision between the guide hole 104a on the rotation operation unit 82 side and the tubular portion 88 on the launch handle base 81 side is reduced by the urging force of the operation lever 92. .. When the rotation operation unit 82 is in the non-operation position, the guide hole 104a on the rotation operation unit 82 side and the tubular portion 88 on the launch handle base 81 side do not come into contact with each other, and the first engagement portion 95 and the second The rotation operation unit 82 may be held in a non-operation position by engaging with the engagement unit 96.

FIG. 16C shows an example in which the rotation operation unit 82 is returned to the non-operation position in a state where the operation lever 92 is not pressed (in the first position), but the operation lever 92 is pressed. Of course, it is also possible to return the rotation operation unit 82 to the non-operation position in the state (in the second position). In this case, since the operating lever 92 is held in the second position in advance, the first engaging portion 95 comes into contact with the second engaging portion 96 when the rotation operating portion 82 reaches the non-operating position. Also in this case, when the rotation operation unit 82 is in the non-operation position, the guide hole 104a on the rotation operation unit 82 side and the tubular portion 88 on the launch handle base 81 side do not come into contact with each other, and the first engagement portion 95 And the second engaging portion 96 may be engaged to hold the rotation operating portion 82 in the non-operating position.

As shown in FIG. 16D, in a state where the rotation operation unit 82 is in the non-operation position, the player operates the operation lever 92 instead of the rotation operation unit 82 from the second position to the first position (second operation). Then, the second engaging portion 96 on the operation lever 92 side pushes and moves the first engaging portion 95 on the rotation operation unit 82 side, so that the rotation operation unit 82 reaches a specific position against the urging force of the return spring 83. Moving. At this time, since the rotation amount (displacement amount) of the rotation operation unit 82 is set to be equal to or less than the foul threshold value (FIG. 16A), the player touches the rotation operation unit 82 in that state and fires. When the means 16 is activated, the launched game ball becomes a foul ball without reaching the game area 15a.

Therefore, after the player operates the ball pulling operation means 47 to pull out the game ball of the upper plate 44 to the lower plate 45 side, he / she wants to collect all the few game balls remaining on the upstream side of the ball feed unit 61. In this case, if the launching means 16 is operated while the operating lever 92 is operated and held in the first position, the remaining game balls can be easily and surely collected as foul balls. While the player operates the operation lever 92 from the second position to the first position (second operation) and maintains that state, the rotation operation unit 82 is held at the specific position and returns to the non-operation position. There is no such thing.

As shown in FIGS. 17 and 18, a pair of left and right speaker mounting protrusions 111a and 111b projecting forward from the door base 25 are integrally formed on the upper portion of the door base 25. As shown in FIGS. 19 to 22, the speaker mounting protrusions 111a and 111b have a substantially quadrangular front view in which openings 112 and 113 are formed on both front and rear sides, and the rear openings 113 to the upper part. Speakers 30a and 30b are detachably inserted and housed.

As shown in FIG. 20, the speaker mounting protrusion 111a is provided with receiving portions 114b and 114c for the first and second upper units 42a and 42b. That is, the speaker mounting protrusions 111a on the hinges 13 and 26 are provided with receiving portions 114b and 114c for the first and second upper units 42a and 42b on the left and right sides of the flat portion 114a, and the receiving portions 114b and 114c are provided. The upper surfaces of the upper units 42a and 42b are substantially flush with the flat portion 114a. Further, as shown in FIG. 21, a receiving portion 114d for the second upper unit 42b is provided on the upper side of the speaker mounting protrusion 111b on the opposite side of the hinges 13 and 26.

As shown in FIG. 22, the upper speakers 30a and 30b include a magnet 116, a coil bobbin 117, a voice coil 118, a diaphragm 119, a center cap 120, and the like in the speaker frame 115, and a front cover 121 is provided on the front side of the speaker frame 115. It is installed. The front cover 121 is fitted into the opening 112 on the front side of the speaker mounting protrusions 111a and 111b.

Each of the upper speakers 30a and 30b has a light guide body 124 arranged in an internal space 122 on the inner peripheral side such as a magnet 116, and an LED substrate on which an LED 125 is mounted close to the rear end side of the light guide body 124. When the LED 125 of the LED substrate 126 emits light, the light is emitted from the light guide body 124 to the front side through the center cap 120 and the front cover 121.

The light guide body 124 and the center cap 120 are made of a transparent synthetic resin, and the front cover 121 is formed with a large number of small holes 121a so that sound and light are emitted to the front side. The light guide body 124 is inserted into the through hole 115b of the rear wall portion 115a of the speaker frame 115 and is detachably supported. Further, on the back side of the rear wall portion 115a, the LED substrate 126 is detachably fixed with screws or the like so that the LED 125 faces the light guide body 124 in the front-rear direction. The front cover 121 may be colorless and transparent, colored transparent, or opaque. When the front cover 121 is made of a colorless transparent or colored transparent synthetic resin, a concave-convex diffused reflection portion is formed on the back surface side thereof so that the front cover 121 itself emits light by the light from the LED 125. good.

By assembling the light emitting means such as the light guide body 124 and the LED board 126 to the upper speakers 30a and 30b in this way, the light from the LED 125 of the LED board 126 is transmitted from the light guide body 124 through the center cap 120 and the front cover 121 to the front side. Can be irradiated to. Therefore, the upper speakers 30a and 30b can be used not only for generating sound effects but also for producing light emission, and an unprecedented effect can be expected.

Of the first and second upper units 42a and 42b constituting the upper unit 42, the first upper unit 42a is a common component commonly used for a plurality of types of models like the lower unit 41. The second upper unit 42b has a design, a function, and the like peculiar to each model, and can be easily attached and detached as compared with the first upper unit 42a. In the upper unit 42 of the present embodiment, as shown in FIGS. 17, 18 and the like, the portion corresponding to the left vertical base portion 28a is attached to the first upper unit 42a, the upper base portion 27, and the right vertical base portion 28b. The corresponding portion is the second upper unit 42b, but the division points of the first and second upper units 42a and 42b are arbitrary. Of course, the entire upper unit 42 may have a unique configuration for each model and can be easily attached and detached.

For example, when manufacturing a plurality of types of models, the first upper unit 42a is commonly used, and the second upper unit 42b having a configuration peculiar to each model is combined with the first upper unit 42a to form a viewing window 24 of the front door 4. Consists of the peripheral part. With this configuration, it is possible to easily manufacture different models of pachinko machines by changing the design of the second upper unit 42b and other configurations while using the first upper unit 42a in common.

Depending on the model of the pachinko machine, the design and other configurations of the first upper unit 42a can be changed. In that case, the door base 25 will be common to a plurality of models. Therefore, in both the first upper unit 42a and the second upper unit 42b, electronic parts and the like that are commonly required for each model, such as the upper speakers 30a and 30b for generating sound effects and the intermediate speakers 31a and 31b, are used. Electronic components and the like mounted on the door base 25 side and specific to a specific model are incorporated in the first upper unit 42a and the second upper unit 42b, or the second upper unit 42b.

As shown in FIGS. 1, 17, 18, 23 to 25, etc., the first upper unit 42a is located between the left upper speaker 30a and the left intermediate speaker 31a along the left side of the viewing window 24. A light emitting decoration that is arranged vertically and is arranged on the front side of the door base 25 and has a large number of LEDs 130 mounted on the front surface, and a diffused reflection portion 132a is formed inside and covers the LED substrate 131 from the front side. A cover 132 and an internal lens 133 arranged on the front side of the LED substrate 131 are provided, and the light emitting decorative cover 132 is made to emit light by the light from the LED 130 of the LED substrate 131.

The LED board 131 is divided into a plurality of pieces, for example, and is connected by a connector 134 or the like. The light emitting decorative cover 132 is made of a colorless transparent or colored transparent synthetic resin, and is provided with an uneven diffused reflection portion 132a on the inner surface of the back side.

As shown in FIGS. 24 and 25, the upper side 134a of the light emitting decorative cover 132 protrudes in front of the lower side 134b, and the upper side 134a is the receiving portion 114b of the speaker mounting protrusion 111a as shown in FIG. 20 and the like. , 114c overlaps. The distance between the LED substrate 131 and the light emitting decorative cover 132 is large on the upper side and smaller on the lower side.

As shown in FIGS. 23 to 25, the internal lens 133 is formed with a through hole 135 corresponding to each LED 130 on the upper side 134a where the distance between the LED substrate 131 and the light emitting decorative cover 132 is large. A conical or spherical concave lens portion 136 is formed on the front surface side or the back surface side corresponding to each LED 130 on the lower side 134b where the distance between the LED substrate 131 and the light emitting decorative cover 132 is small.

Therefore, when each LED 130 of the LED substrate 131 emits light, the light from the LED 130 directly irradiates the diffused reflection portion 132a of the light emitting decorative cover 132 through the through hole 135 on the upper side 134a of the light emitting decorative cover 132. Since the distance between the 131 and the light emitting decorative cover 132 is large, the light from the LED 130 irradiates the diffusely reflecting portion 132a while being appropriately diffused.

On the other hand, on the lower side 134b where the distance between the LED substrate 131 and the light emitting decorative cover 132 is small, the light from the LED 130 is diffused by the concave lens portion 136 and irradiates the diffused reflection portion 132a of the light emitting decorative cover 132. Therefore, it is possible to prevent or reduce the light emission unevenness between the upper side 134a and the lower side 134b on the light emitting decorative cover 132 side as much as possible.

The concave lens portion 136 is composed of a conical recess 136a formed on the front surface of the internal lens 133 and a spherical protrusion 136b formed on the back surface of the internal lens 133 corresponding to the conical recess 136a. The concave lens portion 136 may have a light diffusing function, and the specific cross-sectional shape does not matter.

As shown in FIGS. 1, 17, 26 to 28, etc., the second upper unit 42b has a front view substantially L straddling the upper speaker 30a on the left side, the upper speaker 30b on the right side, and the intermediate speaker 31b on the right side. It is formed in a character shape, for example, a horizontal unit portion 141 corresponding between the left and right upper speakers 30a and 30b, a vertical unit portion 142 corresponding between the upper speaker 30b and the intermediate speaker 31b, and their horizontal unit portions. The first and second positioning means 144 and 145 are provided with a rear view substantially L-shaped unit reinforcing plate 143 straddling the 141 and the vertical unit portion 142 and mounted on the back side thereof, and arranged on both end sides. And a plurality of distributed arrangements, for example, three first to third locking means 146 to 148, and a plurality of dispersed arrangements, for example, three screw type first to third fixing means 149 to 151. It is detachably attached to the door base 25 from the front side according to (FIGS. 6, 7, etc.).

The horizontal unit portion 141 includes a unit main body portion 152 and a frame movable effect means 153 arranged, for example, substantially in the center of the unit main body portion 152 in the left-right direction. Further, as shown in FIGS. 29 to 32, the frame movable effect means 153 has a movable portion 154 capable of sliding in a substantially front-rear direction with respect to the unit main body portion 152, and the movable portion 154 at the origin position and from the origin position thereof. Also equipped with a driving means 140 that drives to and from the forward position on the front side, but the sliding operating direction of the movable portion 154 (hereinafter, simply referred to as “sliding operating direction”) is slightly as shown in FIG. 27 and the like. It has a downward slope.

As shown in FIGS. 29 to 31, the movable portion 154 constituting the frame movable effect effect means 153 includes a movable main body portion 155 and a frame movable body 156 arranged on the front side of the movable main body portion 155. .. The movable main body portion 155 is formed in a substantially cylindrical shape with the central axis directed in the slide operation direction. For example, on the rear end side, a first guide roller 158 corresponding to the first slide guide 157 on the unit main body portion 152 side is provided. The second guide roller 160 corresponding to the second slide guide 159 on the unit main body portion 152 side and the driven portion 161 that receives the driving force from the driving means 140 are arranged.

The first guide rollers 158 can be rotated around an axis in the left-right direction, for example, and a plurality of the first guide rollers 158 are arranged on the left and right sides of the movable main body portion 155 along the slide operation direction (here, two each). Like the first guide roller 158, the second guide roller 160 is rotatable around an axis in the left-right direction, and is arranged, for example, one on each side of the movable main body portion 155. The left and right second guide rollers 160 are arranged, for example, at positions inside the left and right first guide rollers 158 and offset to one side (here, the upper side) in the vertical direction. The first guide roller 158 and the second guide roller 160 are supported by a movable guide sheet metal 162 fixed to the rear end side of the movable main body portion 155.

The driven portion 161 is arranged, for example, on the lower side of the rear end portion of the movable main body portion 155. It is composed of a mounted bush 161b.

Further, on the front end side of the movable main body portion 155, a rotation guide 163, a ratchet claw 164, a rotation lock lever 165, a rotation position detecting means 166, and the like are provided. The rotation guide 163 is for rotatably supporting the frame movable body 156, and is formed in a short cylindrical shape having a smaller diameter than the outer peripheral wall 155a of the movable main body portion 155, and is integrally formed inside the outer peripheral wall 155a, for example. It is provided.

The ratchet claw 164 is for holding the frame movable body 156 at one or a plurality of rotation positions, and is in a state of being movable between a protruding position protruding toward the inner peripheral side of the rotation guide 163 and a retracting position not protruding. , Is arranged at a predetermined position (here, the upper position) on the circumference of the rotation guide 163, and is elastically urged toward the protruding position side by the spring 164a. As shown in FIG. 31, the tip portion of the ratchet claw 164 is formed in a pointed shape by the inclined surfaces formed corresponding to both sides in the circumferential direction of the rotation guide 163.

The rotation lock lever 165 is for locking the frame movable body 156 so that it can be released at one or a plurality of rotation positions. For example, the rotation lock lever 165 is arranged on the front side of the front end portion of the movable main body portion 155 so as to substantially follow the outer peripheral wall 155a. The lock lever base 167 fixed to the outer peripheral side of the outer peripheral wall 155a is swingably supported around the rotation shaft 167a in the slide operation direction. The rotary lock lever 165 has a substantially arc shape along the circumferential direction of the outer peripheral wall 155a, and has a pressing operation portion 165a projecting toward the outside of the outer peripheral wall 155a, for example, on one end side, and an inner circumference of the outer peripheral wall 155a, for example, on the other end side. A lock claw portion 165b protruding toward the side is provided integrally with each other, and is supported in a swingable state between the lock position and the unlock position by a rotation shaft 167a arranged substantially in the center in the longitudinal direction. , Is urged to the lock position side by the spring 165c. The rotary lock lever 165 shifts from the locked position to the unlocked position when the pressing operation unit 165a is pressed against the urging force of the spring 165c.

Further, the rotation position detecting means 166 detects the rotation position of the frame movable body 156, and is configured by, for example, a photo sensor. When the rotation position of the frame movable body 156 is a predetermined origin rotation position, the frame is movable. For example, it is arranged forward in the vicinity of the rear side of the rotation guide 163 so that the detected portion 166a on the body 156 side can be detected, and is fixed to the movable main body portion 155 via the sensor base 168.

The frame movable body 156 includes a decorative unit 169 and a decorative support 170 that supports the decorative unit 169 on the rear side. As shown in FIGS. 29 to 31, the decorative support 170 is concentric with the first cylindrical portion 172 corresponding to the inner circumference of the rotation guide 163 on the movable main body portion 155 side and the front side of the first cylindrical portion 172. A second cylindrical portion 173 that is arranged and formed to have a diameter larger than that of the first cylindrical portion 172, and a fixed portion that is arranged on the front side of the second cylindrical portion 173 and extends radially outside the second cylindrical portion 173. For example, the base portion 174 is integrally provided, the first cylindrical portion 172 is inserted into the rotation guide 163 from the front side, and the retaining member 175 formed in a substantially disk shape having a larger diameter than the rotation guide 163 is rotated. By fixing from the rear side of the guide 163 to the rear end side of the first cylindrical portion 172, it is rotatably supported with respect to the movable main body portion 155. A rotary bush 176 is arranged between the rotary guide 163 and the first cylindrical portion 172 on the front edge side.

The retaining member 175 is provided with, for example, a rearward protrusion-shaped detected portion 166a in the vicinity of the outer edge portion on the back surface side, and is movable when the rotation position of the frame movable body 156 is the origin rotation position shown in FIG. The rotation position detecting means 166 on the main body 155 side detects the detected portion 166a.

Further, on the retaining member 175, a rotation preventing portion 175a is formed at a predetermined position on the outer periphery thereof, for example, in the shape of a protrusion outward in the radial direction. The rotation stop portion 175a is for limiting the rotation of the frame movable body 156 to a certain range (here, between the origin rotation position and the storage rotation position), and as shown in FIG. 31, the frame movable body 156 Along with the rotational operation, it moves between the first restricting portion 177a and the second restricting portion 177b on the movable main body portion 155 side. When the frame movable body 156 comes into contact with the frame movable body to the retracted rotation position, it substantially comes into contact with the second regulating portion 177b.

On the outer peripheral side of the first cylindrical portion 172, for example, V grooves 178 formed in the axial direction are arranged at one or a plurality of locations in the circumferential direction. The V-groove 178 corresponds to the ratchet claw 164, and the frame movable body 156 is held at that position by engaging the ratchet claw 164 with the V-groove 178. Since the tip of the ratchet claw 164 has a pointed shape corresponding to the V groove 178, the holding force is weak, and by applying a certain rotational force or more to the frame movable body 156, the ratchet claw 164 has a spring 164a. It moves to the retracted position side along the slope of the V-groove 178 against the force, and the holding state is released.

One or more V-grooves 178 are provided corresponding to one or more rotation positions of the frame movable body 156. In the present embodiment, a total of five V-grooves 178 are provided corresponding to the origin rotation position, the storage rotation position, and, for example, three locations equally divided between them, but the V-groove 178 corresponds to the origin rotation position. It may be provided only at the position corresponding to the origin rotation position and the storage rotation position. Of course, if three or more V-grooves 178 are provided, they do not have to be evenly spaced.

Further, on the outer peripheral side of the second cylindrical portion 173, for example, lock grooves 179 formed in the axial direction are arranged at one or a plurality of locations in the circumferential direction. The lock groove 179 corresponds to the lock claw portion 165b of the rotary lock lever 165, and when the lock claw portion 165b of the rotary lock lever 165 engages with the lock groove 179, the frame movable body 156 rotates at that position. Locked to an impossible state. Since the rotary lock lever 165 is urged to the lock position side by the spring 165c, when the lock claw portion 165b engages with the lock groove 179, the locked state is maintained. In order to rotate the frame movable body 156 from that state, the pressing operation unit 165a is pressed to move the rotation lock lever 165 to the unlocked position, and the engagement between the lock claw portion 165b and the lock groove 179 is released. There is a need.

One or more lock grooves 179 are provided corresponding to one or more rotation positions of the frame movable body 156. In the present embodiment, a total of three lock grooves 179 are provided corresponding to the origin rotation position, the storage rotation position, and, for example, one place (intermediate rotation position) that equally divides them. As described above, all the lock grooves 179 correspond to any of the plurality of V grooves 178, respectively. The lock groove 179 may be provided only at a position corresponding to the origin rotation position, or may be provided only at a position corresponding to the origin rotation position and the storage rotation position. Of course, if three or more lock grooves 179 are provided, they do not have to be evenly spaced. Further, all the lock grooves and all the V grooves may have a one-to-one correspondence.

The decorative unit 169 is, for example, flat in the front-rear direction, and as shown in FIG. 26, for example, a frame first decorative portion 180a arranged in the center in the left-right direction and a pair arranged on the left and right sides of the frame first decorative portion 180a. The frame second decorative portion 180b exhibits a predetermined three-dimensional shape, and the lower side of the frame first decorative portion 180a is arranged so as to correspond to the front side of the movable main body portion 155. When the board movable body 371, which will be described later, rises to the upper limit position and becomes a specific relative positional relationship, the frame movable body 156 is visually integrated with the board movable body 371 and is integrated into a specific form (designed here). The form of the "butterfly") is formed, for example, the frame first decorative portion 180a having a circular front view corresponds to the head (or front body) of the butterfly, and the frame first decorative portion 180a is formed. The second decorative portion 180b of the frame overhanging to the left and right and the upper side corresponds to the front wing of the butterfly.

As shown in FIG. 27, the decorative unit 169 is arranged substantially perpendicular to the slide operation direction. That is, the frame movable body 156 is arranged so as to be tilted to the front side by a predetermined angle and the front surface to face diagonally forward and downward.

As shown in FIGS. 26 to 30, the decoration unit 169 includes a decoration base 181 constituting the back side of the frame first and second decorative portions 180a and 180b, and the frame first and second decorative portions 180a and 180b. The light emitting decorative covers 182a and 182b each constituting the front side, and the decorative frames 183a and 183b mounted on the front side along the outer periphery of the decorative base 181 and supporting the light emitting decorative covers 182a and 182b on the outer peripheral side, and the frame first. 1, LED substrates 184a, 184b arranged between the decorative base 181 and the light emitting decorative covers 182a, 182b corresponding to the second decorative portions 180a, 180b, and a rotating body arranged in the frame first decorative portion 180a. The 185 and the rotation driving means 186 for rotationally driving the rotating body 185 are provided, and the decorative base 181 is detachably fixed to the front side of the fixed base portion 174 on the decorative support 170 side.

The decorative base 181 is, for example, non-translucent, and as shown in FIG. 30, a bearing portion 187 is provided substantially in the center of the frame first decorative portion 180a along the slide operation direction, and the bearing portion 187 rotates. The rotation shaft 185a of the body 185 is rotatably inserted. The rotating body 185 is formed in a three-dimensional shape in the shape of, for example, a wind turbine, and is fixed to the front end side of the rotating shaft 185a. Further, in the decorative base 181 for example, a bulging portion 188 that bulges backward is formed on the lower side of the bearing portion 187, and a rotary driving means including a stepping motor or the like is formed on the back surface 188a of the bulging portion 188. The 186 is mounted in a state where the drive shaft 186a is projected forward. The rotation driving means 186 is arranged in the first and second cylindrical portions 172 and 173 of the decorative support 170.

A drive gear 189 is fixed to the front end side of the drive shaft 186a of the rotary drive means 186, and a driven gear 190 is fixed to the rear end side of the rotary drive 185a. The drive gear 189 and the driven gear 190 are fixed. And are in mesh. As a result, the driving force of the rotation driving means 186 is transmitted to the rotating body 185 via the driving gear 189, the driven gear 190, and the rotating shaft 185a, and the rotating body 185 rotates.

As shown in FIGS. 26 and 30, the LED substrate 184a corresponding to the frame first decorative portion 180a has a substantially circular shape centered on the rotating shaft 185a and is arranged on the rear side of the rotating body 185 and is arranged on the front side thereof. In the vicinity of the outer peripheral portion, a plurality of LEDs 191a are arranged at substantially equal intervals in the circumferential direction, and further, on the inner peripheral side thereof, a plurality of LEDs 191b are also arranged at substantially equal intervals in the circumferential direction. An annular reflector 192 is arranged in the vicinity of the front side of the LED substrate 184a corresponding to the arrangement position of the LEDs 191a and 191b, and a substantially circular inner lens 193 is arranged inside the arrangement position of the LEDs 191a and 191b. Have been placed. Further, the light emitting decorative cover 182a corresponding to the frame first decorative portion 180a is made of a colorless transparent or colored transparent synthetic resin in which the internal rotating body 185 can be visually recognized, and has a bowl shape covering the outer peripheral side from the front side of the rotating body 185. It is formed.

The reflector 192 is for guiding the light from the LED 191a on the outer peripheral side to the light emitting decorative cover 182a side and the light from the LED 191b on the inner peripheral side to the inner lens 193 side, respectively, and is formed of a non-transmissive synthetic resin. The outer ring portion 192a corresponding to the LED 191a on the outer peripheral side and the inner ring portion 192b corresponding to the LED 191b on the inner peripheral side are integrally provided. As shown in the enlarged view of FIG. 30, the outer ring portion 192a is formed with a light guide hole 192c penetrating in the front-rear direction corresponding to each LED 191a, and the outer ring portion 192a is formed in the light guide hole 192c with the LED 191a. Is substantially in contact with the front surface side of the LED substrate 184a in a state of accommodating.

As shown in the enlarged view of FIG. 26, the inner lens 193 has a notch portion 193a corresponding to the LED 191b formed on the outer peripheral side, and is arranged inside the outer ring portion 192a of the reflector 192 along the front surface of the LED substrate 184a. There is. The inner ring portion 192b extends on the inner peripheral side of the outer ring portion 192a along the front surface of the inner lens 193 to at least the inside of the notch portion 193a. Further, on the front side of the reflector 192, a support groove 192d is provided over the entire circumference at a position corresponding to the front side of the light guide hole 192c, and the rear end side of the light emitting decorative cover 182a is fitted into the support groove 192d from the front side. are doing. As a result, the light from the LED 191a on the outer peripheral side is guided to the light emitting decorative cover 182a by turning the light guide hole 192c, and the light from the LED 191b on the inner peripheral side is guided to the inner lens 193 side by turning the inner ring portion 192b or the like. .. As a result, the light emitting decorative cover 182a on the front side of the rotating body 185 and the inner lens 193 on the rear side of the rotating body 185 can be made to emit light individually.

As shown in FIG. 26, the LED substrate 184b corresponding to the frame second decorative portion 180b has a shape corresponding to substantially the entire frame first decorative portion 180a, and for example, two types of LEDs (first light emitting body) are on the front side thereof. ) A plurality of 194a and 194b are arranged respectively. The LEDs 194a are arranged at substantially equal intervals at positions corresponding to the outer periphery of the "butterfly" formed by the frame movable body 156 and the board movable body 371, and can emit light in a single color such as white. The LEDs 194b are distributed substantially evenly in, for example, the internal region of the "butterfly", and can emit light in multiple colors, for example. Further, the light emitting decorative cover 182b corresponding to the frame second decorative portion 180b is made of a colorless transparent or colored transparent synthetic resin, and an uneven diffused reflection portion is provided on the inner surface of the back side. The LED 194a and the LED 194b may be of the same type.

As shown in FIGS. 26, 28, etc., the unit main body portion 152 includes an upper wall portion 195 arranged substantially horizontally, a front wall portion 196 on the front side, a lower peripheral wall portion 197 from the lower side to the left side, and a rear portion. It is formed in a substantially box shape, for example, with the right side opening at the back wall portion 198 on the side.

The unit main body portion 152 is provided with a recessed portion 201 that is recessed inward (substantially upward) from the lower surface side in front view, for example, in a portion slightly to the left of the substantially center in the left-right direction. The left side portion constitutes the left connecting portion 202 that is visually connected to the first upper unit 42a and the speaker mounting protrusion 111a, and the portion on the right side of the recessed portion 201 is not a frame that projects downward. It constitutes the movable body 203.

The frame non-movable body 203 is a portion that forms a “butterfly” as a specific form together with the frame movable body 156 and the board movable body 371, and is arranged in the lower right part of the frame movable body 156 in front view as shown in FIG. The left wall portion 203a is formed in a substantially vertical direction, and the lower wall portion 203b is formed in an inclined shape slightly downward to the right, and the front side is recessed backward as shown in FIG. 32, and the recessed portion thereof is formed. A decorative cover 204 is attached so as to substantially fill the space. At least a part of the decorative cover 204 is a colorless transparent or colored transparent light emitting lens portion 204a, and the LED substrate 206 is arranged inside the light emitting lens portion 204a. An uneven diffused reflection portion is provided on the inner surface side of the light emitting lens portion 204a.

For example, two types of LEDs 205a and 205b are arranged on the front side of the LED substrate 206. One or more LEDs 205a are arranged at positions corresponding to the outer circumference of the "butterfly" formed together with the frame movable body 156 and the board movable body 371, and like the LED 194a, it is possible to emit light in a single color such as white. It has become. The LEDs 205b are arranged substantially evenly on the left side of the LED 205a, for example, so as to correspond to the internal region of the "butterfly", and can emit light in, for example, multiple colors like the LED 194b.

Further, as shown in FIG. 32, the front wall portion 196 of the unit main body portion 152 is formed with a movable body mounting hole 207 substantially in the center thereof, and a space behind the movable body mounting hole 207 in the unit main body portion 152 is formed. The frame movable body accommodating portion 208 is provided, and the movable main body portion 155 of the movable portion 154 is accommodated in the frame movable body accommodating portion 208 from the front side of the unit main body portion 152 via the movable body mounting hole 207 so as to be retractable. ing.

As shown in FIGS. 29 and 32, a pair of first slide guides 157 are provided on both the left and right sides of the frame movable body accommodating portion 208 in the unit main body portion 152, and a pair of first slide guides 157 are provided on the upper left and right sides of the frame movable body accommodating portion 208. Two slide guides 159 are arranged respectively. The first slide guide 157 is provided on a pair of left and right first guide bases 209 made of, for example, synthetic resin, and is formed in a long hole shape that descends forward along the slide operation direction. The first guide rollers 158 provided individually are engaged so as to be slidable or rollable.

Further, the second slide guide 159 is a pair of left and right inclined surfaces formed along the slide operation direction on the lower surface side of the second guide base 210 made of, for example, synthetic resin, and one left and right on the movable main body portion 155 side. The second guide rollers 160 provided one by one are substantially in contact with each other in a state where they can slide or roll from the lower side.

As described above, the movable portion 154 has the origin position (FIG. 27) due to the movement of the first guide roller 158 along the first slide guide 157 and the second guide roller 160 along the second slide guide 159. (Indicated by a solid line) and the forward position (indicated by a two-dot chain line in FIG. 27), it is possible to move in the slide operation direction.

The first guide base 209 and the second guide base 210 are supported by the unit main body portion 152 via a guide base frame 211 made of sheet metal. The guide base frame 211 has an upper plate portion 211a arranged substantially parallel to the lower side of the upper wall portion 195 of the unit main body portion 152, and left and right arranged downward along both left and right edges of the upper plate portion 211a. A pair of side plate portions 211b are provided, and a first guide base 209 is provided on, for example, the outer surface side of the left and right side plate portions 211b, and a second guide base 210 is provided on the inner surface side of the left and right side plate portions 211b and on the lower surface side of the upper plate portion 211a. Each is attached detachably.

Further, in the unit main body portion 152, a drive base plate 212 is arranged below the frame movable body accommodating portion 208, and a slide for guiding the driven portion 161 on the movable portion 154 side on the drive base plate 212. The operation of the guide 213, the spring 214 for urging the movable portion 154 to one side in the slide operation direction, for example, the forward position side, the driving force transmitting means 215 for transmitting the driving force of the driving means 140 to the movable portion 154 side, and the movable portion 154. A frame movable body position detecting means 216 or the like for detecting a position is arranged. As shown in FIGS. 29 and 32, the drive base plate 212 corresponds to a range from the lower side of the frame movable body accommodating portion 208 to the left and right sides thereof, for example, the right side, and is slightly along the slide operation direction, for example. It is arranged in an inclined shape that descends forward, and is detachably fixed to the unit main body 152.

As shown in FIGS. 33 to 35, the slide guide 213 is formed in a long hole shape in the front-rear direction corresponding to the driven portion 161 on the movable portion 154 side, and the driven portion 161 is inserted downward. The spring 214 is an elongated coil spring, which is arranged on one side on the left and right sides of the slide guide 213, for example, on the left side, one end side thereof is fixed to, for example, the drive base plate 212 near the rear end side of the slide guide 213, and the other end side is The movable main body portion 155 is fixed to, for example, the rear end side, and the intermediate portion is wound around a pulley 217 arranged near the front end side of the slide guide 213, so that the movable main body portion 155 is arranged in a substantially U-shape in a plan view.

As shown in FIGS. 33 to 35, the driving force transmitting means 215 includes a driving arm 218, a cam gear 219, an idle gear 220, a driving gear 221 and the like. In addition to the drive shaft 140a of the drive means 140, the rotation shafts of the drive arm 218, the cam gear 219, the idle gear 220, and the like are all arranged in a direction orthogonal to the plate surface of the drive base plate 212.

The drive arm 218 is arranged, for example, on the lower surface side of the drive base plate 212, one end side thereof is rotatably supported by the arm shaft 218a, and the drive connecting portion 218b provided on the other end side drives the driven portion 161. The arm 218 is engaged in a slidable state in the longitudinal direction. The arm shaft 218a is arranged on the right side of the slide guide 213 at a substantially central portion in the front-rear direction. A guide hole 218c is formed in the intermediate portion of the drive arm 218 along the longitudinal direction. In this way, the drive arm 218 can swing between the origin drive position on the rear side and the forward drive position on the front side around the arm shaft 218a, and the movable portion 154 is moved via the driven portion 161 accordingly. It slides between the origin position and the forward position along the slide guide 213.

Further, the drive arm 218 is integrally provided with, for example, a detected portion 218d projecting outward in the radial direction at an end portion on the arm shaft 218a side, for example. Further, on the lower surface side of the drive base plate 212, a frame movable body position detecting means 216 made of a photo sensor or the like is arranged corresponding to the detected portion 218d. In the present embodiment, two frame movable body position detecting means 216, an origin position detecting means 216a and a forward position detecting means 216b, are provided, and when the movable portion 154 is at the origin position, the origin position detecting means 216a is a movable portion. When the 154 is in the forward position, the forward position detecting means 216b detects the detected portion 218d, respectively.

The drive arm 218 is elastically urged by the spring 222, for example, toward the rear, that is, toward the origin drive position side. As described above, the movable portion 154 of the present embodiment is urged to the forward position side by the spring 214 and to the origin position side by the spring 222 via the drive arm 218, but is attached to the origin position side by the spring 222. The urging force to the forward position side by the spring 214 is larger than the force.

The cam gear 219 is arranged, for example, on the upper surface side of the drive base plate 212, and is provided with a cam shaft 219a at a predetermined position near the outer peripheral portion. The camshaft 219a penetrates the arc-shaped insertion hole 223 provided in the drive base plate 212 downward, and is slidably engaged with the guide hole 218c of the drive arm 218 under the drive base plate 212. There is. The central shaft 219b of the cam gear 219 is arranged between the slide guide 213 and the arm shaft 218a. The cam gear 219 rotates within a range of about 180 degrees between the first rotation position shown in FIG. 34 and the second rotation position shown in FIG. 35, so that the drive arm 218 has an origin drive position and a forward drive position. Swing between. When the cam gear 219 is in the first rotation position and the drive arm 218 is in the origin drive position, the direction connecting the central shaft 219b on the cam gear 219 side and the camshaft 219a as shown in FIG. 34 (b). Since the directions of the guide holes 218c of the drive arm 218 are substantially orthogonal to each other, the drive arm 218 is locked to the origin drive position against the urging force of the spring 214.

The idle gear 220 is, for example, a two-stage gear integrally including a first gear 220a and a second gear 220b in the axial direction, and is arranged on the upper side of, for example, a drive base plate 212 in a state where the second gear 220b is meshed with the cam gear 219. Has been done.

For example, a screw fixing base 224 is projected on the upper side of the drive base plate 212, and a drive means 140 made of a stepping motor or the like is arranged on the screw fixing base 224 with the drive shaft 140a facing downward. There is. A drive gear 221 is fixed to the drive shaft 140a of the drive means 140, and the drive gear 221 meshes with the first gear 220a of the idle gear 220.

When the drive means 140 operates in the positive direction while the movable portion 154 is in the origin position (FIG. 34), the drive arm 218 is directed from the origin drive position to the forward drive position via the drive gear 221 and the idle gear 220 and the cam gear 219. The movable portion 154 moves forward from the origin position toward the forward position, and the origin position detecting means 216a changes from ON to OFF. Then, when the drive arm 218 reaches the forward drive position and the movable portion 154 reaches the forward position (FIG. 35), the forward position detecting means 216b changes from OFF to ON and the drive means 140 stops. When the driving means 140 operates in the opposite direction from that state, the movable portion 154 returns to the origin position through the process opposite to the above (FIG. 34). As described above, in the frame movable effect means 153 of the present embodiment, by operating the drive means 140 in both forward and reverse directions, the frame movable body 156 is moved forward between the origin position and the forward position on the front side thereof. It can be moved back and forth along the slide movement direction.

Further, the frame movable body 156 can rotate around an axis in a substantially front-back direction (sliding operation direction). For example, when packing for transportation, the pressing operation unit 165a of the rotation lock lever 165 is pressed to lock the frame movable body 156. By releasing, the rotation can be performed from the origin rotation position (FIG. 36 (a)) to the retracted rotation position (FIG. 36 (c)) via the intermediate rotation position (FIG. 36 (b)). The frame movable body 156 protrudes greatly upward from the upper wall portion 195 of the unit main body portion 152 at the origin rotation position shown in FIG. 36 (a), but the entire frame movable body 156 protrudes upward from the upper wall portion 195 of the unit main body portion 152. It fits below the upper wall portion 195 and can be packed compactly. When the package is unpacked, the lock is released by pressing the pressing operation unit 165a of the rotation lock lever 165 again to release the lock from the retracted rotation position (FIG. 36 (c)) to the intermediate rotation position (FIG. 36 (b). )), And it may be rotated to the origin rotation position (FIG. 36 (a)). Further, the frame movable body 156 may be driven by the drive means 140 on condition that the frame movable body 156 is determined to be in the origin rotation position based on the detection signal of the rotation position detection means 166. good.

As shown in FIGS. 6, 17, and 32, the upper wall portion 195 is formed with, for example, a notch portion 225 on the front edge side thereof, and when the frame movable body 156 is at the origin position, the rotation lock lever 165 is formed. The pressing operation portion 165a is exposed to the upper side through the notch portion 225. In this way, in order to prevent an operation due to mischief, the pressing operation unit 165a of the rotation lock lever 165 is arranged behind the frame movable body 156, and when the frame movable body 156 is in the origin rotation position, the frame movable body 156 It is hidden behind and invisible from the front.

As shown in FIGS. 26 to 28, the vertical unit portion 142 includes a unit main body portion 231, an operation effect means 232 arranged at substantially the center of the unit main body portion 231 in the vertical direction, and a unit main body portion 231 for example. It is provided with a blowing means 233 arranged on the upper side.

As shown in FIGS. 37 to 41, the operation effect means 232 is an operation for driving the operation handle 234, the slide support means 235 for holding the operation handle 234 so as to be movable in the front-rear direction, and the operation handle 234 in the front-rear direction. The handle driving means 236, the driving force transmitting means 237 that transmits the driving force of the operating handle driving means 236 to the operating handle 234, the operating handle position detecting means 238 that detects the operating position of the operating handle 234, and the slide supporting means 235. The operation handle base 239 and the like for supporting the operation handle driving means 236 and the like are provided.

In the present embodiment, the origin position detecting means 238a for detecting that the operation handle 234 is in the origin position, the front end position detecting means 238b for detecting that the operation handle 234 is in the front end position, and the operation handle 234 are in the pushing position. Three types of operation handle position detecting means 238 are provided with the pushing position detecting means 238c for detecting the presence in the above. The origin position, front end position and push-in position regarding the operation handle 234 will be described later.

As shown in FIGS. 37 to 39, the operation handle 234 has a cylindrical handle body portion 241 arranged in a substantially front-back direction, for example, a substantially cylindrical handle body portion 241 and a handle arranged on the front end side of the handle body portion 241. It is provided with an operation unit 242. On the rear end side of the handle main body 241, for example, a pair of slide members 243a and 243b are arranged on both left and right sides of the inside, and a driven portion 244 is arranged at a predetermined position (here, the upper part) on the circumference.

The left and right slide members 243a and 243b are detachably fixed to the inner surface side of the handle main body 241. For example, on the facing surface side thereof, a guide roller 246 corresponding to the slide guide 245 on the slide support means 235 side is provided. A plurality of slide protrusions (two in this case) are arranged along the front-rear direction, and for example, slide protrusions 248 are integrally provided on one of the upper and lower sides as shown in FIGS. 40 to 42. The slide protrusion 248 is formed with a slide hole 248a through which the slide shaft 247 on the slide support means 235 side is inserted.

The driven portion 244 is a portion that receives the driving force from the operation handle driving means 236, and is from the outer peripheral side of the rear end portion (here, the upper side) of the handle main body portion 241 to the central axis side (here, the lower side) of the handle main body portion 241. ), And a bush 244b mounted on the driven shaft 244a.

The handle operation portion 242 is a portion gripped by the player, and is attached to the front end side of the handle main body portion 241 so as to project to the outer peripheral side of the handle main body portion 241 on the entire circumference thereof, and the rear opening / closing cover 418 is attached. And a front cover 250 that covers the front side of the opening / closing cover 418, and an LED board 251 or the like is arranged inside. At least a part of the front cover 250 constitutes a light emitting lens portion. The handle operation portion 242 is not perpendicular to the axial direction (front-back direction) of the handle main body portion 241 but is arranged slightly diagonally to the left and forward toward the player.

Further, on the front end side of the operation handle 234, for example, one or a plurality (two in this case) vibration means 252 are arranged inside the handle operation portion 242 or the handle main body portion 241. By operating the vibrating means 252, the handle operating portion 242 vibrates.

As shown in FIGS. 37, 40, 41 and the like, the slide support means 235 includes a pair of left and right guide members 253a and 253b, and a connecting member 254 and the like for connecting the left and right guide members 253a and 253b.

The guide members 253a and 253b are elongated in the front-rear direction and face each other at regular intervals to the left and right. It has been inserted. The left and right guide members 253a and 253b each have slide guides 245 formed in a long hole shape in the front-rear direction, and the slide guides 245 have two guide rollers 246 provided on the left and right sides in the handle body 241. Engages so that it can slide or roll.

Further, slide shafts 247 are arranged in the front-rear direction in the vicinity of the left and right slide guides 245, and both front and rear ends thereof are supported by guide members 253a and 253b. The slide shaft 247 is inserted into a slide hole 248a provided in the slide protrusion 248 of the slide members 243a and 243b. The guide members 253a and 253b are reinforced by guide sheet metals 255a and 255b, respectively.

In this way, the operation handle 234 is pushed in by the guide rollers 246 of the slide members 243a and 243b moving along the slide guide and the slide protrusions 248 of the slide members 243a and 243b moving along the slide shaft 247. It is possible to slide and move in the front-rear direction between the position and the front end position (FIGS. 39 and 41) on the front side of the position. The origin position of the operation handle 234 (FIGS. 38 and 40) is set slightly in front of the push position between the push position and the front end position, and the operation handle 234 is set at least between the origin position and the push position. , Is elastically urged forward by the spring 256. The spring 256 is a coil spring having a predetermined length, and is inserted behind the slide protrusion 248 on the slide shaft 247.

The connecting member 254 connects the guide members 253a and 253b to the left and right, and is arranged on the front end side of the guide members 253a and 253b.

Further, for example, the front end position detecting means 238b is arranged on the front end side of the guide members 253a and 253b, and the pushing position detecting means 238c is arranged on the rear end side. The front end position detecting means 238b is, for example, a photo sensor, which is arranged on the lower side of the connecting member 254, for example, and when the operation handle 234 comes to the front end position, it is detected on the lower side of the rear end portion of the handle main body portion 241. The unit 257 is detected. Further, the push-in position detecting means 238c is also, for example, a photo sensor, for example, arranged on the lower side of the rear end portion of one guide member 253a, and when the operation handle 234 comes to the push-in position (FIG. 42), for example, one slide member. The detected portion 258 provided on the 243a is detected.

Further, on the front side of the operation handle base 239, a handle cover 259 formed in a tubular shape in the front-rear direction that covers the handle body portion 241 of the operation handle 234 is attached.

As shown in FIGS. 37 to 39, the driving force transmitting means 237 includes a feed screw 261 for moving the driven portion 244 of the operation handle 234 back and forth, and a feed screw gear that rotates integrally with the feed screw 261. It is composed of 262, a drive gear 263 fixed to the drive shaft 236a of the operation handle drive means 236, and a gear train 264 arranged between the drive gear 263 and the feed screw gear 262.

The lead screw 261 has a long rod shape in the front-rear direction and is arranged between the left and right guide members 253a and 253b. It is supported in a good condition. A feed screw gear 262 that rotates integrally with the feed screw 261 is arranged on the rear end side of the feed screw 261. A spiral feed groove 265 is formed on the outer peripheral surface of the feed screw 261, and the driven portion 244 of the operation handle 234 is slidably engaged with the feed groove 265, for example, from above. As a result, when the feed screw 261 rotates, the driven portion 244 is guided by the feed groove 265 and moves in the front-rear direction, and the operation handle 234 moves in the front-rear direction between the origin position and the front end position accordingly.

Further, a widening portion 266 having a groove width wider than that of other portions is provided at the rear end portion of the feed groove 265. The widened portion 266 is widened to the rear side, and the play in the front-rear direction of the driven portion 244 is larger than that of the other portions. The position of the operation handle 234 when the driven portion 244 is on the front end side in the widening portion 266 is the origin position (FIG. 38), and the position of the operation handle 234 when the driven portion 244 is on the rear end side is the push-in position (FIG. 38). 42). Since the operation handle 234 is urged to the origin position side (front side) by the spring 256 at least between the origin position and the push-in position, the operation handle 234 is on the front side even if the driven portion 244 reaches the widening portion 266. However, when the player pushes the spring 256 backward against the urging force of the spring 256, the operation handle 234 can move to the pushing position.

The operation handle drive means 236 is configured by a stepping motor or the like, and is arranged above, for example, the feed screw 261. For example, the operation handle drive means 236 is mounted on the front side of the operation handle base 239 with the drive shaft 236a facing the rear side. .. A drive gear 263 is mounted on the drive shaft 236a. The gear train 264 arranged between the drive gear 263 and the feed screw gear 262 is composed of, for example, a plurality of (five here) gears, each of which is rotatably mounted on the front side of the operation handle base 239. There is.

Further, the origin position detecting means 238a is arranged on the front side of the operation handle base 239. The origin position detecting means 238a is, for example, a photo sensor so as to detect the detected portion 269 when the operation handle 234 reaches the origin position. The detected portion 269 is provided so as to project near the outer peripheral portion of the sensor gear 270 that is interlocked with the feed screw 261, for example. The sensor gear 270 is arranged, for example, on the lower side of the feed screw 261 and on the front side of the operation handle base 239, and is interlocked with the feed screw gear 262 via the idle gear 271.

As described above, in the operation effect means 232 of the present embodiment, the operation handle driving means 236 is operated in both forward and reverse directions to move the operation handle 234 to the origin position (shown by a solid line in FIG. 27) and to the front side thereof. It can be moved back and forth between the front end position (shown by the alternate long and short dash line in FIG. 27), and the operating handle 234 can be vibrated by operating the vibrating means 252. Further, in the state where the operation handle 234 is in the origin position, as shown in FIG. 42, the player can push the operation handle 234 to the push-in position (shown by the two-dot chain line in FIG. 27).

As shown in FIGS. 26 to 28, etc., the unit main body portion 231 forms a lower surface with an upper wall portion 281 arranged substantially horizontally, a left wall portion 282 and a right wall portion 283 forming each of the left and right side surfaces. The lower wall portion 284, the front decorative cover 285 that covers the front side, and the base sheet metal 286 on the back side are formed in a substantially box shape. The operation effect means 232 is arranged in the unit main body portion 231 in a state where the front portion of the operation handle 234 and the handle cover 259 covering the operation handle 234 is projected forward through the opening 287 formed in the front decorative cover 285. For example, the operation handle base 239 is fixed to the front side of the base sheet metal 286.

Further, in the unit main body 231 as shown in FIG. 26, for example, a blower means 233 is arranged on the upper side of the operation handle 234. The blower means 233 is a sirocco fan or the like having an impeller built in the blower case 233a, and can blow air from the blower port 288 formed in the front decorative cover 285 toward, for example, the handle operation portion 242 of the operation handle 234. It has become.

Further, at least a part of the front decorative cover 285 constitutes a light emitting lens portion, and on the rear side thereof, for example, LED substrates 289 are arranged above and below the operation handle 234.

The unit main body portion 152 of the horizontal unit portion 141 and the unit main body portion 231 of the vertical unit portion 142 are connected to each other by a sheet metal unit reinforcing plate 143 arranged on the back side thereof, and one second upper unit 42b. Consists of.

As shown in FIGS. 17, 21, and 22, an opening 291 corresponding to the speaker mounting protrusion 111b for the upper speaker 30b is provided on the back surface side of the second upper unit 42b. The speaker mounting protrusion 111b can be freely inserted and removed from the opening 291, and the upper inner wall 291a of the opening 291 can be placed on the upper surface of the receiving portion 114d of the speaker mounting protrusion 111b. Further, as shown in FIGS. 17 and 20, the speaker mounting protrusion 111a has a receiving portion 114c for the second upper unit 42b, and the end portion of the second upper unit 42b on the speaker mounting protrusion 111a side has a receiving portion 114c. An overlapping portion 292 that overlaps the receiving portion 114c from above is provided integrally with, for example, the upper wall portion 195.

If such a configuration is adopted, when the second upper unit 42b is mounted on the front side of the door base 25, the speaker mounting protrusion 111b is used as a guide for the opening 291 and the speaker mounting protrusion 111a is used as the overlapping portion 292. It is possible to work while using each as a guide, and the second upper unit 42b can be easily arranged at a predetermined mounting position on the door base 25 side.

Further, after the opening 291 and the overlapping portion 292 of the second upper unit 42b correspond to the left and right speaker mounting protrusions 111a and 111b, the second upper unit 42b is connected to the door base 25 via the speaker mounting protrusions 111a and 111b. It is possible to leave it on the side and perform alignment and the like while supporting substantially the entire load on the second upper unit 42b side by the speaker mounting protrusions 111a and 111b. Therefore, it is not necessary for the worker to constantly support the load of the second upper unit 42b during the mounting work of the second upper unit 42b, and the burden on the worker at the time of mounting can be reduced.

As shown in FIG. 17, the first positioning means 144 is arranged on the upper tip side (left end side) of the second upper unit 42b, and the second positioning means 145 is arranged on the side lower end side of the second upper unit 42b. There is. As shown in FIG. 20 and the like, the first positioning means 144 is positioned in the overlapping portion 292 of the positioning recess 144a formed in the receiving portion 114c of the speaker mounting protrusion 111a and the end portion of the second upper unit 42b. It is provided with a protrusion 144b, and the positioning protrusion 144b and the positioning recess 144a make it possible to position the upper tip side of the second upper unit 42b in the front-rear and left-right directions.

The positioning recess 144a and the positioning protrusion 144b are formed in an L-shape in a plan view on the inner portion of the speaker mounting protrusion 111a. The first positioning means 144 may be provided with a positioning recess 144a in the overlapping portion 292 and a positioning protrusion 144b in the receiving portion 114c. Further, the first positioning means 144 may have another structure.

As shown in FIGS. 43A and 43B, the second positioning means 145 is bent at the lower end side of the positioning hole portion 145a formed in the door base 25 or the vertical reinforcing member 33b thereof and the unit reinforcing plate 143. The positioning protrusion 145b is provided, and the positioning hole 145a and the positioning protrusion 145b make it possible to position the lower end side of the side portion of the second upper unit 42b in the left-right direction with respect to the door base 25.

As shown by the alternate long and short dash line in FIG. 43B, there is a vertical margin required for engaging and disengaging the locking means 146 to 148 between the positioning hole portion 145a and the positioning protrusion portion 145b. The second positioning means 145 may be provided with a positioning hole portion 145a in the unit reinforcing plate 143 and a positioning protrusion portion 145b in the door base 25. Further, the second positioning means 145 may have another structure.

Therefore, when mounting the second upper unit 42b, the second upper unit 42b is doord by a plurality of first to third locking means 146 to 148 and first to third fixing means 149 to 151 arranged in the intermediate portion. Although it is fixed to the base 25, by providing the first and second positioning means 144 and 145 on both ends of the second upper unit 42b, the left and right positions of both ends of the second upper unit 42b can be reliably regulated. can. Therefore, there is an advantage that it is possible to prevent the position shift of the lower end side of the second upper unit 42b due to the mischief of the player or the like.

As shown in FIGS. 44 to 46, the first to third locking means 146 to 148 are provided at three locations: the upper tip side (left end side) of the second upper unit 42b, the upper end side of the side portion, and the middle portion of the side portion. The second is provided with locking claws 146a to 148a integrally provided downward on the unit reinforcing plate 143 and hole-shaped locking portions 146b to 148b provided on the vertical reinforcing member 33b. The locking means 147 is provided with a clamping means 293.

The third locking means 148 has the maximum protrusion length of each of the locking claws 146a to 148a of the first to third locking means 146 to 148, and the first locking means 146 and the second locking means 147 have the maximum protrusion length. It is getting shorter in order. That is, the engagement lengths 146c to 148c between the locking claws 146a to 148a of the first to third locking means 146 to 148 and the locking portions 146b to 148b are such that the engagement length 148c> the engagement length 146c>. The engagement length is 147c.

The engagement lengths 146c to 148c of the first to third locking means 146 to 148 are set to the engagement length 148c> the engagement length 146c> the engagement length 147c, and the first to third engagements are set. When the locking claws 146a to 148a of the stopping means 146 to 148 are engaged with the locking portions 146b to 148b to lock the second upper unit 42b to the door base 25, the third locking means 148, the first engagement The first to third locking means 146 to 148 can be sequentially engaged in the order of the stopping means 146 and the second locking means 147. Therefore, the locking claws 146a to 148a can be easily engaged with the locking portions 146b to 148b as compared with the case where the first to third locking means 146 to 148 are simultaneously engaged.

Any one of the engagement lengths 146c to 148c of the first to third locking means 146 to 148 may be maximized, and the other two engagement lengths may be substantially the same. For example, the engagement length 148c of the third locking means 148 is maximized, and the engagement lengths 146c and 147c of the first and second locking means 146 and 147 are substantially the same length shorter than the engagement length 148c. It is also possible to do. In this case, when mounting the second upper unit 42b, each of the locking means 146 to 148 sequentially from the lower third locking means 148 to the upper first and second locking means 146 and 147. Will be engaged.

As shown in FIGS. 46A and 46B, the second locking means 147 is compared with other locking means 146 and 148 by arranging a plurality of locking claws 147a and locking portions 147b on the left and right. The clamp means 293 is provided so as to tighten the locking claw 147a after engaging with the locking portion 147b toward the locking portion 147b.

The clamping means 293 has a plan-view U-shaped bracket 293a fixed to the vertical reinforcing member 33b under the locking portion 147b, and a plan-view inverted U-shape pivotally supported around the support shaft 293b by the bracket 293a. The clamp lever 293c is provided with a U-shaped clamp tool 293e which is connected to the middle of the clamp lever 293c by a connecting shaft 293d and engages with the upper engaging portion 147d of the locking claw 147a from above. The clamp lever 293c is provided with an operation unit 293f on the free end side thereof.

When mounting the second upper unit 42b, after engaging the locking claws 146a to 148a of the first to third locking means 146 to 148 with the locking portions 146b to 148b, the clamping tool 293e of the clamping means 293 is engaged. It is engaged with the engaging portion 147d of the stop claw 147a. Then, the clamp lever 293c is rotated downward around the support shaft 293b, and the connecting shaft 293d is on the vertical reinforcing member 33b side from the line connecting the engagement position of the clamp tool 293e with the locking claw 147a and the support shaft 293b. When it comes into contact with the vertical reinforcing member 33b, the locking claw 147a of the second locking means 147 is tightened toward the engaging portion 147b in the engaging direction. Therefore, the locking claw 147a of the second locking means 147 is stronger than the other first and third locking means 146 and 148.

Therefore, it is possible to prevent mechanical vibration of the second upper unit 42b as compared with the case where the engaging portion 147d of the locking claw 147a of the second locking means 147 is only engaged from above, and the screw. It is possible to reliably prevent slackening and the like due to vibration of the first to third fixing means 149 to 151 of the formula.

As shown in FIGS. 6 and 7, the first to third fixing means 149 to 151 are arranged at three locations corresponding to the upper tip side (left end side) and the upper and lower end sides of the side portion of the second upper unit 42b. Has been done. As shown in FIGS. 19, 47, and 48, the first to third fixing means 149 to 151 have screw holes 149a to 151a formed in the unit reinforcing plate 143 and a door base 25 from the lateral reinforcing member 32 side. The unit reinforcing plate 143 is attached to the door base 25 side from the back side by screwing the fixing screws 149c to 151c into the screw holes 149a to 151a. It is designed to be tightened and fixed.

As shown in FIG. 19, screw insertion portions 111c are formed in the front-rear direction on the second upper unit 42b side of the speaker mounting protrusions 111a on the hinges 13 and 26 sides, and screws are inserted from the unit reinforcing plate 143 side. A fixing screw 149c is inserted through the portion 111c. The fixing screw 149c is screwed into a screw hole 149a formed at the tip of the bent portion 143a of the unit reinforcing plate 143 on the rear side of the screw insertion portion 111c.

The first to third fixing screws 149c to 151c are inserted across the horizontal reinforcing member 32 or the vertical reinforcing member 33b and the support members 149d to 151d fixed to the horizontal reinforcing member 32 or the vertical reinforcing member 33b. Further, a retaining member 149e to 151e such as a snap ring is provided between the horizontal reinforcing member 32 or the vertical reinforcing member 33b and the support members 149d to 151d. The outer circumference of the fixing screws 149c to 151c on the tip end side is chamfered so as to be easily inserted into the screw holes 149a to 151a and to prevent injury by catching fingers or the like.

On the front frame 3 side, as shown in FIG. 48, a step portion 3a corresponding to the operation portions 150b and 151b of the fixing screws 150c and 151c is inside the outer peripheral wall 3b. As shown in FIG. 48B, when the fixing screws 150c and 151c are tightened, the stepped portion 3a also has the fixing screws 150c and 151c even when the front door 4 is closed to the front frame 3 side. The front door 4 can be closed to the front frame 3 side without interfering with the operation units 150b and 151b.

However, when the front door 4 is to be closed to the front frame 3 side without tightening the fixing screws 150c and 151c, the stepped portion 3a has the fixing screws 150c and 151c as shown in FIG. 48A. There is a gap between the front frame 3 and the front door 4 due to interference with the operation units 150b and 151b of the above, and the door cannot be closed. As a result, when the second upper unit 42b is mounted, a mistake may occur in which the front door 4 is closed to the front frame 3 side while the fixing screws 150c and 151c of the second and third fixing means 150 and 151 are forgotten to be tightened. Can be prevented. The unit reinforcing plate 143 is integrally formed by punching a sheet metal material into a substantially L-shape in front view, but it may be divided into a plurality of pieces.

As shown in FIG. 28, each harness (not shown) pulled out from the movable portion 154, the operation effect means 232, the blower means 233, etc. of the second upper unit 42b has, for example, the inner relay board 294 in the horizontal unit portion 141. It is integrated into the unit side harness 295 via. The unit-side harness 295 is pulled out to the rear side of the front door 4 through the opening 296 (FIG. 28) of the unit reinforcing plate 143 and the opening 297 (FIG. 49) on the door base 25 side formed on the rear side. ..

As shown in FIG. 49, on the rear side of the upper base portion 27 of the door base 25, a long upper relay board 298 in the left-right direction is provided adjacent to the opening 297 arranged in the substantially central portion in the left-right direction. .. The upper relay board 298 is arranged in the accommodating recess 299 formed in the narrow portion of the upper base portion 27. Two board-side connectors 301 and 302 are mounted rearward on the upper relay board 298, and the connector 295a of the unit-side harness 295 is detachably connected to one of the board-side connectors 301. ..

The connector 303a of the unit relay harness 303 is detachably connected to the other board-side connector 302. The relay harness 303 for the unit was pulled out in the left-right direction along the rear upper end of the upper base portion 27 of the door base 25 to the end opposite to the hinges 13 and 26 via the vicinity of the upper side of the upper speaker 30b and the like. Later, it is pulled out from the opening 304 on the end side to the front side of the door base 25.

As shown in FIG. 18, the unit relay harness 303 pulled out from the opening 304 to the front side is located near the upper side of the intermediate speaker 31b along the edge of the vertical base portion 28b opposite to the hinges 13 and 26 of the door base 25. It is arranged in the vertical direction and connected to the lower relay board (not shown) side of the lower base portion 29 side via the inside of the speaker cover 305b of the intermediate speaker 31b. The speaker covers 305a and 305b are arranged around the front side of the intermediate speakers 31a and 31b.

As shown in FIGS. 8 and 18, the unit relay harness 303 arranged in the vertical direction on the front side of the vertical base portion 28b of the door base 25 is covered with a protective cover 306 in substantially the entire vertical direction. The protective cover 306 has an L-shaped cross section, is arranged along the outer peripheral wall 306a of the vertical base portion 28b, and is detachably fixed to the door base 25 by a fixing tool such as a screw.

As shown in FIG. 49, two board-side connectors 308a and 308b are provided at the upper end of the LED board 131 in the first upper unit 42a so as to correspond to the opening 307 of the door base 25. Harnesses 309a and 309b detachably connected to the board-side connectors 308a and 308b are connected to the LED boards 126a and 126b on the upper speakers 30a and 30b side via the rear side of the upper base portion 27 of the door base 25. The two board-side connectors 308a and 308b are connected to the lower relay board or the like from the lower end side via the wiring pattern of the LED board 131.

On the rear side of the vertical base portion 28a on the hinges 13 and 26 side of the door base 25, a speaker relay board 310 is provided in the vicinity of the upper speaker 30a, and the speaker side harnesses 311a and 311b from the upper speakers 30a and 30b are provided. , The speaker relay harness 312 on the speaker drive source side is connected via the speaker relay board 310.

The speaker relay board 310 is provided with three board-side connectors 313a, 313b, 314, and the two board-side connectors 313a, 313b are provided with speaker-side harnesses 311a, 311b from the upper speakers 30a, 30b, respectively. A speaker relay harness 312 is detachably connected to one board-side connector 314. As shown in FIG. 8, the speaker relay harness 312 is arranged in the vertical direction along the vertical reinforcing member 33a attached to the vertical base portion 28a on the hinges 13 and 26 sides of the door base 25, and is rearward by the protective cover 315. Protected from the side.

The speaker relay harness 312 and the protective cover 315 are arranged in the vertical direction between the vicinity of the upper speaker 30a and the vicinity of the lower end of the lower base portion 29. The protective cover 315 has an L-shaped or U-shaped cross section that covers the relay harness 312 for speakers, is arranged in the vertical direction along the vertical reinforcing member 33a, and is attached to and detached from the back side of the door base 25 by a fixing tool such as a screw. It is fixed freely.

By providing the speaker relay harness 312 on the back side of the vertical base portion 28a on the hinges 13 and 26 sides of the door base 25 in this way, the speaker relay harness is provided regardless of the first upper unit 42a on the front side of the vertical base portion 28a. Maintenance and inspection of 312 can be easily performed.

On the rear side of the protective cover 315, as shown in FIG. 50, a rib-shaped insertion blocking portion 315a for preventing the insertion of an unauthorized member into the inside from between the front door 4 and the front frame 3 protrudes rearward. It is provided in. That is, on the hinges 13 and 26 sides of the front frame 3, an outer protrusion 316c and an inner protrusion 316d are provided in the vertical direction on the front wall portion 316b of the main body frame portion 316a, and the back side of the front wall portion 316b. A sheet metal reinforcing member 316e is provided along the outside of the outer hinge portion 316c. The reinforcing member 316e has an inner bent portion 316f that bends inward from the front end.

The vertical reinforcing member 33a on the hinges 13 and 26 sides of the door base 25 has a rear bending portion 33a1 that bends rearward along the inner peripheral wall portion 317a of the door base 25 and a rear end of the rear bending portion 33a1. An outer bent portion 33a2 that bends outward is provided over a substantially total length in the vertical direction.

Then, between the front door 4 and the front frame 3, when the front door 4 is closed toward the front frame 3 around the hinges 13 and 26, the outer bent portion 33a2 and the inner peripheral wall portion 317a of the front door 4 are formed. The inner bent portion 316f of the reinforcing member 316e is inserted between them to form a bent maze 318 that prevents the insertion of the unauthorized member. An outer peripheral wall portion 317c is provided on the outside of the inner peripheral wall portion 317a via an inclined wall portion 317b at the rear end, and the rear end of the light emitting decorative cover 132 is in contact with the front end of the outer peripheral wall portion 317c.

The rear wall portion 315b of the protective cover 315 is equal to or protrudes rearward from the outer bent portion 33a2 of the vertical reinforcing member 33a, and then the insertion blocking portion 315a protruding rearward from the wall portion 315b has an insertion blocking portion 315a. It is arranged in the vertical direction in the entire range from the vicinity of the upper speakers 30a and 30b to the vicinity of the lower end of the lower base portion 29. The insertion blocking portion 315a has a rib-like shape so as to approach the inside of the inner protrusion portion 316d of the front frame 3 when the front door 4 is closed toward the front frame 3. The attachment portion 315c of the protective cover 315 is attached to the door base 25 by a fixing tool such as a screw.

By providing the rib-shaped insertion blocking portion 315a projecting rearward from the rear wall portion 315b of the protective cover 315 inside the vertical reinforcing member 33a in this way, the illegal member is temporarily inserted through the bending maze 318. Even if such a situation occurs, the insertion blocking portion 315a and the internal protrusion 316d can prevent further entry of unauthorized members. Further, since the insertion blocking portion 315a is provided on the protective cover 315, it can be easily carried out without the need to significantly change the structure or the like on the front door 4 side.

As shown in FIGS. 6, 7, 19, 22, 22, and the like, the upper base portion 27 of the door base 25 has upper speakers 30a, 30b, harnesses 295,309a, 309b, 311a, 311b, and a relay board 310 for speakers. A pair of left and right upper back covers 319a and 319b for covering a part or all of the above from the back side are detachably provided. The upper back cover 319a on the hinges 13 and 26 sides is provided with a notch 319a1 corresponding to the first fixing means 149 so that the operating portion 149b of the fixing screw 149c of the first fixing means 149 can be operated from the back side. There is. The upper back cover 319b on the opposite side of the hinges 13 and 26 is provided between the board side connector 302 of the upper relay board 298 and the clamping means 293 so that the clamping means 293 can be operated.

By providing the upper back covers 319a and 319b in this way, the door of the front door 4 is compared with the case where the upper speakers 30a and 30b, the harness 295,309a, 309b, 311a and 311b and the speaker relay board 310 are exposed. The appearance of the upper part of the back side of the base 25 can be improved.

On the other hand, the substrate side on the upper relay board 298 side to which the opening 297 formed in the upper base portion 27 in the left-right direction, that is, the opening 297 formed in the upper base portion 27 and the unit side harness 295 drawn out from the opening 297 are connected. The upper back covers 319a and 319b are not provided in the portion corresponding to the connector 301. Therefore, the connector 295a of the unit-side harness 295 can be easily attached to and detached from the board-side connector 301 of the upper relay board 298. At the same time, the fixing screw 149c of the first fixing means 149 and the clamping means 293 can also be operated regardless of the upper back covers 319a and 319b. Therefore, it is possible to eliminate the trouble of attaching and detaching the upper back covers 319a and 319b each time the second upper unit 42b is attached and detached.

Although the upper back covers 319a and 319b are detachable separately on the left and right, it is also possible to connect and integrate the left and right upper back covers 319a and 319b. However, in this case, when attaching / detaching the second upper unit 42b, after removing the left and right integrated upper back covers 319a and 319b, the unit side harness 295 is attached to the board side connector 301 of the upper relay board 298. It needs to be attached and detached.

As shown in FIGS. 51 and 52, the game board 15 is provided with a base plate 321 such as a veneer plate, and a guide rail 322 for guiding the game ball launched from the launching means 16 is annularly formed on the front side of the base plate 321. In addition to being arranged, a large number of game nails (not shown) are arranged in the game area 15a inside the guide rail 322, in addition to unit parts such as the central display frame unit 323, the start winning unit 324, and the normal winning unit 325. Further, for example, a game information display means 326 is arranged at the lower outer side of the game area 15a. Further, a liquid crystal display means 327 and a board movable effect means 328 are arranged on the rear side of the game board 15, and are mounted on a back mounting base 329 (FIGS. 54 to 57, etc.) fixed to the back surface of the game board 15. There is. A transparent plate made of synthetic resin may be used for the base plate 321.

The base plate 321 is formed, for example, in a substantially rectangular shape in front view, and as shown in FIG. 52, one or a plurality (here, three) for mounting the central display frame unit 323, the starting winning unit 324, and the normal winning unit 325. ) Are formed in the mounting holes 330a to 330c so as to penetrate in the plate thickness direction. Further, on the front surface side of the base plate 321, a plurality of, for example, three first to third rail members 331 to 333 constituting the guide rail 322 are mounted.

The first rail member 331 is formed in a substantially bow shape from the lower left side of the base plate 321 to the upper right portion through the substantially center of the left edge portion and the substantially center of the upper edge portion, and is formed with a front wall portion 334 parallel to the base plate 321. , A peripheral wall portion 335 having a substantially constant width projecting rearward along the outer periphery of the front wall portion 334 is integrally provided, and the rear end side of the peripheral wall portion 335 is in contact with the front surface of the base plate 321. It is detachably fixed to the base plate 321. In the first rail member 331, of the peripheral wall portion 335, the inner peripheral wall portion 335a on the game area 15a side is formed in a substantially arc shape in front view to form a part of the guide rail 322.

The second rail member 332 is formed in a thin plate shape having a constant width in the front-rear direction, which stands substantially vertically on the front surface side of the base plate 321 and is parallel to the inside of the first rail member 331 from the upper left portion to the lower left portion of the base plate 321. It is arranged in a substantially arc shape so as to do so. The portion sandwiched between the first rail member 331 and the second rail member 332 is a launch guide passage 336 that guides the game ball launched by the launch means 16 to the game area 15a. Further, at the downstream end of the launch guide passage 336, a return prevention valve 337 for preventing the return of the game ball from the game area 15a side to the launch guide passage 336 side is provided.

The third rail member 333 is attached to the right edge portion and the lower edge portion of the base plate 321 so as to connect the upper right side end portion of the first rail member 331 and the left lower side end portion of the second rail member 332. The front wall portion 338, which is formed in a substantially L-shape in front view along the base plate 321 and is parallel to the base plate 321, and the peripheral wall portion 339 having a substantially constant width projecting rearward from the peripheral portion of the front wall portion 338 are integrally integrated. The peripheral wall portion 339 is detachably fixed to the base plate 321 with the rear end side in contact with the front surface of the base plate 321. In the third rail member 333, the inner peripheral wall portion 339a on the game area 15a side of the peripheral wall portion 339 constitutes a part of the guide rail 322.

The central display frame unit 323 is arranged along the outer periphery of the mounting hole 330a formed in the base plate 321 to form an opening window 340 for visually recognizing the liquid crystal display means 327 and the board movable effect means 328. For example, it is composed of four constituent members 323a to 323d on the left, right, top and bottom, and is detachably attached to the base plate 321 from the front side. The game ball that has passed through the return prevention valve 337 from the launch guide passage 336 and has flowed into the game area 15a flows down either the left left flow path 341 or the right right flow path 342 in the game area 15a. It has become like.

The left component 323a constitutes at least an upstream portion of the left flow path 341, and as shown in FIG. 51, guides across the arrangement position of the return prevention valve 337 from the upper left portion to the left center portion of the game area 15a. It is arranged along the rail 322. The left component 323a is provided with a left inflow portion 341a constituting the inlet of the left flow path 341 on the upper end side and a left outflow portion 341b for discharging the game ball to the downstream side of the left flow path 341 on the lower end side. A plurality of forward protruding obstacle portions 343 are provided in the passage portion between them. It is desirable that at least a part of the left component 323a is transparently formed so that the liquid crystal display means 327 and the board movable effect means 328 on the rear side can be visually recognized from the front side.

The right component 323b constitutes at least an upstream portion of the right flow path 342, and is arranged along the guide rail 322 from the upper right portion to the lower right portion of the game area 15a on the upper end side thereof, as shown in FIG. Is provided with a right inflow portion 342a which is an inlet of the right flow path 342, and is downstream from the right inflow portion 342a with a normal symbol starting means 344, a second special symbol starting means 346, a large winning means 347, and a normal winning means. 348 and the like are arranged. It is desirable that at least a part of the right component 323b is transparently formed so that the liquid crystal display means 327 and the board movable effect means 328 on the rear side can be visually recognized from the front side.

The upper component 323c is arranged along the guide rail 322 so as to connect the upper end sides of the left component 323a and the right component 323b to the left and right, and as shown in FIGS. 51 and 52, the launch guide passage is provided. It is provided with a right guide passage 351 that guides a game ball that has passed through a return prevention valve 337 from 336 and has flowed into the upper side of the game area 15a to a right flow path 342.

The right guide passage 351 has an inflow port 351a provided on the left end side of the upper component member 323c, a vertical passage portion 351b provided substantially downward from the inflow port 351a, and a vertical passage portion 351b descending to the right from the lower end side. The lateral passage portion 351c provided in an inclined shape and the outlet 351d provided on the right end side of the lateral passage portion 351c are provided. For example, the lateral passage portion 351c is longer than the vertical passage portion 351b. It is formed in an L shape. Further, a return rubber 352 is arranged on the upstream end side of the right guide passage 351.

The inflow port 351a is arranged between the inflow portion (arrangement position of the return prevention valve 337) of the game area 15a and the uppermost portion of the guide rail 322, and opens substantially upward toward the guide rail 322. A left inflow portion 341a on the left component 323a side is arranged between the inflow portion of the game area 15a and the inflow port 351a. The return rubber 352 is arranged on the upper right side of the inflow port 351a with the collision surface 352a of the game ball facing, for example, diagonally downward to the left, and is fixed to, for example, the upper component member 323c. Further, the outlet 351d communicates with the right inflow portion 342a on the right component 323b side, for example, in the vicinity of the guide rail 322. When the game ball launched by the launching means 16, passing through the return prevention valve 337 and flowing into the game area 15a reaches the return rubber 352 along the guide rail 322, most of the game balls flow into the inflow port 351a. , It flows down the right flow path 342 via the right guide passage 351 but otherwise flows into the left inflow section 341a and flows down the left flow path 341.

As described above, in the present embodiment, the right guide passage 351 is arranged on the upper side (predetermined location) of the game area 15a by arranging the right guide passage 351 away from the guide rail 322 corresponding to the predetermined range on the upper side of the guide rail 322. , The non-inflow region 353 in which the game ball cannot flow is formed in an inward (downward) concave shape. In other words, the right guide passage 351 is arranged along the edge thereof so as to avoid the non-inflow region 353. The upper component 323c is provided with a closing plate 354 that fills the non-inflow region 353 integrally with the right guide passage 351. On the front side of the non-inflow region 353, the frame non-movable body 203 on the front frame 3 side is arranged with the transparent plate 36a on the front door 4 side interposed therebetween. It is desirable that the upper component member 323c has at least a transparent portion of the right guide passage 351 so that the liquid crystal display means 327 and the board movable effect means 328 on the rear side can be visually recognized from the front side.

The lower component 323d is arranged so as to connect the lower end sides of the left component 323a and the right component 323b at positions separated from the guide rail 322, and the game ball is freely rolled in the left-right direction to the center. A stage 355 that drops the ball from either the falling portion 355a or the other part to the front side, a warp inlet 356 into which a game ball flowing down the left flow path 341 can flow in, and a game ball flowing into the warp inlet 356 are staged. It is equipped with a stage guide passage 357 that guides to 355. It is desirable that at least a part of the lower constituent member 323d is transparently formed so that the liquid crystal display means 327 and the board movable effect means 328 on the rear side can be visually recognized from the front side.

The start winning unit 324 is arranged along the guide rail 322 on the lower side of the central display frame unit 323, and is detachably mounted on the mounting hole 330b formed in the base plate 321 from the front side. The first special symbol starting means 345, the out port 358, and the like are arranged in the starting winning unit 324.

The normal winning unit 325 is arranged along the guide rail 322 on the left side of the starting winning unit 324 under the central display frame unit 323, and is detachably mounted from the front side with respect to the mounting hole 330c formed in the base plate 321. Has been done. For example, a plurality of (here, two) ordinary winning means 349, 350 are arranged in the ordinary winning unit 325.

In the present embodiment, one out port 358 is arranged in the most downstream part of the game area 15a (in the present embodiment, the lower center of the game area 15a), but in addition to the most downstream part of the game area 15a, One or more out ports may be arranged at other positions. In this case, the arrangement position of the out port is arbitrary, and may be provided, for example, in the ordinary winning unit 325 in which the ordinary winning means 349, 350 is arranged, or the unit in which the large winning means 347 is arranged (center in this embodiment). It may be provided on the right component 323b) of the display frame unit 323.

As shown in FIG. 53, the game information display means 326 includes four LED groups composed of, for example, eight LEDs 360, and a total of 32 LEDs 360 are the normal symbol display means 361 and the normal hold number display means. 362, 1st special symbol display means 363, 2nd special symbol display means 364, 1st special hold quantity display means 365, 2nd special hold quantity display means 366, variation shortening notification means 367, right-handed notification means 368 and number of rounds. A predetermined number is assigned to the notification means 369. That is, each of the eight LED 360s belonging to the first and second LED groups 326a and 326b constitutes the first and second special symbol display means 363 and 364, respectively, and the eight LED 360s belonging to the third LED group 326c are two. Eight LEDs 360 belonging to the fourth LED group 326d are configured as the first special reserved quantity display means 365, the second special reserved quantity display means 366, the normal hold quantity display means 362, and the variation shortening notification means 367, respectively. Two of them form the normal symbol display means 361, the other two form the right-handed notification means 368, and the remaining four form the round number notification means 369, respectively.

The normal symbol starting means 344 is for starting the variable display of the normal symbol by the normal symbol display means 361, and is composed of a passing gate or the like through which the game ball can pass, and the passing detecting means 344a for detecting the passage of the game ball. It is equipped with. The ordinary symbol starting means 344 is provided, for example, on the downstream side of the right inflow portion 342a in the right component 323b of the central display frame unit 323, and allows a game ball flowing down the right flow path 342 to pass through.

The ordinary symbol display means 361 is for displaying the ordinary symbol in a variable manner, and is composed of, for example, two LEDs 360 in the game information display means 326 (FIG. 53), and the ordinary symbol starting means 344 detects a game ball. Based on this, after those two LEDs 360 constituting the normal symbol emit light in the normal fluctuation light emission pattern, the hit determination random number value included in the normal random number information acquired at the time of detecting the game ball by the normal symbol starting means 344 is If it matches the predetermined hit determination value, the fluctuation is stopped in the hit mode (predetermined mode), and in other cases, the fluctuation is stopped in the off mode. It should be noted that the two LEDs 360 constituting the normal symbol can display one or more hit modes and one or more missed modes depending on the combination of their light emitting modes (for example, lighting / extinguishing), and are in normal fluctuation. As the light emission pattern, for example, a plurality of specific types (here, two types) of light emission modes are switched at predetermined time intervals (for example, 128 ms).

Further, when the ordinary symbol starting means 344 detects a game ball during the ordinary holding period including the symbol change of the ordinary symbol display means 361 and the ordinary profit state, the ordinary random number information acquired by the detection is predetermined. The maximum number of reserved pieces, for example, 4 pieces, is held and stored, and each time the normal holding period ends, one piece is consumed and the normal symbol is changed. The stored number of ordinary random number information (ordinary hold number) is notified to the player by the ordinary hold number display means 362 or the like. The normal hold number display means 362 is composed of, for example, two LEDs 360 in the game information display means 326 (FIG. 53), and depends on the combination of the respective light emission modes (for example, lighting / blinking / extinguishing) of the two LEDs 360. , 0 to 4 types of 5 types of normal hold numbers can be displayed.

The first special symbol starting means (symbol starting means) 345 is for starting the symbol variation by the first special symbol display means 363, and is composed of a non-opening / closing type winning means having no opening / closing means, and is a winning game ball. The winning prize detecting means (starting winning prize detecting means) 345a for detecting the above is provided. The first special symbol starting means 345 is provided, for example, in the starting winning unit 324, and is arranged in an upward opening shape corresponding to the central drop portion 355a of the stage 355, and is arranged in an upward opening shape, and is a warp on the left flow path 341 side. Due to the existence of a winning route from the entrance 356 via the stage 355, the game ball flowing down the left flow path 341 can be won with a higher probability than the game ball flowing down the right flow path 342. There is. When a game ball wins a prize in the first special symbol starting means 345, a predetermined number of game balls are paid out as prize balls per prize.

The second special symbol starting means (symbol starting means) 346 is for starting the symbol variation by the second special symbol display means 364, and the game ball can be won in the open state and cannot be won by the operation of the opening / closing portion 346b. It is composed of openable and closable winning means that can be changed to a closed state (or more difficult to win than the open state), and is equipped with a winning detection means (starting winning detection means) 346a that detects a winning game ball, and normally displays a symbol. When the stop symbol after the change of the means 361 becomes a hit mode and a normal profit state occurs, the opening / closing portion 346b changes from the closed state to the open state for a predetermined time.

The second special symbol starting means 346 is provided, for example, on the downstream side of the normal symbol starting means 344 in the right component 323b of the central display frame unit 323, and the game ball flowing down the right flow path 342 can win a prize. It has become. When a game ball wins a prize in the second special symbol starting means 346, a predetermined number of game balls are paid out as a prize ball per prize.

The first special symbol display means (symbol display means) 363 is composed of, for example, eight LEDs 360 in the game information display means 326 (FIG. 53), and the first special symbol start means 345 detects a game ball. Under the condition (when the symbol start condition is satisfied), after the eight LEDs 360 constituting the first special symbol emit light in the light emission pattern during the special fluctuation, they are acquired when the game ball is detected by the first special symbol start means 345. If the jackpot determination random number value included in the first special random number information matches a predetermined jackpot determination value (when winning in a random number lottery), the first jackpot mode (specific mode) is used, and in other cases. Is designed to stop the fluctuation in the first outlier mode (non-specific mode). When the stop symbol after the change of the first special symbol display means 363 becomes the first jackpot mode, the first extraordinary profit state occurs.

The second special symbol display means (symbol display means) 364 is composed of, for example, eight LEDs 360 in the game information display means 326 (FIG. 53), and the second special symbol start means 346 detects a game ball. Under the condition (when the symbol start condition is satisfied), after the eight LEDs 360 constituting the second special symbol emit light in the light emission pattern during the special fluctuation, they are acquired when the game ball is detected by the second special symbol start means 346. If the jackpot judgment random number value included in the second special random number information matches the predetermined jackpot judgment value (if the random number is won), the second jackpot mode (specific mode) is used, and in other cases. Is designed to stop the fluctuation in the second outlier mode (non-specific mode). When the stop symbol after the change of the second special symbol display means 364 becomes the second jackpot mode, the second special profit state occurs.

The first and second special symbol display means 363 and 364 have one or a plurality of first and second jackpot modes and one or a plurality of first and a plurality of light emission modes (for example, lighting / extinguishing) of each of the eight LEDs 360. The second out-of-range mode can be displayed, and the light emission pattern during the special fluctuation is such that, for example, a specific plurality of types (here, two types) of light emission modes are switched at predetermined time intervals (for example, 128 ms).

In addition, the first and second special symbols are started during the special holding period including the symbol change of the first special symbol display means 363, the symbol change of the second special symbol display means 364, and the first and second special profit states. When the means 345 and 346 detect the game ball, the first and second special random number information (random number information) acquired by the means 345 and 346 are stored in a predetermined upper limit, for example, 4 each. Will be done. Then, when the reserved memory on the second special symbol side is 1 or more at the end of the special reserved period, one reserved memory of the second special symbol is digested to change the second special symbol, and the first When only the reserved memory on the special symbol side is 1 or more, one reserved memory of the 1st special symbol is digested and the 1st special symbol is changed. As described above, in the present embodiment, when both the first special symbol and the second special symbol do not change, and both the first special symbol side and the second special symbol side have reserved memory. Is designed to give priority to the change of the second special symbol.

The number of stored first and second special random number information (first and second special reserved numbers) is notified to the player by the first and second special reserved number display means 365,366, the liquid crystal display means 327, and the like. To. Here, the first and second special reserved number display means 365 and 366 are composed of two LEDs 360 in each of the game information display means 326 (FIG. 53), and their light emitting modes (for example, lighting / blinking / extinguishing). Depending on the combination, it is possible to display 5 types of 1st and 2nd special reserved pieces of 0 to 4.

The large winning means 347 is an opening / closing type winning means provided with an opening / closing plate 347b that can switch between an open state in which the game ball can be won and a closed state in which the game ball cannot be won. For example, it is arranged on the downstream side of the second special symbol starting means 346 and on the upstream side of the first special symbol starting means 345 in the right component 323b of the central display frame unit 323, and has flowed down the left flow path 341. A game ball that has flowed down the right flow path 342 has a higher probability of winning a prize than a game ball. The big winning means 347 is generated when the first and second special symbols of the first and second special symbol display means 363 and 364 stop in the first and second big hit modes after the change. In the profit state, the opening / closing plate 347b opens to the front side according to any one or a plurality of types of opening patterns, and the game ball that has fallen on the opening / closing plate 347b is made to win a prize inward. When a game ball wins in the large prize-winning means 347, a predetermined number of game balls are paid out as prize balls per prize. In the following description, the first special profit state and the second special profit state are collectively referred to as a "big hit game" (special game).

In the present embodiment, for example, three types of 4R, 6R, and 10R are provided as opening patterns of the big winning means 347 in the big hit game. Each of the 4R, 6R, and 10R open patterns is configured to perform so-called rounds with balls four times, six times, and ten times, respectively. Here, in the round with a payout, after the large winning means 347 is opened, when the number of winnings to the large winning means 347 reaches a predetermined number (for example, 9) or a predetermined time (for example, 28 seconds) has elapsed. It is set to close the big prize means 347, and if the player hits right at the big prize means 347 on the right flow path 342 side, the maximum number of game balls can be easily won and a large number of prize balls can be won. Can be acquired. In addition to the round with balls, a round with no balls may be provided, or a round without balls may be provided, in which the large winning means 347 opens for a very short time (for example, 0.2 seconds). Only open patterns may be provided.

In the present embodiment, it is possible to generate a special gaming state advantageous to the player after the end of the jackpot game according to the jackpot symbol random value or the like in the case of the jackpot. The special gaming state is a combination of a high probability state and an open extension state, for example, a "latent state" in which a high probability state occurs and an open extension state does not occur, and a "probability change" in which both a high probability state and an open extension state occur. There are three possible types: "state" and "time saving state" in which the open extension state does not occur and the high probability state does not occur. The normal gaming state is a state in which neither the high probability state nor the open extension state occurs.

In the high probability state, the probability that the first and second special symbols are in the jackpot mode is set to a high probability by increasing the number of jackpot determination values as compared with the other low probability states. ..

Further, during the open extension state, the opening / closing pattern of the second special symbol starting means 346 is switched from the normal opening / closing pattern (for example, 0.2 seconds × 1 opening) to the extended opening / closing pattern (for example, 2 seconds × 3 times opening). In addition to that, for the first and second special symbols, the fluctuation time of the first and second special symbol display means is switched to a shortened fluctuation time, which is shorter than the normal fluctuation time, respectively, and for the normal symbol, the hit probability is the normal probability. It has become possible to switch from (for example, 1/10) to a high probability (for example, 1 / 1.3) and from a normal fluctuation time (for example, 27 seconds) to a shortened fluctuation time (for example, 2.7 seconds). There is.

In the present embodiment, it is assumed that either the probabilistic change state or the time saving state occurs with a predetermined probability after the end of the jackpot game. For example, the probabilistic state ends when the next big hit occurs, and the probable change state ends when the first and second special symbols fluctuate a predetermined number of times (for example, 50 times) or when the next big hit occurs by then. do. The probability change state may also be configured to end when the first and second special symbols fluctuate a predetermined number of times before the next big hit occurs.

The ordinary winning means 348 to 350 are non-opening and closing type winning means having no opening / closing means, and include winning detection means 348a to 350a for detecting the winning game ball, and are included in the ordinary winning unit 325, the central display frame unit 323, and the like. Have been placed. When a game ball wins in the ordinary winning means 348 to 350, a predetermined number of game balls are paid out as a prize ball per winning.

The out port 358 allows the game ball that has flowed down the game area 15a without winning any of the winning means such as the first and second special symbol starting means 345 and 346 from the game area 15a to the rear side of the game board 15, for example. It is formed on the guide rail 322 on the lower side of the first special symbol starting means 345, for example, in a downward-sloping shape that penetrates the base plate 321 back and forth. In addition, a plurality of out ports 358 may be provided.

As shown in FIGS. 54 to 57, a liquid crystal display means 327 and a board movable effect means 328 are mounted on the back side of the base plate 321 via a back mounting base 329. The back mounting base 329 is formed in a substantially box shape with the front side open, and a rectangular opening 329b is formed in the back wall 329a, and the liquid crystal display means 327 uses the display screen 327a in the opening 329b. It is detachably fixed to the back side of the back wall 329a in a corresponding state.

As shown in FIG. 51, the liquid crystal display means 327 can variablely display the effect symbol 370 in parallel with the variable display of the first and second special symbols by, for example, the first and second special symbol display means 363 and 364. In addition, various images such as the first and second reserved images X1 to X4, Y1 to Y4, and the changing reserved image Z indicating the number of first and second special reserved images can be displayed.

Here, the effect symbol 370 includes a plurality of symbol sequences (here, three) composed of a plurality of symbols such as a number symbol, and each symbol constituting each of these symbol sequences is, for example, 1 to 8 or the like. It is composed of a combination of the symbol main body portion 370a composed of the numbers and others of No. 1 and the character and other decorative portions 370b attached to the symbol main body portion 370a. For example, the effect symbol 370 starts the fluctuation by vertical scrolling for each symbol row according to the predetermined fluctuation pattern substantially at the same time as the fluctuation start of the first and second special symbols, and the stop symbol on the predetermined effective line is the predetermined mode. For example, the final stop is made substantially at the same time as the fluctuation stop of the first and second special symbols. In the effect symbol 370, for example, when all the stop symbols on the effective line are the same, the jackpot effect mode is used, and in other cases, the off effect mode is used. When it becomes a specific mode), the effect symbol 370 becomes a jackpot effect mode (specific effect mode), and when the first and second special symbols become the first and second deviated modes (non-specific mode), the effect symbol 370 becomes. Is an out-of-order effect mode (non-specific effect mode).

Further, regarding the first and second reserved images X1 to X4, Y1 to Y4, and the changing reserved image Z, the first and first are based on the fact that the first and second special symbol starting means 345 and 346 detect the game ball. 2 When the number of special reserved images increases, one additional first and second reserved images X1 to Y1 to be displayed on the liquid crystal display means 327, and the first and second special symbol display means 363 and 364 are used. When the number of the first and second special reserved images decreases based on the start of new fluctuations of the first and second special symbols, for example, the pending image Z being changed is deleted, and the first and second reserved images X1 to , Y1 ~ are shifted one by one toward the front side of the queue (for example, the right side of the screen), and the extruded first and second reserved images X1 and Y1 are moved to a predetermined position, for example, to make a new fluctuation. It is designed to be changed to the middle hold image Z.

As shown in FIGS. 54 to 58, the board movable effect means 328 is a pair of left and right elevating drive units 373 and 373 that drive the board movable body 371 in the vertical direction via the board movable body 371 and the board movable body base 372. And have.

The board movable body base 372 has, for example, a symmetrical horizontally long substantially plate shape, and is arranged substantially parallel to the display screen 327a on the front side of the liquid crystal display means 327. It is connected to the elevating slider 375 on the 373 side.

The board movable body 371 is, for example, flat in the front-rear direction and is pivotally attached to the front side of the board movable body base 372 via a left-right hinge pin 376 arranged on the lower back side, so as to be along the front surface of the board movable body base 372. It is configured to swing between an upright state (shown by a solid line in FIG. 56) and an inclined state (shown by a two-dot chain line in FIG. 57) tilted forward by a predetermined angle with respect to the upright state. For example, the board first decorative portion 377a arranged in the center in the left-right direction and the board second decorative portion 377b arranged on the left and right sides of the board first decorative portion 377a exhibit a predetermined three-dimensional shape.

The board movable body 371 is raised to the upper limit position by the elevating drive unit 373, and when it has a specific relative positional relationship with the frame movable body 156 as shown in FIGS. 61 (b1) and 61 (b2), the frame movable body 371 is a frame movable body. It is designed to be visually integrated with the 156 to form a specific form (here, the designed "butterfly"), for example, the front-view rectangular board first decorative portion 377a is the body (or rear) of the butterfly. The second decorative portion 377b of the board, which corresponds to the body) and projects to the left and right of the first decorative section 377a of the board, corresponds to the hind wings of the butterfly.

As shown in FIGS. 54, 58, etc., the board movable body 371 includes a decorative base 378 constituting the back side, a light emitting decorative cover 379 mounted on the front side of the decorative base 378, and a pair of left and right guide rollers 380. The LED substrate 381 is provided on the rear side of the light emitting decorative cover 379. The decorative base 378 is, for example, non-translucent, and a hinge pin 376 is arranged on the lower back side thereof. The luminescent decorative cover 379 is made of a colorless transparent or colored transparent synthetic resin, and is provided with an uneven diffused reflection portion on the inner surface of the back side.

The LED substrate 381 is arranged in a range corresponding to, for example, the second decorative portion 377b of the board, and for example, a plurality of two types of LEDs (second light emitting bodies) 381a and 381b are arranged on the front side thereof. The LEDs 381a are arranged at substantially equal intervals at positions corresponding to the outer periphery of the "butterfly" formed by the frame movable body 156 and the board movable body 371, and can emit light in a single color such as white. The LEDs 381b are distributed substantially evenly in, for example, the internal region of the "butterfly", and can emit light in multiple colors, for example. The LED 381a and the LED 381 b may be of the same type.

The pair of left and right guide rollers 380 are arranged above the hinge pin 376, for example, and rotate around the axis in the left-right direction on the tip side of the roller support portion 382 projecting outward from both left and right ends of the movable board 371. It is supported in a rotatable state.

The left and right elevating drive units 373 are arranged on the left and right sides on the front side of the liquid crystal display means 327, and as shown in FIGS. 54, 55, 59, 60, etc., the board movable body base 372 is connected. The elevating guide 383 that guides the elevating slider 375 in the vertical direction between the upper limit position and the lower limit position, the upper limit position holding means 384 that holds the elevating guide 383 in the upper limit position, and the elevating guide 383 are arranged near one end side. The drive pulley 385, the driven pulley 386 arranged near the other end of the elevating guide 383, the drive means 387 such as a stepping motor for rotationally driving the drive pulley 385, and the drive pulley 385 and the driven pulley 386 are wound around each other. An endless belt 388 to which the elevating slider 375 is fixed at a predetermined position on the circumference thereof, a spring 389 that urges the elevating slider 375 in the ascending direction, and an elevating / lowering that restricts the elevating slider 375 to be released at the lower limit position. The regulating means 390, the swing guide 391 that guides the board movable body 371 in the swing direction via the guide roller 380 of the board movable body 371, the elevating guide 383, the drive pulley 385, the driven pulley 386, the drive means 387, etc. It is equipped with an elevating base 392 and the like to support.

The elevating base 392 is arranged vertically along the left and right edges of the liquid crystal display means 327, for example, and is detachably fixed to the front side of the back wall 329a of the back mounting base 329, for example. The elevating base 392 is provided with bulging portions 393, 394 that bulge forward, respectively, on the upper end side and the lower end side thereof.

The elevating guide 383 is, for example, an elongated columnar shape, and is arranged in the vertical direction between the upper bulging portion 393 and the lower bulging portion 394 on the front side of the elevating base 392. , It is slidably supported between the upper limit position and the lower limit position. The upper limit position holding means 384 is composed of a magnet 395 arranged on the elevating base 392 side, for example, the upper bulging portion 393, and a magnet attraction sheet metal 396 arranged on the elevating slider 375 side corresponding to the magnet 395. When the elevating slider 375 reaches the upper limit position, the magnet 395 attracts the magnet attraction sheet metal 396 to hold the elevating slider 375 in the upper limit position. Of course, the magnet 395 may be arranged on the elevating slider 375 side and the magnet attraction sheet metal 396 on the elevating base 392 side, respectively, or the upper limit position holding means 384 may be configured by a pair of magnets.

A drive pulley 385 is arranged near the upper end of the elevating guide 383, and a driven pulley 386 is arranged near the lower end. It is supported by the base cover 397. The drive means 387 is mounted, for example, on the front side of the upper bulge portion 393, and the drive gear 398 mounted on the drive shaft 387a meshes with the gear portion 385a of the drive pulley 385. By operating the drive means 387 in the forward and reverse directions, the board movable body base 372 and the board movable body 371 can be moved up and down between the lower limit position and the upper limit position via the belt 388 and the elevating slider 375. In this embodiment, the lower limit position of the movable board 371 is set as the origin position.

The spring 389 is an elongated coil spring, for example, arranged in the vicinity of the elevating guide 383, one end side of which is fixed to, for example, the lower end side of the elevating base 392, and the other end side is fixed to, for example, the upper side of the elevating slider 375. The intermediate portion is arranged in an inverted U shape in front view by being wound around a pulley 399 arranged on the upper end side of the elevating base 392, for example, and the board movable body 371 is urged in the ascending direction via the elevating slider 375. ing.

Further, on the elevating base 392, a board movable body position detecting means 400 including a photo sensor or the like for detecting the operating position of the board movable body 371 is arranged. In the present embodiment, two board movable body position detecting means 400, that is, an origin position detecting means 400a and an upper limit position detecting means 400b, are provided, and when the board movable body 371 is in the origin position (lower limit position), the origin position is detected. When the board movable body 371 is in the upper limit position, the means 400a detects the non-detection portion 375a provided on the elevating slider 375, for example, by the upper limit position detecting means 400b.

The swing guide 391 is formed in a groove shape in which the guide roller 380 on the board movable body 371 side is slidably engaged, and is substantially vertically on the side surface side of the guide member 401 mounted on the front side of the base cover 397, for example. Have been placed. Here, the elevating guide 383 that guides the board movable body base 372 is arranged straight in the vertical direction, whereas the swing guide 391 that guides the guide roller 380 on the board movable body 371 side is a bent portion in the front-rear direction. have.

That is, the swing guide 391 of the present embodiment is provided with a bent portion 391a at a predetermined position on the upper side, for example, an inclined guide portion 391b formed in an inclined shape with the upper end side rising forward from the bent portion 391a, and the lower end side being an elevating guide. It is a non-tilted guide portion 391c formed in parallel with the 383. Further, the front-rear position of the non-tilted guide portion 391c corresponds to the position of the guide roller 380 in a state where the board movable body 371 faces directly in front. As a result, when the board movable body 371 rises from the origin position, the board movable body 371 is maintained in a state of facing directly in front while the guide roller 380 slides on the non-tilted guide portion 391c, but the guide. When the roller 380 passes through the bent portion 391a and enters the inclined guide portion 391b, the board movable body 371 continues to rise on the lower side where the hinge pin 376 is provided, whereas the guide roller 380 continues to rise. The provided upper side moves to the front side along the inclined guide portion 391b. As a result, the board movable body 371 gradually begins to tilt forward shortly before reaching the upper limit position, and when the upper limit position is reached, the tilt angle becomes substantially the same predetermined angle as the tilt angle of the frame movable body 156 (. FIG. 57).

The elevating control means 390 has a restricting member 402 that can be changed to a restricted position that regulates the ascending movement of the elevating slider 375 at the origin position (lower limit position) and an unregulated deregulation position, and the elevating / lowering that drives the restricting member 402. A regulated drive means 403 and a link member 404 that transmits the driving force of the lift regulated drive means 403 to the regulator member 402 are provided, and are arranged, for example, on the lower front side of the base cover 397 corresponding to the vicinity of the lift slider 375 at the origin position. Has been done.

The regulating member 402 is swingable, for example, around the rotation shaft 402a in the front-rear direction between the regulation position and the regulation release position, and the regulation arm portion 402b and the urging arm portion 402c are arranged in the radial direction with respect to the rotation shaft 402a. At the regulated position, the regulated arm portion 402b engages with the regulated portion 405 on the elevating slider 375 side from above to prevent the elevating slider 375 from moving ascending, and rotates, for example, clockwise from the restricted position. At the regulation release position, the engagement with the regulated portion 405 is released, and the ascending movement of the elevating slider 375 is allowed. The restricting member 402 is elastically urged in the counterclockwise direction, that is, on the restricted position side by a spring 406 arranged between the urging arm portion 402c and the base cover 397.

For example, the link member 404 is swingable around the rotation shaft 404a in the front-rear direction on the lower side of the regulation member 402, and one end side of the rotation shaft 404a is connected to the regulation member 402 with the connecting pin 402d on the regulation arm portion 402b. The other end side is connected to the drive shaft 403a of the elevating regulation drive means 403 made of an electromagnetic solenoid or the like. The elevating regulation driving means 403 is arranged, for example, on the lower side of the regulating member 402 and the link member 404, and on the front side of the base cover 397 with the drive shaft 403a oriented in the left-right direction, for example.

When the board movable body 371 is in the origin position (FIGS. 61 (a1) and (a2)), the restricting member 402 of the elevating regulating means 390 is held in the restricted position by the urging of the spring 406, and the regulating arm portion 402b is held by the elevating slider. Since it is in a state of being engaged with the regulated portion 405 of 375 from above (FIG. 60 (b)), the board movable body 371 is securely held at its origin position. As a result, it is possible to reliably prevent the problem that the movable board 371 deviates from the origin position due to, for example, the urging force of the spring 389.

When moving the board movable body 371 from the origin position to the upper limit position, first, the regulation member 402 of the elevating regulation means 390 is switched to the regulation release position. That is, by operating the elevating regulation driving means 403, the link member 404 is rotated counterclockwise around the rotation shaft 404a, whereby the regulation member 402 is rotated clockwise against the urging force of the spring 406. As a result, the regulation arm portion 402b is disengaged from the regulated portion 405 of the elevating slider 375, and the elevating slider 375 can be moved up.

Subsequently, the drive means 387 is operated in the positive direction. As a result, the belt 388 rotates and the elevating slider 375 rises along the elevating guide 383, and the board movable body base 372 and the board movable body 371 on the front side thereof rise accordingly. After the start of the ascent, the board movable body 371 maintains a forward-facing state without tilting back and forth until the guide roller 380 reaches the bent portion 391a of the swing guide 391, but the guide roller 380 bends the swing guide 391. When entering the tilt guide portion 391b beyond the portion 391a, the board movable body 371 gradually tilts to the front side, and the tilt becomes maximum when the upper limit position is reached. The inclination of the board movable body 371 at this time is substantially the same as the inclination of the frame movable body 156.

When the board movable body 371 reaches the upper limit position (board side specific position) (FIGS. 61 (b1), (b2)), the board movable body 371 and the frame movable body 156 are separated from each other in the front-rear direction, but up and down. Since they are close to each other and their inclinations are almost the same, they are visually integrated to form a "butterfly" when viewed from the front. The game area 15a and the transparent plate unit 35 exist between the board movable body 371 and the frame movable body 156. For example, in the central display frame unit 323, the upper constituent member 323c on the upper side thereof is transparent. Since it is formed and the board movable body 371 on the rear side can be visually recognized from the front side, the board movable body 371 and the frame movable body 156 are not visually separated. Moreover, by arranging the non-inflow region 353 in which the game ball cannot flow in inwardly (downward) inwardly on the upper side of the game region 15a and arranging the frame non-movable body 203 on the front side thereof, the board movable body. Since the 371 and the frame movable body 156 are visually connected, the visual sense of unity between the board movable body 371 and the frame movable body 156 becomes stronger.

When the drive means 387 is operated in the opposite direction while the board movable body 371 is in the upper limit position (FIGS. 61 (b1) and (b2)), the board movable body 371 follows the path opposite to that at the time of ascending to the origin position. Move to (FIGS. 61 (a1), (a2)). That is, the inclination of the movable board 371 gradually decreases as it descends, and when the guide roller 380 exceeds the bent portion 391a of the swing guide 391, the inclination disappears, and then the forward state is maintained until the origin position is reached. Be maintained. When the board movable body 371 reaches the origin position, the regulated portion 405 of the elevating slider 375 automatically engages with the regulating arm portion 402b against the urging force of the spring 406.

Of course, the frame movable body 156 may be configured to move up and down with the same inclination as the board movable body 371, but the board movable body 371 is tilted when the upper limit position is reached as in the present embodiment. By moving the board movable body 371 without tilting other than the above, the operating space of the board movable body 371 can be minimized. Further, a swing driving means for tilting the board movable body 371 may be separately provided, but this is separate from the elevating guide 383 for guiding the board movable body 371 in the vertical direction as in the present embodiment. By providing the swing guide 391 for guiding the board movable body 371 in the swing direction in parallel, it is possible to perform both the ascending / descending drive and the swing drive of the board movable body 371 with one driving means. be.

Further, on the back side of the game board 15, for example, a ball collecting case 411 is arranged under the back mounting base 329 as shown in FIGS. 3, 54 to 56 and the like. The ball collecting case 411 is for collecting a game ball guided to the back side of the game board 15 through the out opening 358 or by winning various winning means, and as shown in FIGS. 54 to 56, the ball collecting case 411 is used. A discharge port 412 is provided on the lower side. The game balls collected in the ball collecting case 411 are discharged from the discharge port 412 to the outside of the machine through the discharge passage on the front frame 3 side. Further, the ball collecting case 411 is provided with an out ball detecting means 414 for detecting a game ball (out ball) passing through the discharge port 412. In addition, in order to quickly perform detection by the out ball detecting means 414 without ball clogging, a plurality of discharge ports 412 in which the out ball detecting means 414 is arranged may be provided. Further, the out ball detecting means 414 may be provided in, for example, a discharge passage on the front frame 3 side.

Further, for example, a main board case 415 in which the main control board 415a is stored is mounted on the back side of the ball collecting case 411, and an effect control is performed on the back side of the back mounting base 329 on the upper side thereof, as shown in FIG. The effect board case 416 in which the substrate 416a and the effect interface board 416b are stored, the liquid crystal board case 417 in which the liquid crystal control board 417a is stored, and the like are mounted.

Further, on the back side of the front frame 3, an opening / closing cover 418 that covers the back side of the game board 15 so as to be openable / closable is detachably attached, and the game ball tank 419 and the tank rail 420 are paid out to the left and right sides on the upper side thereof. The means 421 and the payout passage 422 are attached to each of the game balls, and when the game ball wins a prize means such as the large winning means 347, or when there is a ball lending command from an automatic ball lending machine (not shown). The game ball in the tank 419 is paid out by the payout means 421 via the tank rail 420, and the game ball is guided to the upper plate 44 via the payout passage 422. The opening / closing cover 418 is arranged so as to cover a part of the upper side of the main board case 415 from the rear side, for example.

Further, a board mounting base 423 is detachably mounted on the lower portion of the back side of the front frame 3, and a power supply board case 424 and a payout control board 425a in which the power supply board 424a is stored are mounted on the back side of the board mounting base 423. The payout board case 425 in which the is stored is detachably attached to each. The power supply board 424a is provided with a power supply switch 426 that can be turned ON / OFF from the outside of the power supply board case 424. A discharge passage for discharging the out ball to the outside of the machine is provided integrally with, for example, a board mounting table 423.

FIG. 62A is a schematic block diagram of the control system of this pachinko machine. In FIG. 62A, the main control board 415a controls the game control operation, and the game information display means 326, the normal symbol starting means 344, the first special symbol starting means 345, and the second special symbol on the game board 15. Starting means 346, large winning means 347, ordinary winning means 348 to 350, etc. are connected via, for example, a relay board (not shown), and below that, voice output is performed based on a control command from the main control board 415a. Control commands from the effect control board 416a that performs effect control such as illumination emission and drive of a movable body, the liquid crystal control board 417a that controls the liquid crystal display means 327 based on the control commands from the effect control board 416a, and the main control board 415a. Sub-control means such as a payout control board 425a that controls the payout means 421 based on the above, and a launch control board 427 that controls the launch means 16 based on a launch control signal or the like from the payout control board 425a are connected.

Further, the main control board 415a is connected to an operation means such as a RAM clear switch 431 and a setting change operation means 432, and a display means such as a performance information display means 433. As shown in FIG. 3, both the RAM clear switch 431 and the setting change operation means 432 can be operated from the outside of the main board case 415, and the performance information display means 433 can be visually recognized from the outside of the main board case 415. In this state, they are mounted on the main control board 415a, respectively. In the present embodiment, the RAM clear switch 431, the setting change operation means 432, and the performance information display means 433 are all arranged at positions that are not covered by the open / close cover 418.

The RAM clear switch 431 is operated when the RAM is cleared when the power is turned on, and can be pressed from the outside of the main board case 415, for example, and is configured to be OFF when not operated and ON when pressed. ing. Further, the setting change operation means 432 is operated when changing the setting, etc., and can be switched on / off by inserting a dedicated setting key into the keyhole portion from the outside of the main board case 415 and rotating the keyhole. It has become. In this embodiment, by operating the setting change operation means 432 or the like, the jackpot probability, that is, the probability that the first and second special symbols become the jackpot mode (probability of winning in a random number lottery) is set in a plurality of stages (here, the probability of winning). It is possible to change to 6 steps of settings 1 to 6). Details of this setting change and the like will be described later.

The performance information display means 433 constitutes a setting display means 434 and a performance display means 435, and is provided with, for example, 4-digit 7-segment displays 433a to 433d so as to be visible through a transparent main board case 415. For example, it is mounted on the main control board 415a in the main board case 415 so as to function as the setting display means 434 during the first period and as the performance display means 435 during the second period different from the first period. It has become.

The setting display means 434 displays the setting information indicating the set value (here, any of the settings 1 to 6) in a different display mode depending on, for example, whether or not the set value has not been finalized. Any one of "1" to "6" and "1." to "6." can be displayed on at least a part of the performance information display means 433 corresponding to the settings 1 to 6, and is confirmed during the setting change period. The setting information corresponding to the previous setting value is, for example, "1" to "6" (first display mode) without dots, and corresponds to the fixed setting value during the predetermined period after the setting change period ends and the setting confirmation period. The setting information to be set can be displayed by, for example, "1." to "6." (second display mode) with dots. Of course, whether or not the set value is before confirmation may be expressed by a difference in display mode (for example, lighting / blinking) other than the presence or absence of dots, and the setting information corresponding to the setting value before and after confirmation may be displayed in the same manner. It may be displayed in an embodiment.

In this embodiment, among the 4-digit 7-segment display units 433a to 433d of the performance information display means 433, the 7-segment display unit 433d on the left end side of the rear view, which is closest to the front side when the front frame 3 is opened, is used. Although it is used as the setting display means 434, for example, a 7-segment display unit 433a other than the 7-segment display unit 433d may be used as the setting display unit 434, or the 7-segment display units 433c to 433d and the 7-segment display units 433b to 433d. A 7-segment display unit having two or more digits such as, etc. may be used as the setting display means 434.

The performance display means 435 displays a so-called base value on at least a part of the performance information display means 433, for example, on the 7-segment display units 433a to 433d. The base value is an example of specific information obtained based on the game performance, and is calculated by, for example, "(number of payouts during a specific period / number of outs during a specific period) x 100". Here, the "specific period" is a period during which the jackpot game is not in progress and the special game state is not in progress. Therefore, the "specific period" starts when the symbol change, which is the jackpot mode, ends during the normal gaming state (when the start condition is satisfied), and the final symbol change (missing change) during the special gaming state. It ends when it ends (when the end condition is met). In the actual control process, it is determined whether or not the start condition / end condition is satisfied after the symbol change ends. Therefore, after the symbol change ends, a specific period starts when the start condition is satisfied, and the symbol changes. After the end of the fluctuation, the specific period may end when the end condition is satisfied.

The performance display means 435 of the present embodiment can switch and display four types of base values, for example, a real-time base value, a first cumulative base value, a second cumulative base value, and a third cumulative base value. .. The real-time base value is a real-time base value during the unit measurement period with the unit measurement period until the number of outs reaches a predetermined number (for example, 60,000). The 1st to 3rd cumulative base values are the cumulative base values in the unit measurement period 1 to 3 times before, respectively. Of course, only the base value in real time may be displayed, or the cumulative base value of one type, two types, or four or more types may be displayed.

As described above, the RAM clear switch 431, the setting change operation means 432, and the performance information display means 433 (setting display means 434 and performance display means 435) are all arranged on the rear side of the gaming machine main body 1. Since it is necessary to unlock and open the front frame 3 in order to access, the RAM clear switch 431 and the setting change operation means 432 cannot be operated by anyone other than those involved in the hall, and the performance information display means. It is also not possible to see the display contents of 433 (setting display means 434, performance display means 435).

Further, in the present embodiment, the game information display means 326 and the performance information display means 433 are mainly driven and controlled by a dynamic lighting method. As shown in FIG. 63, 1-byte dynamic lighting commons C0 to C7 can be output from the LED common port of the main control board 415a, and among them, the lines of dynamic lighting commons C0 to C3 are game information. The lines of the dynamic lighting commons C4 to C7 are connected to the LED groups 326a to 326d of the display means 326, respectively, to the 7-segment display units 433a to 433d of the performance information display means 433.

Further, 1-byte dynamic lighting data D10 to D17 and D20 to D27 can be output from the LED data ports 1 and 2 of the main control board 415a, respectively, and the lines of the dynamic lighting data D10 to D17 of the LED data port 1 can be played. The lines of the dynamic lighting data D20 to D27 of the LED data port 2 are connected to the LED groups 326a to 326d of the information display means 326, respectively, to the 7-segment display units 433a to 433d of the performance information display means 433.

The effect control board 416a and the liquid crystal control board 417a are connected to the effect interface board 416b connected to the main control board 415a as shown in FIG. 62 (a), and control from the main control board 415a to the effect control board 416a. Both the command and the control command from the effect control board 416a to the liquid crystal control board 417a are transmitted via the effect interface board 416b.

Further, various effect means to be controlled by the effect control board 416a, for example, speakers 17, 30a, 30b, 31a, 31b, an illumination means 436 composed of a large number of LEDs arranged in each part, a frame movable effect means 153, and an operation effect. In addition to the means 232, the board movable effect means 328, and the like, the effect operation means 43 and the like that can be operated by the player are connected to the effect control board 416a via, for example, the effect interface board 416b.

Subsequently, the power-on process (FIG. 64) executed on the main control board 415a at the time of power-on will be described. In this power-on process (FIG. 64), interrupts are first disabled so that interrupt processes such as timer interrupts are not executed (S1), a stack pointer is set (S2), and sub-board startup wait processes (S3 to S5) are performed. Run. That is, a value corresponding to the sub-board start-up waiting time (for example, 2 seconds) is set in a predetermined register (S3), and subtraction processing (S4) is performed until the value becomes 0, that is, until the sub-board start-up waiting time elapses. ) Is repeated. Further, the power supply abnormality signal monitoring process (S6) that waits until the power supply abnormality signal is turned off is executed, and the protection and prohibition area of the RAM is invalidated (S7).

Then, the initial setting (S8) of the work area is executed. Here, for example, the solenoid port buffer and the power supply abnormality confirmation counter are cleared respectively, and the initial value 01H is set in the system operation status. Further, a power-on command (BA08H) is transmitted to the effect control board 416a (S9). When the effect control board 416a receives the power-on command (BA08H), for example, the liquid crystal display means 327 displays "Please Wait" or the like (FIGS. 101 and 102).

Then, it stands by while clearing the WDT (Watchdog Timer) until the power-on signal and the payout communication confirmation signal acquired from the input port are turned on (S10, S11).

Subsequently, the process proceeds to the processes of S12 to S22 shown in FIG. 65. The processes of S12 to S22 include "setting change" for executing the setting change process (S14) and RAM clear process (S15), and "RAM clear process (S15)" for executing the RAM clear process (S15) without executing the setting change process (S14). "RAM clear", "setting confirmation" to execute setting confirmation processing (S20) and backup restoration processing (S21), "backup restoration" to execute backup restoration processing (S21) without executing setting confirmation processing (S20), It is performed in any of the five types of processing modes of "RAM error" that executes the power re-on wait process (S17).

Further, among these five types of processing modes, the four types excluding "RAM abnormality" are the ON / OFF state of the setting change operation means 432, the ON / OFF state of the RAM clear switch 431, and the door (front frame 3). It is selected according to the combination of open / closed state. The open / closed state of the door is determined by an ON / OFF signal of a door open switch (not shown). The door opening switch is configured to be turned on when the front frame 3 is opened to the front side with respect to the outer frame 2 and turned off when the front frame 3 is closed.

In the present embodiment, as shown in FIG. 69, when both the RAM clear switch 431 and the setting change operation means 432 are ON, "setting change" is selected in principle, the RAM clear switch 431 is ON, and the setting change operation is performed. When the means 432 is OFF, "RAM clear" is selected. However, even if the setting change operation means 432 and the RAM clear switch 431 are both ON, when the door is closed, "setting change" is not performed. "Clear RAM" is selected. Similarly, when the RAM clear switch 431 is OFF and the setting change operation means 432 is ON, "setting confirmation" is selected in principle, and when both the RAM clear switch 431 and the setting change operation means 432 are OFF, the setting change operation means 432 is OFF. "Backup recovery" is selected, but even if the RAM clear switch 431 is OFF and the setting change operation means 432 is ON, "Backup recovery" is selected instead of "Setting confirmation" when the door is closed. It has become.

As described above, in the present embodiment, the situation where the RAM clear switch 431 and the setting change operation means 432 are ON even though the door (front frame 3) is not open is suspected to be fraudulent, so the setting is changed. "Setting change" and "setting confirmation" related to the function are subject to door opening, and when the door is closed, "RAM clear" that does not execute the setting change processing (S14) and "setting confirmation processing (S20)" that is not executed are not executed. "Restore backup" is selected. For "RAM clear" and "backup recovery" that are not related to the setting change function, only the ON / OFF state of the RAM clear switch 431 and the setting change operation means 432 is a condition, and the open / closed state of the door is not a condition. ..

Hereinafter, the processes of S12 to S22 will be described in detail according to the source programs shown in FIGS. 66, 67 and the like with reference to the flowchart of FIG. 65 and the like. Note that FIGS. 66 and 67 show the source programs S12 to S22 in the storage order on the memory. In addition, on the right side of the source program, the processes to be executed and those are executed for each of the above-mentioned five types of processing modes of "setting change", "RAM clear", "setting confirmation", "backup recovery", and "RAM error". The execution order of is indicated by an arrow and the number on the upper right.

In the input port data acquisition process (S12), as shown in FIG. 66, the data of the input port (P_INPT1) is input to the A register (Sa1). In the present embodiment, the input signal corresponding to the 0th to 7th bits of the input port (P_INPT1) is as shown in FIG. 68, and the ON / OFF signal (door opening signal) of the door opening switch is the 4th bit. , The ON / OFF signal of the RAM clear switch 431 is input to the 5th bit, and the ON / OFF signal of the setting change operation means 432 is input to the 6th bit, respectively. In Sa1, the data of the 0th to 7th bits of the input port (P_INPT1) is input to the 0th to 7th bits of the A register, respectively.

Following the input port data acquisition process (S12), the setting change branch determination process (S13) is executed. This setting change branch determination process (S13) determines whether or not to select "setting change" as the processing mode, and as shown in FIG. 66, the value of the A register and the mask data "01110000B" (@ DOPEN +). By obtaining the logical product (AND) with (@ RWMCR + @ SETKY), the 4th bit corresponding to the ON / OFF signal (door opening signal) of the door opening switch and the 1st bit corresponding to the ON / OFF signal of the RAM clear switch 431. 5 bits, bits other than the 6th bit corresponding to the ON / OFF signal of the setting change operation means 432 are masked, and the A register is updated with the masked data (Sb1).

As shown in FIG. 69, the 4th bit of the A register after the processing of Sb1 is executed is 1 when the door (front frame 3) is open, 0 when the door (front frame 3) is closed, and the 5th bit is also The RAM clear switch 431 is 1 when it is ON, 0 when it is OFF, and the 6th bit is 1 when the setting change operation means 432 is ON and 0 when it is OFF. At this time, there are eight types of combinations of the values of the fourth, fifth, and sixth bits of the A register as shown in FIG. 69. In the following description, the combination of the values a4, a5, and a6 of the fourth, fifth, and sixth bits of the A register at this time is expressed by A (a4, a5, a6) as necessary.

Subsequently, the value of the A register is compared with "01110000B" (@ DOPEN + @ RWMCR + @ SETKY) to obtain the difference between them (Sb2). The value obtained by this is set when the 4th, 5th, and 6th bits of the A register are all 1 (A (1,1,1)), that is, the door (front frame 3) is opened and the RAM clear switch 431 is set. It becomes 0 when both the change operation means 432 and the change operation means 432 are ON. If the obtained value (difference) is 0, for example, 1 is set in ZF (zero flag). If the value obtained in Sb2 is 0 (ZF = 1), that is, if A (1,1,1), "change setting" is selected as the processing mode, and SYSTEM_80 (RAM abnormality determination processing (RAM abnormality determination processing). The process proceeds to the next setting change process (S14) without jumping to S18)) (Sb3).

In this jump process of Sb3, the relative address jump "JR" instruction is used instead of the absolute address jump "JP" instruction. In the absolute address jump "JP" instruction, the jump destination address is specified by the absolute address (2 bytes), whereas in the relative address jump "JR" instruction, the jump destination address is specified by the relative address (1 byte). Therefore, the "JR" instruction has the advantage that the program capacity can be reduced by one byte. However, in the case of the "JR" instruction, the range that can be specified as the jump destination is limited compared to the "JP" instruction, and it is in the range of -128 to +127 bytes from the location of the PC register, so it exceeds that range. Cannot be used when jumping.

In the setting change process (S14), as shown in the source program of FIG. 66 and the flowchart of FIG. 70, first, the setting change start command (BA76H) indicating that the setting change period has started is transmitted (Sc1 and Sc2). When the effect control board 416a receives the setting change start command (BA76H), for example, the liquid crystal display means 327 displays "setting is being changed" or the like (FIG. 101).

Next, the backup flag is cleared (Sc3). This is to ensure that if a power failure occurs during the setting change period, a backup error is determined by the RAM abnormality determination process (S16) described later when the power is turned on next time. It also increments the system operation status (Sc4). As a result, the system operation status changes from the initial value of 01H (see S8 in FIG. 64) to 02H.

Subsequently, the set value data is read from the set value work area of the RAM, set as the set work value in, for example, the W register (Sc5), and the value of the W register is decremented (Sc6). In the present embodiment, any of settings 1 to 6 can be selected as the set value, and any of 0 to 5 is set in the set value work area on the RAM depending on the set value (any of settings 1 to 6). The setting value data is stored. Therefore, if the value of the set value work area is normal, any of 0 to 5 is first stored in the W register, and then decremented to become any of -1 to 4.

Then, the setting work value of the W register is compared with 5 which is the maximum value of the setting value data (the value obtained by subtracting 1 from 6 which is the maximum setting value (@DANMAX)), and the difference between them is a negative value. If there is, set CF (carry flag) to 1 (Sc7). Here, if the value of the set value data set in the W register in Sc5 is a normal value (any of 0 to 5), the value obtained in the comparison process of Sc7 becomes a negative value and CF = 1. On the other hand, if the value of the set value data is an abnormal value (for example, 6), it does not become a negative value, so CF ≠ 0. Next, the setting work value of the W register is incremented (Sc8). As a result, the set work value decremented by Sc6 returns to the original value.

Then, it is determined whether or not CF = 1, and if it is not CF = 1, it shifts to Sc11 (SYSTEM_60) after clearing the setting work value of the W register with Sc10, but if CF = 1, Sc10 is set. It skips and shifts to Sc11 (SYSTEM_60) (Sc9). As a result, when there is an abnormality in the set value data, 0 corresponding to the setting 1 can be forcibly set in the set work value. Of course, the value set in the W register (setting work value) at the time of abnormality is not limited to 0, and may be any of within the normal range (0 to 5).

In the case of the present embodiment, since the RAM abnormality determination process (S16) described later is not executed before the setting change process (S14) (see FIG. 65), the set value is set due to the RAM abnormality at the start of the setting change process (S14). The work area setting value data may not be within the normal range. Therefore, in the present embodiment, in the setting change process (S14), the RAM is executed by executing the set value abnormality correction process (Sc6 to Sc10) for correcting the set value data to a normal value (0 in this case) when the set value data is an abnormal value. Even if something is wrong, the setting change process can proceed.

Subsequently, after the WA register data is saved on the stack by Sc11, the A register is cleared (Sc12), and the system input / output management process (M_SYSIO) is called (Sc13).

This system input / output management process (first processing module, display control process) mainly performs dynamic lighting control of the setting display means 434 (7-segment display unit 433d of the performance information display means 433), and FIG. 71 (a). ) And the flowchart of FIG. 71 (b), first, by outputting the predetermined data (@ GAI1) to the external terminal port (P_GAIBU2), the output of the security signal is turned on (Ss1), and the LED common. Clear the output to the port (Ss2). Then, the start address of the numerical 7-segment decoding table (D_N7STBL) is set in the HL register (Ss3). As shown in FIG. 72, the 7-segment decoding table for numerical values is composed of 6 types of setting values 1 to 6 and 1 byte each corresponding to an error, for a total of 7 bytes of display pattern data.

Subsequently, the display pattern data is acquired from the address obtained by adding the value of the W register (the setting work value if the setting change processing is in progress) to the value of the HL register (the start address of the 7-segment decoding table for numerical values). , The value of the A register is updated by obtaining the logical sum (OR) with the A register (0 when the setting change processing is in progress) (Ss4). As a result, for example, when the setting change process is in progress, the display pattern data corresponding to the set work value, for example, "100000011B" for displaying "1" when the set work value is 0, is set in the A register. If the value is 5, "01111101B" for displaying "6" is set.

Then, the display pattern data of the A register is output to the LED data port 2 (P_LED2) (Ss5). Further, if the LED output counter (W_LEDNT) is incremented (Ss6) and the lower 2 bits of the LED output counter after the increment are "11", the common data for designating the 7-segment display unit 433d (setting display means 434). (@ CMN23) is output to the LED common port (P_LEDCMN) (Ss7 to Ss9), but if the lower 2 bits of the LED output counter are not "11", Ss9 is skipped, so the output to the LED common port is cleared. Will remain LED. As a result, the setting display means 434 (7-segment display unit 433d) is turned on every time the lower 2 bits of the LED output counter become "11" (once every 4 times), and the setting work value at that time is set. When any of "1" to "6" is displayed and the lower 2 bits of the LED output counter are not "11" (3 times in 4 times), the light is turned off.

In the jump process of Ss8, the "JRS" instruction which can make the program capacity smaller than the "JR" instruction is used. In the case of the "JR" instruction, the instruction has 1 byte and the relative address specification of the jump destination is 1 byte, for a total of 2 bytes. In the case of the "JRS" instruction, the instruction has 3 bits and the relative address specification of the jump destination has 5 bits. The total number of bytes is 1 byte, and the program capacity of the "JRS" instruction can be further reduced by 1 byte compared to the "JR" instruction. However, in the case of the "JRS" instruction, the range that can be specified as the jump destination is further limited than that of the "JR" instruction, and is in the range of -16 to +15 bytes from the location of the PC register.

Subsequently, the system confirmation process (M_WAIT) is called (Ss10). This system confirmation processing (waiting time formation module, cycle adjustment waiting time processing) is for providing a predetermined waiting time (here, about 4 ms), and is the source program of FIG. 73 (a) and FIG. 73 (b). As shown in the flowchart of the above, first, the WDT is cleared (St1), and the initial value (here, 6654) is set as the timer value in the WA register (St2). Then, after repeating decrementing until the timer value of the WA register becomes 0 (St3, St4), the power supply abnormality check process (M_PWRCHK) is called (St5), and the system checking process (M_WAIT) is terminated. In this embodiment, by setting 6654 as the timer initial value in St2, the execution time of the process during system confirmation is abbreviated as 4 ms, which is the timer interrupt cycle (data output timing cycle in the dynamic lighting method) described later. Matching.

As shown in FIG. 74, the power supply abnormality check process (M_PWRCHK) first reads the power supply abnormality signal transmitted from the power supply board 424a twice (S41). Then, it is determined whether or not the levels of the power supply abnormality signals read twice match (S42), and if those levels do not match (S42: No), the process returns to S41 and if they match (S42: Yes). ) Determines whether or not the power supply abnormality signal is ON, that is, whether or not the level of the power supply abnormality signal is the “H” level (S43).

If the power supply abnormality signal level is not "H" level (ON) (S43: No), the value of the power supply abnormality confirmation counter is cleared (S44), and the power supply abnormality check process is terminated.

On the other hand, when the level of the power supply abnormality signal is "H" level (ON) (S43: Yes), the value of the power supply abnormality confirmation counter is incremented (S45), and the value of the power supply abnormality confirmation counter after the increment is increased. For example, it is determined whether or not the value has reached 2 (S46). If the value of the power supply abnormality confirmation counter is less than 2 (S46: No), the power supply abnormality check process is terminated as it is.

When the value of the power supply abnormality confirmation counter reaches 2 in S46 (S46: Yes), it is determined that the power supply is abnormal, and the power supply cutoff command (BA33H, BA55H) is transmitted (S47), and the system operation status is 00H. The backup flag is set to ON (= AA55H) on condition that the above conditions are met (S48, S49). Here, for example, since the system operation status is set to 02H during the setting change process (Sc4), the backup flag remains OFF (= 0000H) when a power failure occurs during the setting change process.

Then, the protection of the RAM is enabled and the prohibited area is invalidated (S50). As a result, writing data to the RAM is prohibited in the subsequent processing. In addition, after clearing the output ports such as the external terminal port, subport, solenoid port, LED common port, and LED data port (S51) and disabling timer interrupts (S52), the infinite loop process is repeated while clearing the WDT. Wait for the power supply voltage to drop and the CPU to enter the non-operating state (S53).

The explanation will be continued by returning to FIG. 71. When the above system checking process (M_WAIT) is completed (Ss10), an operation input information acquisition process for acquiring input information of the RAM clear switch 431, setting change operation means 432, etc. is executed using the input data table (D_SWINTBL2). (Ss11, Ss12), and the system input / output management process (M_SYSIO) is terminated.

As described above, in the present embodiment, as shown in FIG. 71 (c), the LED output counter is incremented each time the system input / output management process is executed, and a waiting time of 4 ms is provided. Only when the lower bit is "11", the common data specifying the 7-segment display unit 433d (setting display means 434) is output to the LED common port (P_LEDCMN), and the output to the LED common port is cleared in other cases. It becomes a state. As a result, the lighting / extinguishing pattern of the 7-segment display unit 433d (setting display means 434) becomes 4 ms on → 12 ms off → 4 ms on → 12 ms off → ... It matches the lighting / extinguishing pattern of the 7-segment display unit 433d (4ms on → 12ms off → 4ms on → 12ms off → ...) at the time of displaying the base value.

Further, in the present embodiment, the processing of Sc7 to Sc19 or Sc11 to Sc19 (processing during setting change) is repeated at high speed until the setting change operation means 432 is turned off (Sc15, Sc16), and the setting change operation is performed each time. Whether or not it has been done (Sc17 to Sc19), that is, whether or not the RAM clear switch 431 has changed from OFF to ON is determined, but an operation input information acquisition process (Ss11, Ss11, which acquires input information of the RAM clear switch 431 and the like). Since the waiting time (predetermined waiting time) of 4 ms is provided by calling the system confirmation processing (predetermined waiting time processing) before Ss12), it is possible to prevent erroneous detection due to chattering of the RAM clear switch 431. .. Further, since the cycle adjustment waiting time for creating a 4 ms cycle for dynamic lighting control is used as the predetermined waiting time (4 ms), a processing program for waiting time for chattering prevention may be separately provided. The program capacity can be reduced in comparison.

The explanation will be continued by returning to FIG. 70. When the above system input / output management process (M_SYSIO) is completed (Sc13), after the data is returned from the stack to the WA register (Sc14), whether or not the setting change end condition is satisfied, that is, the setting change operation means 432 It is determined whether or not the OFF edge is detected (Sc15), and if the OFF edge of the setting change operation means 432 is not detected, it is determined whether or not a predetermined setting change operation is performed (Sc16, Sc17). In the present embodiment, the RAM clear switch 431 is also used for the setting change operation, and in Sc17, it is determined that the setting change operation has been performed when the ON edge of the RAM clear switch 431 is detected.

Then, when it is determined that the setting change operation has been performed, the process shifts to Sc7 (SYSTEM_50) (Sc18). That is, the set work value at that time is compared with 5 which is the maximum value of the set value data (value obtained by subtracting 1 from 6 which is the maximum set value (@DANMAX)), and even if the difference between them is a negative value. If CF (carry flag) is set to 1 (Sc7). As a result, CF = 1 is set only when the set work value is 0 to 4 out of 0 to 5. Next, the set work value is incremented (Sc8), and when CF = 1 (when the set work value after increment is 6), 0 is set in the set work value (Sc9, Sc10).

As described above, in the present embodiment, the setting work value change processing of Sc7 to Sc10 is executed every time the setting change operation (operation of the RAM clear switch 431) is performed during the setting change period, so that the setting change operation can be performed. The set work value is changed cyclically in the range of 0 to 5. Since the setting work value change processing (Sc7 to Sc10) has the above-mentioned setting value abnormality correction processing (Sc6 to Sc10) and a partial processing (Sc7 to Sc10) in common, it is compared with the case where the setting work value change processing (Sc7 to Sc10) is performed separately. The program capacity can be kept small.

Following the setting work value change processing (Sc7 to Sc10), the processing after Sc11 is performed. Further, when it is determined in Sc17 that there is no setting change operation, the process shifts to Sc11. Since the processing of Sc11 to Sc14 has already been described, the details are omitted here, but by this processing, the display of the setting display means 434 also changes according to the change of the setting work value.

As described above, in the setting change processing (S14), as long as the setting change operation means 432 is ON, the processing of Sc7 to Sc14 is performed when the setting change operation is performed, and the setting change operation is not performed. Is repeatedly executed in the processes of Sc11 to Sc14. Then, when the setting change operation means 432 is switched from ON to OFF and the setting change end condition is satisfied, the setting change period ends and the setting work value of the W register is stored in the set value work area (Sc20). As a result, the provisional setting work value changed by the operation of the RAM clear switch 431 during the setting change period is fixed as the setting value data. Then, it jumps to the RAM clear process (S15) (Sc21) and ends the setting change process.

In the subsequent RAM clearing process (S15), as shown in the source program of FIG. 67 and the flowchart of FIG. 75, first, a specific range of the work area (RAM in the area) in the area is cleared (Sg1 to Sg6). That is, first, the address (W_BACKFLG) of the backup flag area in the RAM in the area is set in the HL register (Sg1). This is the start address of the clear target range. Also, the A register is cleared (Sg2). Then, the process (Sg3) of clearing the area specified by the HL register and incrementing the value of the HL register is repeatedly executed until the value of the HL register reaches, for example, the start address (@ RWM2TOP) of the RAM outside the area. (Sg3 to Sg5).

In the present embodiment, a predetermined range on the RAM is assigned as a work area in the area (RAM in the area), and a predetermined range following the predetermined range is assigned as a work area outside the area (RAM outside the area). Therefore, the areas after the backup flag area in the RAM in the area are cleared to 0 by the above Sg1 to Sg5. In the present embodiment, each area for storing the LED output counter, the system operation status, and the set value data is provided in front of the backup flag area in the RAM in the area, and therefore is not cleared by the processing of Sg3 to Sg5. The LED output counter is cleared to 0 at the next Sg6.

Following the clear processing (Sg1 to Sg6) of the RAM in the area, the start address of the initial value setting table (D_INISET2) is loaded into the HL register (Sg7), and the data set processing is called (Sg8), for example, invalid. An initial value (for example, a value corresponding to 30 seconds) is set in the information timer, and a predetermined deviation mode is set in the first special symbol and the second special symbol. This rogue information timer is for counting the output time of the security signal. For example, in the timer interrupt process described later, the security signal is output until the value of the rogue information timer becomes 0.

Subsequently, the setting change via determination process (Sg9) for determining whether or not the setting change process (S14) has been passed is executed. In the present embodiment, it is determined whether or not the value of the system operation status (initial value 01H) is 02H (see Sc4), and if the value of the system operation status is 02H, the setting change process (S14) is performed. It is determined that the next processing via setting change (Sg11 to Sg22) is executed, but if the value of the system operation status is not 02H, the processing via setting change is skipped and the system shifts to Sg23. ..

In the process via setting change (Sg11 to Sg22), first, 00H is set in the system operation status (Sg11), and a setting change end command (BA77H) indicating that the setting change period has ended is transmitted (Sg12, Sg13). By setting 00H to the system operation status, for example, even if a power failure occurs after that, the backup flag will be turned ON (= AA55H) in S48 and S49 of the power supply abnormality check process (FIG. 74) described above, so the next time. When the power is turned on, there is no waiting for the power to be turned on again due to a backup error.

Further, the common data (@ CMN23) designating the 7-segment display unit 433d (setting display means 434) is output to the LED common port (P_LEDCMN) (Sg14). Then, the start address of the 7-segment decoding table for numerical values (D_N7STBL) (FIG. 72) is set in the HL register, and the value of the set value data is set in the A register (Sg15, Sg16), and the value of the HL register (7 for numerical values). The display pattern data is acquired from the address obtained by adding the value (set value data) of the A register to the start address of the seg-decode table, and is set in the A register (Sg17). As a result, the display pattern data corresponding to the set value data, for example, "10000110B" for displaying "1" when the set value data is 0, is displayed in the A register as "6" when the set value data is 5. "01111101B" for displaying "01111101B" is set.

Then, the value of the A register is updated by obtaining the logical sum (OR) of the value of the A register and the display pattern data "10000000B" (@SEG_DP) corresponding to ". (Dot)" (Sg18). , The display pattern data of the A register is output to the LED data port 2 (P_LED2) (Sg19). As a result, any one of "1." to "6." corresponds to the set value data (any of 0 to 5) confirmed by the setting change process, which is the setting display means 434, that is, the performance information display means 433-7. It is displayed on the seg display unit 433d. In this way, when the setting change period ends and the setting value data is confirmed, the display mode of the setting information displayed on the setting display means 434 is different from that during the setting change period up to that point (for example, a dot is added). By doing so, it is possible to visually notify the operator that the set value data has been confirmed. At this time, the amount of light may be changed (for example, increased) or the display pattern may be changed (for example, from blinking to lighting) in place of or in addition to the change in the display content (addition of dots, etc.).

Subsequently, the waiting time processing (Sg20 to Sg22) for a predetermined time (for example, about 1 second) is executed. That is, first, a value (250 in this case) corresponding to a predetermined time (for example, about 1 second) is set in the B register (Sg20), and the above-mentioned system checking process (M_WAIT) is performed while subtracting the value in the B register. It is repeatedly executed until the value of the B register after subtraction becomes 0 (Sg21, Sg22). Since the process during system confirmation of the present embodiment is for providing a waiting time of 4 ms as described above, by repeating this 250 times, the set value data (0 to 5) after the determination by the setting display means 434 is performed. The display corresponding to (any of)) (hereinafter referred to as the setting change confirmation display) can be continued for about 1 second.

In addition, the system is being checked to adjust the data output timing to a fixed cycle by the display control of the setting display means 434 (7-segment display unit 433d) in the waiting time processing (1 second) for the setting change confirmation display. Since the processing (waiting time formation module) is used, the program capacity can be reduced as compared with the case where the dedicated waiting time processing is provided. In the present embodiment, as described above, the drive control is performed by the static lighting method for the setting change confirmation display for about 1 second.

Following the above processing via setting change (Sg11 to Sg22), 02H, which is lower byte data for the RAM clear command, is set in the W register and then jumped to the common processing (S22) (Sg23, Sg24). End the RAM clear process.

In the common process (S22), as shown in the source program of FIG. 67 and the flowchart of FIG. 76, BA01H (initialization command data) is first stored in the DE register (Sk1), and the command data is stored by the command transmission process (Sk2). Send. Further, the W register is loaded into the E register (Sk3), and the command data of the DE register is transmitted by the command transmission process (Sk4). For example, in the case of "setting change", since 02H is set in the W register (Sg23), the lower byte of BA01H stored in the DE register is changed to 02H and BA02H (RAM clear command) is transmitted. Will be done.

Subsequently, the game state notification information update process (M_MKINFO) is executed (Sk5). In this game state notification information update processing (Sk5), various commands are transmitted according to the processing mode. That is, when the processing mode is either "setting confirmation" or "backup recovery", the first and second special hold quantity specification commands (B0xxH, B1xxH) based on the values of the first and second special hold counts. The set value command (F6xxH) based on the set value data and the state specification command (FAxxH to FDxxH) based on the gaming state are sequentially transmitted (Sk51 → Sk52 to Sk54). Further, when the processing mode is neither "setting confirmation" nor "backup recovery", that is, when either "setting change" or "RAM clear", the setting value command (F6xxH) based on the setting value data is executed. The first and second special hold quantity designation commands (B0xxH, B1xxH) and the status designation commands (FAxxH to FDxxH) are not transmitted (Sk51 → Sk55). Further, when the first and second special symbols are not changing, a customer waiting command (BA04H) is transmitted (Sk56, Sk57).

Then, initial values are set in various internal function registers (Sk6 to Sk10). For example, the LED common port is cleared here, thereby ending the setting change confirmation display for about 1 second. In addition, the work area is initially set (Sk11, Sk12). In the initial setting of this work area, for example, 00H is set in the system operation status, the launch control signal is set to ON, and the initial value is set in the operation confirmation timer.

The operation confirmation timer is for measuring the execution time of the operation confirmation display of the performance display means 435. For example, it is stored in the RAM in the area, and as an initial value, a value obtained by adding 1 to the timer value corresponding to, for example, 4800 ms is used. It is set. In the present embodiment, as will be described later, the operation confirmation timer is subtracted by 1 in the timer interrupt process executed in the 4 ms cycle (S82 in FIG. 89), so that the timer value corresponding to 4800 ms is 1200, and the operation confirmation timer The initial value is 1201 which is obtained by adding 1 to this. As described above, in the present embodiment, the initial setting of the operation confirmation timer used for measuring the execution time of the operation confirmation display is performed in the processing at the time of turning on the power (before the main loop processing).

The description will be continued by returning to the setting change branch determination process of S13 (FIGS. 65 and 66). If the value obtained in Sb2 is not 0 (ZF ≠ 1), that is, if it is not A (1,1,1), the process jumps to SYSTEM_80 in FIG. 66, that is, the RAM abnormality determination process (S16) (Sb3). ..

The RAM abnormality determination process (S16) determines whether or not to select the processing mode of the “RAM abnormality”, and as shown in FIG. 66, first determines whether or not the RAM is abnormal (Sd1, Sd2). .. That is, the set value data is acquired from the set value work area (W_SETHVAL) of the RAM in the area, and the set value data is compared with 6 which is the set maximum value (@DANMAX) to obtain the difference between them (Sd1). In the case of the present embodiment, the set value data of any of 0 to 5 should be stored in the set value work area on the RAM depending on which of 1 to 6 is selected, so that it is normal. If so, the difference between the set value data and 6 is a negative value. Therefore, if the difference is not a negative value (JF = 0), it is determined that the RAM is abnormal, and the process jumps to SYSTEM_90, that is, the power restart waiting process (S17) (Sd2).

If the RAM is not abnormal, it is determined whether or not the backup is abnormal (Sd3, Sd4). That is, the value of the backup flag is compared with AA55H (@BACKUP) to obtain the difference between them (Sd3). If the difference is not 0 (ZF ≠ 1), it is determined that the backup is abnormal, and the process proceeds to the next SYSTEM_90, that is, the power restart waiting process (S17) without jumping (Sd4).

As described above, when the backup flag is cleared (Sc3) in the setting change processing (S14) and a power supply abnormality is detected in the power supply abnormality check processing, the backup flag is turned ON only when the system operation status is 00H (=). Since it is set to AA55H), if a power failure occurs during the setting change period, the RAM error determination process (S16) determines that a backup error occurs at the next power-on, and the power is turned on again. Wait processing (S17) is executed.

In the power re-on wait process (S17), as shown in the source program of FIG. 66 and the flowchart of FIG. 77, first, the power re-on command (BA7FH) is transmitted (Se1, Se2). When the effect control board 416a receives the power supply turn-on command (BA7FH), for example, the liquid crystal display means 327 displays "RAM error, turn on the power again and set the setting to 1" or the like (FIG. 102). ..

Then, the W register is set to 06H, which is an offset value for displaying "E" (Se3), the A register is cleared (Se4), and the system input / output management process (M_SYSIO) is called (Se5). The power supply wait state (Se6) is set so that the process of is repeated indefinitely. Here, the system input / output management process has already been described in the setting change process (S14), but the operation is partially different from that in the setting change process due to the difference in the value of the W register. That is, in this power supply re-on wait process, 06H is set in the W register when calling the system input / output management process (Se3). Therefore, in the system input / output management process Ss4 (FIG. 71), the numerical 7-segment display is used. The seventh display pattern data in the decode table, that is, "01111001B" for displaying "E" is set in the A register. Therefore, "E" indicating an error is displayed on the setting display means 434, that is, the 7-segment display unit 433d of the performance information display means 433.

As described above, in the present embodiment, the process related to the dynamic lighting control of the performance information display means 433 and the power supply abnormality check process are set as the system input / output management process (display control module), and the setting change process (S14) and the power cycle wait process. The program capacity is reduced by sharing it among (S17) and the like.

Further, as described above, in the case of a RAM abnormality or a backup abnormality, the present embodiment is configured to forcibly turn on the power again by shifting to the power re-on wait state. If the power re-turning wait process (S17) is executed due to a RAM error, and if it is not A (1, 1, 1) in S13 at the next power re-turning, it is determined that the RAM is abnormal again and the power is turned on again. Wait processing (S17) is executed. Therefore, when the power is turned on again while waiting for the power to be turned on again, the door (front frame 3) is opened and the RAM clear switch 431 and the setting change operation means 432 are both turned on to change the setting (setting change processing). It is necessary to execute S14) and set the set value to any value among the settings 1 to 6.

As described above, in the case of "RAM error", the setting change process (S14) is executed by turning on the power again, and the set value is set to a normal value, so that the power is turned on again. In that respect, in the case of "setting change" for executing the setting change process (S14), it is not necessary to wait for the power to be turned on again even if the RAM is abnormal. Therefore, in the present embodiment, the RAM abnormality determination process (S16) is executed after the setting change branch determination process (S13) in order to eliminate unnecessary processing.

The explanation will be continued by returning to the RAM abnormality determination process of S16. If it is determined in S16 that neither the RAM nor the backup is abnormal, the process proceeds to SYSTEM_110 in FIG. 67, that is, the RAM clear branch determination process (S18) (Sd4). This RAM clear branch determination process (S18) determines whether or not to select the process mode of "RAM clear". As shown in FIG. 67, first, the value of the fifth bit (@B_RWMCR) of the A register is determined. Is transferred to CF (carry flag) (Sf1). If the CF (fifth bit of the A register) is 1, that is, if the RAM clear switch 431 is ON, the "RAM clear" processing mode is selected, and the next RAM clear without jumping at Sf2. It shifts to the process (S15), but otherwise jumps to SYSTEM_160, that is, the setting confirmation branch determination process (S19).

In the present embodiment, of the eight combinations of the values of the fourth, fifth, and sixth bits of the A register, the RAM clear branch determination process (S18) is executed in seven other than A (1,1,1). In the case of kind. Of these seven types, the "RAM clear" processing mode is selected from three types: A (0,1,1), A (1,1,0), and A (0,1,0). Since this is the case (see FIG. 69), in this S18, it is sufficient to determine only the 5th bit out of the 4th, 5th, and 6th bits of the A register.

Since the set value work area is not cleared by the RAM clear process (S15) as described above, in the present embodiment, the RAM error determination process (S16) is executed before the RAM clear branch determination process (S18). It is configured.

The RAM clear processing (S15) and subsequent processing are as described above, but in this case, the system operation status remains at the initial value of 01H at the time of Sg9 in the RAM clear processing (S15). In the setting change via determination process (Sg9), it is determined that the setting change process (S14) is not used, and the setting change via determination process (Sg11 to Sg22) is not executed. Therefore, since the setting change confirmation display for about 1 second is not performed, there is no needless waiting time of 1 second even though the setting change is not performed.

The setting confirmation branch determination process (S19) that shifts when it is determined in the RAM clear branch determination process (S18) that the fifth bit of the A register is not 1 is either "setting confirmation" or "backup recovery". Is to be selected. In this way, by performing the setting confirmation branch determination process (S19) after the RAM abnormality determination process (S16), it is possible to avoid a situation in which the setting cannot be restored due to a RAM error after the setting confirmation or the backup restoration is determined.

In the setting confirmation branch determination process (S19), as shown in FIG. 67, first, the value of the A register is compared with "01010000B" (@ DOPEN + @SETKY) and the difference between them is obtained (Sh1). The value obtained by this is when the 4th and 6th bits of the A register are 1 and the 5th bit is 0 (= A (1,0,1)), that is, the door (front frame 3) is opened and the RAM is cleared. It becomes 0 when the switch 431 is OFF and the setting change operation means 432 is ON (see FIG. 69). If the obtained value (difference) is 0, for example, 1 is set in ZF (zero flag). Then, if the value obtained in Sh1 is not 0 (ZF = 0), that is, if it is not A (1,0,1), the processing mode of "backup recovery" is selected instead of "setting confirmation", and the next step is The setting confirmation process (S20) is skipped, and the process shifts (jumps) to SYSTEM_180, that is, the backup return process (S21) (Sh2).

In the present embodiment, of the eight combinations of the values of the fourth, fifth, and sixth bits of the A register, the setting confirmation branch determination process (S19) is executed only when the fifth bit is 0. Is. Of these four types, the "setting confirmation" processing mode is selected only in the case of A (1,0,1), and the other A (0,0,1) and A (1). , 0,0), A (0,0,0), the processing mode of "backup recovery" is selected in all cases (see FIG. 69).

In the backup recovery process (S21), as shown in FIG. 67, first, the address of the backup flag in the area RAM is set in the HL register (Sj1), and the backup flag is set from the address of the winning opening error detection timer 3 in the area RAM. The value obtained by subtracting the address and adding 1 is set in the B register (Sj2), and the 0 clear process is called (Sj3). In the present embodiment, the backup flag work area is next to the set value work area of the RAM in the area, and the error-related work is from the next to the backup flag work area to the winning opening error detection timer 3 work area. It is an area. Therefore, by the above Sj1 to Sj3, the backup flag work area in the RAM in the area and the subsequent error-related work area are cleared to 0. In this way, even when the backup is restored, only the error-related work area is cleared to 0 so that the error information before the power failure is not carried over.

Then, 03H, which is the lower byte data for the power failure recovery display command, is set in the W register (Sj4), and the process proceeds to the next common process (S22). The common process (S22) has already been described, but in this case, since 03H is set in the W register, the power failure recovery display command follows the transmission (Sk1 and Sk2) of the initialization command (BA01H). (BA03H) is transmitted.

The explanation is continued by returning to the setting confirmation branch determination process (S19). In Sh2 of FIG. 67, if the value obtained in Sh1 is 0 (ZF = 1), that is, if A (1,0,1), the processing mode of "setting confirmation" is selected, and SYSTEM_180 (backup). The process proceeds to the next setting confirmation process S20 without jumping to the return process S21).

In the setting confirmation process (S20), as shown in the source program of FIG. 67 and the flowchart of FIG. 78, first, an initial value (for example, a value corresponding to 30 seconds) is set in the invalid information timer (W_SGTMER) (Si1). This rogue information timer is for counting the output time of the security signal. For example, in the timer interrupt process described later, the security signal is output until the value of the rogue information timer becomes 0. In the present embodiment, in the case of "setting confirmation", since the initial value is set in the invalid information timer at the start of the setting confirmation process (S20), a predetermined time (here, 30 seconds) is set after the setting confirmation is completed. The output of security signals is guaranteed. That is, for example, when the initial value is set to the invalid information timer at the end of the setting confirmation process (S20), for example, the power is turned off (power cut) during the setting confirmation period, the setting change operation means 432 is turned off, and the power is turned on. There is a possibility that the output of the security signal can be canceled if the backup is restored by re-inputting (return to power failure). Since the initial value corresponding to the second is set, the output of the security signal cannot be canceled. That is, in the present embodiment, the security signal is output externally even when the game process is executed without executing the setting confirmation process (S20) when the power is cut off during the execution of the setting confirmation process (S20) and the subsequent power failure is restored. Therefore, it is possible to reliably output the security signal for a predetermined time.

Subsequently, a setting confirmation start command (BA60H) indicating that the setting confirmation period has started is transmitted (Si2, Si3). When the effect control board 416a receives the setting confirmation start command (BA60H), for example, the liquid crystal display means 327 displays "setting confirmation in progress" or the like (FIG. 102). In addition, for example, by adding the set value data to the lower byte of the setting confirmation start command (BA60H), the setting confirmation start command (BA60H to BA65H) to which the information of the setting value data is added may be transmitted.

Next, the set value data acquired from the set value work area was set in the W register (Si4), and "10000000B" (@SEG_DP), which is the display pattern data corresponding to ". (Dot)", was set in the A register. Above (Si5), the system input / output management process (M_SYSIO) is called (Si6). A series of processes is repeatedly executed until the setting confirmation end condition is satisfied, that is, until the OFF edge of the setting change operation means 432 is detected. (Si7, Si8).

Here, the system input / output management process has already been described in the setting change process (S14) and the power restart wait process (S17), but the setting change process is performed because the values of the W register and the A register are different. Some operations are different from those in the process of waiting for the power to be turned on again. That is, in this setting confirmation process, the set value data is set in the W register and the display pattern data corresponding to ". (Dot)" is set in the A register when calling the system input / output management process (Si4, respectively). Si5), in Ss4 (FIG. 71) of the system input / output management process, from the address obtained by adding the value of the W register (set value data) to the value of the HL register (the start address of the 7-segment decoding table for numerical values). The display pattern data is acquired, the logical sum (OR) with the A register (display pattern data corresponding to ". (Dot)") is obtained, and the value of the A register is updated. As a result, any one of "1." to "6." is displayed on the setting display means 434, that is, the 7-segment display unit 433d of the performance information display means 433 corresponding to the set value data (any of 0 to 5). Will be done.

Then, when the OFF edge of the setting change operation means 432 is detected, a setting confirmation end command (BA67H) indicating that the setting confirmation period has ended is transmitted (Si9, Si10), and the backup restoration process (S21) already described is performed. Move to.

As described above, in the present embodiment, the process related to the dynamic lighting control of the setting display means 434 (7-segment display unit 433d) and the power supply abnormality check process are set as the system input / output management process (M_SYSIO), and the setting change process (S14) and the power supply reset. The program capacity is reduced by standardizing between the input waiting process (S17) and the setting confirmation process (S20).

When the above S12 to S22 are completed, the process proceeds to the main loop processing (S23 to S28). In this main loop processing, interrupts are prohibited (S23), various random numbers are updated (S24), all registers are saved in the stack area (S25), out-of-area processing (S26) is executed, and then all registers are restored. A series of processes of allowing interrupts (S27) and allowing interrupts (S28) are repeatedly executed. As a result, for example, the timer interrupt process is called and executed at a cycle of 4 ms.

Here, in the out-of-area processing (S26), as shown in FIG. 79, the in-region stack pointer is first saved (S61), and the out-of-area RAM check processing (S62) is executed. In this out-of-area RAM check process (S62), for example, as shown in FIG. 80, it is determined whether or not there is an abnormality in the out-of-area RAM (S71), and it is a condition that it is determined that there is an abnormality in the out-of-area RAM. (S71: Yes), the out-of-area RAM is initialized (cleared) (S72).

As described above, when an abnormality occurs in the out-of-region RAM during the main loop, the out-of-region RAM is initialized (S71, S72), but in the present embodiment, the operation confirmation timer is stored in the in-region RAM. Therefore, for example, even if an abnormality occurs in the out-of-area RAM before the value of the operation confirmation timer reaches 0, the value of the operation confirmation timer is not cleared.

Following the out-of-area RAM check process (S62), the performance display aggregation division process (S63) is executed. The performance display aggregation division process (S63) calculates the base value (specific value) to be displayed on the performance display means 435, and for each unit measurement period until the "total number of outs" reaches a predetermined number (for example, 60,000). In addition, the number of outs during a specific period (hereinafter referred to as "normal out number") excluding during the jackpot game (including during the jackpot start / end interval), high probability state, and open extension state, and also during the specific period. The real-time base value (specific value) is calculated by counting the number of payouts (hereinafter referred to as "normal payout number") and dividing the "normal payout number" by the "normal out number". The main control board 415a that executes this performance display aggregation division process (S63) constitutes a specific value calculation means for calculating a base value (specific value).

In the present embodiment, a total out counter that counts the "total out number" based on the detection signal by the out ball detecting means 414 and a normal out counter that counts the "normal out number" based on the detection signal by the out ball detecting means 414. An out counter and a winning counter (specific number counter) that counts the number of winnings (specific number) to each winning means during a specific period based on the detection signal provided by the winning detecting means provided in each winning means are provided. There is. The "normal payout number" is counted based on the number of winnings to each winning means by the winning counter and the number of winning balls for each winning means. Switching between addition / non-addition of each counter for each game state is as shown in FIG. 81. In the following description, the period in which the winning detection means and the out-ball detecting means 414 are added to the winning counter and the normal out-counter when the game ball is detected is referred to as an "addition period", and the period in which the addition is not made is referred to as a "non-addition period".

In the performance display aggregate division process (S63), the count process by each counter is always performed, but the process of calculating the base value using the counter value is executed when the start value is set in the aggregate division counter described later. However, it is not executed at other timings. In addition, when the unit measurement period ends, the real-time base value at that time becomes the new first cumulative base value, and the first and second cumulative base values up to that point become the new second and third cumulative base values, respectively. Become.

After the performance display aggregation division process (S63) is executed, the stack pointer in the area is returned (S64), and the process outside the area is terminated.

In the present embodiment, the counting by the winning counter is performed based on the detection by the winning detecting means 345a to 350a provided in the winning means 345 to 350, and the counting by the normal out counter is based on the detection by the out ball detecting means 414. However, as shown in FIG. 51, since there is a distance between the winning detection means 345a to 350a and the out ball detecting means 414, one game ball passes through the winning detecting means and then passes through the out ball detecting means 414. It will take some time before. FIG. 82 shows the minimum and maximum values of the elapsed time from when the game ball passes through the winning detection means to when it passes through the out-ball detecting means 414. It is shown for each (excluding the big winning means 347). Similarly, for the out port 358, the minimum value and the maximum value of the elapsed time from passing through the out port 358 to passing through the out ball detecting means 414 are shown. Hereinafter, the elapsed time from passing through the winning detection means or the out opening to passing through the out ball detecting means 414 is referred to as "specific elapsed time".

In the present embodiment, as is clear from the positional relationship between the winning detection means and the out ball detecting means 414 shown in FIG. 51, the magnitude relationship of the minimum values Ta1 to Te1 shown in FIG. 82 is Tb1> Tc1> Td1> Ta1> Te1. Similarly, the magnitude relationship of the maximum values Ta2 to Te2 is Tb2> Tc2> Td2> Ta2> Te2. For example, the normal winning unit 325 is provided with a second out port, and the unit of the large winning means 347 is provided with a third out port, and the minimum and maximum values of the specific elapsed time for the second out port are Tf1, Tf2, and the first, respectively. When the minimum and maximum values of the specific elapsed time for the three out ports are Tg1 and Tg2, respectively, the magnitude relationship between the minimum values Ta1 to Tg1 is, for example, Tb1> Tc1> Td1> Tf1> Tg1> Ta1> Te1, and the maximum values are also the same. The magnitude relationship between Ta2 and Tg2 is, for example, Tb2> Tc2> Td2> Tf2> Tg2> Ta2> Te2. Hereinafter, when it is assumed that the second out port is provided, Tf1 and Tf2 are used as the minimum and maximum values of the specific elapsed time, and when it is assumed that the third out port is also provided, the specific elapsed time is used. Tg1 and Tg2 are used as the minimum and maximum values of.

Here, depending on the winning timing to the winning means, the addition period (specific period) is set when the winning detecting means is passed, but the non-adding period is set when the out ball detecting means 414 is passed. , It is conceivable that the winning counter is added but the out counter is not normally added. Due to the shift to (specific period), the winning counter may not be added, but the normal out counter may be added.

In order to eliminate such inconvenience, in the present embodiment, when the jackpot variation of the first and second special symbols (the last symbol variation before the end condition of the specific period is satisfied) is executed during the normal game state. Is configured to make the fluctuation time longer than the maximum value (specific time) of the specific elapsed time of the starting winning means for the symbol variation. In addition, if the last 1st and 2nd special symbols before the end of the special gaming state are out of alignment fluctuations (the last symbol fluctuations before the start condition of the specific period is satisfied), the fluctuation time is used as the symbol. It is configured to be longer than the maximum value (specific time) of the specific elapsed time of the starting winning means regarding fluctuation.

FIG. 83A shows a symbol variation in which a game ball wins a prize in the first special symbol starting means 345 and becomes a big hit by the first special symbol display means 363 in a normal gaming state and in a state where the first special hold number is 0. Is shown as an example when. In this case, at the end of the change of the first special symbol, the addition period (specific period) is shifted to the non-addition period (big hit game), but the change time of the first special symbol is the specific progress regarding the first special symbol starting means 345. Since it is longer than Ta2 (see FIG. 82), which is the maximum value of the time (elapsed time from the time when the game ball passes through the winning detection means 345a to the time when the game ball passes through the out ball detecting means 414), the game ball is the winning detecting means 345a. Both the timing of passing through the ball and the timing of the game ball passing through the out ball detecting means 414 are during the addition period, and the above-mentioned inconvenience does not occur.

Further, FIG. 83 (b) shows the final variation (for example, the 50th time) of the time saving state in which the game ball wins the second special symbol starting means 346 in the time saving state and the second special holding number is 0. An example is shown in the case where the deviation variation is performed by the second special symbol display means 364. In this case, at the end of the change of the second special symbol, the non-addition period (time saving state) is changed to the addition period (specific period), but the change time of the second special symbol is the specific progress regarding the second special symbol starting means 346. Since it is longer than Tb2 (see FIG. 82), which is the maximum value of the time (the elapsed time from when the game ball passes through the winning detection means 346a to when it passes through the out ball detecting means 414), the game ball is the winning detecting means 346a. Both the timing of passing through the ball and the timing of the game ball passing through the out ball detecting means 414 are during the non-addition period, and the above-mentioned inconvenience does not occur.

As described above, for the start winning prize related to the final symbol variation before switching between the addition / non-addition period, the passing timing of the winning detection means and the out-ball detection by appropriately setting the fluctuation time of the final symbol variation. It is possible to prevent the passage timing of the means 414 from being divided into an addition period and a non-addition period.

On the other hand, winning a prize during the change that is the jackpot mode of the first and second special symbols (during the last symbol change before the end condition of the specific period is satisfied) and the last first and first before the end of the special gaming state. The passing timing of the winning detection means and the passing timing of the out-ball detecting means 414 are added to the winning during the fluctuation of the second special symbol (the last symbol change before the start condition of the specific period is satisfied). It cannot be completely prevented from being divided into a period and a non-addition period. The same applies to the game ball passing through the out opening 358.

Therefore, in the present embodiment, as illustrated below, each winning detection means (excluding the large winning means 347) is set for a predetermined period before the end of the change in the last symbol change before the end of the addition period or the start of the addition period. And, it is set to substantially the same time as the minimum value of the specific elapsed time for the out port 358.

FIG. 84 shows an example in which the effect symbol 370 fluctuates in the SP reach 1 jackpot fluctuation pattern during the normal gaming state (addition period). In this SP reach 1 jackpot fluctuation pattern, after the SP reach effect (a), the winning effect (b1 to b3) as to whether or not the jackpot is achieved, the winning effect (c1 to c3) relating to the jackpot, and the jackpot symbol display. The symbol is confirmed (e) through (sway fluctuation) (d1 to d3), but the fluctuation time after the jackpot symbol display (sway fluctuation) is set to the minimum value of the specified elapsed time (specific time; here, the specification regarding the out port 358). It is set to a time shorter than Te1), which is the minimum value of the elapsed time (almost the same time may be used). Further, the fluctuation time after the winning effect is longer than the maximum value of the specific elapsed time (specific time; here, Tb2 which is the maximum value of the specific elapsed time of the second special symbol starting means 346) (may be substantially the same time). ) Is set. As the minimum value and the maximum value of the specific elapsed time, any of Ta1 to Tg1 and Ta2 to Tg2 may be used, respectively.

Here, regarding the white arrow and the black arrow shown in the lower part of FIG. 84, the start point indicates the passing timing of the winning detection means and the like, the end point indicates the passing timing of the out ball detecting means 414, and the white arrow indicates the addition / If it does not span the non-addition period, the black arrow indicates the case where it spans the addition / non-addition period. The same applies to FIGS. 85 to 87.

In the example of FIG. 84, when the winning means is won or the ball is entered into the out opening 358 after the jackpot symbol display (sway fluctuation), the passing timing of the out ball detecting means 414 is after the transition to the non-addition period ([[]. 1], [2]). In addition, if the player wins a prize in the winning means or enters the out opening 358 before the winning effect in which the player has not yet grasped whether or not it is a big hit, the passing timing of the out ball detecting means 414 is before the transition to the non-addition period. ([3], [4]).

The period of the winning effect is a transitional period, and when the winning means is won or the ball is entered into the out opening 358 during the winning effect, the passing timing of the out ball detecting means 414 shifts from before the transition to the non-addition period. It will be either later ([5], [6]). In [6] of FIG. 84, an example is shown in which a game ball that has entered the out opening 358 in the early stage of the winning effect passes through the out ball detecting means 414 during the addition period, but the timing of entering the out opening 358 is different. If it is late, for example, at the end of the winning effect, the timing of passing through the out ball detecting means 414 may be after the transition to the non-addition period (non-specific period). Similarly, in [5] of FIG. 84, an example is shown in which a game ball that has won a prize in the normal winning means 350 at the end of the winning effect passes through the out ball detecting means 414 after the transition to the non-addition period (non-specific period). However, if the winning timing to the normal winning means 350 becomes earlier and, for example, the early stage of the winning effect, the timing of passing through the out ball detecting means 414 may be before the transition to the non-addition period (during the addition period). be.

Further, in FIG. 84, only an example of winning / winning in the normal winning means 350 and the out opening 358 during the winning effect is shown ([5], [6]), but for example, the timing of winning / winning is the winning effect. In the early stage of, for example, for all winning means and out openings including the second and third out openings, the passing timing of the out ball detecting means 414 of the game ball after winning / entering is during the addition period (specific period). If the winning / winning timing is the final stage of the winning production, all the winning means including the second and third out openings and a part of the out openings, for example, the second special symbol starting means 346, normal winning. With respect to the means 348 to 350, the passing timing of the out ball detecting means 414 of the game ball after winning is after the transition to the non-addition period (non-specific period), and other examples such as the second and third out openings and the first special symbol. For the starting means 345 and the out port 358, the passing timing of the out ball detecting means 414 of the game ball after winning / winning may be set to be during the addition period (specific period).

It should be noted that the winning effect of FIG. 84 includes two as stop symbol candidates of the changing medium symbol, "7" which constitutes the jackpot effect mode and "6" which constitutes the off-target effect mode. The content is that the time until they appear and are destroyed with a hammer is competed by two characters (b1), and "6" is destroyed first and "7" remains (b2, b3).

In the winning effect, the board movable body 371 operates in front of the liquid crystal display means 327 to return to the origin position (c1), and the jackpot effect mode of "7, 7, 7" is displayed in the center of the screen, for example (c2). , The effect symbol 370 is reduced and moved to the corner of the screen to display an animation of the content to congratulate the jackpot by a character or the like (c3), and the jackpot effect mode of "7, 7, 7" is displayed again in the center of the screen, for example. (C4) It is the content. Here, if the winning / winning timing is c1 to c3 of the winning effect, for example, for all the winning means and the out openings including the second and third out openings, the out balls of the game ball after the winning / winning. If the passing timing of the detection means 414 is during the addition period (specific period) and the winning / winning timing is c4 of the winning effect, for example, for all the winning means and the out openings including the second and third out openings. The passing timing of the out-ball detecting means 414 of the game ball after winning / winning may be set to be after the transition to the non-addition period (non-specific period). For example, the part (c1, c2) from the operation of the frame movable body 156 at the beginning to the display of the jackpot effect mode of "7, 7, 7" may be included in the previous winning effect instead of the winning effect.

The jackpot symbol display is displayed in the center of the screen, for example, after returning to the normal screen (d1) and after the animation in which each production symbol of "7, 7, 7" changes (rotation, scaling, shaking, etc.) (d2). (D3) It is the content. Here, by lengthening the period of the jackpot symbol display d1 to d3 and the symbol confirmation e, for example, the second and third out openings can be used regardless of whether the winning / winning timing is c1 to c4 of the winning effect. For all the winning means and the out opening including the winning means, the passing timing of the out ball detecting means 414 of the game ball after winning / winning may be configured to be during the addition period (specific period). Further, in the present embodiment, the period (d1) of the normal screen before each symbol is changed by the animation is also included in the jackpot symbol display, but the jackpot symbol display is defined after the animation of each symbol (d2, d3). The period (d1) of the normal screen before that may be included in the winning effect.

FIG. 85 shows an example in which the effect symbol 370 fluctuates in the SP reach 2 jackpot fluctuation pattern during the normal gaming state (addition period). This SP reach 2 jackpot fluctuation pattern was revived after the SP reach effect (a), the winning effect (b1 to b3) indicating whether or not it was a big hit, the losing effect (c) indicating that it was a loss, and the big hit. The symbol is confirmed after the revival effect (d1 to d4) indicating that, and the jackpot symbol display (sway fluctuation), but the fluctuation time after the jackpot symbol display (sway fluctuation) is the minimum value of the specific elapsed time (specific time; here). Then, the time is set shorter than Te1), which is the minimum value of the specific elapsed time for the out port 358 (may be substantially the same time). Further, the fluctuation time after the defeat effect is longer than the maximum value of the specific elapsed time (specific time; here, Tb2 which is the maximum value of the specific elapsed time of the second special symbol starting means 346) (may be substantially the same time). ) Is set. As the minimum value and the maximum value of the specific elapsed time, any of Ta1 to Tg1 and Ta2 to Tg2 may be used, respectively.

In the example of FIG. 85, when the winning means is won or the ball is entered into the out opening 358 after the jackpot symbol display (sway fluctuation), the passing timing of the out ball detecting means 414 is after the transition to the non-addition period ([[]. 1], [2]). In addition, if the player wins the winning means or enters the out opening 358 before the losing effect for which the player does not know the jackpot, the passing timing of the out ball detecting means 414 is before the transition to the non-addition period ([[]. 3], [4]).

The period of the resurrection effect is a transitional period, and when the winning means is won or the ball is entered into the out port 358 during the resurrection effect, the passing timing of the out ball detecting means 414 shifts to before the transition to the non-addition period. It will be either later ([5], [6]). In [6] of FIG. 85, an example is shown in which a game ball that has entered the out port 358 in the early stage of the revival effect passes through the out ball detecting means 414 during the addition period, but the timing of entering the out port 358 is different. If it is late, for example, at the end of the revival effect, the timing of passing through the out ball detecting means 414 may be after the transition to the non-addition period (non-specific period). Similarly, in [5] of FIG. 85, an example is shown in which a game ball that has won a prize in the normal winning means 350 at the end of the revival effect passes through the out ball detecting means 414 after the transition to the non-addition period (non-specific period). However, if the winning timing to the normal winning means 350 becomes earlier and, for example, the early stage of the revival production, the timing of passing through the out ball detecting means 414 may be before the transition to the non-addition period (during the addition period). be.

Further, in FIG. 85, only an example of winning / winning in the normal winning means 350 and the out opening 358 during the revival production is shown ([5], [6]), but for example, the timing of winning / winning is the revival production. In the early stage of, for example, for all winning means and out openings including the second and third out openings, the passing timing of the out ball detecting means 414 of the game ball after winning / entering is during the addition period (specific period). If the winning / winning timing is the final stage of the revival production, all the winning means including the second and third out openings and a part of the out openings, for example, the second special symbol starting means 346, normal winning. With respect to the means 348 to 350, the passing timing of the out ball detecting means 414 of the game ball after winning is after the transition to the non-addition period (non-specific period), and other examples such as the second and third out openings and the first special symbol. For the starting means 345 and the out port 358, the passing timing of the out ball detecting means 414 of the game ball after winning / winning may be set to be during the addition period (specific period).

It should be noted that the winning effect of FIG. 85, like the winning effect of FIG. 84, constitutes an effect mode that is different from "7", which constitutes the jackpot effect mode, as a stop symbol candidate of the changing medium symbol. It is a content that two characters with "6" appear and the time until they are destroyed with a hammer is competed by two characters (b1), but "7" is destroyed first and "6" remains. (B2, b3). Further, the defeated effect is a content that displays the out-of-order effect mode of "7, 6, 7" on the normal screen (c).

The revival effect is substantially the same as the winning effect of FIG. 84, in which the movable board 371 operates in front of the liquid crystal display means 327 and returns to the origin position (d1), and the jackpot effect mode of "7, 7, 7". For example, after displaying in the center of the screen (d2), the effect symbol 370 is reduced and moved to the corner of the screen to display an animation of the content to congratulate the big hit by the character etc. (d3), and then "7, 7, 7" again. The jackpot effect mode is displayed in the center of the screen, for example (d4). Here, if the winning / winning timing is d1 to d3 of the revival effect, for example, for all the winning means and the out opening including the second and third out openings, the out ball of the game ball after the winning / winning. If the passing timing of the detection means 414 is during the addition period (specific period) and the winning / winning timing is d4 of the revival effect, for example, for all the winning means and the out openings including the second and third out openings. The passing timing of the out-ball detecting means 414 of the game ball after winning / winning may be set to be after the transition to the non-addition period (non-specific period).

The jackpot symbol display and symbol determination are the same as those in FIGS. 84 (d1) to (d3) and (e). Here, by lengthening the period for displaying the jackpot symbol and confirming the symbol, all winnings including, for example, the second and third out openings, regardless of whether the winning / winning timing is d1 to d4 of the revival effect. The means and the out opening may be configured so that the passing timing of the out ball detecting means 414 of the game ball after winning / winning is during the addition period (specific period).

FIG. 86 shows an example in which the effect symbol 370 fluctuates in a normal deviation 1 fluctuation pattern as the final fluctuation during the time saving state (non-addition period). This normal deviation 1 fluctuation pattern is performed after the left, right, and middle symbols are temporarily stopped (a to d), and then a result effect (e1 to e3, f) for displaying game performance information in a time-saving state is performed. It is confirmed (g). The result effect is composed of a result display period (f) for displaying game performance information and a result display start period (e1 to e3) before that, during which the off-target symbol display (sway fluctuation) is performed in parallel. Will be done. Further, in the example of FIG. 86, the fluctuation time after the result display period of the result effect is shorter than the minimum value of the specific elapsed time (specific time; in this case, Te1 which is the minimum value of the specific elapsed time for the out port 358). It may be about the same time). Further, the fluctuation time after the result display start period of the result effect is longer than the maximum value of the specific elapsed time (specific time; here, Tb2 which is the maximum value of the specific elapsed time for the second special symbol starting means 346) (. It may be about the same time). As the minimum value and the maximum value of the specific elapsed time, any of Ta1 to Tg1 and Ta2 to Tg2 may be used, respectively.

In the example of FIG. 86, when the winning means is won or the ball is entered into the out opening 358 after the result display period of the result effect, the passing timing of the out ball detecting means 414 is after the transition to the addition period ([1]]. , [2]). Further, if the winning means is won or the ball is entered into the out opening 358 before the final symbol is stopped (temporarily stopped), the passing timing of the out ball detecting means 414 is before the transition to the addition period ([3], [Four]). Then, the result display start period in the result effect is a transient period, and when the winning means is won or the ball is entered into the out opening 358 during the result display start period, the passing timing of the out ball detecting means 414 is the addition period. It will be either before or after the migration ([5], [6]).

In the result effect of FIG. 86, the change period from the start of the result display to the display of the final numerical value is the result display period (e1 to e3), and the period during which the final numerical value is displayed as the result display. (F) is the result display period. During this result effect, the design of "6, 7, 7", which is an out-of-order effect mode, is reduced and displayed in a temporarily stopped state (e1 to e3), and is completely stopped (f) by the end of the result effect. There is.

FIG. 87 shows an example in which the effect symbol 370 fluctuates in the usual Wrong Answer 2 fluctuation pattern as the final fluctuation during the time saving state (non-addition period). This normal Wrong Answer 2 variation pattern is a result effect (e1 to e3, f, g1, g2) that displays game performance information in a time-saving state after each of the left, right, and middle symbols is temporarily stopped (a to d). , The design is confirmed via the normal screen (h). The result effect is composed of a result display period (f) for displaying game performance information, a result display start period (e1 to e3) before that, and a final end display period (g1, g2). In addition, the pattern display (sway fluctuation) is performed in parallel from the result effect to the normal screen. Further, in the example of FIG. 87, the fluctuation time after the normal screen is shorter than the minimum value of the specific elapsed time (specific time; here, Te1 which is the minimum value of the specific elapsed time for the out port 358) (even at substantially the same time). Good) is set. Further, the fluctuation time after the end display period of the result effect is longer than the maximum value of the specific elapsed time (specific time; here, Tb2 which is the maximum value of the specific elapsed time related to the second special symbol starting means 346) (omitted). It may be the same time). As the minimum value and the maximum value of the specific elapsed time, any of Ta1 to Tg1 and Ta2 to Tg2 may be used, respectively.

In the example of FIG. 87, when the winning means is won or the ball is entered into the out opening 358 after the normal screen after the result effect, the passing timing of the out ball detecting means 414 is after the transition to the addition period ([1]]. , [2]). Further, if the winning means is won or the ball is entered into the out opening 358 before the final symbol is stopped (temporarily stopped), the passing timing of the out ball detecting means 414 is before the transition to the addition period ([3], [Four]). The result effect period is a transitional period, and when the winning means is won or the ball is entered into the out port 358 during the result effect, the passing timing of the out ball detecting means 414 is before and after the transition to the addition period. ([5], [6]).

In the result effect of FIG. 87, the change period from the start of the result display to the display of the final numerical value is the result display period (e1 to e3), and the period during which the final numerical value is displayed as the result display. Is defined as the result display period (f), for example, the period during which the screen is blacked out and "END" is displayed is the end display period (g1, g2). During the result display start period of this result effect, the symbol of "6, 7, 7", which is an off-effect effect mode, is reduced and displayed in a temporarily stopped state, and is completely stopped by the end of the result display period.

FIG. 88 shows “setting change”, “RAM clear”, and “setting confirmation” of the main commands transmitted from the main control board 415a to the effect control board 416a and the transmission order thereof in the power-on processing described above. , "Backup recovery" and "RAM error" are shown for each of the five types of processing modes. As is clear from FIG. 88, the setting change start command (BA76H) and the setting change end command (BA77H) in the "setting change", the setting confirmation start command (BA60H) and the setting confirmation end command (BA67H) in the "setting confirmation". , The power re-on command (BA7FH) in "RAM error" is transmitted only in each processing mode, but the other commands are commonly transmitted in a plurality of processing modes.

Subsequently, the timer interrupt processing (FIG. 89) of the main control board 415a will be described. In this timer interrupt process (FIG. 89), first, the power supply abnormality check process (S81) is executed. This power supply abnormality check process (S81) is common to the power supply abnormality check process shown in FIG. 74 already described. In this way, the program capacity can be further reduced by standardizing the power supply abnormality check processing between the power-on processing and the timer interrupt processing.

When the power supply abnormality check process (S81) is completed, the timer management process (S82) for managing various timers used for game control, and the detection information by various sensors such as the winning detection means and the operating means provided in each winning means are input. Input management process to manage (S83), setting error check process to check abnormalities related to set values (S84), error management process to monitor the occurrence of various errors (S85), random number update to update various random numbers such as jackpot judgment random numbers. The prize ball management process (S87) for managing the prize balls, such as the process (S86) and the transmission of the payout control command to the payout control board 425a, is executed.

Here, in the timer management process (S82), for example, a subtraction process of the operation confirmation timer is also performed. The subtraction process of the operation confirmation timer is performed until, for example, the value of the operation confirmation timer becomes 0. The operation confirmation timer is a value obtained by adding 1 to the timer value corresponding to the operation confirmation time (here, 4800 ms) as the initial value in the work area initial setting process (Sk12 in FIG. 76) in the common process (S22) at the time of turning on the power. Specifically, since 1201 is set, it is decremented by 1 in the first timer management process (S82) after the power is turned on, and becomes 1200 corresponding to 4800 ms.

Further, following the prize ball management process (S87), a normal symbol management process (S88), a normal electric accessory management process (S89), a special symbol management process (S90), and a special electric accessory management process (S91) are performed. Run.

The normal symbol management process (S88) manages the fluctuation of the normal symbol by the normal symbol display means 361, and based on the normal symbol starting means 344 detecting the game ball, the normal random number information such as the hit determination random number value. And the ordinary random number information is stored in the first-in, first-out storage area up to a predetermined upper limit reserved number (for example, 4), and the ordinary symbol display means 361 is in a state where variable display is possible and one or more. On condition that the ordinary random number information is stored (the number of normally reserved numbers is 1 or more), the first hit determination random number value is taken out from the ordinary random number information queue, and the hit determination random number value is predetermined. The hit / miss judgment (hit judgment) is performed according to whether or not it matches the hit judgment value, and the stop symbol and the fluctuation time after the change of the normal symbol are selected based on the hit judgment result, and the normal symbol is selected. The display means 361 is used to change the normal symbol.

Further, the ordinary electric accessory management process (S89) manages the ordinary profit state, and the stop symbol after the change of the ordinary symbol display means 361 is the hit mode based on the hit determination result of S88. In such a case, the opening / closing portion 346b of the second special symbol starting means 346 is changed to the open state according to a predetermined opening / closing pattern to generate a normal profit state.

The special symbol management process (S90) manages the fluctuation of the first and second special symbols by the first and second special symbol display means 363 and 364, and the first and second special symbol starting means 345 and 346 Based on the detection of the game ball, the first and second special random number information consisting of the jackpot determination random number value, the jackpot symbol random number value, and other random number values are acquired, and the first and second special random number information are predetermined. The upper limit reserved number (for example, 4 each) is stored in the first-in first-out storage area, and when the first and second special symbol display means 363 and 364 are in a state where variable display is possible, the second special If the number of holdings is 1 or more, the second special random number information queue is taken out, and if only the first special holding number is 1 or more, the first special random number information queue is taken out from the first jackpot determination random number value. The jackpot judgment random number value is used to determine the jackpot / miss with a predetermined jackpot probability, and the stop symbol mode of the first and second special symbols and the variation pattern of the effect symbol are determined according to the jackpot determination result. Etc. are determined, and the first and second special symbols are changed by the first and second special symbol display means 363 and 364.

The special electric accessory management process (S91) manages the jackpot game, and the result of the jackpot determination becomes the jackpot, and the stop symbol after the change of the first and second special symbol display means 363 and 364 is the jackpot mode (specification). (Aspect), a jackpot game (first and second special profit states) in which the opening / closing plate 347b of the big winning means 347 is changed to the open state according to a predetermined opening pattern is generated. The main control board 415a that executes this special electric accessory management process (S91) constitutes a jackpot game executing means (special game executing means) that executes a jackpot game (special game).

Following the special electric accessory management process (S91), the external terminal process (S92) and the LED management process (S93) are executed. In the external terminal processing (S92), processing for outputting various information from the external output terminal to an external device such as a hall computer is performed. In the present embodiment, for example, the initial value (for example, the value corresponding to 30 seconds) is set in the invalid information timer at the start of the setting confirmation process (S20), but in this external terminal process (S92). While subtracting the invalid information timer, a security signal is output from the external output terminal until the value becomes 0 (that is, until, for example, 30 seconds have elapsed).

Further, the LED management process (S93) manages the light emission of the LEDs constituting the game information display means 326, the performance display means 435 (performance information display means 433), and the like. In the present embodiment, the game information display means 326 and the performance information display means 433 are driven and controlled by a dynamic lighting method.

In the LED management process (S93), as shown in FIG. 90, first, a clear signal is output to the LED common port and the LED data port to clear the port (S101), and the LED output counter is incremented (S102). Then, the common data corresponding to the value of the LED output counter is selected from the LED common output selection table (FIG. 91 (a)) (S103), and the common data is output to the LED common port (S104).

In the LED common output selection table of the present embodiment, as shown in FIGS. 91A and 63, the first common data that turns on the common C0 and the common C4, and the common C1 and the common C5 are turned on. Four types of common data are provided: the second common data, the third common data that turns on the common C2 and the common C6, and the fourth common data that turns on the common C3 and the common C7. The 1st to 4th common data are selected cyclically in that order according to the increase of the LED output counter.

As a result, the lighting target of the game information display means 326 changes sequentially in the order of LED group 326a → 326b → 326c → 326d → 326a → ... For each interrupt (here, every 4ms), and similarly, the performance display means 435 ( The lighting target of the performance information display means 433) changes sequentially as in the 7-segment display unit 433a → 433b → 433c → 433d → 433a → ....

Subsequently, with respect to the LED output counter, the value of the fifth bit when the lowest bit is the 0th bit is determined (S105), and two LED data output information tables A and B (FIG. 91 (b) are determined according to the value. ))) (S106a, 106b). As a result, the LED data output information table can be switched every 32 interrupts (128 ms). Of course, the number of interrupts to switch the LED data output information table is arbitrary.

Here, the LED data output information tables A and B correspond to the LED data port 1 connected to the game information display means 326, and as shown in FIG. 91, the LED data output information tables A and B correspond to the first to fourth common data, respectively. The 1st to 4th LED data A0 to A3 and B0 to B3 are provided. That is, the first LED data A0 and B0 are the LED data of the LED group 326a (first special symbol display means 363) of the game information display means 326 corresponding to the common C0, and the second LED data A1 and B1 are in the common C1. The LED data of the LED group 326b (second special symbol display means 364) of the corresponding game information display means 326, and the third LED data A2 and B2 are the LED group 326c (special) of the game information display means 326 corresponding to the common C2. The fourth LED data A3 and B3 are the LED data of the LED group 326d (ordinary symbol display means 361 and the like) of the game information display means 326 corresponding to the common C3.

When either of the LED data output information tables A and B is selected (S106a, S106b), the LED data corresponding to the value of the LED output counter is selected from the LED data output information table (S107), and the LED data is used as LED data. Output to port 1 (S108) and end the LED management process.

By the above processing, the four LED groups 326a to 326d of the game information display means 326 can be turned on while being sequentially switched every 4 ms, and two types of display modes can be switched every 128 ms in the same group.

Returning to the timer interrupt process of FIG. 89, the description will be continued. When the LED management process (S93) described above is completed, the contents of all the registers are saved in the stack area (S94), and then the performance display update process (S95) for displaying by the performance display means 435 is executed. By this performance display update processing (S95), after the operation confirmation display in which the performance display means 435 repeats all lighting and all turning off is performed for a predetermined operation confirmation time (for example, about 5 seconds), the performance display aggregation division processing (FIG. Multiple types of base values calculated in S63) of 79 (here, four types of real-time base values and first to third cumulative base values) are displayed on the performance display means 435. Multiple base value display periods (real-time base values) The display period, the first to third cumulative base value display periods) is cyclically switched at predetermined time (for example, about 5 seconds, here 4.8 seconds).

As described above, since the operation confirmation display of the performance display means 435 is executed in the LED management process (S93) of the timer interrupt, the start time is the setting display performed for a predetermined time (for example, about 1 second) after the setting change is completed. After the setting change confirmation display by the means 434 is completed. After the operation confirmation display of the performance display means 435, the base value may be displayed only for a predetermined period such as when the door (front frame 3) is open, or when a predetermined condition other than the passage of time is satisfied ( For example, when a button operation is performed), a plurality of base value display periods may be switched.

In the four 7-segment display units 433a to 433d (FIGS. 3 and 63) constituting the performance display means 435, for example, the upper two-digit 7-segment display units 433d and 433c are the types of base values (real-time base value, 1st to 1st to 3rd). The identification display unit (separate from the third cumulative base value) and the like, and the lower two-digit 7-segment display units 433b and 433a are numerical display units that display the numerical values of the base value and the like.

The base value is measured for each unit measurement period until the total number of outs reaches a predetermined number (60,000 in this case), but the power is turned on during the first unit measurement period after the first power is turned on. It does not start from time, but starts after a predetermined pre-measurement period has elapsed (for example, when the total number of outs reaches a predetermined number (here, 300)).

During the real-time base value display period, for example, "bL." Showing the real-time base value is displayed on the identification display unit, and for example, the real-time base value at the start of the real-time base value display period or immediately before the start of the real-time base value display period is displayed on the numerical display unit. However, if the display mode of "bL." In the identification display unit is different between lighting and blinking, depending on whether or not the total number of outs in the unit measurement period at that time has reached a predetermined threshold value (for example, 6000). It is designed to let you. For example, the base value is displayed on the numerical display after rounding off to the first decimal place, but if the rounded value is 3 digits or more, "99." or the like indicating overflow is displayed on the numerical display. do.

Further, during the 1st to 3rd cumulative base value display period, for example, "b1." To "b3." Showing the 1st to 3rd cumulative base values are displayed on the identification display unit, and the numerical display unit thereof. The 1st to 3rd cumulative base values at the time are displayed, but if the 1st to 3rd cumulative base values have not yet been obtained, for example, "b1." To "b3." In the identification display unit are blinking. At the same time, "---" is displayed on the numerical display unit. For example, until the end of the first unit measurement period after the first power-on, none of the first to third cumulative base values have been obtained, so the performance display means during the first to third cumulative base value display periods. The display of 435 is "b1 .--" to "b3 .--".

During the pre-measurement period (total number of outs is less than 300) before the start of the first unit measurement period, "bL.", "B1." To "b3." It is displayed, and for example, "---" is lit up on the numerical display unit.

In the performance display update process (S95), as shown in FIG. 92, all the registers are first saved (S111), and then the display update process (S112) displays the data in the identification display unit output buffer and the numerical display unit output buffer, respectively. The pattern data is set, and the display pattern data set in the identification display unit output buffer and the numerical display unit output buffer is selected by the LED management process (FIG. 90) by the subsequent display data output process (S113). By outputting data to the LED data port 2 (FIG. 63) according to the 7-segment display unit), a predetermined display is performed on the performance display means 435. Then, the test firing test signal output process (S114) is executed, all the registers are restored, and the process ends (S115).

Hereinafter, the processing procedure of the display update processing (S112) will be described with time lapse while appropriately referring to the time charts of FIGS. 98 to 100. In the display update process (S112), as shown in FIG. 93, only when the execution of the display update process is the first time after the power is turned on (S121: Yes), various information (operations) regarding the display of the performance display means 435 are performed. Initial setting of the first information excluding the confirmation timer) is performed (S122). Various methods can be considered for the determination of S121, but in the present embodiment, the determination is made based on whether or not the value of the operation confirmation timer is a value corresponding to 4800 ms, specifically 1200 or not. The operation confirmation timer of this embodiment is set to a value obtained by adding 1 to the timer value corresponding to 4800 ms as the initial value, specifically 1201 in the work area initial setting process (Sk12 in FIG. 76) at the time of turning on the power. Since 1 is subtracted in the first timer management process (S82) after that, the value of the operation confirmation timer is 1200 corresponding to 4800 ms at the time of the first display update process (S112) after the power is turned on.

In S122, for example, 0 is set in the blinking cycle timer, 15 is set in the lighting / extinguishing switching counter, a predetermined non-start value is set in the aggregation division counter, and 4 is set in the display content pointer, and the identification display unit output buffer and the identification display unit output buffer and The extinguished data (0000H) is set in the output buffer of the numerical display unit. Here, the blinking cycle timer is for measuring the blinking cycle, the lighting / extinguishing switching counter is for switching between lighting and extinguishing when blinking, and the aggregate division counter is counted in the performance display aggregate division process (S63). This is to specify the timing for calculating the real-time base value using the value. Further, the display content pointer is for designating the display content of the performance display means 435, that is, the type of the base value, for example, a real-time base value, a value of 1 to 4 corresponding to the first to third cumulative base values. It is designed to take.

As described above, in the present embodiment, the first information regarding the display of the performance display means 435, that is, the blinking cycle timer, the on / off switching counter, the total division counter, and the display content pointer are configured to be initially set after the power is turned on. So, for example, every time the power is turned on, the lighting / extinguishing state when the operation confirmation display is started does not differ, and the type of base value that is initially displayed after the operation confirmation display does not differ. The state at the start of display of the performance display means 435 after being turned on can always be the same.

Further, in the present embodiment, among the predetermined information regarding the display of the performance display means 435, the operation confirmation timer is initially set by the power-on processing before the interrupt processing is started (Sk12), and the other first information. For example, the blinking cycle timer, the on / off switching counter, the total division counter, and the display content pointer are initially set by interrupt processing (S122), so the processing time when the power is turned on is short, and quick startup is possible. be.

The blinking cycle timer, the on / off switching counter, the total division counter, and the display content pointer are stored in the out-of-area RAM (second storage area). Therefore, when it is determined in the out-of-area RAM check process (FIG. 80) that the out-of-area RAM is abnormal (S71: Yes), the operation confirmation timer stored in the in-area RAM is not cleared, but the out-of-area RAM is not cleared. The blinking cycle timer, lighting / extinguishing switching counter, total division counter, display content pointer, etc. stored in are cleared.

Subsequently, the blinking cycle timer is incremented (S123), and it is determined whether or not the value of the blinking cycle timer after the addition is a predetermined value (75 corresponding to 0.3 seconds in this case) or more (S124). If the value of the blinking cycle timer is less than a predetermined value (S124: No), the display update process ends here. If the value of the blinking cycle timer in S124 is a predetermined value (75 in this case) or more (S124: Yes), the blinking cycle timer is cleared (S125) and the processing after S126 is executed. As described above, the processing after S125 is executed every time the blinking cycle timer reaches 75, which is a predetermined value, that is, every time, for example, 0.3 seconds (= 4 ms × 75) elapses.

In the above-mentioned S122, since the extinguishing data (0000H) is set as the initial value in the identification display unit output buffer and the numerical display unit output buffer, respectively, until the first yes determination is made in S124 (the blinking cycle timer is the first). The performance display means 435 is completely turned off for about 0.3 seconds (T1 to T2 in FIG. 98) (until the predetermined value is reached).

Following S125, the lighting / extinguishing switching counter is incremented (S126), and it is determined whether the value of the lighting / extinguishing switching counter after the addition is an even number or an odd number (S127). It shifts to S131 of FIG. 94, and if it is an odd number, it shifts to S141 of FIG. 95. That is, for example, every 0.3 seconds, the processing after S131 shown in FIG. 94 and the processing after S141 shown in FIG. 95 are alternately performed.

In the present embodiment, since 15 is set as the initial value in the lighting / extinguishing switching counter in S122, the lighting / extinguishing switching counter becomes an even number (= 16) in S127 (T2 in FIG. 98) for the first time after the power is turned on. It shifts to S131 of FIG. 94. Since the lighting / extinguishing switching counter at this time is 16 and is equal to or higher than a predetermined value (15 in this case), the lighting / extinguishing switching counter is cleared by S131 and becomes 0 (see FIG. 98). Further, since the value of the operation confirmation timer at this time is 1126 (see FIG. 98) and is not 0 (S132: No), lighting data (FFFFH) is set in the identification display unit output buffer and the numerical display unit output buffer, respectively. (S133, S134), and the display update process ends here. As a result, the performance display means 435 switches from the all-off state to the all-on state. The lighting data of S133 and S134 are directly written to each output buffer without referring to the data table or the like.

In the display update process 0.3 seconds later, the lighting / extinguishing switching counter after addition by S126 becomes 1 (T3 in FIG. 98), so that it is determined to be an odd number in S127 and the process shifts to S141 in FIG. 95. Since the value of the operation confirmation timer at this point is 1051 (see FIG. 98) and is not 0 (S141: No), turn-off data (0000H) is set in the identification display unit output buffer and the numerical display unit output buffer, respectively. (S142, S143). As a result, the performance display means 435 switches from the all-on state to the all-off state. The extinguished data of S142 and S143 are also written directly to each output buffer without referring to the data table or the like. Further, since the value of the lighting / extinguishing switching counter at this point is 1 and not a predetermined value (15 in this case) (S147: No), the display update process ends here.

The above processing is repeated until the lighting / extinguishing switching counter after addition by S126 reaches 15 (T4 in FIG. 98). Then, when the lighting / extinguishing switching counter after addition by S126 becomes 15 (T5 in FIG. 98), it is determined as an odd number in S127 and the process shifts to S141 in FIG. Since it is 1 (see FIG. 98) and not 0, the extinguishing data (0000H) is set in the identification display unit output buffer and the numerical display unit output buffer in S142 and S143, respectively. As a result, the performance display means 435 switches from the all-on state to the all-off state.

Since the lighting / extinguishing switching counter at this time is 15, the subsequent determination of S147 becomes Yes, and the processes of S148 to S151 are executed. That is, 1 is added to the display content pointer (S148), and 1 is set to the display content pointer on condition that the display content pointer after the addition is a predetermined value (here, 5) or more (S149: Yes). (S150). In the present embodiment, since 4 is set as the initial value in the display content pointer in S122, the value of the display content pointer after the addition in S148 is 5, and it is determined in S149 that the value is equal to or higher than the predetermined value, and is displayed in S150. 1 is set in the content pointer. Then, the start value is set in the aggregate division counter (S151), and the display update process ends.

When the start value is set in the aggregate division counter, in the performance display aggregate division process (S63 in FIG. 79), the division process for calculating the real-time base value using the count value at that time is performed. When the real-time base value is calculated, the aggregate division counter is set to the non-start value. Even if the start value is set in the aggregation division counter, for example, during the pre-measurement period in which the real-time base value is not displayed, the real-time base value may not be calculated.

In the display update process 0.3 seconds later, the lighting / extinguishing switching counter after addition by S126 is 16 (T6 in FIGS. 98 and 99). , The on / off switching counter is cleared and becomes 0. Since the operation confirmation timer is already 0 at this point (S132: Yes), the operation confirmation display is terminated and the processes of S135 to S138 are executed. As described above, in the present embodiment, the operation confirmation display for switching between all off and all on of the performance display means 435 at predetermined time (0.3 seconds) is about 5.1 seconds (=) from T1 to T6 in FIG. 0.3 seconds x 17) It is done.

In S135 to S138, first, the identification display unit display pattern data corresponding to the display content pointer is acquired from the identification display unit LED data table (S135), and the acquired identification display unit display pattern data is set in the identification display unit output buffer. (S136). As shown in FIG. 96A, the identification display unit LED data table includes "bL.", "B1.", "B2.", And "b3" corresponding to the values 1 to 4 of the display content pointer. The display pattern data corresponding to the display of "." Is stored in advance. Since the value of the display content pointer at this point is 1 (see FIG. 99), the display pattern data corresponding to the display of "bL." Is set in the identification display unit output buffer.

Further, the numerical display unit display pattern data corresponding to the display contents on the numerical display unit is acquired from the decimal numerical value LED data table (S137), and the acquired numerical display unit display pattern data is set in the numerical display unit output buffer. (S138). The display content on the numerical display unit is determined based on the display content pointer and the section pointer, for example, as shown in FIG. 97. Here, the interval pointer indicates a period related to the measurement of the base value. For example, as shown in FIG. 97, a "pre-measurement period" followed by a "first unit measurement period", a "second unit measurement period", and "a second unit measurement period". A value of 1 to 5 is taken corresponding to five types of periods, "the third unit measurement period" and "after the fourth unit measurement period". Further, as shown in FIG. 96B, the decimal value LED data table contains in advance 10 types of numbers "0" to "9" and 1-byte display pattern data corresponding to "-". It is stored.

At this point (T6 in FIG. 99), there is a high possibility that the display content pointer is 1 and the section pointer is 1 (pre-measurement period). Therefore, as shown in FIG. 97, the display content of the numerical display unit is ". --- ". Therefore, "01000000B" corresponding to the tens digit "-" and "01000000B" corresponding to the ones digit "-" are acquired from the decimal value LED data table and set in the numerical display unit output buffer. Will be done.

As a result, the real-time base value display period (pre-measurement period) is started at the time point of T6 in FIGS. 98 and 99 (the end time of the operation confirmation display), and the display of the performance display means 435 is changed from the all off state to "bL-. It can be switched to "-".

In the display update process 0.3 seconds later (T7 in FIG. 99), the lighting / extinguishing switching counter after addition by S126 becomes 1, and it is determined in S127 that it is an odd number. Then, since it is determined in S141 of FIG. 95 that the value of the operation confirmation timer is 0 (S141: Yes), in the subsequent S144, it is determined whether the display mode of the identification display unit is lit / blinking. On condition that the determination result is blinking (S145: Yes), the extinguishing data (0000H) is set in the identification display unit output buffer (S146). As a result, the display of the identification display unit is switched from, for example, "bL." To the off state. Since the value of the numerical display unit output buffer is not updated, the display of the numerical value display unit remains unchanged, for example, as "---".

The above processing is repeated until the lighting / extinguishing switching counter after addition by S126 reaches 16 (T8 in FIG. 99). When the lighting / extinguishing switching counter after addition by S126 becomes 15 (T8 in FIG. 99), the determination in S147 in FIG. 95 is Yes. Therefore, the display content pointer is changed from 1 by the processing of S148 to S151. As it changes to 2, the start value is set in the aggregate division counter.

As a result, 0.3 seconds later (T9 in FIG. 99), the real-time base value display period ends and the first cumulative base value display period starts anew. It becomes a blinking state, and for example, "---" is lit and displayed on the numerical display unit.

FIG. 100 shows the performance when the section pointer is 3 (second unit measurement period) and the display content pointer is 2 (first cumulative base value display period) as an example when the display mode of the identification display unit is lit. The display state of the means 435 is shown. When the section pointer is 3 and the display pointer is 2, the display mode of the identification display unit is lit (FIG. 97). Therefore, when the value of the lighting / extinguishing switching counter after the addition of S126 is an even number, identification is performed. The identification display unit display pattern data corresponding to "b1." Is set in the display unit output buffer, and the numerical display unit display pattern data corresponding to the first cumulative base value at that time is set in the numerical display unit output buffer (S135). If the value of the lighting / extinguishing switching counter after the addition of S138) and S126 is an even number, neither the identification display unit output buffer nor the numerical display unit output buffer is updated. Therefore, during the first cumulative base value display period of T10 to T11 in FIG. 100, "b1." Is lit and displayed on the identification display unit, and the first cumulative base value at that time is lit and displayed on the numerical display unit. ..

Then, when the display content pointer is switched from 2 to 3 and the second cumulative base value display period is started (T11 in FIG. 100), the display mode of the identification display unit blinks (FIG. 97), so that S126 is added. When the value of the subsequent lighting / extinguishing switching counter is an even number, the identification display unit display pattern data corresponding to "b2." Is displayed in the identification display unit output buffer, and "---" is displayed in the numerical display unit output buffer. When the corresponding numerical display unit display pattern data is set (S135 to S138) and the value of the lighting / extinguishing switching counter after the addition of S126 is an odd number, the extinguishing data (0000H) is set in the identification display unit output buffer. (S146). Therefore, during the second cumulative base value display period from T11 to FIG. 100, "b2." Is blinked and displayed on the identification display unit, and "---" is lit and displayed on the numerical display unit.

If an error occurs in the out-of-area RAM during the operation check display (T1 to T6 in FIG. 98) (S71: Yes in FIG. 80), the out-of-area RAM is cleared (S72), but the operation check timer is in the area. It is not cleared because it is stored in the inner RAM. Therefore, the operation confirmation display is not interrupted and continues as it is at least until the value of the operation confirmation timer reaches 0. However, in this case, the blinking cycle timer, the on / off switching counter, the display content pointer, etc. (first information) stored in the out-of-area RAM are cleared, so that, for example, the blinking timing (the value of the blinking cycle timer is predetermined). The timing of reaching the value (75)) may change. Further, when the display content pointer is cleared, the initial display content after the operation confirmation display may change.

Returning to the timer interrupt process of FIG. 89, the description will be continued. When the performance display update process (S95) described above is completed, the contents of the saved register are restored (S96), the WDT is cleared (S97), and the timer interrupt process is terminated.

Subsequently, the control operation of the effect control board 416a will be described. The effect control board 416a is produced by various effect means such as a liquid crystal display means 327, an illumination means 436, speakers 17, 30a, 30b, 31a, 31b, a frame movable effect means 153, an operation effect means 232, and a board movable effect means 328. As shown in FIG. 62B, the power-on control means 441, the special hold quantity display control means 442, the symbol variation effect control means 443, the error notification control means 444, and the like are provided.

The power-on control means 441 controls various effect means such as the liquid crystal display means 327 based on receiving various control commands from the main control board 415a at the time of power-on.

In FIGS. 101 and 102, the main reception commands from the main control board 415a and the operation contents of the corresponding liquid crystal display means 327, the illumination means 436, the speaker 17, etc., the movable effect means 153, 328, etc. are processed for each processing mode. FIG. 101 shows the case of “RAM clear” and “setting change”, and FIG. 102 shows the case of “backup recovery”, “setting confirmation” and “RAM error”.

When the RAM is cleared, as shown in FIG. 101, when a power-on command (FA08H) is received, character information such as "Please Wait" is displayed on the liquid crystal display means 327, but all the lighting means 436 are displayed. The light is turned off, no sound such as BGM is output from the speaker 17 or the like (silence), and the movable effect means 153, 328 or the like maintains a state of being stopped at the origin position, for example (no change). Then, when the initialization command (BA01H) is received after that, the liquid crystal display means 327, the illumination means 436, the speaker 17, etc. continue to be in the previous state, but the movable effect means 153, 328, etc. are initially operated (the initial operation (). The execution of the initialization operation) is started.

Then, when the RAM clear command (BA02H) is received, a predetermined symbol mode by the effect symbol 370, for example, "2, 3.7" (low accuracy screen) is displayed on the liquid crystal display means 327, and all the illumination means 436 are displayed. It is turned on, a predetermined RAM clear sound is output from the speaker 17 and the like, and the movable effect means 153, 328 and the like continue to be in the state (initial operation) up to that point.

After that, when the customer waiting command (BA04H) is received, the display of the liquid crystal display means 327 continues as it is until the demo display is started after 180 seconds, for example, and the illumination means 436 emits light in a predetermined customer waiting pattern, for example. The BGM output is continued from the speaker 17 or the like until, for example, fades out after 30 seconds have elapsed, and the movable effect means 153, 328 and the like continue to be in the state up to that point.

As for the setting change, as shown in FIG. 101, when the setting change start command (BA76H) is received after performing the same processing as when the RAM is cleared when the power-on command (FA08H) is received. , The liquid crystal display means 327 displays character information such as "setting is being changed" indicating that the setting is being changed, and the illumination means 436 is made to emit light in a predetermined setting changing pattern, for example, from the speaker 17 or the like. A predetermined setting changing sound is output, but the movable effect means 153, 328 and the like are maintained in the previous state. Then, when the setting change end command (BA77H) is received after that, for example, the liquid crystal display means 327, the illumination means 436, the speaker 17, etc., the movable effect means 153, 328, etc. all maintain the previous state. When the setting change end command (BA77H) is received, the character information such as "setting is being changed" displayed on the liquid crystal display means 327 is erased, and the light emission in the setting changing pattern of the lighting means 436 is terminated. It may be turned off and the output of the sound being changed from the speaker 17 or the like may be stopped. The effect mode of each effect unit at the time of receiving the subsequent initialization command (BA01H), RAM clear command (BA02H), and customer waiting command (BA04H) is the same as that at the time of RAM clear.

As for the backup recovery time, as shown in FIG. 102, when the power-on command (FA08H) and the initialization command (BA01H) are received, the same processing as when the RAM is cleared is performed, and then the power failure recovery display command (BA03H) is performed. ) Is received, text information such as "Recovered from power failure, please restart the game" is displayed on the liquid crystal display means 327, but the illumination means 436 is completely turned off, for example. For the speaker 17 and the like, the mute state is maintained, and for the movable effect means 153 and 328 and the like, for example, the initial operation is continued. After that, when the first and second special hold quantity designation commands (B0xxH, B1xxH), the set value command (F6xxH), and the state designation commands (FAxxH to FDxxH) are received, for example, the liquid crystal display means 327, the illumination means 436, and the speaker 17 Etc., the state up to that point is maintained for any of the movable effect means 153, 328 and the like. Then, when the customer waiting command (BA04H) is received, the liquid crystal display means 327 has a predetermined symbol mode according to the effect symbol 370, for example, "2, 3.7" (low) until the demo display is started after 180 seconds have elapsed. (Probability screen) is displayed, the illumination means 436 is made to emit light in a predetermined customer waiting pattern, for example, and BGM output is continued from the speaker 17 or the like until it fades out after 30 seconds, for example, and the movable effect means 153, 328 and the like are displayed. Continue the state up to that point.

At the time of this backup recovery, the state before the power failure is restored. Therefore, for example, if the information of the special symbol indicated by the game information display means 326 before the power failure is the jackpot stop mode, even after the backup recovery. It will return in the stop mode of the jackpot. Here, when the setting change process is executed, after the RAM clear process, as the information of the special symbol indicated by the game information display means 326, a value indicating a stop mode of disconnection, a value indicating non-lighting, and other specific values If (display mode not used during the game) is set, a contradiction occurs with the display mode of the special symbol at the time of backup restoration, and this causes backup restoration (that is, non-setting change) or setting change processing is performed. The player can determine the contradiction. This is not limited to the information of the special symbol shown by the game information display means 326, but the same can be said for the information of the ordinary symbol. Therefore, when the backup is restored, the information on whether or not the special symbol is changing is confirmed, and if it is determined that the special symbol is not changing, the display mode of the special symbol indicated by the game information display means 326 is changed. By setting the same stop mode as the above, even if the information of the special symbol indicated by the game information display means 326 is a display mode indicating a hit when the backup is restored, a value indicating the stop mode of the loss or non-lighting. Since it can be rewritten to a value indicating the above value and other specific values (display mode not used during the game), there is no contradiction with the setting change process.

Here, the reason for confirming the information on whether or not the special symbol is changing is that if the special symbol is changing, the information on the changing special symbol will be rewritten as an error. This is because if the fluctuation is a hit fluctuation, a contradiction will occur in which the hit is displayed in a missed manner. It cannot be said that such a contradiction meets the standards that can be provided to the market as a gaming machine, and it is an event that should never occur, so the configuration is as described above. In this way, when the backup is restored, if a specific condition (non-variable, waiting for a customer, etc.) is satisfied by referring to the information of the special symbol, the information of the special symbol of the game information display means 326 is rewritten. Also, by this, the same information is displayed as the game information display means when the backup is restored when a specific condition (state before power failure is non-variable, waiting for customers, etc.) is satisfied, and when the RAM is cleared or the setting is changed. It can be specified as a display mode of the special symbol of 326, and it becomes possible to make it difficult to determine whether or not the setting change process has been performed. Further, the same configuration may be made by referring not only to the information of the special symbol but also to whether or not the customer is in the waiting state, which can occur only during the non-variation of the special symbol. Further, it is desirable that not only the special symbol but also the normal symbol shown by the game information display means 326 has the same configuration. As a result, it is possible to configure the normal symbol as well as the special symbol so that there is no contradiction in the display mode when the backup is restored and when the setting is changed.

As for the setting confirmation, as shown in FIG. 102, when the setting confirmation start command (BA60H) is received after performing the same processing as when the RAM is cleared when the power-on command (FA08H) is received. , The liquid crystal display means 327 displays character information such as "setting is being confirmed" indicating that the setting is being confirmed, and the illumination means 436 is made to emit light in a predetermined setting confirmation pattern, for example, from the speaker 17 or the like. A predetermined setting confirmation sound is output, but the movable effect means 153, 328 and the like are maintained in the previous state. After that, when the setting confirmation end command (BA67H) is received, for example, the liquid crystal display means 327, the illumination means 436, the speaker 17, etc., the movable effect means 153, 328, etc. all maintain the previous state. Then, the initialization command (BA01H), the power failure recovery display command (BA03H), the first and second special hold quantity designation commands (B0xxH, B1xxH), the setting value command (F6xxH), the status designation command (FAxxH to FDxxH), and the customer waiting The effect mode of each effect unit at the time of receiving the medium command (BA04H) is the same as that at the time of returning to backup. For example, when the setting confirmation end command (BA67H) is received, the character information such as "setting confirmation" displayed on the liquid crystal display means 327 is erased, and the light emission in the setting confirmation pattern of the illumination means 436 is terminated. Then, the light may be turned off and the output of the sound during setting confirmation from the speaker 17 or the like may be stopped.

When the RAM is abnormal, as shown in FIG. 102, when the power-on command (FA08H) is received, the same processing as when the RAM is cleared is performed, and then the power-on command (BA7FH) is received. , Displays text information such as "RAM error, please turn on the power again and set the setting to 1" to prompt the liquid crystal display means 327 to turn on the power again, but the lighting means 436, speaker 17, etc. are movable. The production means 153, 328 and the like are maintained in their previous states.

The special hold quantity display control means 442 controls the display of the first and second special hold quantity on the liquid crystal display means 327, and corresponds to the increase / decrease in the first and second special hold quantity, the first special hold. Corresponds to the number of first reserved images X1 to X4 (maximum 4), the second reserved images Y1 to Y4 for the second special reserved number (maximum 4), and the changing 1st and 2nd special symbols. The variable pending image Z is displayed on the liquid crystal display means 327.

In the present embodiment, in order to preferentially digest the reserved storage of the second special symbol over the reserved storage of the first special symbol, the second special symbol side is prioritized also for the reserved display, and as shown in FIG. 51, the first The second reserved images Y1 to Y4 are partially overlapped and displayed on the front side of the reserved images X1 to X4. When the hold addition command regarding the first and second special hold numbers is received from the main control board 415a, one additional hold addition image X1 to Y1 to the first and second hold images X1 to Y1 is displayed at the end of the queue. Further, when the hold subtraction command regarding the first and second special hold numbers is received from the main control board 415a, the first and second hold images X1 to Y1 are directed toward the front side of the queue one by one. At the same time as shifting, the extruded first and second reserved images X1 and Y1 are moved to, for example, a predetermined position to be changed to the variable reserved image Z.

The symbol variation effect control means 443 controls the display of the effect symbol 370 and the movement of the movable body, the sound output, the illumination emission, etc., and is designated when the variation pattern command is received from the main control board 415a. Based on the variation pattern scenario corresponding to the variation pattern, the variation effect of the effect symbol 370 on the liquid crystal display means 327 and the accompanying movable body operation, voice output, and illumination emission are started, and the variation stop command is received. Occasionally, the variation of the effect symbol 370 is stopped by the stop symbol selected based on the stop symbol command and the variation pattern command.

FIGS. 103 to 105 show an example of the movable body effect by the frame movable body 156, the board movable body 371, and the operation handle 234 performed during the fluctuation of the effect symbol 370. FIG. 103A shows a state during a predetermined reach effect, and an animation image by a predetermined character is displayed on the liquid crystal display means 327. At this time, the frame movable body 156, the board movable body 371, and the operation handle 234 are held at their respective origin positions.

During the reach effect, when the operation effect accompanied by the operation of the operation handle 234 by the player is started, as shown in FIGS. 103 (b), (c) and 104 (d), the liquid crystal display means 327 receives the operation effect. A countdown image such as "3 → 2 → 1" suggesting the timing of the operation is displayed together with the operation guidance image indicating that the operation handle 234 should be operated. At this time, the operation handle 234, for example, continuously repeats the exit / exit operation, and then stops at the origin position immediately before the countdown ends.

Then, when the player pushes the operation handle 234 in accordance with the timing of the end of the countdown, the liquid crystal display means 327 is blacked out as shown in FIG. 104 (e), and then the board is movable as shown in FIG. 104 (f). The body 371 starts ascending movement on the front side of the liquid crystal display means 327.

The board movable body 371 rises while facing directly in front, and then begins to tilt forward immediately before reaching the upper limit position. When the upper limit position is reached, it is abbreviated as the upper frame movable body 156 as shown in FIG. 105 (g). It has the same inclination. When the board movable body 371 reaches the upper limit position and the frame movable body 156 and the board movable body 371 have a specific relative positional relationship, the two movable bodies 156 and 371 are visually integrated in front view to form a "butterfly". Form a morphology. At this time, the game area 15a exists between the board movable body 371 and the frame movable body 156, but in the central display frame unit 323, the upper constituent member 323c and the like on the upper side thereof are transparently formed. Since the board movable body 371 on the rear side can be visually recognized from the front side, the board movable body 371 and the frame movable body 156 are not visually separated. Moreover, by arranging the non-inflow region 353 in which the game ball cannot flow in inwardly (downward) inwardly on the upper side of the game region 15a and arranging the frame non-movable body 203 on the front side thereof, the board movable body. Since the 371 and the frame movable body 156 are visually connected, the visual sense of unity between the board movable body 371 and the frame movable body 156 becomes stronger.

Further, when the board movable body 371 reaches the upper limit position and the form of the "butterfly" is completed, as shown in FIG. 105 (g), the frame movable body 156 and the board movable body 371 constituting the "butterfly" shape are further formed. And the LED arranged on the frame non-movable body 203 emits light in a common light emitting mode. This common light emitting mode may be any one that emphasizes the sense of unity of the "butterfly", but for example, the LEDs 194a, 381a, 205a arranged along the outer circumference of the "butterfly" are turned on (or blinked) all at once. May emphasize the shape of the "butterfly".

After the board movable body 371 reaches the upper limit position and the form of the "butterfly" is completed, for example, a predetermined effect image is displayed on the liquid crystal display means 327, the operation handle 234 vibrates, and the rotating body 185 starts rotating. .. Further, as shown in FIG. 105 (h), the frame movable body 156 reciprocates back and forth between the origin position and the forward position, and in synchronization with this, the board movable body 371 reciprocates up and down within a range where the inclination changes, for example. Operate. This makes it possible to further emphasize that the frame movable body 156 and the board movable body 371 are integrated to form a "butterfly".

After that, as shown in FIG. 105 (i), the light emission of the LEDs 194a, 381a, 205a is stopped, and both the frame movable body 156 and the board movable body 371 return to the origin position.

The error notification control means 444 controls error notification, for example, when an error command is received from the main control board 415a, an image display by the liquid crystal display means 327, an audio output by a speaker 17 or the like, and a lamp (illumination means 436). ) It is configured to execute error notification by light emission or the like for a predetermined period.

In the present embodiment, for example, regarding the door opening error when the opening of the front frame 3 or the like is detected, the start timing of each error notification by the voice, the lamp, and the liquid crystal is all when the error occurs (when the door is opened). The end timing of error notification is different for each. That is, as shown in FIG. 106, the error notification by the liquid crystal ends when the error is resolved (when the door is closed), the error notification by the lamp ends when a predetermined time (for example, 30 seconds) elapses after the error ends, and the error notification by voice. Is designed to end when a predetermined time has elapsed from the start of notification.

In this way, the voice error notification in the case of a door opening error ends after a predetermined time has elapsed from the occurrence of the error, but the door opening error notification duration by voice is the base value display cycle by the performance display means 435. It is set as follows in relation to.

That is, the performance display means 435 is designed to periodically display a plurality of types of base values at predetermined time intervals, but the number of types of base values to be displayed on the performance display means 435 is displayed by N and each base value. Assuming that the time is T and the duration of door opening error notification by voice is Tes, as shown in FIG. 106, Tes> T × (N-1). For example, if N = 4 and T = 5, Tes> 15.

In this way, by setting the door opening error notification duration Tes by voice to be larger than T × (N-1), for example, 16 seconds, the error notification by voice always spans all the base value display periods. It is effective in the detection and deterrence of goto acts. If Tes is made longer and, for example, Tes> T × N, error notification can be executed by voice while all the base values are displayed in T (seconds) increments, and Tes> T × (Tes> T × ( If N + 1) is set, error notification by voice can always be executed during the period of one base value display cycle by the performance display means 435.

As described above, in the pachinko machine of the present embodiment, the rotation operation unit (first operation means) 82 and the rotation operation unit 82 that can be changed between the non-operation position and the operation upper limit position by an external operation are provided. A return spring (urging means) 83 for urging toward a non-operating position and an operating lever (second operating means) 92 capable of first operation from the outside are provided, and the launching means 16 is attached to the rotation operation unit 82. The game ball is launched with a firing intensity according to the displacement amount from the non-operation position, and the game ball launched with the displacement amount equal to or less than the specific threshold value does not reach the game area 15a and exceeds the specific threshold value. The game ball fired in the state reaches the game area 15a, and when the first operation is performed on the operation lever 92, the firing operation by the firing means 16 is not executed, and the rotation operation unit (first) When the operation means) 82 is in the non-operation position and the second operation is performed on the operation lever (second operation means) 92, the rotation operation unit 82 is moved to the operation upper limit position side along with the second operation. Since the displacement is configured to be equal to or less than the specific threshold value, the foul ball can be easily and surely launched by operating the operation lever 92.

Further, while the second operation is being performed on the operation lever 92, the rotation operation unit 82 is held without returning to the non-operation position. Further, when the rotation operation unit 82 is in the non-operation position, the first operation with respect to the operation lever 92 is prohibited, and the second operation is permitted.

Further, when the frame movable body 156 and the board movable body 371 have a specific relative positional relationship, the frame movable body 156 and the board movable body 371 are visually integrated to form a "butterfly" form (specific form). It is configured to do. At this time, the inclination of at least one of the frame movable body 156 and the board movable body 371 (here, the board movable body 371) changes immediately before the specific relative positional relationship is established, so that the frame movable body in the specific relative positional relationship is established. The inclinations of the 156 and the movable board 371 are substantially the same. Further, when the frame movable body 156 and the board movable body 371 have a specific relative positional relationship, the LED on the frame movable body 156 side (first light emitting body) and the LED on the board movable body 371 side (second light emitting body) Is designed to emit light in a common light emitting mode.

Further, a non-inflow region 353 in which the game ball cannot flow in is arranged in an inwardly recessed shape at a predetermined position in the game region 15a, and is arranged in the front frame 3 and visually as a frame movable body 156 and a board movable body 371. At least a part of the frame non-movable body 203 that is integrated with the non-movable body 203 to form a part of the specific form is configured to be located on the front side of the non-inflow region 353.

Further, in the game area 15a, a left flow path 341 on the left side, a right flow path 342 on the right side, and a right guide passage 351 for guiding the game ball flowing into the upper side of the game area 15a to the right flow path 342 are provided. , The right guide passage 351 is arranged along the edge of the non-inflow region 353. Further, the right guide passage 351 is transparently formed, and when the board movable body 371 is in the upper limit position (board side specific position), a part of the board movable body 371 is located behind the right guide passage 351. ing. Further, the return rubber 352 is arranged on the upstream end side of the right guide passage 351.

Further, each of the normal out counters that count the number of outs during a specific period based on the detection by the out ball detecting means 414 and the detection by the winning detecting means including the starting winning winning detecting means 345a and 346a during the specific period. A winning counter (specific number counter) that counts the number of winnings (specific number) to the winning means, and a specific value calculating means that calculates a base value (specific value) based on each count value of the normal out counter and the winning counter. The specific period starts when the start condition is satisfied at least after the end of the symbol variation by the first and second special symbol display means 363 and 364, and by the first and second special symbol display means 363 and 364. It is configured to end when the end condition is satisfied after the end of the symbol variation, and during a specific period, the fluctuation time of the last symbol variation before the end condition is satisfied is set as the start prize detecting means 345a, 346a. The game ball detected by is made longer than the maximum value (specific time) regarding the elapsed time until it is detected by the out ball detecting means 414, and the fluctuation time of the last symbol variation before the start condition is satisfied is started. The game ball detected by the winning detection means 345a and 346a is made longer than the maximum value (specific time) regarding the elapsed time until the game ball is detected by the out ball detecting means 414.

Further, during the specific period, the game ball detected by the start winning winning detection means during the predetermined period before the end of the symbol change in the last symbol change before the end condition is satisfied is subsequently detected by the out ball detecting means. It is set to a shorter time than the specific time it takes to be detected.

Further, during a non-specific period other than a specific period, the game ball detected by the start winning detection means for a predetermined period before the end of the symbol change in the last symbol change before the start condition is satisfied is subsequently. The time is set to be shorter than the specific time required for detection by the out-ball detecting means.

FIG. 107 exemplifies the second embodiment of the present invention, and partially modifies the first embodiment to provide an intermediate decorative body 451 on the frame movable body 156, and the intermediate decorative body 451 is mounted on the game board 15 side. An example of arranging the non-inflow region 353 in front of the non-inflow region 353 is shown.

For example, the intermediate decorative body 451 is substantially the same as the frame non-movable body 203 in the first embodiment in terms of the front shape, and is arranged in a protruding shape under the decorative unit 169 in the frame movable body 156. It is designed to operate integrally with 156.

Then, when the frame movable body 156 is within the movable range (frame side specific position) between the origin position and the forward position, the intermediate decorative body 451 is located on the front side of the non-inflow region 353 in the upper constituent member 323c and is in front of the frame movable body 156. It does not overlap with the right guide passage 351 visually.

In this way, the intermediate decorative body 451 that operates integrally with the frame movable body 156 may be arranged on the front side of the non-inflow region 353.

FIG. 108 illustrates a third embodiment of the present invention, in which the first embodiment is partially modified so that the frame non-movable body 203 overlaps the front side of the right guide passage 351 in the front view, but the player. An example is shown in which the right guide passage 351 is arranged so as not to overlap with the front side of the right guide passage 351 from the diagonally upward viewpoint corresponding to the height of the eyes.

With this configuration, the frame non-movable body 203 can be arranged so as to project more toward the game area 15a side (here, the lower side), and the visual sense of unity with the board movable body 371 is further enhanced. Is possible.

The second embodiment can also be changed as in the third embodiment. That is, the intermediate decorative body 451 overlaps the front side of the right guide passage 351 in at least a part of the movable range between the origin position and the forward position in the front view, but corresponds to the height of the player's eyes. It may be arranged so as not to overlap the front side of the right guide passage 351 from the diagonally upward viewpoint.

FIG. 109 illustrates a fourth embodiment of the present invention, and shows an example in which the jackpot start interval and the jackpot end interval are set to a time longer than a predetermined time in relation to the display cycle of the base value by the performance display means 435. ing.

During the jackpot start interval and jackpot end interval, the symbol does not change and the jackpot winning means 347 is not opened, so check the base value by the performance display means 435 so that the hall staff etc. do not interfere with the game. It can be said that this is one of the few periods that can be done.

Therefore, in the present embodiment, when the number of types of base values displayed on the performance display means 435 is N, the display time for each base value is T, and the length of the jackpot start / end interval is Tin, for example, Tin> T × (N-1). For example, if N = 4 and T = 5, Tin> 15. In this way, by making the length Tin of the jackpot start / end interval longer than 15 seconds, it is possible to execute the jackpot start / end interval so as to always straddle all the base value display periods, and the jackpot can be executed. It is possible to check all types of base values during the start / end interval.

If Tin is made longer, for example, Tin> T × N, all base values are displayed by at least T (seconds) during the jackpot start / end interval, and Tin is further lengthened, for example, Tin> T. If × (N + 1), the base value display cycle by the performance display means 435 is executed at least once during the jackpot start / end interval, so that there is more room for checking the base value during the jackpot start / end interval. It is possible to carry it.

In addition, in the case of this 4th embodiment, the base value confirmation possible notification that the base value can be confirmed may be executed during the jackpot start / end interval. In this base value confirmable notification, for example, in addition to displaying words such as "base value can be confirmed" on the liquid crystal display means 327, the remaining time until the end of the jackpot start / end interval such as "remaining XX seconds" is displayed as a countdown, for example. You may try to do it. Further, only one of the jackpot start interval and the jackpot end interval may be set to the above length.

FIGS. 110 and 111 illustrate a fifth embodiment of the present invention, and show an example in which a guide gutter 452 for guiding a game ball winning a prize in the second special symbol starting means 346 to the discharge port 412 side is arranged. Further, in the present embodiment, the shape for guiding the game ball in the ball collecting case 411 will also be described.

As shown in FIGS. 110 and 111, the ball collecting case 411 is mounted and fixed to the back side of the base plate 321 in a state of being covered from the rear side on the lower back side of the back mounting base 329. On the front side of the bottom of the back mounting base 329, an opening 453 long in the left-right direction is provided along the back surface of the base plate 321.

The bottom surface of the ball collecting case 411 is composed of a plurality of inclined surfaces whose discharge port 412 side, which is arranged at the center of the ball collecting case 411 in the left-right direction and is lowered, is formed of the discharge port 412 and the inclined surfaces 461 to 465 around the discharge port 412. A part is arranged below the opening 453 of the ball collecting case 411.

On the bottom surface of the ball collecting case 411, for example, the left first inclined surface 461 is arranged on the left side of the discharge port 412, and the left second inclined surface 462 is further arranged on the upstream side (left side) thereof. The right first inclined surface 463 is arranged on the right side, the right second inclined surface 464 is arranged on the upstream side (right side) thereof, and the central inclined surface 465 is arranged on the rear side of the discharge port 412, for example.

The inclined surfaces 461 to 465 all have an inclination angle that descends forward, and the forward inclination angles thereof are, for example, substantially the same (for example, 3 degrees). On the other hand, the inclined surfaces 461 to 464 arranged on the left and right of the discharge port 412 have an inclination angle in the left-right direction so that the discharge port 412 side is low, but the inclination angles of the inclined surfaces 461 to 464 in the left-right direction. Are not the same, but partly different. That is, for example, the inclined surfaces 461 and 462 arranged on the left side of the discharge port 412 have substantially the same inclination angle in the left-right direction (for example, 5 degrees), but the inclined surface arranged on the right side of the discharge port 412. Regarding 466 and 464, the right second inclined surface 464 on the upstream side has a larger inclination angle in the left-right direction than the right first inclined surface 463 on the downstream side (for example, the right first inclined surface 463 is 4 degrees and the right second). 2 The inclined surface 464 is 5 degrees). Further, the inclined surface 461 on the left side and the inclined surface 463 on the right side of the discharge port 412 have different inclination angles in the left-right direction (for example, the left first inclined surface 461 is 5 degrees and the right first inclined surface 463 is. 4 degrees).

The relationship between the left and right inclined surfaces 461 and 463 of the discharge port 412 in the left-right direction is arbitrary. For example, even if the inclined angle of the right inclined surface 463 is larger than the inclined angle of the left inclined surface 461. good. Further, the inclination angle of the side with many winning detection switches (or winning means) (right side in the present embodiment) around the discharge port 412 may be larger than the inclination angle of the side with few winning detection switches (or the left side in the present embodiment). This makes it possible to increase the ejection efficiency of the game ball. Further, although a step is formed at the boundary portion of the inclined surfaces 461 and 462 and the boundary portion of the inclined surfaces 461 and 464, the step may not be provided.

Further, on the back side of the base plate 321, a guide gutter 452 is arranged corresponding to the lower side of the winning detection means 346a provided in the second special symbol starting means 346. The guide gutter 452 includes an inflow port 452a on the upstream end side and an outflow port 452b on the downstream end side. It is arranged substantially in the vertical direction so as to pass between the detection means 348a and the prize detection means 347a arranged below the prize detection means 346a and closer to the discharge port 412 than the prize detection means 346a. The inlet 452a is connected to the downstream side of the winning detection means 346a, and the outlet 452b is opened, for example, downward in the vicinity of the upper side of, for example, the right second inclined surface 464 on the bottom surface of the ball collecting case 411.

The guide gutter 452 is arranged so that the outlet 452b is closer to the outlet 412 than the inlet 452a, and guides the game ball toward the outlet 412 between the inlet 452a and the outlet 452b. An inclination guide portion 452c is provided, and the inclination angle of the inclination guide portion is larger than the inclination angle of the right second inclined surface 464 or the like. Further, the guide gutter 452 is arranged so as to avoid the vicinity thereof and sufficiently pass the position closer to the discharge port 412 with respect to the winning detection means 348a below the winning detecting means 346a. A game ball that has won a prize in the second special symbol starting means 346 and has passed through the winning detection means 346a passes through the guide gutter 452, for example, to avoid a collision with another winning means or the like and to discharge the game ball earlier. You can reach 412. Further, since the game ball discharged from the outlet 452b lands on the inclined surface 464, it is possible to immediately guide the game ball to the discharge port 412 side.

Although the embodiments of the present invention have been described in detail above, the present invention is not limited to these embodiments, and various modifications can be made without departing from the spirit of the present invention. For example, in the embodiment, an example is shown in which the out ball detecting means 414 is arranged on the downstream side of each winning detection means and the out port 358, but the out ball detecting means is arranged on the upstream side of each winning detecting means and the out opening 358. For example, it may be arranged at the entrance of the game area 15a and configured to detect a game ball that has passed through the return prevention valve 337. In this case, if the elapsed time from passing through the out ball detecting means to passing through the winning detection means or the out opening is defined as the "specific elapsed time", the last symbol before the end of the addition period or before the start of the addition period. FIGS. 84 to 84, in which the predetermined period before the end of the fluctuation in the fluctuation is set to a time shorter than the minimum value of the specific elapsed time for each winning detection means (excluding the large winning means 347) and the out port 358 (may be substantially the same time). The example of FIG. 87 can be applied as it is. However, in this case, for the white arrows and black arrows shown in FIGS. 84 to 87, the starting point is the passing timing of the out ball detecting means, and the ending point is the passing timing of the winning detecting means and the like.

The predetermined value of the specific elapsed time may be an average value, a maximum value, or the like instead of the minimum value. Further, the "minimum value (predetermined value) of the specific elapsed time" may be the minimum value (predetermined value) of the specific elapsed time for all the winning means, etc., or for the specific winning means, for example, the starting winning means. It may be the minimum value (predetermined value) of the specific elapsed time.

Further, in the embodiment, the predetermined period before the end of the change in the last symbol change before the end of the addition period or the start of the addition period is set as the symbol determination period + α, but the predetermined period may be only the symbol determination period. For example, in the case of FIGS. 84 and 85, the fluctuation time of the symbol determination is set to the same time as or shorter than the minimum value of the specific elapsed time (here, Te1 which is the minimum value of the specific elapsed time for the out port 358). For example, the fluctuation time after the jackpot symbol display (sway fluctuation) is the same as or longer than the maximum value of the specific elapsed time (here, Tb2 which is the maximum value of the specific elapsed time for the second special symbol starting means 346). May be set to. Further, in the case of FIG. 86, the fluctuation time of the symbol determination is set to the same time as or shorter than the minimum value of the specific elapsed time (here, Te1 which is the minimum value of the specific elapsed time for the out port 358), for example, the result. Set the fluctuation time after the effect display period to be the same as or longer than the maximum value of the specific elapsed time (here, Tb2, which is the maximum value of the specific elapsed time for the second special symbol starting means 346). May be good. Further, in the case of FIG. 87, the fluctuation time of the symbol determination is set to the same time as or shorter than the minimum value of the specific elapsed time (here, Te1 which is the minimum value of the specific elapsed time for the out port 358), for example, normal. The fluctuation time after the screen may be set to the same time as or longer than the maximum value of the specific elapsed time (here, Tb2 which is the maximum value of the specific elapsed time for the second special symbol starting means 346).

In the embodiment, when the frame movable body 156 and the board movable body 371 approach each other and have a specific relative positional relationship, the inclination of the board movable body 371 changes so as to be substantially the same as the inclination of the frame movable body 156. However, the inclination of the frame movable body 156 may be changed, or the inclination of both the frame movable body 156 and the board movable body 371 may be changed. For example, when the board movable body 371 rises and approaches the frame movable body 156, the inclination of the frame movable body 156 may be reduced so as to face directly in front of the board movable body 371.

In the embodiment, the frame movable body 156 is configured to form a "butterfly" by moving the board movable body 371 to the upper limit position while remaining at the origin position, but the board movable body 371 is set to the origin position. The frame movable body 156 may be configured to form a specific form by moving to a predetermined position while stopped. Further, both the frame movable body 156 and the board movable body 371 may be configured to form a specific form by moving to a position other than the origin position.

When the frame movable body 156 and the board movable body 371 are separated from each other and do not form a specific form, for example, the board movable body 371 is deformed to form a form different from the "butterfly" (specific form). It may be configured in. The same applies to the frame movable body 156.

In the embodiment, one frame movable body 156 and one board movable body 371 are configured to form one specific form (butterfly), but at least the frame movable body and the board movable body forming the specific form are formed. A plurality of one may be provided. For example, when a pair of frame movable bodies are arranged on the left and right sides of the viewing window 24 and the board movable body moves to the center of the liquid crystal display means 327, the board movable body and the left and right pair of frame movable bodies form a specific form. You may try to do it.

Regarding the movable body effect using the board movable body and the frame movable body, the order of returning to the standby position (origin position) after the movable body effect is to first return the frame movable body to the standby position and then move the board movable body to the standby position. You may try to return to. Since the frame movable body is configured so that the player can directly touch it, there is a risk that the frame movable body will cause problems such as stopping the moving frame movable body by hand or pinching an object in the movable part. Is higher than the movable board. Therefore, since it is desirable to end the movable body effect, that is, to move to the standby position as quickly as possible, the frame movable body may be moved to the standby position before the board movable body.

On the contrary, the movable board may be moved to the standby position before the movable frame. Since the movable board is located on the front side of the liquid crystal display, the operation of the movable board may hide the display of the liquid crystal display. That is, the contents of the liquid crystal display are restricted until the movable panel moves to the standby position. Therefore, in order to eliminate the restriction as quickly as possible, the movable panel is first moved to the standby position. After moving the frame movable body, the frame movable body may be moved to the standby position.

Further, the movable board and the movable frame may be moved to the standby position at substantially the same time or at the same time. In this case, since simultaneous drive is performed, the current value used by the gaming machine temporarily increases, but if a power supply that can handle this is prepared, move it to the standby position by simultaneous drive. You may. Further, in order to suppress the current value due to simultaneous driving, for example, the LEDs and / or other LEDs mounted on the frame movable body and the board movable body when moving to the standby position are configured to be turned off. May be good.

The liquid crystal display may be started before the movable board and the movable frame move from the effect position to the standby position (origin position). In this case, for example, as shown in FIG. 105 (h), the symbol won this time may be displayed. Further, the continuation of the winning effect that was executed before the movable body effect may be executed.

When the operating means that can be operated by the player is equipped with a vibration means that produces a vibration effect, the vibration effect is executed when the frame movable body and the board movable body form an integrated form (design). You may do so. Further, after that, the vibration effect may be executed until the frame movable body or the board movable body returns to the standby position. However, if the game parts on the frame side such as the operating means are equipped with vibration means, the vibration is transmitted to the entire frame by the vibration effect, and the vibration may affect the operation of the frame movable body. Since there is a property, it is possible not to execute the vibration effect at least when the frame movable body is operating. For example, when the frame movable body and the board movable body form an integrated form (design), the frame movable body is stopped at the effect position, and the vibration effect is executed during that time, from the effect position to the standby position. When moving, the vibration effect may be terminated. Further, the vibration effect may be executed again after moving to the standby position. With such a configuration, it is possible to reduce the risk that the movement of the frame movable body is affected by the vibration effect.

It may have an operation pattern in which the frame movable body and the board movable body are individually operated. Then, a specific motion pattern that operates the frame movable body and the board movable body to form an integrated form (design), a frame motion pattern that operates only the frame movable body, and a board motion pattern that operates only the board movable body. And may be configured to be used properly according to the content of the production. For example, in the winning effect of notifying the final hit of the reach of the hit fluctuation, a specific motion pattern is executed, and in the case of a hit, the frame movable body and the board movable body form an integrated form (design). By setting it to, the effect of the movable body effect may be enhanced.

Further, in the case of a hit fluctuation or a missed fluctuation, a movable body notice for operating the movable body may be executed as a notice for notifying the jackpot expectation degree of the fluctuation. In this case, the frame movement pattern or the board movement may be executed. The pattern may be executed and the specific motion pattern may not be used in the notice of the movable body. As a result, only the board motion pattern and / or the frame motion pattern is executed before the hit effect of the frequently executed deviation fluctuation and hit variation, so that the feeling of exhilaration and the impact when the specific motion pattern is executed are relative. Can be enhanced.

A state in which the frame movable body and the board movable body are operated to form an integrated form (design) in a jackpot state, a time saving state, a latent probability state, a probability change state, etc., which are advantageous to the player as compared with the normal game state. May be maintained. As a result, while the player is staying in an advantageous gaming state, the movable body of the board frame forms an integrated form, so that the player who is playing, of course, can open the hole during non-gaming. Even for pachinko players, it is possible to attract an integrated movable body effect using the entire gaming machine. Further, in the case of such a configuration, it is desirable that the lamp effect corresponding to the fluctuation effect executed during the game is also a lamp pattern conscious of the fact that the board / frame movable body is integrated, for example. In the normal game state in which the board / frame movable body is not integrated, each executes an independent lamp pattern, whereas in the game state in which the board / frame movable body is integrated, each executes an independent ramp pattern. It is desirable to configure it so that the light emission effect is executed by a lamp pattern that can be seen integrally.

Regarding the initialization of the movable body performed when the power is turned on, if there are a specific operation pattern, a frame operation pattern, and a board operation pattern as the operation patterns of the movable body used during the fluctuation, the initialization is performed for all the operation patterns. You may. In this case, the board operation pattern and / or the frame operation pattern may be executed, and then the specific operation pattern may be executed. At that time, if the board operation pattern or the frame operation pattern cannot normally execute the operation, the specific operation pattern may not be executed. Further, regarding the initialization, only a specific operation pattern may be performed, or only a board operation pattern and a frame operation pattern may be performed. In this case, regardless of which one is selected, it is possible to execute the operation check of each movable body of the board frame, so it is possible to reduce the time required for initialization compared to executing all the operation patterns. Become.

The standby position of the movable board may be arranged so as to be behind the movable frame in front view. With such a configuration, the board movable body is arranged so as to be hidden by the frame movable body in the front view, and the board movable body stands by at a position that becomes a blind spot of the player. As a result, when the movable body is produced, the board movable body can be configured to suddenly appear in the visible area of the player from the rear side of the frame movable body, and the player can be surprised. By forming an integrated form (design) between the board movable body and the frame movable body that have appeared, it is possible to perform a more impactful movable body production. Further, when the standby position of the board movable body is arranged so as to be behind the frame movable body in front view, even if all of the board movable bodies are arranged so as to be behind the frame movable body in front view. Alternatively, a part of the movable board may be arranged so as to be behind the movable frame in front view. Further, the standby position of the movable board may be a position that can be a blind spot of the player in front view, for example, so as to be located behind the game board or game parts in the same direction as the upper part where the movable frame is located. It may be arranged. Further, when the frame movable body is arranged on the left and right sides or the lower part instead of the upper part, it may be in the same direction.

The frame movable body and the design of the game board surface (game area) may form an integrated design. Further, the frame movable body, the design of the game board surface, and the board movable body may form an integrated form (design). This makes it possible to form a more integrated design for the entire board frame when the frame movable body operates. The design of the game board surface may be drawn on the game board, may be a sticker-like design, or may be a design (shape, drawing, sticker, etc.) applied to the game parts attached to the game board. good.

By setting the movement direction of the frame movable body and the board movable body to a common direction, it may be configured to execute an integrated movable body movement effect at the time of the movable body effect. For example, when the movable body is produced, the movable board starts moving from the lower side to the upper side, and when the movement to the upper side is completed, the movable frame body moves toward the upper side of the gaming machine. This makes it possible to perform a movable body effect by a more integrated operation using the board / frame movable body. In addition, at the end of the movable body production, the frame movable body first starts to move downward, and when the movement to the standby position is completed, the board movable body is moved from the upper side to the lower side and returned to the standby position. You may do so. In this way, a more integrated board frame movable body effect may be executed from the start to the end of the movable body effect.

It was decided to form an integrated form (design) by operating the board movable body and the frame movable body, but one type or a plurality of types may be used to form the integrated form. .. That is, the operation of the movable board and the movable frame forms the first integrated design, and then the movable board and / or the movable frame further operates, so that the second integrated design is different from the first integrated design. It may be configured to form an integral design. Further, the second integrated design may be different from the first integrated design, for example, it may form a character or design completely different from the first integrated design, or the first integrated design is deformed. It is also possible to form a second integrated design that seems to perform some specific operation. Further, the second integrated design is not limited to the one formed after the first integrated design is formed, and when the first specific motion pattern is executed, the first integrated design is formed and the second specific motion pattern is executed. If so, the second integrated design may be formed. Further, the reliability of the hit may be different depending on whether the first integrated design is formed or the second integrated design is formed.

A plurality of movable frames and movable boards may be provided and combined to form an integrated design. By operating the first frame movable body and the first board movable body, the first integrated design is formed, and by operating the second frame movable body and the second board movable body, the second integrated design is formed. Then, by operating the 1st frame movable body and the 2nd board movable body, the 3rd integrated design is formed, and by operating the 2nd frame movable body and the 1st board movable body, the 4th integrated design is formed. It may be configured to form. Further, the fifth integrated design may be formed by operating the first frame movable body, the second frame movable body, the first board movable body, and the second board movable body.

By moving the movable board body to a predetermined position without operating the movable frame body, an integrated design may be formed. Further, the frame movable body may be moved to a predetermined position without operating the board movable body to form an integrated design. When the frame movable body, the board movable body, and the game board surface design form an integrated design, the frame movable body is operated to form the first integrated design with the game board surface design, and the board movable body is formed. By operating it, a second integrated design with the design of the game board surface may be formed. Further, the frame movable body and the board movable body may be operated to form a third integrated design with the design of the game board surface. In this case, the reliability of the jackpot may be different depending on whether the first integrated design is formed, the second integrated design is formed, or the third integrated design is formed. ..

When having a frame movable body and a plurality of board movable bodies, at least the movement of the first board movable body or the movement of the first board movable body and the second board movable body causes the first board movable body and the second board movable body. The first integrated design may be formed by the above, and the second integrated design may be formed by the first board movable body and the frame movable body by at least the operation of the first board movable body. Further, at least by the operation of the second board movable body, the second board movable body and the frame movable body may form the third integrated design. In this way, the first integrated design formed by the movement of the plurality of board movable bodies, and the board movable body and the frame movable body formed by the movement of at least one of the plurality of board movable bodies. By having a configuration having a second integrated design, it is possible to make the movable body production more impactful. Further, in this case, the reliability of the big hit when each appears is different between the one-piece design formed only by the movable board body and the one-piece design formed by the movable board body and the movable frame body. May be good. In addition, it is desirable to configure the design so that the reliability of a big hit is higher when an integrated design formed by a movable board body and a movable frame body that can give more impact to the player appears. ..

Regarding the launch guide passage 336 on the front side of the game board 15, for example, a part of the upstream end side (launching means side) is hidden behind the front door 4 (that is, off the outside of the viewing window 24), and the game ball inside from the front side. It may be a concealed passage portion where is not visible. At this time, when a foul ball is consciously generated by operating the operation lever 92 from the second position to the first position (second operation), the firing intensity is set so that the launched game ball returns in the concealed passage portion. You may. Alternatively, the firing intensity may be set so that the launched game ball passes through the concealed passage portion and returns.

For example, the output period of the security signal related to the setting confirmation may be either during the setting confirmation process or after the setting confirmation process, or may be both of them. Further, the output time (predetermined time) of the security signal related to the setting confirmation can be arbitrarily set from a short time of, for example, about 50 ms to a long time of 30,000 ms or more. It is possible to output different security signals during the setting confirmation process and after the setting confirmation process. In the embodiment, the initial value is set in the invalid information timer at the start of the setting confirmation process, but a flag indicating the execution of the setting confirmation process may be set.

In the embodiment, in the dynamic lighting control of the performance information display means 433 during setting change and setting confirmation, common data is specified only during lighting (4 ms), and common data is not specified during turn-off (12 ms). Although it is configured to be (cleared), it may be configured to switch the common data every 4 ms as in the case of displaying the base value on the performance information display means 433 during the game. In that case, it is desirable to specify the lighting data during the lighting (4ms) and switch to the lighting data during the extinguishing (12ms) to control the lighting.

Further, in the embodiment, it is decided to modularize the program for performing dynamic lighting and call a common submodule between changing the setting and confirming the setting, but the present invention is not limited to this, and the performance information display means 433 is used during the game. May be configured to call the lighting module used to display the base value in.

In the embodiment, a part of the performance display means 435 is configured to be used as the setting display means 434, but the entire performance display means 435 may be used as the setting display means 434, or the setting display means 434 and the performance. The display means 435 may be provided separately.

In the embodiment, an example is shown in which the operation confirmation display is continuously executed even when the out-of-area RAM is cleared due to an error in the out-of-area RAM during the operation confirmation display of the performance display means 435. If an abnormality occurs in the out-of-area RAM during the operation confirmation display and the out-of-area RAM is cleared, the operation confirmation display of the performance display means 435 may be interrupted.

As the first configuration in this case, for example, it is conceivable to partially change the embodiment and store the operation confirmation timer in the out-of-region RAM as well as the blinking cycle timer, instead of the in-region RAM. As a result, when an abnormality occurs in the out-of-area RAM (S71: Yes in FIG. 80), the out-of-area RAM is initialized (cleared) (S72), and the operation confirmation timer becomes 0, so that it operates. If the confirmation display is in progress, the operation confirmation display is interrupted at that point and will not be restarted thereafter.

This first configuration may be further modified so that, for example, when an abnormality occurs in the out-of-area RAM and the out-of-area RAM is initialized (cleared), the initial value is set in the operation confirmation timer. .. As a result, the operation confirmation display can be executed again from the beginning. At this time, the operation confirmation timer may be configured to set the initial value only when the timing at which the out-of-area RAM is initialized is during the operation confirmation display. As a result, it is possible to prevent the operation confirmation display from being performed again when an abnormality occurs in the RAM outside the area after the operation confirmation display is completed. On the contrary, if the operation confirmation timer is configured to set the initial value regardless of the timing when the out-of-area RAM is initialized, the operation is confirmed again when an abnormality occurs in the out-of-area RAM after the operation confirmation display is completed. The display is done. If an error occurs in the out-of-area RAM and the out-of-area RAM is initialized (cleared), not only the initial value is set in the operation check timer, but also the blinking cycle timer, the on / off switching counter, and the display contents. The pointer and the like may also be configured to set initial values. In the case of the display update process (FIG. 93) of the embodiment, when the value of the operation confirmation timer is 1200 corresponding to 4800 ms in S121, S122 for setting the initial value in the blinking cycle timer or the like is executed, so that the operation is confirmed, for example. If a value obtained by adding 1 to the timer value corresponding to 4800 ms as the initial value is set in the timer, specifically 1201, the initial value can be set in the blinking cycle timer or the like. If a value other than 1, for example, 1200, which is a timer value corresponding to 4800 ms, is set, S122 is not executed, so that the initial value is not set in the blinking cycle timer or the like.

Further, as a second configuration for interrupting the operation confirmation display when the out-of-area RAM is cleared, for example, when an abnormality occurs in the out-of-area RAM and the out-of-area RAM is cleared by partially changing the embodiment. It is conceivable to clear the operation confirmation timer stored in the RAM in the area. As a result, if the out-of-area RAM is cleared during the operation check display due to an error in the out-of-area RAM, the operation check timer is also cleared and becomes 0, so the operation check display is interrupted at that point and then restarted. There is no.

Further, as a third configuration in which the operation confirmation display is interrupted when the out-of-area RAM is cleared, for example, when an abnormality occurs in the out-of-area RAM and the out-of-area RAM is cleared by partially changing the embodiment, the out-of-area RAM is cleared. It is conceivable to set the initial value in the operation confirmation timer stored in the RAM in the area. As a result, when the out-of-area RAM is cleared during the operation confirmation display due to an abnormality in the out-of-area RAM, the operation confirmation display can be executed again from the beginning. At this time, the operation confirmation timer may be configured to set the initial value only when the timing at which the out-of-area RAM is initialized is during the operation confirmation display. As a result, it is possible to prevent the operation confirmation display from being performed again when an abnormality occurs in the RAM outside the area after the operation confirmation display is completed. On the contrary, if the operation confirmation timer is configured to set the initial value regardless of the timing when the out-of-area RAM is initialized, the operation is confirmed again when an abnormality occurs in the out-of-area RAM after the operation confirmation display is completed. The display is done. If an error occurs in the out-of-area RAM and the out-of-area RAM is initialized (cleared), not only the initial value is set in the operation check timer, but also the blinking cycle timer, the on / off switching counter, and the display contents. The pointer and the like may also be configured to set initial values. In the case of the display update process (FIG. 93) of the embodiment, when the value of the operation confirmation timer is 1200 corresponding to 4800 ms in S121, S122 for setting the initial value in the blinking cycle timer or the like is executed, so that the operation is confirmed, for example. If a value obtained by adding 1 to the timer value corresponding to 4800 ms as the initial value is set in the timer, specifically 1201, the initial value can be set in the blinking cycle timer or the like. If a value other than 1, for example, 1200, which is a timer value corresponding to 4800 ms, is set, S122 is not executed, so that the initial value is not set in the blinking cycle timer or the like.

The mode of the operation confirmation display of the performance display means 435 is not limited to all blinking in which all the 7-segment display units blink at the same time, and may be sequentially blinking in which a plurality of 7-segment display units blink in order.

Of the setting change function units (RAM clear switch 431, setting change operation means 432, setting display means 434, etc.) related to the setting change function, the RAM clear switch 431 and the setting change operation means 432 can be mainly operated from the outside. It is necessary to expose the setting display means 434 to the outside (rear side) of the board case 415, but it is desirable to house the setting display means 434 in the main board case 415 because the display contents can be visually recognized from the outside. This makes it difficult to access at least the setting display means 434. Therefore, for example, the setting display means 434 displays a setting value that is disadvantageous to the player while illegally changing the setting value to be advantageous to the player. It is possible to prevent such a goto act.

Since the setting change function changes the jackpot probability, it is important to be able to easily find traces of goto behavior. Therefore, when the electronic components connected to each setting change function unit (for example, the main control CPU → the electronic component 1 → the electronic component 2 → the setting change function unit are connected in this order, the electronic component 1 and the electronic component 2 are connected. It is desirable to arrange at least one of them at a position that does not overlap with the control number notation part, the opening history notation part, etc. of the main board case 415. As a result, when the main board case 415 is visually recognized from the rear of the gaming machine main body 1 (when the main control board 415a is visually recognized through the back portion of the main board case 415), the electronic components connected to each setting change function unit are connected. It can be easily confirmed. In addition, not limited to the control number notation part and the opening history notation part, for example, when a sticker showing the number of stages of set values (settings 1 to 6 etc.) and the jackpot probability for each setting is attached to the main board case 415. It is desirable to have the same configuration.

Further, not limited to the electronic components connected to each setting change function unit, for example, the electronic components connected to the performance display means 435 for displaying the base value (not limited to those physically connected, for example, the main control). It is desirable that the same configuration is used for (including both the electronic component 1 and the electronic component 2 when the CPU → the electronic component 1 → the electronic component 2 → the performance display means 435 are connected in this order). As a result, even if an act of rewriting or resetting the base value in the cumulative game is performed due to some kind of fraudulent activity on the electronic component, it becomes easy to find the trace.

The opening / closing cover 418 may be arranged so as to be located behind each setting change function unit provided on the main board case 415. As a result, each setting change function unit cannot be accessed unless the opening / closing cover 418 is opened, which is advantageous in terms of suppressing the goto action. Further, while adopting a configuration in which the opening / closing cover 418 is located on the rear side of the main board case 415, an opening is provided in a part of the opening / closing cover 418 so that the setting change function unit and the opening / closing cover 418 do not overlap each other in the front-rear direction. A notch or the like may be provided. As a result, since a part of the main board case 415 has a front-rear relationship with the opening / closing cover 418, it is possible to prevent the main board case 415 from being easily removed unless the opening / closing cover 418 is opened. In addition, it is not necessary to open the open / close cover 418 when accessing each setting change function unit in order to change the setting, so that the setting change can be easily performed. Considering only the ease of access when a person involved in the hall changes the setting, the opening / closing cover 418 may be configured not to be located on the rear side of the main board case 415.

Further, among the setting change function units, some of the function units may be arranged at positions that do not overlap the opening / closing cover 418 in the front-rear direction, and other functional parts may be arranged at positions that overlap the opening / closing cover 418 in the front-rear direction. .. For example, among the setting change function units, the setting display means 434 (performance information display means 433) is arranged at a position overlapping the opening / closing cover 418, and the other setting change operation means 432, RAM clear switch 431, etc. are arranged. It may be arranged at a position where it does not overlap the opening / closing cover 418 in the front-rear direction. As a result, since it is difficult to access the setting display means 434, it is possible to suppress the goto action of changing the display of the setting information, and access the setting change operation means 432, the RAM clear switch 431, etc. without opening the open / close cover 418. Therefore, the setting can be easily changed.

Further, in the case of the setting change operation means 432 in which the setting key is inserted into the keyhole portion and the ON / OFF operation is performed as in the embodiment, the keyhole portion may be arranged at a position overlapping the opening / closing cover 418 in the front-rear direction. Further, in this case, the opening / closing cover 418 may not be closed when the setting key is inserted in the keyhole portion. For example, it is conceivable to make the gap between the keyhole portion when the open / close cover 418 is closed and the open / close cover 418 on the rear side smaller than the protruding height of the setting key when the open / close cover 418 is inserted into the keyhole portion. .. This makes it possible to prevent forgetting to remove the setting key after changing the setting or confirming the setting. On the contrary, the open / close cover 418 may be closed even when the setting key is inserted. This prevents the open / close cover 418 and the setting key from being damaged due to contact with the setting key even if the open / close cover 418 is closed with the setting key inserted after the setting is changed or the setting is confirmed. can.

Further, by arranging the keyhole portion of the setting change operation means 432 at a position where it does not overlap the opening / closing cover 418 in the front-rear direction, the opening / closing cover 418 may be closed even when the setting key is inserted. In this case, with the open / close cover 418 closed, the head of the setting key inserted in the keyhole portion may be configured to protrude to the rear side of the open / close cover 418. As a result, when the open / close cover 418 is closed with the setting key inserted after changing the setting or confirming the setting, the setting key protrudes from the open / close cover 418, so it is easy to notice that the setting key is forgotten to be removed. There is an advantage.

Among the setting change function units, a combination of one arranged at a position overlapping the opening / closing cover 418 in the front-rear direction and one arranged at a position not overlapping the opening / closing cover 418 in the front-rear direction is arbitrary. When the setting display means 434 (performance information display means 433) is arranged at a position overlapping the opening / closing cover 418 in the front-rear direction, at least the portion of the opening / closing cover 418 corresponding to the rear side of the setting display means 434 is the opening / closing cover. It is desirable to set the light transmission so that the set value can be visually recognized even when the 418 is closed. Further, the heat dissipation hole provided in the opening / closing cover 418 may be arranged at a position overlapping the setting display means 434 in the front-rear direction. As a result, the visibility when confirming the set value is improved. Further, among the setting change function units, a combination of one arranged at a position overlapping the heat radiation hole of the opening / closing cover 418 in the front-rear direction and one arranged at a position not overlapping the heat radiation hole of the opening / closing cover 418 in the front-rear direction is arbitrary (all). It may be a position where they overlap, or it may be a position where they do not all overlap).

To send commands related to setting change functions (hereinafter referred to as setting information commands) such as setting change start command (BA76H), setting change end command (BA77H), and setting confirmation start command (BA60H) from the main control board 415a to the sub board. It is desirable to wire the harness (hereinafter referred to as a specific harness) at a position where it overlaps the opening / closing cover 418 in the front-rear direction. When the opening / closing cover 418 has a plurality of heat dissipation holes, it is desirable to wire the specific harness at a position avoiding the heat dissipation holes. Further, the "harness" referred to here is composed of a plurality of signal lines connecting the connectors at both ends, but as described above, it may be wired at a position where it overlaps the opening / closing cover 418 in the front-rear direction, or a heat dissipation hole of the opening / closing cover 418. Wiring should include at least the signal line to which the setting information command is transmitted out of the plurality of signal lines. This makes it difficult to access the specific harness from the rear side of the gaming machine. For example, by inserting and removing the signal line of the specific harness or the specific harness and charging an illegal electronic component, information different from the original setting information command is illegal. It is possible to suppress the goto action such as sending to the sub board.

Further, the specific harness may be wired at a position where it does not overlap the opening / closing cover 418 in the front-rear direction, or may be wired at a position where it overlaps the heat radiation hole of the opening / closing cover 418 in the front-rear direction. As a result, the access to the specific harness from the rear side of the game machine becomes easy, the visibility of the specific harness from the rear side of the game machine becomes high, and the visual confirmation can be easily performed. Further, the specific harness may be difficult to access by covering the periphery of the plurality of signal lines with a specific member such as vinyl. Even in that case, fraudulent activity can be prevented more firmly by adopting the above-mentioned arrangement.

In the embodiment, it is possible to identify whether the setting information is before or after confirmation by adding ". (Dot)" to the setting information displayed on the setting display means 434. For example, among the 7-segment display units 433a to 433d constituting the performance information display means 433, the setting information before the setting information is confirmed due to the difference in the display mode of the 7-segment display units 433b to 433d not used as the setting display means 434. It may be notified whether it is the one after the confirmation.

In the embodiment, it is configured to notify that the setting is being changed or the setting is being confirmed by the lighting means 436, the speaker 17, etc., the liquid crystal display means 327, etc., which are controlled on the sub board side, but the main control board 415a side. It may be notified by a panel lamp controlled by or a setting display means 434. Here, the illumination means 436 controlled on the sub-board side is, for example, a movable body mounted on the frame side of the gaming machine, an operating means, LEDs provided on other decorative parts, or the gaming board side of the gaming machine. It is an LED provided in various game parts such as a movable body, a starting port, an attacker, and a center case mounted on the machine. On the other hand, the board lamp controlled on the main control board 415a side is a game information display means 326 (FIG. 53) provided on the game board 15 so as to be visible from the front of the game machine.

The game information display means 326 receives a signal directly from the main control board 415a about various matters related to the symbol lottery determined on the main control board 415a side without going through the sub control board, and displays the contents of a plurality of types of light emission. It is designed to be notified by means. In the embodiment, as a plurality of types of light emitting display means configured by the game information display means 326, the normal symbol display means 361, the first and second special symbol display means 363, 364, and the first and second special reserved number display. Means 365, 366, ordinary hold quantity display means 362, fluctuation shortening notification means 367, right-handed notification means 368, and round number notification means 369 have been exemplified, but are not limited thereto.

Then, during the setting change and / or the setting confirmation, the LED 360 constituting the game information display means 326 is made to emit light in a predetermined light emitting mode so as to notify that the setting is being changed and / or the setting is being confirmed. It may be configured. In this case, the light emitting mode of the game information display means 326 may be one in which all of the LEDs 360 are turned on, blinking, or the like, or a part of the above-mentioned plurality of types of light emitting display means may be turned on, blinking, or the like. .. At this time, it may be possible to distinguish whether the setting is being changed or the setting is being confirmed by making the light emission mode different between the setting being changed and the setting being confirmed, and conversely, the setting being being changed and the setting being being confirmed. By making the light emission mode the same, it may not be possible to distinguish between the setting being changed and the setting being confirmed.

Further, in the case of the embodiment, the game cannot be played while the setting is being changed or the setting is confirmed (specifically, the launch operation is impossible, the winning to the starting winning opening is invalid, or the symbol is changed. It is a state in which processing is not executed, that is, a timer interrupt processing for performing these processing as a main control program has not been started yet), and each light emitting display means of the game information display means 326 is also originally. Cannot display the light emission. Therefore, no matter what mode of light emission the game information display means 326 is to emit light in order to notify the fact during the setting change and / or the setting confirmation, the hall officials misunderstand that it is a notification regarding the symbol change. Although it is unlikely that the game information display means 326 emits light as follows during setting change and / or setting confirmation, more effective notification is possible.

That is, when notifying that the setting is being changed or the setting is being confirmed by turning on / off / blinking all of the light emitting display means of the game information display means 326, many LEDs 360 visually indicate the light emitting mode. It can be easily confirmed. Further, in the case of notifying only by a specific single light emitting display means, it is impossible to notify when the light emitting unit of the light emitting display means is out of order, but when notifying by using all the light emitting display means. I don't have to worry about that.

Further, in the case of notifying that the setting is being changed or the setting is being confirmed by turning on / off / blinking or the like of any one of the plurality of types of light emitting display means of the game information display means 326. , The program capacity for light emission control can be reduced as compared with the case of notifying using all the light emission display means. Further, in that case, when the light emitting display means is composed of a single light emitting unit (LED360), the visibility is lower than that of the case where the light emitting unit is composed of a plurality of light emitting units, but the lighting / extinguishing is performed from the main control. / The program capacity for transmitting the control signal indicating blinking can be further reduced.

Further, in the case of notifying that the setting is being changed or the setting is being confirmed by combining at least two or more of the plurality of types of light emitting display means of the game information display means 326 to turn on / off / blink. It is possible to make it easier to recognize that the current situation is not during the game but during the setting change or setting confirmation. For example, in the case of a pachinko machine in which the second special symbol is changed and displayed in preference to the first special symbol as in the embodiment, the first special symbol and the second special symbol change at the same time during the game. Therefore, the light emitting display means (first and second special symbol display means 363 and 364) corresponding to the first special symbol and the second special symbol should be turned on at the same time while the setting is being changed or the setting is confirmed. Therefore, it can be easily recognized that the setting is being changed or the setting is being confirmed. Of course, other two or more light emission display means may be used to notify that the setting is being changed or the setting is being confirmed in a light emission mode that cannot occur during the game.

Further, even if at least one light emitting display means of the game information display means 326 is turned on / off / blinking in a light emitting mode that cannot be played during the game, it may be notified that the setting is being changed or the setting is being confirmed. good. For example, when the round number notification means 369 does not display in a blinking state during the game, the round number notification means 369 may be blinked to notify that the setting is being changed or the setting is being confirmed. ..

Here, the light emitting mode of the light emitting display means of the game information display means 326 has been described as lighting / extinguishing / blinking, etc., but the lighting / blinking in this case means something visually recognized as such. And. That is, when the game information display means 326 is controlled by the dynamic lighting method as in the embodiment, the blinking state is actually high speed even in the lighting state, but this is the lighting state. The blinking state refers to a case where the lighting state (high-speed blinking) and the extinguishing state (lighting off) are visually repeated at predetermined intervals.

Further, when controlling the light emitting display means of the game information display means 326 during the game, a dynamic lighting method is used, and when controlling the light emitting display means of the game information display means 326 during setting change or setting confirmation, static lighting is used. It may be a method. For example, since the generation of the timer interrupt process of 4 ms is permitted during the game, any of the light emitting units of the light emitting display means of the game information display means 326 is used for each interrupt by using the process repeated every 4 ms. It is possible to switch the common data that determines whether to transmit data related to lighting, which makes it easy to perform dynamic lighting control that repeatedly turns on / off at predetermined intervals for each interrupt, while changing settings or setting. During the confirmation, it is before the game becomes possible, and since the generation of 4 ms timer interrupt processing is not yet permitted during this period, it is necessary to realize it when trying to execute the same processing. Program capacity becomes large. In that respect, if the control of the game information display means 326 is a static lighting method while the setting is being changed or the setting is being confirmed, data regarding lighting can be sent to any of the light emitting units of the game information display means 326. Since it is only necessary to transmit, it is possible to overwhelmingly reduce the program capacity as compared with the case of dynamic lighting control. In this way, the lighting control method of the game information display means 326 may be different between during the game, during the setting change, and / or during the setting confirmation.

Further, the game information display means 326 may be provided with a light emitting display means for notifying that the setting is being changed and / or the setting is being confirmed, separately from the light emitting display means used during the game. In this case, a light emitting display means for notifying that the setting is being changed and a light emitting display means for notifying that the setting is being confirmed may be separately provided. When one type of light emitting display means (one or more light emitting units) notifies that the setting is being changed and the setting is being confirmed, the setting is being changed by making the light emitting mode different between the setting being changed and the setting being being confirmed. It may be possible to identify whether the setting is being confirmed or not, and conversely, by making the light emission mode the same between the setting being changed and the setting being confirmed, it is possible to identify whether the setting is being changed or the setting is being confirmed. You may not be able to do it.

Further, when the game information display means 326 is provided with a light emission display means for notifying that the setting is being changed and a light emission display means for notifying that the setting is being confirmed, in addition to the light emission display means used during the game. , It is desirable to arrange them so as to be adjacent to each other, but they may be arranged so as to sandwich another light emitting display means.

Further, since the performance display means 435 is always operated to display the base value during the game, basically, the control that the off state is continued for a long time during the game is not performed. Therefore, in a state where the game is not in progress, such as when the setting is being changed or the setting is being confirmed, by intentionally continuing the off state, it is possible to recognize that the current state is not in the game, thereby changing the setting or confirming the setting. It is possible to notify that it is inside. In this way, in consideration of the original display mode of the performance display means 435, it is possible to notify that the setting is being changed or the setting is being confirmed by intentionally turning off the light instead of the lighting state. This also applies when the setting display means 434 and the performance display means 435 are provided separately.

Next, the merits of notifying the game information display means 326 (board lamp), the setting display means 434, and the performance display means 435 that the main control side controls that the setting is being changed or the setting is being confirmed will be described below. .. If it is notified that the setting is being changed or the setting is being confirmed only by the liquid crystal display means 327 such as the illumination means 436 and the speaker 17 controlled on the sub side, the main control board and the sub control board are subjected to a goto action. If the signal line connecting the speaker is disconnected, it will not be possible to notify that the setting is being changed or the setting is being confirmed. For example, the setting can be easily changed or set without being known to the people involved in the hall. It will be possible to confirm. On the other hand, in addition to (or instead of) the liquid crystal display means 327 such as the illumination means 436 and the speaker 17 controlled on the sub side, the game information display means 326 (board lamp) and the setting display means 434 controlled on the main control side. By notifying the performance display means 435 that the setting is being changed or the setting is being confirmed, the game information display means is provided even if the signal line connecting the main control board and the sub control board is disconnected. Since the notification is performed by the 326, the setting display means 434, and the performance display means 435, it becomes possible for the hall personnel to notice the goto action.

Further, the setting is being changed by using the game information display means 326 visible from the front side of the game machine, the setting display means 434 and / or the performance display means 435 (performance information display means 433) visible from the rear side of the game machine. If it is configured to notify that the setting is being confirmed or the setting is being confirmed, it is possible to confirm the state of the setting being changed or being confirmed from both the front side and the rear side of the gaming machine.

Further, the liquid crystal display means 327 (effect means) such as the illumination means 436 and the speaker 17 that control the sub side (effect control board 416a) that the setting is being changed or the setting is being confirmed is not notified by the main control side. Although it may be configured to be notified by the game information display means 326, the setting display means 434, and the performance display means 435 controlled by the sub-side, the liquid crystal display means 327 such as the illumination means 436 and the speaker 17 controlled by the sub side. For example, the distinctiveness is further improved by configuring the game information display means 326, the setting display means 434, and the performance display means 435, which are controlled by the main control side, to perform notification.

Further, although the game information display means 326 is exemplified as a board lamp for notifying that the setting is being changed and / or the setting is being confirmed, any light emitting means may be used as long as it is controlled by the main control board side. For example, it may be provided on either the board side or the frame side.

In the embodiment, an example in which the RAM clear switch 431 is used for the setting change operation is shown, but an operation means other than the RAM clear switch 431, for example, an effect operation means 43 or the like may be used for the setting change operation. The setting change operation means 432 may be provided with a setting change operation function in addition to the ON / OFF function related to the setting change. Further, an operation means dedicated to the setting change operation may be provided.

The setting change operation means 432 may be provided on a board different from the main control board 415a. For example, a setting change operation board may be separately provided, and a setting change operation means 432 may be provided therein.

In the embodiment, the set value is configured to be changeable to 6 stages of settings 1 to 6, but the number of stages of the set value is arbitrary, and may be 2 to 5 stages or 7 or more stages.

When the effect control board 416a receives the setting change end command (BA77H), the liquid crystal display means 327, the illumination means 436, the speaker 17, etc. may be used to notify that the setting change period has ended. Further, when the effect control board 416a receives, for example, a setting confirmation end command (BA67H) or the like, the liquid crystal display means 327, the illumination means 436, the speaker 17, etc. may be used to notify that the setting confirmation period has ended. good.

For example, by adding the current setting value to the lower byte of the setting change end command, the setting value information may be added to the setting change end command and transmitted to the sub-control. For example, a command configuration such as BA70H (setting 1) to BA75H (setting 6) may be used, and the setting work value after the setting change may be added to the setting change end command BA70H, or the setting work value after the setting change may be added. May be added to the setting change end command BA70H after loading the setting value data. In this way, by putting the setting value information after the setting change on the setting change end command and sending it to the sub control, for example, on the sub control side, when leaving the history of the setting change setting value, the setting change end command The history can be stored by referring to the lower byte of. Further, if necessary, it is also possible to notify the process for notifying the end of the setting change, which is performed when the setting change end command is received, in the notification mode according to the set value.

During the operation confirmation display of the performance display means 435, the initial operation (initial operation) by the board movable body 371 provided on the game board 15 or the frame movable body 156 provided on the front frame 3 side may be executed. .. Further, it is desirable to configure the movable body so that the initial operation of the movable body is completed by the time the operation confirmation display of the performance display means 435 is completed, but only for the movable body of either the board movable body 371 or the frame movable body 156. It may be configured so that the initial operation ends during the operation confirmation display. Further, the initial operation of the movable body may be executed after the operation confirmation display of the performance display means 435 is completed. In this case, of course, the initial operation is completed after the operation confirmation display is completed.

During the operation confirmation display of the performance display means 435, at least one of the lamp, sound, and liquid crystal display on the front side of the gaming machine may be used to notify that the operation confirmation display is in progress. As a result, the hall employees and the like can confirm from the front side of the gaming machine that the performance display means 435 is displaying the operation confirmation. Even during the operation confirmation display of the performance display means 435, the variable display of the first and second special symbols and the ordinary symbols may be configured to be startable.

In the embodiment, the base value is displayed on the performance display means 435 as an example of the performance information (specific information), but the performance information to be displayed is not limited to this, and the accessory ratio (so-called electric chew (second special)) is displayed. In addition to the game ball / electric chew and the large winning opening paid out by winning the symbol starting means 346) and the large winning opening (large winning means 347), the starting winning opening (first special symbol starting means 345) and other prizes A game ball paid out by winning a prize in the mouth) may be displayed. This makes it possible to display the percentage of the total payout game balls paid out by the accessory such as the electric chew or the big winning opening on the performance display means 435. Further, when displaying a plurality of types of performance information, for example, a base value and a bonus ratio on the performance display means 435, both the base value and the bonus ratio are switched and displayed at a predetermined timing or by operating a button. Alternatively, only the accessory ratio may be displayed. Further, a monitor for displaying the base value and a monitor for displaying the accessory ratio may be provided separately.

Various history information related to the set value may be stored, and the history information may be displayed by a predetermined display means, for example, a display means (such as a liquid crystal display means 327) controlled by the effect control board 416a side. In this case, the date and time when the setting change process or the setting confirmation process is performed may be stored as history information and can be displayed. In that case, the setting value set by the setting change process and the setting value confirmed by the setting confirmation process may be stored as history information and displayed together with the date and time of the setting change process and the setting confirmation process. In addition, for example, if the date and time of setting change cannot be obtained because the RTC (real-time clock) is not installed, the elapsed time from the previous setting change is set as the setting value set by, for example, the setting change process. , It may be stored together with the set value confirmed by the setting confirmation process and can be displayed. In this case, each time the power is turned on, the accumulated energization time is accumulated and counted from that point, and when the setting change process or setting confirmation process is executed, the accumulated energization count value at that time is stored as history information. It may be configured in. Further, in that case, the accumulated count value of the elapsed energization time is cleared when the setting change process is executed, and is not cleared even if the setting confirmation process is executed. Even when the RTC is installed, for example, the elapsed time from the previous setting change may be stored and displayed as history information together with the date and time of the setting change or the like, or instead of the date and time. Further, when the date and time of the setting change process and the setting confirmation process are stored as history information, for example, the elapsed time from the previous setting change may be calculated and displayed based on the history information. Further, when specific error information occurs, that fact may be stored as history information and can be displayed.

If it is determined that the set value is an abnormal value, the date and time may be stored as history information and can be displayed. Further, when a normal set value is set after it is determined that the set value is an abnormal value, the elapsed time or the like during that period may be displayed. In addition, originally, the set value is not changed during the game, or the set value does not change from the normal value to the abnormal value, but when the set value is changed even during the game due to noise or goto action. May store the date and time as history information and make it displayable. Further, even when the RAM clear processing or the backup restoration processing is performed, it may be stored as history information, for example, and the date and time, the number of times, and the like may be displayed.

It is desirable to display the history information during the setting confirmation process or the setting change process. Further, when a predetermined operation input is made during the setting confirmation process or the setting change process, the history information may be displayed on the display means. Further, even during the game, if there is a predetermined operation input, the history information may be displayed on the display means.

The history information as described above may be stored in an SRAM provided on the effect control board 416a side. The effect control CPU of the effect control board 416a reads the information of the SRAM when the power is turned on and stores it in the internal work, and performs a process of storing the information of the internal work in the SRAM at a predetermined timing described later. Basically, the history information is stored in the SRAM, but when the history information is updated, the value of the internal work is updated. By updating the value of the internal work at the time of updating in this way, it is not necessary to access the SRAM every time it is updated, the frequency of access to the SRAM can be reduced, and the processing speed can be increased.

Further, for the updated information of the internal work, for example, the elapsed time stored in the internal work may be referred to and stored in the SRAM at the timing when it is determined that the predetermined time has elapsed. Further, the value of the internal work is transmitted at the timing when a predetermined command such as a setting confirmation command, a setting confirmation end command, a setting change command, or a setting change completion command is transmitted from the main control board 415a side to the effect control board 416a side. May be stored in the SRAM. Here, if a setting confirmation command, a fixed confirmation end command, a setting change command, or a setting change completion command is sent, new history information will be added at that point, so a new history will be added first. It is desirable to store the information in the internal work and then store it in the SRAM. At this time, the backup data may be stored in the backup area of the SRAM (hereinafter, the area for storing the history information of the SRAM is set as the main area, and the backup data is stored. The area is used as the backup area).

Further, the sum value may be calculated for the information of the internal work and stored in the SRAM in the same manner. As a result, for example, when the history information of the SRAM is read into the internal work at the timing when the power of the effect control CPU is turned on or the timing of displaying the history information, the sum value of the read internal work and the stored sum value are compared. By doing so, it is possible to determine whether or not the history information is normal. Here, if the history information read to the internal work is not normal, the history information stored for backup may be read from the SRAM to the internal work. Also at this time, the sum value of the read internal work and the sum value stored for backup may be compared to determine whether the data is normal or not. If it is determined that the backup history information is not normal, the internal work information may be initialized and the initialization data may be written to the SRAM. In this case, the initialization data is also written to the backup area of the SRAM. On the other hand, when it is determined that the history information for backup is normal, the information of the internal work is written in the main area of the SRAM. As a result, the history information of the main area determined to be abnormal can be rewritten to the normal one.

The main area and backup area for storing SRAM history information include, for example, a checksum storage area (2 bytes), the latest history position information storage area (2 bytes), an elapsed time storage area (4 bytes), and a history storage area (2 bytes). 300 bytes) and the like may be provided respectively. Here, the checksum value is stored in the checksum storage area. Further, in the latest history position information storage area, position information for storing the latest history information is stored. For example, when up to 30 histories are currently stored, the next history information to be stored is the 31st, so the latest history position information storage area stores the position information to be stored as the 31st history information. are doing. Here, when the maximum number of memorable history information is 50, when a new history is stored after the 50 history, the information in the first history is overwritten. Therefore, the latest history position information storage area is information indicating the first history. It should be noted that, for example, up to 50 pieces of such history information are stored in the above-mentioned history storage area. Further, in the elapsed time storage area, the accumulated count value and the like of the above-mentioned energization elapsed time are stored.

While the history information is being displayed, the history information may be switched by operating operation means such as the cross operation means and the effect operation means 43 on the front side of the gaming machine. For example, when the screen displayed first is the first page, a predetermined number (for example, up to the tenth) of history information is displayed in a form retroactive to the past, with the latest history information as the first page. To. Then, for example, by operating the left and right keys of the cross operation means, the page is switched to the second page, and the history information from the 11th to the 20th is displayed. By the same operation, for example, the fifth page can be switched, and thereby, for example, all 50 histories can be displayed. Therefore, at the timing when the page switching operation is performed, only the history information that needs to be displayed on the next page to be displayed is transmitted to the liquid crystal control CPU or the display means by a command. Become. Further, the display of the first page of the history information is started when an operation means (for example, the effect operation means 43) different from the operation means for switching pages (here, the left and right keys of the cross operation means) is operated. You may try to do it. Further, when an operation means (for example, the effect operation means 43) different from the operation means for switching pages (here, the left / right key of the cross operation means) is operated while displaying any page, the history information is displayed. The display may be terminated. Further, during a predetermined period (setting confirmation, setting change, etc.), it may be possible to switch between display and non-display of history information each time a predetermined operation means (here, the effect operation means 43) is operated.

While displaying the history information, it is desirable to hide the performance display means 435 that displays the base value. Further, it is desirable not to display the operation confirmation of the performance display means 435 while the history information is being displayed. Further, even while the history information is being displayed, the volume and / or the amount of light may be adjusted so as to be effective. In this case, even if the adjustment of the volume and / or the amount of light is effective during the display of the history information, it is desirable that the display means displaying the history information does not display that the adjustment is effective. When doing so, it is desirable to display it at a position that does not overlap with the history information. Further, while the history information is being displayed, the adjustment of the volume and / or the amount of light may not be possible.

Further, it is desirable not to execute the initialization operation of the movable body on the board side at least while the history information is displayed. As a result, it is possible to prevent the movable body on the board side from moving to the front side of the display means (liquid crystal display means 327) and obstructing the visibility of the display screen. Similarly, the movable body on the frame side may not be initialized. However, the movable body on the frame side may be initialized if there is no possibility of interfering with the display screen of the liquid crystal display means 327 or the like. In this case, for example, the vibrating means 252 mounted on the operating means such as the operating handle 234, the blowing means 233 for ejecting air, and the like may also be initialized. As a result, for the movable body on the frame side, the initialization operation can be terminated first, so that after the display of the history information is completed, that is, after the setting confirmation process and the setting change process are completed, the movable body on the board side It is efficient because you only have to initialize it. Further, the present invention is not limited to this, and the initialization operation may be performed for all the movable bodies after the display of the history information is completed.

In the embodiment, only one out ball detecting means 414 is provided, but a plurality of out ball detecting means 414 may be provided. In this case, the discharge port 412 may be provided for each of the plurality of out ball detecting means 414, or the plurality of out ball detecting means 414 may be arranged for one discharge port 412. As a result, the discharge efficiency of the game ball is increased, and the risk that the game ball is congested around the discharge port 412 and the ball is clogged can be reduced. Further, when a plurality of out ball detecting means 414 are provided in one discharge port 412, it is desirable to arrange at least two on the left and right. As a result, the out-ball detecting means 414, which easily detects the game ball flowing down from the left inclined surface 461 (FIG. 110, 111), and the game ball flowing down from the right inclined surface 463 (FIG. 110, FIG. 111) are detected. The role can be shared with the easy-to-use out-ball detecting means 414, and the discharge efficiency is further increased, so that the risk of ball clogging can be reduced.

Further, in order to allow the game ball to flow down to the discharge port 412 more efficiently, a guide rib for guiding the game ball to the discharge port 412 side may be provided on the inclined surface around the discharge port 412. A plurality of the guide ribs may be provided, and for example, the guide ribs arranged on the left inclined surface 461 side and the guide ribs arranged on the right inclined surface 463 side may be asymmetrical (for example, have different lengths). .. Further, one guide rib may guide the game ball to the back side of the discharge port 412, and the other guide rib may guide the game ball to the front side of the discharge port 412. By making the configuration of the guide ribs different on the left and right of the discharge port 412 in this way, the game ball flowing down from the inclined surface 461 on the left side and the game ball flowing down from the inclined surface 463 on the right side can be moved to the discharge port 412. The arrival timing can be different, and the risk of ball clogging around the discharge port 412 can be reduced.

Further, when a plurality of discharge ports 412 are provided and the out ball detecting means 414 are arranged respectively, the guide ribs arranged on the left inclined surface 461 side and the guide ribs arranged on the right inclined surface 463 side are different discharge ports. It may be configured to guide the game ball toward 412. Further, the guide ribs arranged on the left inclined surface 461 side go to the discharge port 412 on the left side (may be the right side), and the guide ribs arranged on the right inclined surface 463 side go to the right side (may be the left side) discharge port 412. Each may be configured to guide the game ball. In this way, by guiding the game ball to different discharge ports 412 by a plurality of guide ribs, the risk of ball clogging around the discharge port 412 can be reduced.

In the configuration shown in FIGS. 110 and 111, when the inclination angles in the left-right direction are different between the inclined surfaces 461 and 462 on the left side and the inclined surfaces 461 and 464 on the right side, the inclination of the winning detection switch and the side with many out openings are inclined. The inclination angle of the surface may be larger than the inclination angle of the inclined surface on the lesser side. Further, the side on which a winning means such as a so-called attacker (large winning means 347) or an electric chew (second special symbol starting means 346), which may temporarily win a large number of game balls, is arranged (in this embodiment). Regarding the inclined surface on the right side), the inclination angle is made larger than the inclined surface on the opposite side (left side in this embodiment) to increase the flow speed of the game ball and reduce the risk of ball clogging. good.

In order to facilitate the guidance of the game ball that has entered the out port 358 to the discharge port 412, an inclined surface that is inclined from the out port 358 toward the discharge port 412 may be provided. This inclined surface may have an inclined angle different from the inclined surface on the right side and / or the inclined surface on the left side of the discharge port 412, or may have the same inclined surface.

At least a part of the discharge port 412, the out ball detecting means 414, the inclined surface for guiding the game ball to the discharge port 412 side, and the like may be arranged not on the game board 15 side but on the front frame 3 side.

The out-ball detecting means 414 may be arranged so as to be offset to one side in the left-right direction with respect to the specific reference position. In this case, the specific reference position may be the center of the game board 15 in the left-right direction (of the base plate 321), the center of the game area 15a in the left-right direction, and the leftmost winning detection switch and the rightmost winning detection switch. It may be the center in the left-right direction of. Of course, the out-ball detecting means 414 may be arranged on the game board 15 side or the front frame 3 side.

Further, the one side in the left-right direction with respect to the specific reference position may be the side where the ejection time of the game ball is long. On the side where the ejection time of the game ball is long, when the out ball detecting means 414 is arranged at the specific reference position, the winning detection switch which takes the longest time for the winning ball to reach the out ball detecting means 414 is arranged. It may be the side with a small inclination angle of the inclined surface around the out ball detecting means 414. Further, it may be on the side where more prize detection switches are arranged (it takes time to eject due to collision between game balls, etc.), or on the side where the prize detection switch is arranged at a higher position. May be good. In addition, one side in the left-right direction with respect to the specific reference position is the side with a relatively large number of winning opportunities and winning opportunities (for example, the winning detection switch 347a of the big winning means 347 in which many balls win during the big hit, and many during the time reduction / probability change. It may be the side on which the winning detection switch 346a of the electric chew (second special symbol starting means 346) in which the ball wins a prize is located.

Further, when a plurality of out ball detecting means 414 are arranged, the center position of the plurality of out ball detecting means 414 may be shifted to one side in the left-right direction with respect to the specific reference position, or the plurality of out ball detecting means 414 may be shifted to one side in the left-right direction. All of may be shifted to one side in the left-right direction with respect to the specific reference position. Further, any one of the plurality of out ball detecting means 414 may be shifted to one side in the left-right direction with respect to the specific reference position.

When the normal winning unit 325 is provided with an out port (second out port), a game ball that has passed through the second out port passes, for example, a guide gutter (not shown) and lands on an inclined surface 462 (FIG. 110). The time required for the game ball to pass through the winning detection switches 349a and 350a may be different from the time required for the game ball to pass through the guide gutter and land on the inclined surface 462. In this case, by making the latter shorter than the former, it is possible to reduce the lag in the detection timing of the game ball due to the state change, and it is possible to make the timing at which the game ball flows down to the discharge port 412 different. It is possible to reduce ball clogging near the exit 412. Similarly, when the out port (third out port) is provided in the vicinity of the large winning means 347, the game ball that has passed through the third out port passes through, for example, a guide gutter (not shown) and the inclined surface 464. The time required to land on (FIG. 110) and the time required for the game ball passing through the winning detection switches 347a and 348a to pass through the guide gutter and land on the inclined surface 464 may be different. In that case, the latter may be shorter than the former. In addition, in order to make the time from winning to landing on the slope different, the flow length of each guide gutter provided behind the winning means may be different, or the slope that is the landing surface from the outlet of each guide gutter. The distance to the gutter may be different.

All the above-described embodiments and modifications may be combined in any way, and the contents described as the embodiments and modifications are not limited to the individual embodiments and modifications. For example, the second and third embodiments are modifications of the first embodiment, respectively, but the third embodiment can be applied to the second embodiment. Further, the fourth embodiment is applicable to all of the first to third embodiments and combinations thereof. Furthermore, the fifth embodiment is applicable to all of the first to fourth embodiments and combinations thereof. Further, the modified examples and other various matters described after the embodiment can also be applied to the first to fifth embodiments and their combinations.

Further, the present invention can be similarly implemented in various ball game machines such as arrange ball machines and sparrow ball game machines, as well as in game machines other than ball game machines such as slot machines.

3 Front frame 15 Game board 15a Game area 156 Frame movable body 203 Frame non-movable body 353 Non-inflow area 371 Board movable body

Claims (1)

Based on the winning of the game ball to the symbol starting means, the symbol display means capable of variablely displaying the symbol according to any of a plurality of types of variable patterns, and the symbol display means.
A special game execution means for executing a special game when the stop symbol after the change by the symbol display means becomes a specific mode, and a special game execution means.
The winning detection means provided in each of the plurality of winning means including the symbol starting means, and
Out-ball detection means to detect out-ball and
A normal out counter that counts the number of outs during a specific period based on the detection by the out ball detecting means, and
A specific number counter that counts a specific number during the specific period based on the detection by the winning detection means,
A specific value calculation means for calculating a specific value based on each count value by the normal out counter and the specific number counter is provided.
The specific period starts when a predetermined start condition is satisfied at least after the end of the symbol change by the symbol display means, and when the predetermined end condition is satisfied after the end of the symbol change by the symbol display means. In the pachinko machine that ends in
During the specific period, it takes a predetermined period of the last symbol change before the end condition is satisfied until the game ball detected by the winning detection means is subsequently detected by the out ball detecting means. Set to a time shorter than a specific time,
The predetermined period is started at a predetermined timing after the end of the winning effect of whether or not the symbol has the specific mode.
A gaming machine characterized by that.

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