JP5617154B2 - Game machine - Google Patents

Description

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

One type of gaming machine is a pachinko machine. The pachinko machines, for example, whether the extracted election game ball to generate equivalent or state when ball entrance to start ball entrance means provided in the game area game ball that is struck by the firing device is guided Done. If you win in the previous Ki抽 election, the player advantageous tow or condition occurs, the player it is possible to win the Yu skill value (winning balls, etc.).

In recent years, that the player operates are those or changes the display contents on the Viewing device, operation means you like or corresponding sound flow from the speaker is provided (for example, see Patent Document 1 ).
JP 2004-81603 A

By the way, a more innovative operation means is required.

  Note that the above-described problem is not limited to pachinko machines, but also applies to other gaming machines such as slot machines.

  The present invention has been made to solve the above-described problems and the like, and an object thereof is to provide a gaming machine provided with a novel operation means.

The gaming machine according to claim 1,
An operation unit that is provided on a front surface portion of the gaming machine and is displaced between an operation position when operated and a non-operation position when not operated;
Urging means for urging the operation portion toward the non-operation position;
An operation means comprising an operation detection means for detecting that the operation unit has been displaced to the operation position,
The operation means includes
A movable body relatively displaceable with respect to the operation unit;
Drive means capable of displacing the movable body,
The operation unit is detected by the operation detection unit when the operation unit at the non-operation position is operated to the operation position side as the movable body is displaced by driving of the drive unit. It is configured to be restricted from being displaced to the operation position ,
Comprising lottery means capable of performing lottery on whether or not the displacement of the operation unit is restricted by the movable body;
Even when the displacement of the operation unit is restricted by the movable body, the operation unit is configured to be operable by a predetermined amount when the operation unit is operated with a predetermined operation force. It is said.

  According to claim 1, it is possible to provide a gaming machine provided with a novel operation means.

  Hereinafter, an embodiment of a pachinko gaming machine (hereinafter simply referred to as “pachinko machine”) will be described in detail with reference to the drawings. Here, FIG. 1 is a front view of the pachinko machine 10, FIG. 2 is a perspective view, and FIG. 3 is a perspective view showing a state in which the inner frame 12 and the front frame set 14 are opened. FIG. 4 is a front view showing the configuration of the inner frame 12, the game board 30, and the like. FIG. 5 is a rear view of the pachinko machine 10, and FIG. 6 is a perspective view showing a state in which the inner frame 12, the back pack unit 203, and the like are opened. However, in FIG. 3, for the sake of convenience, nails and accessories placed on the surface of the game board 30, a glass unit 137 attached to the front frame set 14, and the like are omitted.

  As shown in FIG. 3 and the like, the pachinko machine 10 includes an outer frame 11 that constitutes an outline of the pachinko machine 10, and an inner frame 12 is supported at one side of the outer frame 11 so as to be opened and closed. .

  As shown in FIG. 6 and the like, the outer frame 11 has an upper side frame constituting portion 11a and a lower side frame constituting portion 11b made of a wooden plate material, and the left side frame constituting portion 11c and the right side frame constituting portion 11d are made of aluminum alloy. Each of the frame components 11a to 11d is assembled in a rectangular frame shape as a whole by a detachable fastener such as a screw.

  An upper hinge 81 and a lower hinge 82 are attached to the upper and lower ends of the left side frame constituting portion 11c (see FIG. 1). The upper and lower hinges 81 and 82 support the upper and lower portions of the inner frame 12 so that the inner frame 12 can be rotated. As a result, the inner frame 12 can be opened and closed. And the inner frame 12 etc. are accommodated in the space part formed inside the outer frame 11.

  The right side frame constituting portion 11d is formed with an extending wall portion 83 that protrudes from the vicinity of the rear end portion in the width direction toward the inside of the outer frame 11. The extending wall 83 covers the entire upper and lower sections corresponding to the locking device 600 (see FIG. 6) provided on the back side of the right side of the inner frame 12 from the back side of the inner frame 12 (see FIG. 5). In addition, as shown in FIG. 3, a pair of upper and lower receiving portions 84 and 85 to which the locking member of the locking device 600 is locked are provided on the front surface side of the extending wall portion 83. Further, a pressing portion 86 that abuts on an inner frame opening detection switch 92 described later is provided on the lower receiving portion 85 so as to protrude toward the inner side of the outer frame 11.

  Furthermore, a resin curtain decoration 87 is attached to the lower frame constituting portion 11b. A rib 88 projecting upward is integrally formed at the back of the upper surface of the curtain decoration 87. This makes it difficult to form a gap with the inner frame 12.

  As shown in FIG. 3, the opening / closing axis of the inner frame 12 is set up and down on the left side when viewed from the front of the pachinko machine 10, so that the inner frame 12 can be opened forward with the opening / closing axis serving as an axis. It has become. The inner frame 12 is mainly composed of a resin base 38 whose outer shape is rectangular, and a substantially elliptical window hole 39 is formed at the center of the resin base 38.

  A front frame set 14 is attached to the front side of the inner frame 12 so that it can be opened and closed. As with the inner frame 12, the front frame set 14 can be opened forward with an opening / closing axis set along the top and bottom on the left side when viewed from the front of the pachinko machine 10.

  The front frame set 14 has a rectangular outer shape like the inner frame 12, and covers almost the entire front side of the inner frame 12 in the closed state. A substantially elliptical window 101 is formed at the center of the front frame set 14. Thereby, the game board 30 (game area) attached to the rear surface of the inner frame 12 can be visually recognized from the outside through the window portion 101 of the front frame set 14 and the window hole 39 of the inner frame 12. The detailed configuration of the game board 30 will be described later.

  As shown in FIG. 1, on the front side of the front frame set 14, a lower tray 15 as a ball tray is provided at the lower center, and game balls discharged from the discharge port 16 are stored in the lower tray 15. It is possible. In addition, on the front side of the lower plate 15, a ball removal lever 25 for discharging the game ball from the lower plate 15 is provided. In addition, an effect button 125 with a built-in LED is provided on the left side of the lower plate 15, and by pressing the effect button 125, a corresponding effect is performed on a decorative symbol display device 42 described later. Or the production content is changed.

  On the right side of the lower plate 15, a game ball launching handle (hereinafter simply referred to as a handle) 18 protruding toward the front side is provided. The handle 18 is provided with a touch sensor (not shown) and an operation amount detection means (not shown) for detecting the operation amount of the operation unit of the handle 18.

  An upper plate 19 is provided above the lower plate 15. The upper plate 19 is a ball tray that temporarily stores the game balls and guides them toward a game ball launching device (hereinafter simply referred to as launching device) 60 as launching means, which will be described later, while being aligned in a row. When the upper plate 19 is full of game balls, the game balls to be paid out are guided to the lower plate 15 via the lower plate communication passage 71 and the discharge port 16 described later.

  The upper plate 19 is provided with a ball lending button 121 and a return button 122. Thereby, in the game hall or the like, when the ball lending button 121 is operated with a bill or a card inserted into a card unit (ball lending unit) arranged on the side of the pachinko machine 10, depending on the operation Rental balls are supplied to the upper plate 19. On the other hand, the return button 122 is operated when requesting the return of a card or the like inserted into the card unit. However, the ball lending button 121 and the return button 122 are not necessary for a pachinko machine in which game balls are directly lending to the upper plate 19 from a ball lending device or the like without using a card unit, so-called cash machine.

  Further, the upper plate 19 is provided with a ball removal button 123. When the ball removal button 123 is pressed, a communication hole (not shown) provided on the downstream side of the ball guide path of the upper plate 19 and communicating with the lower plate 15 is opened and stored in the upper plate 19. The game ball is guided (dropped) to the lower plate 15. That is, the player can move the game ball on the upper plate 19 to the lower plate 15 at any time by operating the ball removal button 123.

  In addition, light emitting means such as various lamps are provided around the front surface of the front frame set 14. These light emitting means play a role of enhancing the effect of the game during the game by changing and controlling the light emission mode such as lighting and blinking according to the change of the game state at the time of big hit or predetermined reach. For example, at the periphery of the window portion 101, an annular illumination portion 102 incorporating a light emitting means such as an LED is provided. In addition, error display lamps 104 that are turned on when a predetermined error occurs are provided on both sides of the annular illumination portion 102. In addition, a large number of small through holes are formed in the annular illumination portion 102 above the error display lamps 104 corresponding to the speakers SP (see FIG. 3) provided on the back surface of the front frame set 14. .

  A glass unit 137 is attached to the back side of the front frame set 14. The glass unit 137 is not attached to a pair of conventional front and rear rectangular glass plates separately in front and rear pairs, but is formed into a round shape as a whole and attached after being assembled.

  Next, the inner frame 12 (resin base 38) will be described with reference to FIG. As described above, the game board 30 is mounted on the inner frame 12 (resin base 38) on the rear side of the window hole 39. The game board 30 is attached in a state in which the peripheral edge thereof is in contact with the back side of the inner frame 12 (resin base 38). Therefore, a substantially central portion of the front surface portion of the game board 30 is exposed to the front surface side of the inner frame 12 through the window hole 39 of the resin base 38.

  Further, at the lower part of the front surface of the inner frame 12 (resin base 38), that is, below the window hole 39 (game board 30), a launch rail for guiding the launch device 60 and the game ball immediately after being launched from the launch device 60. 61 is attached. In the present embodiment, a solenoid-type firing device is employed as the firing device 60. In addition, above the launching device 60, a ball feeding device that guides the game balls guided from the upper plate 19 one by one to the launching position of the launching device 60 by driving a built-in driving means (for example, a solenoid). 63 is provided.

  Next, the configuration of the game board 30 will be described with reference to FIG. The game board 30 includes a general winning port 31, a variable winning device 32, a first opportunity corresponding unit (starting port) 33, a second opportunity corresponding port 34, a variable display device unit 35 and the like in a through hole formed by router processing. The game board 30 is attached from the front side of the game board 30 with wood screws or the like. As is well known, when a game ball enters (wins) various winning ports such as the general winning port 31, the variable winning device 32, the first opportunity corresponding unit 33, etc., it is detected by various detection switches, and the upper plate 19 (or the lower plate 15). ) A predetermined number of prize balls are paid out. For example, when there is a ball entering the first opportunity corresponding unit 33, three when there is a ball entering the general winning opening 31, and when there is a ball entering the variable winning device 32 15 game balls are paid out to the upper plate 19 (lower plate 15). In addition, the game board 30 is provided with an out port 36, and the game balls that have not won the various winning ports such as the general winning port 31 are discharged out of the game area through the out port 36. . In addition, the game board 30 is provided with a large number of nails for appropriately dispersing and adjusting the falling direction of the game balls, and various members such as windmills (servants).

  The first opportunity corresponding unit 33 includes an upper winning opening 33a and a lower winning opening 33b through which a game ball flowing down the game area can enter, and a pair of opening and closing members 33c provided on both sides of the lower winning opening 33b. I have. The upper winning opening 33a allows a game ball to always enter, while the lower winning opening 33b is a game that flows down the gaming area by the opening / closing member 33c opening and closing in accordance with the establishment of a predetermined condition. The state can be changed between an open state in which a ball can enter and a closed state in which a game ball cannot enter. In addition, although mentioned later in detail, the 1st opportunity corresponding | compatible unit 33 is provided with the 1st opportunity corresponding | compatible switch 224a, 224b which each detects the game ball which entered the top winning opening 33a and the lower winning opening 33b. When a game ball is detected by the 1 opportunity switch 224a, 224b, whether or not to generate a big hit state is determined, and the special display device 43 and the decorative symbol display device 42 display a variable display. It is the composition that is called. And, when winning in the winning / losing lottery, a big win state (special game state) is given.

  Further, the second opportunity corresponding port 34 is configured so that game balls flowing down the game area can pass one by one. As will be described in detail later, the second opportunity corresponding port 34 includes a second opportunity corresponding switch 225 capable of detecting a game ball passing through the second opportunity corresponding port 34. When a game ball is detected, an open lottery for determining whether or not the first opportunity corresponding unit 33 is opened is performed, and variable display is performed on the normal symbol display device 41. And when winning by open lottery, the 1st opportunity corresponding | compatible unit 33 is made into an open state only for regulation time.

  The variable display device unit 35 receives a prize for the normal symbol display device 41 that displays a variable in response to the passage of the second opportunity corresponding port 34 and the first opportunity corresponding unit 33 (upper winning port 33a or lower winning port 33b). A special display device 43 that performs variable display as an opportunity, and a decorative symbol display device 42 that performs variable display according to the variable display by the special display device 43 are provided.

  The normal symbol display device 41 is configured so that “O” or “X” can be lit and displayed as a normal symbol, and each time the game ball passes through the second opportunity corresponding port 34, for example, the normal symbol is changed from “O” to “ Switching display (fluctuation display) is performed at high speed such as “×” → “◯” →. When the change display is stopped for a few seconds with the “◯” symbol (winning symbol), the first opportunity corresponding unit 33 is opened for a predetermined time. The display contents of the normal symbol display device 41 are directly controlled by a main control device 261 described later.

  In addition, when the game ball newly passes through the second opportunity corresponding port 34 during the fluctuation display of the normal symbol display device 41, the corresponding fluctuation display is performed after the end of the fluctuation display performed at that time. It is configured to be performed. That is, the variable display is on standby (held). The maximum number of the variable display to be held is determined for each model of the pachinko machine, but in this embodiment, it is held up to 4 times, and the hold number is lit and displayed by the hold lamp 44. Yes.

  The special display device 43 is provided on the right side of the normal symbol display device 41, and is composed of three-color light emitting diodes (three-color LEDs) having red, green, and blue emission colors. Then, each time the game ball wins the first opportunity corresponding unit 33, a color change display (variable display) is performed, and the lighting mode (lighting color) when the variable display stops determines whether or not it is a big hit. Is displayed.

  More specifically, when the game ball wins the first opportunity corresponding unit 33, the special display device 43 displays the three-color LED at a high speed such as red → green → blue → red →. When a predetermined time elapses, it is determined and displayed in one of the colors. High-speed color change display means, for example, that red, green, and blue are displayed in order every 4 msec. In the case of winning the big hit lottery, at this time, it is determined and displayed in red or green (for example, stopped for several seconds), and a special gaming state occurs. In particular, red is a display indicating that the game mode after the jackpot is a high probability mode, and green is a display indicating that the game mode after the jackpot is a time reduction mode. The display content of the special display device 43 is also directly controlled by the main control device 261.

  Further, when a new game ball wins the first opportunity corresponding unit 33 during the variable display of the special display device 43, the corresponding variable display is performed after the end of the variable display at that time. It has a configuration. That is, the variable display is on standby (held). The maximum number of the variable display to be held is determined for each model of the pachinko machine, but in this embodiment, it is held up to 4 times, and the hold number is lit and displayed by the hold lamp 46. Yes. In addition, when a new game ball wins the first opportunity corresponding unit 33 during the big hit state, the corresponding change display is also suspended.

  The decorative symbol display device 42 is configured as a liquid crystal display device, and display contents are controlled by a sub-control device 262 and a display control device 45 described later. That is, in the decorative symbol display device 42, auxiliary display contents are determined by the sub-control device 262 based on a command from the main control device 261 so as to correspond to the result displayed on the special display device 43, The display is performed by a display control device 45 described later.

  The decorative symbol display device 42 is provided with, for example, three symbol display areas, upper, middle, and lower, and a plurality of types of symbols (numerals) are sequentially displayed (variably displayed) in each symbol display area. The symbols are stopped and displayed in order for each display region (for example, in the order of the upper symbol display region → the lower symbol display region → the middle symbol display region). For example, when the jackpot is confirmed by the main controller 261, a display corresponding to the jackpot is made on the special display device 43, and the symbol is stopped and displayed on the decorative symbol display device 42 in a combination corresponding to the jackpot (for example, The symbols that are stopped and displayed in the upper symbol display area, the middle symbol display area, and the lower symbol display area are the same), and the big hit state is started.

  Further, when symbols are stopped and displayed in combinations corresponding to jackpots, the same symbol is stopped and displayed in the upper symbol display area and the lower symbol display area, for example, as a preceding stage. In this way, the state where the same symbol is stopped and displayed in the upper symbol display area and the lower symbol display area and the variable display is still being performed in the middle symbol display area is the reach state.

  The variable display device unit 35 is provided with a center frame 47 so as to surround the decorative symbol display device 42. A ball entrance 151 is provided in the upper portion of the center frame 47, and a game ball that has entered the ball entrance 151 is formed inside the center frame 47 along the side of the decorative symbol display device 42. It is guided on a stage 153 formed below the decorative symbol display device 42 via a warp channel 152 extending vertically. The game ball guided on the stage 153 falls from the stage 153 to the front game area, or rolls on the stage 153 and then enters the pocket 154 formed at the center back side of the stage 153. . The pocket 154 communicates with a guide passage 155 that leads to a game area immediately above the first opportunity corresponding unit 33, and a game ball that has entered the pocket 154 corresponds to the first opportunity with a relatively high probability. A unit 33 is entered.

  The variable winning device 32 is normally in a closed state in which a game ball cannot be won, and is in an open state in which a game ball can be won in the case of a big hit (occurrence of a special game state). Specifically, the elapse of a specified time (for example, 30 seconds) or a specified number (for example, 8) of winnings is regarded as one round, and the large winning opening of the variable winning device 32 is repeatedly opened a predetermined number of times (a predetermined number of rounds).

  The game board 30 includes an inner rail component 51 and an outer rail component 52, and a rail 50 that guides a game ball launched from the launch device 60 to the upper part of the game board 30 is attached. As a result, the game balls fired in accordance with the turning operation of the handle 18 are guided through the launch rail 61 and the rail 50 into a game area formed between the game board 30 and the glass unit 137.

  A return ball preventing member 53 is attached to the tip portion of the inner rail constituting portion 51 (the upper left portion in FIG. 4). This prevents a situation in which the game ball once guided from the rail 50 to the game area returns to the rail 50 again.

  In the present embodiment, the outer rail component 52 is interrupted at the upper right portion of the game board 30, and the inner rail component 51 is interrupted at the lower right portion of the game board 30. For this reason, the game area is defined by the inner peripheral surface of the rail 50 and the window hole 39 of the resin base 38. However, since the game ball launched by the launching device 60 may flow backward through the rail 50 until it passes through the return ball prevention member 53, the parallel portions of the inner and outer rail constituting portions 51 and 52 are excluded from the game area. It is burned.

  As shown in FIG. 3, a ball passage unit 70 is provided on the back side of the front frame set 14 below the window portion 101. The ball passage unit 70 includes a lower plate communication passage 71 connected from a payout mechanism portion 352 described later to the discharge port 16 of the lower plate 15, and an upper plate communication passage 73 connected from the payout mechanism portion 352 to the upper plate 19. In addition, there is a gap of a predetermined interval between the launch rail 61 provided on the inner frame 12 and the rail unit 50 (outer rail constituting portion 52), and the ball path unit 70 receives a game ball dropped from the gap. A foul ball passage 72 for guiding to the lower plate 15 is formed. Thereby, if the game ball launched from the launching device 60 does not reach the return ball prevention member 53 and returns to the rail 50 as a foul ball, the foul ball is returned to the lower plate 15 via the foul ball passage 72. Discharged.

  3 and 4 is a payout passage for guiding a game ball paid out by a payout mechanism portion 352, which will be described later, to the front of the inner frame 12, and an upper plate communication passage 73 (upper plate 19). And a passage leading to the lower plate communication passage 71 (lower plate 15). A shutter 68 is provided below the payout passage 67. When the front frame set 14 is opened, the shutter 68 protrudes forward by an urging force of a spring or the like so that the outlet of the payout passage 67 is almost closed. ing. When the front frame set 14 is closed, the shutter 68 is pushed open by the inlet side rear end of the lower plate communication path 71. In addition, the inlets (sphere inflow portions) of the lower plate communication passage 71 and the upper plate communication passage 73 are adjacent to each other, and in the closed state of the front frame set 14, each of the inlets and the discharge passage 67 are separated by a predetermined distance. A game ball can pass through the gap between the two. For this reason, when the upper plate 19 and the upper plate communication passage 73 are filled with game balls, the game balls to be dispensed flow to the lower plate communication passage 71 side (overflow to the inlet side of the lower plate communication passage 71), and the lower plate connection It will be paid out to the lower plate 15 through the passage 71.

  In addition, the ball path unit 70 is provided with a full detection switch (not shown) that detects a game ball located in the lower dish communication path 71. Due to the presence of the full detection switch, it is grasped that the lower plate 15 is full of game balls (the lower plate 15 is full of game balls and the game balls are retained in the lower plate communication path 71). be able to. In the present embodiment, based on the fact that the game ball is continuously detected for a predetermined time by the full detection switch, the control of prohibiting the launching device 60 from being launched is performed. When the game ball stays in the lower tray communication path 71 and the game ball is not detected by the full detection switch (when it is not detected continuously for a predetermined time), the launching device 60 is allowed to be launched.

  Next, the back configuration of the pachinko machine 10 will be described with reference to FIGS. Various control boards are arranged on the back of the pachinko machine 10 so as to be lined up, down, left and right, and partially overlapped in the front and back, and further, a game ball supply device (payout mechanism) for supplying game balls And a protective cover made of resin. The dispensing mechanism and the protective cover are integrated as one unit, and the resin portion is generally sometimes referred to as a back pack. Therefore, this unit is referred to as a “back pack unit 203”.

  First, the back configuration of the game board 30 will be described. As shown in FIG. 6, on the back side of the variable display device unit 35 (see FIG. 4) arranged corresponding to the through hole in the center of the game board 30, a resin frame cover that covers the center frame 47 from the back side. 213 is provided to protrude rearward. Also, on the back side of the frame cover 213, a decorative symbol display device 42, a display control device 45, and a sub control device 262, which are liquid crystal display devices facing forward from the opening of the frame cover 213, can be attached and detached in a state where they are stacked in front and back. Is attached.

  The decorative symbol display device 42 is housed in a housing box 42 a in which an opening for exposing the display unit (liquid crystal screen) of the decorative symbol display device 42 to the front side of the pachinko machine 10 is formed, and the rear surface of the frame cover 213. It is fixed on the side. The display control device 45 is accommodated in the substrate box 45a and fixed to the back side of the decorative symbol display device 42 (accommodation box 42a). The sub-control device 262 is accommodated in the substrate box 262a and fixed to the back side of the display control device 45 (substrate box 45a). In the frame cover 213, an LED control board for driving LEDs and the like built in the center frame 47 is disposed. The storage box 42a and the substrate boxes 45a and 262a are made of a transparent resin material or the like so that the inside can be visually recognized.

  Under the frame cover 213, a back frame set 215 is attached to the game board 30 so as to cover the general winning opening 31, the variable winning device 32, the first opportunity corresponding unit 33, and the like from behind. The back frame set 215 includes a ball collection mechanism (not shown) for collecting game balls that have won prizes in various winning ports. The game balls collected by the ball collection mechanism are guided to a discharge passage portion 217 described later, and discharged from the discharge chute of the discharge passage portion 217 to the outside of the pachinko machine 10.

  In the present embodiment, the back frame set 215 functions as a mounting base for the main controller 261. More specifically, the board box 263 on which the main controller 261 is mounted is pivotally supported with respect to the back frame set 215 and can be opened rearward.

  The main controller 261 is accommodated in a substrate box 263 made of a transparent resin material or the like. The substrate box 263 includes a box base and a box cover that covers the opening of the box base, and the box base and the box cover are connected by a sealing member. The board | substrate box 263 connected with the sealing member becomes a structure which cannot be opened unless a predetermined trace is left. As a result, it is possible to easily find out that the board box 263 has been illegally opened.

  In addition, the game board 30 corresponds to various winning ports such as a general winning port 31 as a winning means and detects a game ball that has entered the various winning holes (entrance detecting means). Is provided. Specifically, as shown in FIG. 4, a winning opening switch 221 is provided at a position corresponding to the general winning opening 31, and a count switch 223 is provided in the variable winning device 32. The first opportunity corresponding unit 33 is provided with first opportunity corresponding unit switches 224a and 224b corresponding to the upper winning opening 33a and the lower winning opening 33b, respectively. Further, a second opportunity corresponding port switch 225 is provided at a position corresponding to the second opportunity corresponding port 34.

  Although not shown, the back frame set 215 is provided with a first board surface relay board that is electrically connected to the prize opening switch 221, the count switch 223, and the second opportunity corresponding port switch 225 via a cable connector. It has been. The first board surface relay board relays the prize opening switch 221 and the like and the main control device 261 as control means, and is electrically connected to the main control device 261 through a cable connector.

  On the other hand, the first opportunity corresponding switches 224a and 224b that detect the entry into the first opportunity corresponding unit 33 (the upper winning opening 33a or the lower winning opening 33b) are directly connected via the connector cable without passing through the relay board. It is connected to the control device 261.

The detection results detected by the various entrance detection switches are taken into the main controller 261. Then, a payout command (the number of game balls to be paid out) corresponding to the winning situation at each time is transmitted from the main control device 261 to the payout control device 311, and a predetermined number of game balls are based on the output signal from the payout control device 311. Is paid out (except when it is detected by the second opportunity corresponding switch 225).
In addition, although not shown in the drawings, the back of the game board 30 is provided with a large winning opening solenoid that opens the large winning opening in the variable winning apparatus 32, and a pair of opening / closing members is provided in the first opportunity corresponding unit 33. A prize opening solenoid for opening and closing the 33c is provided. The back frame set 215 is also provided with a second board surface relay board (not shown) that relays between the solenoid and the main controller 261.

  Next, the configuration of the back pack unit 203 will be described. As shown in FIG. 5, the back pack unit 203 is a unit in which a back pack 351 formed of resin and a payout mechanism portion 352 for a game ball are integrated. Further, the back pack unit 203 is supported so as to be openable and closable with respect to the left side portion (right side in FIG. 5) of the inner frame 12, and can be opened rearward with an open / close axis extending along the vertical direction as an axis. ing. In addition, an external relay terminal plate 240 is provided in the upper left part of the back pack unit 203 (upper right part in FIG. 5).

  The external relay terminal board 240 is for relaying various information transmissions to a hall computer or the like in a game hall, and is provided with a plurality of external connection terminals. For convenience, no reference numeral is given, but for example, a terminal for outputting information on the current gaming state (such as a big hit state or a high probability state), the front frame set 14 detected by the opening detection switches 91 and 92 described later, A terminal for outputting information relating to the opening of the frame 12, a terminal for outputting information relating to various error states such as a ball entry error, a lower tray full tank error, a tank ball no error, a payout error, and the payout from the payout control device 311 A terminal for outputting information on the number of winning balls is provided.

  The back pack 351 is integrally formed of, for example, ABS resin, and includes a protective cover portion 354 that protrudes rearward from the pachinko machine 10 and has a substantially rectangular parallelepiped shape. The protective cover 354 has a shape in which the left and right side surfaces and the upper surface are closed and only the lower surface is opened, and has a size sufficient to cover at least the frame cover 213. However, in the present embodiment, the protective cover portion 354 covers the upper portion and the right portion of the substrate box 263 (the left portion in FIG. 5). Thereby, in the closed state of the back pack unit 203, the sealing member provided at the right part of the board box 263 and the terminal part (board side connector) provided along the upper edge part of the main controller 261 are covered. It will be.

  The payout mechanism 352 is arranged so as to bypass the protective cover 354. That is, a tank 355 opened upward is provided above the protective cover portion 354, and game balls supplied from the island facilities of the game hall are sequentially supplied to the tank 355. Below the tank 355, for example, a tank rail 356 that has two rows of ball passages in the horizontal direction and that is gently inclined toward the downstream side is connected. Further, a case rail 357 is formed vertically on the downstream side of the tank rail 356. It is connected. The payout device 358 is provided at the most downstream portion of the case rail 357, and a required number of game balls are paid out appropriately according to a predetermined electrical configuration such as a payout motor. Then, the game balls paid out from the payout device 358 are supplied to the upper plate 19 and the like.

  The payout mechanism 352 is provided with a payout relay board 381 for relaying a payout command signal from the payout control device 311 to the payout device 358, and a power switch board 382 for taking in the main power from the outside. Yes. The power switch board 382 is supplied with, for example, an AC 24V main power supply via a voltage converter, and the power switch 382a is switched on or off by a switching operation of the power switch 382a.

  Below the back pack unit 203 (substrate box 263), there is provided a lower frame set 251 that is pivotally supported at the left side of the inner frame 12 (right side in FIG. 5) and can be opened rearward. As shown in FIG. 6, the lower frame set 251 is formed with a discharge passage portion 217 into which the game balls collected by the ball collection mechanism described above flow, and a game ball is placed in the most downstream portion of the discharge passage portion 217. A discharge chute (not shown) for discharging to the outside of the pachinko machine 10 is formed. In other words, the game balls that have won the respective winning openings such as the general winning opening 31 are gathered through the ball collecting mechanism of the back frame set 215 and further discharged to the outside of the pachinko machine 10 through the discharge chute of the discharge passage portion 217. In addition, the out port 36 leads to the discharge passage portion 217 in the same manner, and the game balls that have not won any winning port are discharged to the outside of the pachinko machine 10 through the discharge chute. In this embodiment, the back pack unit 203 and the lower frame set 251 are configured separately and can be opened and closed independently. However, the back pack unit 203 and the lower frame set 251 are integrally formed. It is also possible to do.

  Further, as shown in FIG. 5, the payout control device 311, the firing control device 312, the power supply device 313, and the card unit connection board 314 are detachably attached to the back side of the lower frame set 251 in a state where they are overlapped in the front-rear direction. It has been.

  The launch control device 312 and the power supply device 313 are accommodated in the substrate box 313a and fixed to the back side of the lower frame set 251. Although the launch control device 312 and the power supply device 313 are described as independent control devices for convenience, they are actually configured by a single board (printed board).

  The payout control device 311 is housed in the substrate box 311a and is fixed to the back side of the substrate box 313a (the launch control device 312 and the power supply device 313). The substrate box 311a in which the dispensing control device 311 is accommodated is provided with a sealing member in the same manner as the substrate box 263 in which the main control device 261 is accommodated, so that an unsealed trace of the substrate box 311a remains. It has become.

  In addition, the card unit connection board 314 is accommodated in the board box 314a and fixed to the back side of the board box 313a (the firing control device 312 and the power supply device 313).

  Each of the board boxes 311a, 313a, and 314a is made of a transparent resin material or the like so that the inside can be visually recognized.

  Further, the dispensing control device 311 is provided with a state return switch 321 that protrudes outward from the substrate box 311a. For example, when the state return switch 321 is pressed when a payout error occurs, such as a ball clogged in the payout motor unit, the payout motor is rotated forward and reverse to eliminate the ball clogging (return to a normal state).

  Further, the power supply device 313 is provided with a RAM erase switch 323 that protrudes outward from the substrate box 313a. This pachinko machine 10 has a backup function, so that even if a power failure occurs, the pachinko machine 10 retains the state at the time of the power failure and can be restored to the state at the time of the power failure when returning from the power failure (power recovery). it can. Therefore, if the power is turned off in a normal procedure (for example, when the game hall is closed), the state before the power is turned off is stored. If you want to return to the initial state when the power is turned on, hold down the RAM erase switch 323 and hold the power .

  As shown in FIG. 6, a locking device 600 is provided on the back side of the right side of the inner frame 12. The locking device 600 includes a cylinder lock 700 (see FIG. 1 and the like) exposed on the front surface side of the front frame set 14, and a key is inserted into the key hole of the cylinder lock 700, and the inside is operated by rotating to one side. The frame 12 can be unlocked, and the front frame set 14 can be unlocked by rotating to the other side. In the present embodiment, the inner frame 12 is locked to the outer frame 11, and the front frame set 14 is locked to the inner frame 12.

  In addition, as described above, the extending wall portion 83 that covers the entire upper and lower sections corresponding to the locking device 600 from the back side of the inner frame 12 is formed in the right side frame constituting portion 11d of the outer frame 11 (FIG. 5). reference). Thereby, it becomes difficult to make a wire etc. approach from the back side of outer frame 11, and to operate locking device 600 with the wire etc. As a result, the defense performance can be improved. Further, the extending wall portion 83 is configured to cover the right end portion (the left end portion in FIG. 5) of the back pack unit 203 and the lower frame set 251 from the back side, and in the closed state of the inner frame 12, The back pack unit 203 and the lower frame set 251 cannot be opened.

  As shown in FIG. 4, a front frame open detection switch 91 for detecting the opening of the front frame set 14 is provided on the lower right side of the front side of the inner frame 12 (on the right side of the launching device 60). As shown in FIG. 5, an inner frame opening detection switch 92 for detecting the opening of the inner frame 12 is provided on the lower right side on the back side of the inner frame 12 (lower left in FIG. 5). Each of the front frame opening detection switch 91 and the inner frame opening detection switch 92 includes a detection unit that can move in and out of the switch main body, and the front frame opening detection switch 91 is provided so that the detection unit faces forward. The inner frame opening detection switch 92 is provided so that the detection unit faces rearward. When the detection unit is in a state of protruding from the switch main body, an ON signal is output to the main controller 261, and when the detection unit is pressed toward the switch main body and is immersed in the switch main body, an OFF signal is output. It is configured to output to the main controller 261. That is, when the front frame set 14 is closed, the front frame opening detection switch 91 is turned off when the detection unit is pressed on the back surface of the front frame set 14, and when the front frame set 14 is opened, the detection unit returns to the protruding state. Turns on. Similarly, when the inner frame 12 is closed, the inner frame opening detection switch 92 is turned off by the pressing portion 86 integrally formed with the receiving portion 85 of the outer frame 11 and is detected when the inner frame 12 is opened. The part returns to the protruding state and is turned on.

  In the present embodiment, the effect button 125 is characterized. Hereinafter, the configuration of the effect button 125 will be described in detail with reference to FIGS. In the present embodiment, the effect button 125 corresponds to an illumination means and an operation means. FIG. 7 is a schematic cross-sectional view showing the effect button 125 when the movable body 473 is in the first position. 8A is a top view showing the upper substrate 402, FIG. 8B is a top view showing the lower substrate 403, and FIG. 8C is a cross-sectional view showing the support fitting 451. FIG. 9 is a schematic sectional view showing the spring force adjusting means 471. FIG. 10 is a schematic cross-sectional view showing the effect button 124 when the movable body 473 is in the second position. FIG. 11 is a diagram for explaining the circuit configuration of the effect button 125. Note that the portion of the front frame set 14 (the lower plate unit constituting the lower plate 15) to which the effect button 125 is attached is inclined slightly downward toward the front, and therefore the effect button 125 is also attached slightly inclined. However, for the sake of convenience, description will be made assuming that the effect button 125 is simply attached upward.

  As shown in FIG. 7 and the like, the effect button 125 includes a main body 401 fixed to the front frame set 14, an upper substrate 402 as a light emitter block on which three light emitting means L1, L2, and L3 are mounted, A lower substrate 403 disposed opposite to the upper substrate 402 below the substrate 402, an operation unit 404 made of a transparent or semi-transparent material and covering the upper portion of the upper substrate 402, and light emitter driving means for rotating the upper substrate 402 Motor 405, a coil spring 406 as an urging unit for urging the operation unit 404 upward, and an operation detection switch 407 as an operation detection unit for detecting operation of the operation unit 404.

  The main body 401 includes a base plate 411 on which the motor 405 is mounted, and a substantially cylindrical frame 421 configured separately from the base plate 411.

  The base plate 411 is formed in a substantially disk shape, and protrudes upward from the base part 413 so as to surround the motor installation part 412 and a base part 413 formed with a motor installation part 412 that fits the lower part of the motor 405 at the center. And a support wall portion 414 that supports the outer peripheral portion of the lower substrate 403.

  The support wall portion 414 is a wall portion provided to support the lower substrate 403 at a position spaced apart from the base portion 413 by a predetermined distance. In the present embodiment, the support wall portion 414 is provided with three wall portions formed in a substantially circular arc shape in accordance with the outer peripheral shape (circular shape) of the lower substrate 403 at equal positions with the center portion of the lower substrate 403 as the center. (See FIG. 8B). The front end portion of the support wall portion 414 has a stepped shape in which the central portion side of the lower substrate 403 is one step lower, and the lower end and the outer peripheral surface of the outer peripheral portion of the lower substrate 403 are supported by the front end portion of the support wall portion 414. It becomes the composition which is done. Further, as shown by a two-dot chain line in FIG. 8B, a positioning convex portion 417 is formed at the distal end portion of the support wall portion 414, and is formed on the outer peripheral portion of the lower substrate 403 when the lower substrate 403 is installed. The positioning concave portion 419 is fitted into the positioning convex portion 417. Thereby, the lower substrate 403 is positioned and the displacement (rotational displacement) of the lower substrate 403 in the circumferential direction is restricted.

  In the present embodiment, the base portion 413 is provided with a spring support portion 415 that supports the lower end portion of the coil spring 406 and a spring force adjustment means 471 (adjustment means). The spring support portions 415 are substantially cylindrical projections that protrude upward from the base portion 413, and three spring support portions 415 are provided at equal positions around the center portion of the base portion 413. A coil spring 406 (coil spring 406a) is inserted into each spring support portion 415, and a lower portion of the coil spring 406a is supported by the spring support portion 415 (base portion 413).

  Also, three spring force adjusting means 471 are provided at equal positions around the center portion of the base portion 413 so as not to overlap with the spring support portion 415. The spring force adjusting means 471 includes a mounting base 472 that is fixed to the lower surface of the base portion 413 of the base plate 411, a movable body 473 that is slidable up and down with respect to the mounting base 472, and a sub-control device 262 (input And an adjustment motor 474 as a driving means that is electrically connected to the output port 554) and slides the movable body 473 up and down.

  The movable body 473 includes a slide piece 481 having a rack portion 482 that meshes with a gear 490 provided at the tip end of the rotating shaft of the adjustment motor 474, a substantially plate-like mount 484 provided at the upper end portion of the slide piece 481; And a substantially cylindrical support protrusion 485 that protrudes upward from the center of the gantry 484. The movable body 473 is supported by a gear 490 of an adjustment motor 474 that meshes with the rack portion 482, and is configured to be slidable up and down as the adjustment motor 474 is driven (rotation of the gear 490). In addition, each adjustment motor 474 of the three spring force adjustment means 471 installed in the base part 413 carries out the same movement synchronously.

  The mounting base 472 has a permissible hole 476 through which the slide piece 481 of the movable body 473 can be inserted. By sliding the movable body 473 so that the slide piece 481 is inserted into the permissible hole 476, the movable body 473 is moved. A slide width of 473 is secured. Further, a guide portion 477 having a substantially U-shaped cross section that protrudes upward so as to surround the allowance hole 476 is provided at the peripheral portion of the allowance hole 476 of the mounting base 472. Then, the slide piece 481 of the movable body 473 is inserted inside the guide portion 477 (see FIG. 9). The rack portion 482 of the slide piece 481 protrudes from the guide portion 477 to the gear 490 side. Further, as shown in FIG. 9, a guide groove 478 extending in the vertical direction is formed on the inner side surface of the guide portion 477. On the other hand, the slide piece 481 is formed with a guide rib 483 that is inserted into the guide groove 478. The slide of the movable body 473 is guided by the presence of the guide groove 478 and the guide rib 483.

  In addition, a spring insertion hole 487 through which the support protrusion 485 of the movable body 473 (and the coil spring 406b supported by the movable body 473) can be inserted is formed in the base portion 413 of the base plate 411 (main body portion 401). The spring force adjusting means 471 is attached to the base portion 413 so that the support protrusion 485 is inserted into the spring insertion hole 487. Further, the lower portion of the coil spring 406 (coil spring 406b) is inserted into the support protrusion 485 of the spring force adjusting means 471 attached to the base portion 413, and the lower end portion of the coil spring 406b is supported by the gantry 484. . In the present embodiment, the coil spring 406b supported by the spring force adjusting means 471 (movable body 473) has a larger spring constant (larger wire diameter) than the coil spring 406a supported by the spring support portion 415. Is used. In addition, in the attachment state to the base part 413 of the spring force adjustment means 471, the guide part 477 is arrange | positioned spaced apart below from the base part 413 (spring insertion hole 487 peripheral part).

  Further, the gantry 484 is configured to be larger than the spring insertion hole 487, and is configured such that the upper surface of the gantry 484 and the lower surface of the base portion 413 can contact each other. Further, the gantry 484 is configured to be larger than the opening above the guide portion 477, and is configured such that the lower surface of the gantry 484 and the upper end portion of the guide portion 477 can contact each other. In the present embodiment, the movable body 473 has a first position (see FIG. 7) where the upper end portion of the guide portion 477 and the lower surface of the gantry 484 substantially come into contact with each other based on the driving of the adjusting motor 474, and the gantry 484 guides. It is configured so as to be displaceable between a second position (see FIG. 10) that is spaced apart from the portion 477 and is substantially in contact with the upper surface of the base 484 and the lower surface of the base portion 413.

  In the present embodiment, a contact detection switch 491 that detects that the movable body 473 has reached the first position and the second position is provided. The contact detection switch 491 is electrically connected to the movable terminal portion 492 provided on the movable body 473 and the input / output port 554, and the upper terminal portion 493 provided on the lower surface of the base portion 413 and the input / output port 554. And a lower terminal portion 494 provided at the upper end portion of the guide portion 477. When the lower terminal portion 494 and the movable terminal portion 492 come into contact with each other, the circuit including the lower terminal portion 494 and the movable terminal portion 492 is energized, and the movable body 473 has reached the first position (the gantry 484 and The guide portion 477 is substantially in contact with it (state shown in FIG. 7). Further, when the upper terminal portion 493 and the movable terminal portion 492 come into contact with each other, the circuit including the upper terminal portion 493 and the movable terminal portion 492 is energized, and the movable body 473 has reached the second position (mounting base 484 and the base portion 413 are substantially in contact with each other (state shown in FIG. 10). In the present embodiment, when the driving of the adjustment motor 474 is stopped, the detection signal of the contact detection switch 491 is taken into account, and the adjustment is performed when the movable terminal portion 492 contacts the lower terminal portion 494 or the upper terminal portion 493. The drive of the motor 474 is stopped. Accordingly, it is possible to prevent the adjustment motor 474 and the like from being damaged due to the adjustment motor 474 being driven even after the gantry 484 and the base portion 413 or the guide portion 477 come into contact with each other. The mounting base 472 has an opening (not shown) for inserting a wire connected to the contact detection switch 491.

  The frame body 421 includes a cylindrical base portion 422 extending in the vertical direction, an annular edge wall portion 423 provided so as to close a peripheral portion of the opening on the upper side of the base portion 422, and an outer side from the outer peripheral surface of the base portion 422. And a mounting piece 424 protruding from the top. A mounting hole 425 is formed in the mounting piece 424 so as to penetrate vertically. Then, by aligning the mounting hole 425 and a screw hole (not shown) formed in the front frame set 14 (the lower plate unit constituting the lower plate 15) and fixing the screw, the effect button 125 is attached to the front frame. It is attached to the set 14.

  The outer peripheral portion of the base portion 413 of the base plate 411 has a step shape, and the base plate 411 is assembled to the frame body 421 so as to close the lower opening of the frame body 421 (base 422). And the lower part of the frame 421 (base part 422) is supported in the said level | step-difference part. Further, on the outer peripheral portion of the base portion 413, screw fixing portions 420 protruding upward are provided at predetermined intervals (for example, five) along the circumferential direction. The screw fixing portion 420 is formed with a screw hole 420a penetrating along the centrifugal direction of the base portion 413. Then, after assembling the base plate 411 and the frame body 421, the screw hole 420 a and the fixing hole 427 formed in the frame body 421 are aligned and screw-fixed so that the frame body 421 is fixed to the base plate. 411 is attached. In addition, the base plate 411 is formed with openings through which wires connected to the motor 405, the lower substrate 403, and the operation detection switch 407 are inserted.

  The operation unit 404 is provided on a cylindrical peripheral wall portion 431 extending in the vertical direction, a pressing portion 432 that closes an opening on the upper side of the peripheral wall portion 431, and an outer surface side of the peripheral wall portion 431, and supports an upper portion of the coil spring 406. And a spring accommodating portion 433. The peripheral wall portion 431 is in a state of vertically penetrating the edge wall portion 423 of the frame body 421, and the pressing portion 432 protrudes upward from the frame body 421.

  The spring accommodating portion 433 has a substantially cylindrical shape that extends vertically from the intermediate position in the vertical direction of the peripheral wall portion 431 to the lower end portion, with the lower portion opened and the upper portion closed. A total of six spring accommodating portions 433 are provided corresponding to the three spring support portions 415 attached to the base portion 413 of the base plate 411 and the three spring force adjusting means 471 (support protrusions 485), respectively. Yes. Inside each spring accommodating part 433, each upper part of the spring support part 415 and the coil spring 406a, or each upper part of the support protrusion 485 and the coil spring 406b is in an inserted state. The upper portions of the springs 406a and 406b) are supported, and the rotational displacement of the operation unit 404 is restricted.

  The coil spring 406a supported by the spring support portion 415 is always in contact with the bottom surface (upper wall portion: hereinafter referred to as the top wall portion 433a) of the spring accommodation portion 433 by being accommodated in the spring accommodation portion 433 ( Pressure). As described above, the both ends of the coil spring 406a are supported by the spring support portion 415 and the spring accommodating portion 433, and the coil spring 406a is interposed between the base portion 413 and the operation portion 404, thereby operating the coil spring 406a. The portion 404 is biased upward. Further, the outer surface of the spring accommodating portion 433 is substantially in contact with the inner surface of the base portion 422 of the frame body 421 so that when the operation portion 404 moves up and down, the spring accommodating portion 433 and the base portion 422 come into sliding contact. It has become. As a result, the vertical movement of the operation unit 404 is guided.

  In the state where the operation unit 404 is not pressed, the upper surface of the spring accommodating portion 433 and the lower surface of the edge wall portion 423 are brought into contact with each other by the urging force of the coil spring 406 (406a). The operation unit 404 and the base unit 413 are separated from each other in the vertical direction. When the pressing portion 432 of the operating portion 404 is pressed, the coil spring 406 (406a) contracts and the operating portion 404 (pressing portion 432) is moved to the main body portion 401 (edge wall) until the operating portion 404 and the base portion 413 come into contact with each other. Part 423) is displaced in the direction of immersing (downward). Further, when the operation of the pressing portion 432 is released (when the hand is released from the operation portion 404), the coil spring 406 (406a) is extended, and the operation portion 404 is displaced in the direction (upward) protruding from the main body portion 401 to be the original. Return to the state. In the present embodiment, the above-described operation can be realized with only the three coil springs 406a supported by the spring support portion 415.

  As described above, in this embodiment, the movable body 473 that supports the lower end portion of the coil spring 406b is configured to slide up and down between the first position and the second position. In the present embodiment, when the movable body 473 is in the first position below, the coil spring 406b supported by the movable body 473 is separated from the top wall portion 433a of the spring accommodating portion 433, and the operation portion 404 is moved away. When the operation portion 404 and the base portion 413 are brought into contact with each other, the upper end portion of the coil spring 406b and the top wall portion 433a are in contact with each other. On the other hand, when the movable body 473 is in the upper second position, the upper end of the coil spring 406b is also in a state where the operation unit 404 is not operated (the state in which the spring accommodating portion 433 and the edge wall portion 423 are in contact). The portion and the top wall portion 433a are in contact (contacted with each other). In addition, regarding the coil spring 406a, as described above, even when the movable body 473 is in the first position, the upper end portion thereof is in pressure contact with the top wall portion 433a and the operation portion 404 is biased upward. It has become.

  That is, when the movable body 473 is in the first position, the operation unit 404 is urged upward by only the three coil springs 406a, and when the movable body 473 is in the second position, the operation unit 404 is pressed. Is biased upward by a total of six coil springs 406a, 406b. Therefore, in the state where the movable body 473 is in the second position, the urging force of the coil spring 406 acting on the operation portion 404 is larger than in the state where the movable body 473 is in the first position, and therefore the pressing portion A larger force is required to press 432 and displace the operation unit 404 downward. In particular, in the present embodiment, since the spring constant of the coil spring 406b is larger than the spring constant of the coil spring 406a, the operation unit 404 is moved between when the movable body 473 is in the first position and when it is in the second position. The magnitude of the force required when operating is significantly changed.

  The operation detection switch 407 is electrically connected to the operation side terminal portion 435 provided on the inner surface side of the peripheral wall portion 431 of the operation portion 404 and the input / output port 554, and is provided on the base portion 413 of the base plate 411. Side terminal portion 436. When the operation unit 404 is not pressed, the operation side terminal unit 435 and the base side terminal unit 436 are separated from each other. When the operation unit 404 is pressed, the operation side terminal unit 435 and the base side terminal unit 436 are separated. Are in contact with each other. When the operation side terminal portion 435 and the base side terminal portion 436 are in contact with each other, the circuit including the operation side terminal portion 435 and the base side terminal portion 436 is energized, and the operation of the operation portion 404 is detected. ing. The configuration of the operation detection switch 407 is not particularly limited, and for example, the operation of the operation unit 404 may be detected using an optical sensor or the like.

  In the present embodiment, the pressing portion 432 is pressed, and the position of the operating portion 404 when the operating side terminal portion 438 and the base side terminal portion 439 are in contact corresponds to the operating position. The position when the operation side terminal portion 438 and the base side terminal portion 439 are not in contact with each other corresponds to the non-operation position.

  As shown in FIG. 8A, the upper substrate 402 has a substantially disk shape, and light emitting means L1, L2, and L3 are disposed on the upper surface thereof at equal positions with the central portion of the upper substrate 402 as the center. The light emitting means L1, L2, and L3 are configured by three-color LEDs, and light emitting elements (light emitting units) R1, R2, and R3 whose emission color is red, respectively, and light emitting devices (light emitting units) G1, G2, whose emission color is green, G3 has light emitting elements (light emitting portions) B1, B2, and B3 whose emission color is blue. As shown in FIG. 7, the lower surface of the upper substrate 402 is electrically connected to the light emitting means L1, L2, and L3 (light emitting elements R1, R2, R3, G1, G2, G3, B1, B2, and B3). The light emitting side terminal portions P1 to P7 are provided. In the present embodiment, the upper substrate 402 is disposed in the order of P1 → P2 → P3 → P4 → P5 → P6 → P7 from the outer peripheral side toward the inner peripheral side. Moreover, in this embodiment, the light emission side terminal parts P1-P7 are each comprised by calling a some copper wire, and the front-end | tip part is substantially brush shape. Further, in the present embodiment, the light emitting side terminal portions P1 to P7 are arranged at predetermined intervals so as to be aligned on a straight line along the centrifugal direction of the upper substrate 402. That is, the distance between the center portion of the upper substrate 402 and the light emitting side terminal portions P1 to P7 is different, and the trajectory drawn by the light emitting side terminal portions P1 to P7 when the upper substrate 402 rotates once. Both are designed not to overlap. In the present embodiment, for convenience of explanation, the light emitting side terminal portions P1 to P7 are arranged so as to be aligned in a straight line in the centrifugal direction of the upper substrate 402, but are not particularly limited to such a configuration. , They may be scattered instead of on a straight line. In FIG. 8, illustration of a printed wiring (print pattern) for electrically connecting the light emitting means L1, L2, and L3 and the light emitting side terminal portions P1 to P7 is omitted.

  Based on FIG. 11, the correspondence between the light emitting means L1, L2, and L3 and the light emitting side terminal portions P1 to P7 will be described. As shown in the figure, the light emitting side terminal portion P1 is connected to the anode side of the light emitting element R1, the light emitting side terminal portion P2 is connected to the anode side of the light emitting element G1, and the light emitting side is connected to the anode side of the light emitting element B1. The side terminal part P3 is connected. Further, the light emitting side terminal portion P4 is connected to the anode side of the light emitting elements R2 and R3, the light emitting side terminal portion P5 is connected to the anode side of the light emitting elements G2 and G3, and the anode side of the light emitting elements B2 and B3 is connected. The light emission side terminal part P6 is connected. Further, the light emitting side terminal portion P7 is connected to the cathode side of the light emitting elements R1, R2, R3, G1, G2, G3, B1, B2, and B3.

  As shown in FIG. 7, a connecting portion 438 that protrudes in a direction orthogonal to the upper substrate 402 is provided at the center of the lower surface of the upper substrate 402. The connecting portion 438 includes a cylindrical portion 438a into which a distal end portion of a rotating shaft 461 of a motor 405 described later can be inserted at the lower end portion. In addition, the tip part of the rotating shaft 461 of the motor 405 described later in detail has a substantially D-shaped cross section, and the shape of the opening formed inside the cylindrical part 438a is a shape corresponding to this. As a result, the driving force of the rotating shaft 461 inserted into the cylindrical portion 438a is reliably transmitted to the upper substrate 402.

  As shown in FIG. 8B, the lower substrate 403 has a substantially disk shape, and the outer peripheral portion is supported by the support wall portion 414 as described above. An insertion hole 441 penetrating vertically is formed in the center of the lower substrate 403, and the connecting portion 438 of the upper substrate 402 is inserted into the insertion hole 441. That is, the driving force of the motor 405 is not transmitted to the lower substrate 403, and the lower substrate 403 is provided so as not to be displaced with respect to the main body 401.

  On the upper surface of the lower substrate 403, main body side terminal portions Q1 to Q7 corresponding to the respective light emitting side terminal portions P1 to P7 are provided. As shown in FIG. 11, the main body side terminal portions Q1 to Q7 are input / output ports of a sub-control device 262 that controls sound, lamps, etc. via switching elements such as transistors, resistors, capacitors, etc., not shown 554. The sub-control device 262 controls the driving of the switching elements (ON and OFF) by outputting a signal from the input / output port 554, and controls the lighting of the light emitting units L1, L2, and L3.

  The main body side terminal portions Q1 to Q7 in the present embodiment are printed wirings formed on the upper surface of the lower substrate 403. When the upper substrate 402 is rotated once, the corresponding light emitting side terminal portions P1 to P7 are changed. It is formed along the drawn trajectory. That is, when the upper substrate 402 is rotated once, the orbits drawn by the seven light emitting side terminal portions P1 to P7 are seven concentric circles centering on the central portion of the lower substrate 403, and on the circumference of these concentric circles. The main body side terminal portions Q1 to Q7 are extended along the line.

  Specifically, the main body side terminal portions Q1 to Q7 are arranged in the order of Q1, Q2, Q3, Q4, Q5, Q6, and Q7 from the outer peripheral side to the inner peripheral side of the lower substrate 403. The terminal portion Q1 is configured to be in contact with the light emitting side terminal portion P1, the main body side terminal portion Q2 is configured to be in contact with the light emitting side terminal portion P2, and the main body side terminal portion Q3 is configured to be in contact with the light emitting side terminal portion P3. The main body side terminal portion Q4 is configured to be in contact with the light emitting side terminal portion P4, the main body side terminal portion Q5 is configured to be in contact with the light emitting side terminal portion P5, and the main body side terminal portion Q6 is configured to be in contact with the light emitting side terminal portion P6. It is comprised so that contact is possible, and the main body side terminal part Q7 is comprised so that contact with the light emission side terminal part P7 is possible (refer FIG. 11). The light emitting means L1, L2, and L3 are turned on by relatively displacing the upper substrate 402 with respect to the lower substrate 403 while maintaining the contact state between the light emitting side terminal portions P1 to P7 and the main body side terminal portions Q1 to Q7. It can be displaced relative to the lower substrate 403 in the state.

  Further, the main body side terminal portions Q4 to Q7 are formed in a closed annular shape without a break, and are always in contact with the corresponding light emitting side terminal portions P4 to P7 regardless of the rotational phase of the upper substrate 402. Therefore, the light emitting elements R2, R3, G2, G3, B2, B3 of the light emitting means L2, L3 connected to the light emitting side terminal portions P4 to P6, P7 are connected to the anode side (main body side terminal portions Q4 to Q6). When the switching element (not shown) is turned on and the switching element (not shown) connected to the cathode side (main body side terminal portion Q7) is turned on, the upper substrate 402 is energized in any rotational phase. Will be lit.

  On the other hand, the main body side terminal portions Q1 to Q3 are substantially C-shaped with a part missing in the circumferential direction, and are in contact with the corresponding main body side terminal portions Q1 to Q3 as the upper substrate 402 rotates. It will switch to a state and the state which is not contacting. Accordingly, each of the light emitting elements R1, G1, B1 of the light emitting means L1 connected to the light emitting side terminal portions P1 to P3, P7 is turned on by a switching element (not shown) connected to the anode side (main body side terminal portions Q1 to Q3). At the same time, even when a switching element (not shown) connected to the cathode side (main body side terminal portion Q7) is turned on, it is switched between a lighting state and a light-off state according to the rotational phase of the upper substrate 402. Become.

  In the present embodiment, the positions where the main body side terminal portions Q1, Q2, Q3 are interrupted in the circumferential direction of the lower substrate 403 are different, and the main body side terminal portion Q1 opens to the right in FIG. 8B. The main body side terminal portion Q2 is open at the lower left in the figure, and the main body side terminal portion Q3 is open at the upper left in the figure. More specifically, in the centrifugal direction of the lower substrate 403, three sections (section a shown in FIG. 8B) where the main body side terminal portions Q1 to Q3 overlap are provided, and the other sections (FIG. 8B) are provided. In the sections b, c, d) shown, any two of the main body side terminal portions Q1 to Q3 overlap.

  In the present embodiment, since the light emitting side terminal portions P1 to P7 are arranged in a straight line along the centrifugal direction of the upper substrate 402, switching elements (not shown) connected to the main body side terminal portions Q1 to Q3 and Q7. When the light emitting side terminal portions P1 to P7 are located in the section a shown in FIG. 8B, the light emitting elements R1, G1, and B1 of the light emitting means L1 are turned on and the emission color becomes white. When positioned at b, the light emitting elements R1, B1 of the light emitting means L1 are lit and the emission color is purple (magenta), and when positioned at section c, the light emitting elements R1, G1 of the light emitting means L1 are lit and the emission color is yellow, When positioned in the section d, the light emitting elements G1 and B1 of the light emitting means L1 are turned on and the light emission color becomes light blue (cyan).

  That is, when the upper substrate 402 rotates, the combination of the light emitting side terminal portions P1 to P3 that are in contact with the corresponding main body side terminal portions Q1 to Q3 among the light emitting side terminal portions P1 to P3 changes. L1 changes its color while being rotationally displaced. Further, since the lower substrate 403 is not displaced, the light emitting elements R1, G1, and B1 are turned on according to the phase of the light emitting means L1 while the upper substrate 402 makes one rotation (one cycle) based on the driving of the motor 405. The light emitting elements R1, G1, and B1 to be determined are determined in advance. Accordingly, the light emitting means L1 periodically develops the same color. As for the light emitting means L2 and L3, unless the switching element (not shown) connected to the main body side terminal portions Q4 to Q6 (main body side terminal portion Q7) is turned on and off, the emission color is emitted even if the upper substrate 402 is rotated. There is no change.

  Further, as shown in FIG. 7, the lower substrate 403 is provided with guide rails 443 along both side portions of the main body side terminal portions Q1 to Q7 (in FIG. 8B, the guide rails 443 are not provided). (The illustration is omitted). Each guide rail 443 has a substantially triangular cross section and is integrally formed with the lower substrate 403. The presence of the guide rail 443 guides the displacement of the light emitting side terminal portions P1 to P7 accompanying the rotation of the upper substrate 402, and the predetermined light emitting side terminal portions P1 to P7 are not the corresponding main body side terminal portions Q1 to Q7. And the situation where it contacts the adjacent main body side terminal parts Q1-Q7 can be suppressed. In addition, the main body side terminal portions Q1 to Q7 of the present embodiment are formed to be slightly thick, and even if worn slightly due to friction with the light emitting side terminal portions P1 to P7, there is no problem. Further, the light emission side terminal portions P1 to P7 of the upper substrate 402 allow this even when the distance between the upper substrate 402 and the lower substrate 403 is slightly short when the upper substrate 402 is rotated. In order to be able to do so, it is formed slightly longer than the distance between the upper substrate 402 and the lower substrate 403, and is arranged in a slightly bent state (obliquely). The main body side terminal portions Q1 to Q7 may also be formed at the base portion of the inclined surface of the guide rail 443. In addition, the guide rail 443 formed separately from the lower substrate 403 may be fixed to the lower substrate 403.

  In this embodiment, the upper substrate 402 and the lower substrate 403 are unitized and assembled to the main body 401. Hereinafter, a configuration in which the upper substrate 402 and the lower substrate 403 are unitized will be described.

  As shown in FIG. 7 and FIG. 8B, the lower substrate 403 is slightly larger than the upper substrate 402, and the upper substrate 402 and the lower substrate 403 are overlapped with their centers aligned. In addition, a locking hole 445 penetrating vertically is formed in a portion of the lower substrate 403 located outside the outer periphery of the upper substrate 402 (at the outer peripheral position from the main body side terminal portion Q1). Three locking holes 445 are formed at equal positions around the center of the lower substrate 403. Each locking hole 445 is formed with a female screw, and a support fitting 451 as an attaching means is screwed into the locking hole 445.

  As shown in FIG. 8C, the support fitting 451 includes a substantially cylindrical fitting main body 452 fixed to the lower substrate 403, an insertable annular support ring 453 inserted into the fitting main body 452, and A cylindrical bearing 454 inserted into the metal fitting body 452 and a nut 455 fixed to the metal fitting body 452 are provided.

  The metal fitting main body 452 is provided on the columnar general portion 456, one end portion side of the general portion 456, the reduced diameter portion 457 having a smaller diameter than the general portion 456, and the other end portion side of the general portion 456. A general portion 456 and a head 458 having a larger diameter than the locking hole 445 are provided. The general portion 456 includes a screwed portion 456a in which a male screw is formed at the boundary with the head 458, and the screwed portion 456a can be screwed into the locking hole 445. Further, the reduced diameter portion 457 is provided with a bolt portion 457a in which a male screw is formed at the tip portion, and the bolt portion 457a can be screwed to the nut 455.

  The support ring 453 has an outer diameter larger than the diameter of the general portion 456, and an inner diameter (a diameter of the opening on the inner peripheral side) is approximately the same as the diameter of the reduced diameter portion 457. The bearing 454 has an outer diameter approximately the same as the diameter of the general portion 456, and an inner diameter is slightly larger than the reduced diameter portion 457. The nut 455 has an outer diameter (diameter) larger than the diameter of the general portion 456.

  When unitizing the upper substrate 402 and the lower substrate 403, first, the metal fitting body 452 is inserted into the locking hole 445 from the lower surface side of the lower substrate 403, and the lower surface of the lower substrate 403 and the head portion 458 are connected to each other. The locking hole 445 and the screwed portion 456a are screwed together until they come into contact. Thereby, the metal fitting body 452 is fixed to the lower substrate 403.

  Next, the support ring 453 and the bearing 454 are inserted into the reduced diameter portion 457. Accordingly, the lower surface of the support ring 453 is supported by the general portion 456 (boundary portion between the reduced diameter portion 457 and the general portion 456), and the lower surface of the bearing 454 is supported by the support ring 453. Subsequently, the connecting portion 438 of the upper substrate 402 is inserted into the insertion hole 441 of the lower substrate 403 from above the lower substrate 403. At this time, the lower surface of the outer peripheral portion of the upper substrate 402 is supported by being in contact with the upper surface of the support ring 453 of each support fitting 451, and the bearing 454 is substantially in contact with the outer peripheral surface of the upper substrate 402. Then, the nut 455 is fixed to the bolt part 457a. As a result, the lower surface of the nut 455 is substantially in contact with the upper surface of the outer peripheral portion of the upper substrate 402.

  As described above, the upper substrate 402 and the lower substrate 403 that are unitized using the support metal fitting 451 can be rotated relative to the lower substrate 403.

  The rotating shaft 461 of the motor 405 is configured to have a substantially D-shaped cross section at the tip thereof, and is inserted (fitted) into a cylindrical portion 438 a of a connecting portion 438 provided on the upper substrate 402. As a result, the motor 405 and the upper substrate 402 are connected, and the upper substrate 402 is rotationally displaced based on the driving of the motor 405. In addition, the motor 405 incorporates an encoder capable of detecting the rotational phase of the rotating shaft 461. Therefore, the rotational phase of the upper substrate 402 can be adjusted by driving the motor 405 based on the detection information of the encoder.

  The rotation shaft 461 has a predetermined reference phase. When stopping the driving of the motor 405, the motor is set so that the rotation shaft 461 (upper substrate 402) becomes the reference phase based on the detection information of the encoder. 405 is driven and controlled. In this embodiment, the phase of the rotating shaft 461 when the light emitting side terminal portions P1 to P7 are arranged on the virtual line e shown in FIG. 8B is set as the reference phase of the rotating shaft 461 (upper substrate 402). The light emitting side terminal portions P1, P2, and P3 and the main body side terminal portions Q1, Q2, and Q3 are in contact with each other. Thereby, when the motor 405 is not driven, the light emission color of the light emitting means L1 can be white. Further, in the present embodiment, the upper substrate 402 is configured to rotate in the clockwise direction of FIG. 8A by driving the motor 405, and the switching (not shown) connected to the main body side terminal portions Q1 to Q3 and Q7. When all the elements are on, the light emitting means L1 rotates in the clockwise direction with the rotation of the upper substrate 402, while white → purple → white → yellow → white → light blue → white →.・ The emission color changes.

  Here, the assembly operation of the effect button 125 will be briefly described. First, after the upper substrate 402 and the lower substrate 403 are unitized as described above, the connecting portion 438 of the upper substrate 402 and the rotating shaft 461 of the motor 405 are connected. Further, the spring force adjusting means 471 is attached to the base plate 411 (base portion 413) so that the movable body 473 (support protrusion 485) is inserted into the spring insertion hole 487 of the base portion 413. Even if the movable body 473 is not in the first position when the spring force adjusting means 471 is attached to the base portion 413, the movable body 473 is moved to the first position by turning on the power of the pachinko machine 10. The adjustment motor 474 will be driven until it becomes. Next, the motor 405 is fitted into the motor installation portion 412 of the base plate 411. At this time, as described above, the outer peripheral portion of the lower substrate 403 is locked by the upper end portion of the support wall portion 414. Subsequently, the coil spring 406a is fitted into the spring support portion 415, the coil spring 406b is fitted into the support projection 485 of the spring force adjusting means 471, and the coil spring 406 (406a, 406b) is inserted into the spring accommodating portion 433. The base plate 411 and the operation unit 404 are assembled. Thereafter, the frame body 421 is attached to the base plate 411 so as to cover the operation portion 404 and fixed. The production button 125 is assembled as described above.

  Next, the electrical configuration of the pachinko machine 10 will be described. FIG. 12 is a block diagram illustrating an electrical configuration of the pachinko machine 10. The main control device 261 (main substrate) of the pachinko machine 10 is equipped with a CPU 501 as a one-chip microcomputer that is an arithmetic device. The CPU 501 includes a ROM 502 that stores various control programs executed by the CPU 501 and fixed value data, and a RAM 503 that is a memory that temporarily stores various data when the control program stored in the ROM 502 is executed. Various circuits such as an interrupt circuit, a timer circuit, and a data transmission / reception circuit are incorporated. However, the CPU, the ROM, and the RAM may not be integrated into one chip but may be configured as a chip for each function.

  The RAM 503 is a stack area that stores the contents of the internal registers of the CPU 501, the return address of a control program executed by the CPU 501, and a work area (work area) that stores various flags, counters, I / O values, and the like. ) And a backup area 503a.

  The RAM 503 is configured to retain (backup) data by being supplied with a backup voltage from the power supply device 313 even after the pachinko machine 10 is turned off, and is stored in the stack area, work area, and backup area 503a. All data is backed up.

  In the backup area 503a, when the power is cut off due to a power failure or the like, the power of the pachinko machine 10 is restored to the state before the power is turned off when the power is turned on again. (Similarly) is an area for storing stack pointers, values of registers, I / O, and the like. Writing to the backup area 503a is executed when the power is turned off by the main process. Conversely, the return of each value written to the backup area 503a is the main process at the time of power-on (including power-on due to power failure cancellation, and so on). Executed in Note that a power failure signal SK1 output from a power failure monitoring circuit 542, which will be described later, is input to the NMI terminal (non-maskable interrupt terminal) of the CPU 501 when a power failure occurs due to the occurrence of a power failure or the like. Due to the occurrence, the power failure process (NMI interrupt process) is immediately executed.

  Note that if data stored in at least the stack area and the backup area 503a is backed up, it is not always necessary to back up data stored in all areas. For example, the data stored in the stack area and the backup area 503a may be backed up, and the data stored in the work area may not be backed up.

  An input / output port 505 is connected to the CPU 501 incorporating the ROM 502 and RAM 503 via a bus line 504 including an address bus and a data bus. A RAM erase switch circuit 543, a payout control device 311, a sub control device 262, a special display device 43, a normal symbol display device 41, etc., which will be described later, are connected to the input / output port 505. With this configuration, the special display device 43 and the normal symbol display device 41 described above are directly controlled by the main control device 261. On the other hand, the decorative symbol display device 42 is controlled via the sub-control device 262.

  In addition, for convenience, illustration of various relay boards and the like is omitted, but the input / output port 505 includes various types such as a prize opening switch 221, a count switch 223, first trigger corresponding unit switches 224a and 224b, and a second trigger corresponding switch 225. Various electrical components such as detection switches and various substrates are connected. That is, the main controller 261 is provided with a plurality of terminal portions (board side connectors) for connecting connectors of various cable connectors, and the input / output port 505 is configured by these terminal portions.

  The sub-control device 262 (sub-control board) includes a CPU 551 that is an arithmetic unit, various control programs executed by the CPU 551, a ROM 552 that stores fixed value data, and various control programs that are stored in the ROM 552. In addition to a RAM 553 that is a memory for temporarily storing data, an input / output port 554, a bus line 555, various circuits such as an interrupt circuit, a timer circuit, and a data transmission / reception circuit (not shown) are also provided. The RAM 553 is a memory that temporarily stores work data and flags used when the CPU 551 executes various programs.

  A CPU 551, ROM 552, and RAM 553 are connected to the input / output port 554 via a bus line 555 and a display control device 45 is connected. Further, the speaker SP, the effect button 125, various illumination units, and the lamps 102 to 104 are connected to the input / output port 554.

  The CPU 551 of the sub-control device 262 causes the display control device 45 to execute display control based on, for example, a command signal (for example, a variation pattern command) transmitted from the main control device 261 and causes the decorative symbol display device 42 to display the display control device. As described above, in the present embodiment, the special display device 43 controlled by the main control device 261 displays whether or not it is a big hit, and the decorative symbol display device 42 controlled by the sub control device 262. Then, display according to the display of the special display device 43 is performed.

  The payout control device 311 controls payout of prize balls and rental balls by the payout device 358. The CPU 511 that is an arithmetic unit includes a ROM 512 that stores a control program executed by the CPU 511, fixed value data, and the like, and a RAM 513 that is used as a work memory or the like.

  The RAM 513 of the payout control device 311, like the RAM 503 of the main control device 261, has a stack area for storing the contents of the internal registers of the CPU 511 and the return address of the control program executed by the CPU 511, various flags and counters, A work area (work area) in which values such as I / O are stored, and a backup area 513a are provided.

  The RAM 513 is configured to hold (backup) data by being supplied with a backup voltage from the power supply device 313 even after the power of the pachinko machine 10 is turned off, and all stored in the stack area, work area, and backup area 513a. Data is backed up. Note that if data stored in at least the stack area and the backup area 513a is backed up, it is not always necessary to back up data stored in all areas. For example, the data stored in the stack area and the backup area 513a may be backed up, and the data stored in the work area may not be backed up.

  The backup area 513a has a stack pointer, each register at the time of power off, each register, so that the power of the pachinko machine 10 is restored to the state before the power is turned off when the power is turned off. This is an area for storing values such as I / O. The writing to the backup area 513a is executed when the power is turned off by the main process, and the restoration of each value written to the backup area 513a is executed in the main process when the power is turned on. Similarly to the CPU 501 of the main controller 261, the power failure signal SK1 is input to the NMI terminal of the CPU 511 from the power failure monitoring circuit 542 when the power is interrupted due to the occurrence of a power failure or the like. When input to the CPU 511, NMI interrupt processing as power failure processing is immediately executed.

  In the work area, a payout permission flag for which the payout control device 311 is set to allow the payout of prize balls, a command reception flag set when a command transmitted from the main control device 261 is received, and the main control device 261 And a command buffer for storing a command transmitted from.

  The payout permission flag is a flag for setting a prize ball payout permission, and is turned on when a specific command for permitting the payout of the prize ball is transmitted from the main control device 261 and received, and is initially set. It is turned off when it is restored before the process or power shutdown. In the present embodiment, the specific commands are: a payout initialization command for instructing the initial processing of the RAM 513 of the payout control device 311; There are three payout return commands to be transmitted in this case.

  The command reception flag is a flag for confirming whether or not the payout control device 311 has received a command, and is turned on when any command is received. Similar to the payout permission flag, an initial setting process or power-off is performed. It is turned off when returning to the front, and turned off when the command received by the command determination process is determined.

  The command buffer is configured by a ring buffer that temporarily stores commands transmitted from the main control device 261.

  An input / output port 515 is connected to the CPU 511 incorporating the ROM 512 and the RAM 513 through a bus line 514 including an address bus and a data bus. A RAM erase switch circuit 543, a main controller 261, a launch controller 312 and a payout device 358 are connected to the input / output port 515, respectively.

  The card unit connection board 314 includes a ball rental operation unit (a ball rental button 121 and a return button 122) on the front surface of the pachinko machine 10, and a card unit (a ball rental unit) arranged on the side of the pachinko machine 10 in a game hall or the like. Are electrically connected to each other, and receive a ball lending operation command from the player and output it to the card unit. In a cash machine in which game balls are lent directly to the upper plate 19 from a ball lending device or the like without using a card unit, the card unit connection board 314 can be omitted.

  The launch control device 312 permits or prohibits the launch of the game ball by the launch device 60, and the launch device 60 is permitted to drive when predetermined conditions are met. Specifically, a firing permission signal is output from the payout control device 311, a sensor signal is detected that the player is touching the handle 18, and a firing stop switch that stops firing is operated. On the condition that it is not done, the launching device 60 is driven, and the game ball is launched at an intensity corresponding to the operation amount of the handle 18.

  The display control device 45 executes the variable display of the decorative symbols on the decorative symbol display device 42 in accordance with an instruction from the sub-control device 262. The display control device 45 includes a CPU 521, a program ROM 522, a work RAM 523, a video RAM 524, a character ROM 525, a video display processor (VDP) 526, an input port 527, an output port 529, and bus lines 530 and 531. And. An input / output port 554 of the sub control device 262 is connected to the input port 527. Further, a CPU 521, a program ROM 522, a work RAM 523, and a VDP 526 are connected to the input port 527 through a bus line 530. An output port 529 is connected to the VDP 526 via a bus line 531, and a decorative symbol display device 42 as a liquid crystal display device is connected to the output port 529.

  The CPU 521 of the display control device 45 receives the display command transmitted from the sub-control device 262 via the input port 527, analyzes the received command, or performs predetermined arithmetic processing based on the received command to control the VDP 526. (Specifically, generation of an internal command for the VDP 526) is performed. Thereby, display control in the decorative symbol display device 42 is performed.

  The program ROM 522 is a memory that stores various control programs executed by the CPU 521 and fixed value data. The work RAM 523 is a memory that temporarily stores work data and flags used when the CPU 521 executes various programs. It is.

  The video RAM 524 is a memory for storing display data to be displayed on the decorative symbol display device 42, and the display content of the decorative symbol display device 42 is changed by rewriting the content of the video RAM 524. The character ROM 525 is a memory that stores character data such as symbols displayed on the decorative symbol display device 42.

  The VDP 526 is a kind of drawing circuit that directly operates an LCD driver (liquid crystal driving circuit) incorporated in the decorative symbol display device 42. Since the VDP 526 is an IC chip, it is also referred to as a “drawing chip”, and the substance of the VDP 526 can be said to be a microcomputer chip with a dedicated firmware for drawing processing. The VDP 526 adjusts the respective timings of the CPU 521, the video RAM 524, etc. to intervene in reading and writing data, and reads the display data stored in the video RAM 524 at a predetermined timing and causes the decorative symbol display device 42 to display it.

  The power supply device 313 includes a power supply unit 541 that supplies power to each unit of the pachinko machine 10, a power failure monitoring circuit 542 that monitors power interruption due to a power failure, and a RAM erase switch circuit 543 connected to the RAM erase switch 323. And.

  The power supply unit 541 supplies necessary operation power to the main control device 261, the payout control device 311 and the like through a power supply path (not shown). As its outline, the power supply unit 541 takes in AC 24 volt power supplied from the outside, generates + 12V power for driving various switches and motors, + 5V power for logic, backup power for RAM backup, etc. These + 12V power supply, + 5V power supply and backup power supply are supplied to the main control device 261, the payout control device 311 and the like. Note that operation power (+12 V power, +5 V power, etc.) is supplied to the launch control device 312 via the payout control device 311. Similarly, operating power is supplied to various switches, motors and the like via a control device to which these are connected.

  The power failure monitoring circuit 542 is a circuit that outputs a power failure signal SK1 to each NMI terminal of the CPU 501 of the main control device 261 and the CPU 511 of the payout control device 311 when the power is cut off due to the occurrence of a power failure or the like. The power failure monitoring circuit 542 monitors the DC stable voltage of 24 volts, which is the maximum voltage output from the power supply unit 541, and determines that a power failure (power failure) has occurred when this voltage is less than 22 volts. The power failure signal SK1 is output to the main controller 261 and the payout controller 311. Based on the output of the power failure signal SK1, the main control device 261 and the payout control device 311 recognize the occurrence of a power failure and execute a power failure process (NMI interrupt processing).

  The power supply unit 541 normally outputs an output of 5 volts, which is a drive voltage of the control system, for a time sufficient to execute the process at the time of a power failure even after the DC stable voltage of 24 volts becomes less than 22 volts. Configured to maintain the value. Therefore, the main control device 261 and the payout control device 311 can normally execute and complete the power failure process.

  The RAM erase switch circuit 543 is a circuit that takes in the switch signal of the RAM erase switch 323 and clears backup data in the RAM 503 of the main controller 261 and the RAM 513 of the payout controller 311 in accordance with the state of the switch 323. When the RAM erase switch 323 is pressed, the RAM erase switch circuit 543 outputs a RAM erase signal SK2 to the main controller 261 and the payout controller 311. When the power of the pachinko machine 10 is turned on with the RAM erase switch 323 pressed (including power-on due to power failure cancellation), the data in the respective RAMs 503 and 513 are cleared in the main controller 261 and the payout controller 311. The

  Next, the operation of the pachinko machine 10 configured as described above will be described.

  In the present embodiment, the CPU 501 in the main control device 261 performs lottery (big hit lottery) using various counter information in the game. Specifically, as shown in FIG. 13, the jackpot random number counter C1 as a lottery random number counter used for the jackpot lottery and the mode decision used for determining the shift to the high probability mode or the low probability mode described later when the jackpot is won. The counter C2, the variation selection counter C3 used for determining the variation display time of the special display device 43, the initial value random number counter CINI used for setting the initial value of the jackpot random number counter C1, and the variation display time of the special display device 43 Variation type counters CS1 and CS2 used for determining the normal symbol display device 41, and a normal symbol random number counter C4 used for lottery of the normal symbol display device 41 (open lottery to determine whether or not the first opportunity corresponding unit 33 is opened). I am going to use it. Note that the variation selection counter C3 is also used for a variation pattern and reach type lottery when the decorative symbol display device 42 is deviated and varied. The variation type counters CS1 and CS2 are also used for variation pattern selection (effect pattern selection) of the decorative symbol display device 42. Specifically, the variation time of the special display device 43 is determined according to the determined variation pattern, and the variation mode and variation time in the decorative symbol display device 42, that is, the effect pattern (effect mode) are determined.

  Each of the counters C1, C2, C3, CINI, CS1, CS2, and C4 is a loop counter that adds 1 to the previous value every time it is updated and returns to the lower limit value of 0 after reaching the upper limit value. Each counter is periodically updated, and the updated value is appropriately stored in a counter buffer set in a predetermined area of the RAM 503 (except for the random number initial value counter CINI).

  The RAM 503 is provided with a first reserved ball storage area and a second reserved ball storage area as a storage area composed of one execution area and four reserved areas (first to fourth reserved areas). In each area of the first reserved ball storage area, the values of the jackpot random number counter C1, the mode determination counter C2, and the variation selection counter C3 are time-sequentially matched to the winning history of the game balls to the first opportunity corresponding unit 33. It is designed to be stored. In addition, in each area of the second reserved ball storage area, the value of the normal symbol random number counter C4 is stored in time series in accordance with the passing history of the game ball to the second opportunity corresponding port 34. Yes. By adopting this configuration, the variable display on the special display device 43 and the normal symbol display device 41 can be suspended as described above.

  In detail, each jackpot random number counter C1 is incremented one by one within a range of 0 to 917, for example. After reaching an upper limit value (that is, 917) as a closing price, 0 is a lower limit value as a starting price. It is the composition which returns to. Normally, when the jackpot random number counter C1 makes one round, the value of the initial value random number counter CINI at that time is read as the next initial value of the jackpot random number counter C1. The initial value random number counter CINI is a loop counter similar to the jackpot random number counter C1 (value = 0 to 917), and is updated once for each timer interruption and is repeatedly updated within the remaining time of normal processing. On the other hand, the jackpot random number counter C1 is updated periodically (once every timer interruption in this embodiment), and the value of the jackpot random number counter C1 is stored in the jackpot random number counter buffer. Then, the value of the jackpot random number counter C1 stored in the jackpot random number counter buffer is stored in the first reserved ball storage area of the RAM 503 at the timing when the game ball wins the first opportunity corresponding unit 33. There are two types of jackpot random numbers, a low probability state (normal mode, time reduction mode, etc.) and a high probability state (high probability mode). The number of random number values to be 3 is “147, 341, 533”, the number of random number values that are jackpots in the high probability state is 30, and the value is “141 to 150, 341-350, 531-540 ".

  Here, various game modes will be described. In the present embodiment, the game mode (game state) is switched between a normal mode (normal state) and a plurality of specific modes that are more advantageous to the player than the normal mode. More specifically, as the specific mode, two modes, a high probability mode and a time reduction mode, are set. Among these, the high probability mode is a game mode that continues until the next jackpot, and the time reduction mode is a mode that shifts to the next mode after the predetermined period.

  The normal mode refers to a normal state that is not a specific mode such as the high probability mode. Therefore, in the normal mode, the jackpot probability (winning probability of the jackpot state) is a normal low probability.

  In addition, the high probability mode is a big hit when the special display device 43 is stopped and displayed with “red” (the decorative symbol display device 42 is stopped and displayed with a predetermined probability variation symbol), and the subsequent big hit A state in which the probability is higher than that in the low probability state. In the following description, the case where the decorative symbol display device 42 is a jackpot due to the probability variation symbol is referred to as “probability variation jackpot”, and the case where the jackpot is due to a normal symbol other than the probability variation symbol is referred to as “normal jackpot”.

  In the high probability mode, the jackpot probability is increased and the high probability state is entered. In addition, in this embodiment, the variable display time in the special display device 43 is shortened (the time is shortened). Furthermore, the ratio of the open state with respect to the closed state per unit time in the first opportunity handling unit 33 is higher than the ratio in the normal mode. As a result, the time period in which the first opportunity corresponding unit 33 is in the open state becomes longer, so that game balls frequently enter the first opportunity corresponding unit 33, and the big hit lottery continues. At the same time, it will be in good condition. That is, such a state corresponds to the high ball entering state in the present embodiment. Therefore, the high probability mode can be paraphrased as a high probability, a time reduction, and a high pitching mode. On the other hand, the normal mode corresponds to a low pitching state. The opening time of the first opportunity corresponding unit 33 in each mode is not particularly limited and can be set for each model. Further, in the high probability mode, the fluctuation time in the normal symbol display device 41 is shortened, or the probability that the “O” symbol is stopped and displayed in the normal symbol display device 41 (the winning probability of the open lottery) is higher than that in the normal mode. It is also possible to increase the number of times that the first opportunity corresponding unit 33 is opened per winning.

  In addition, the time reduction mode is a big hit when the special display device 43 is stopped and displayed in “green” (the decorative symbol display device 42 is stopped and displayed with a normal symbol other than a predetermined probability variation symbol). Thereafter, the game mode is set while the variable display of the special display device 43 is performed 100 times, which means a state more advantageous to the player than the normal mode. The time reduction mode is a gaming mode in which the jackpot probability is the same low probability as in the normal mode, and the ratio of the open state to the closed state per unit time in the first opportunity corresponding unit 33 is higher than the ratio in the normal mode. . That is, except for the difference in jackpot probability (winning probability in the jackpot state), the same state (time shortening state and high pitching state) is obtained. Therefore, the time shortening mode can be restated as a low probability / time shortening / high pitching mode.

  For example, the mode determination counter C2 is incremented one by one within a range of 0 to 9, for example, and after reaching the upper limit value (that is, 9), the mode determination counter C2 returns to the lower limit value of 0. In the present embodiment, the mode determination counter C2 determines whether or not to shift to the high probability mode after the big hit. Specifically, if the counter value is an odd number such as “1, 3, 5, 7, 9”, the transition to the high probability mode is determined, and if the counter value is an even number such as “0, 2, 4, 6, 8”. In this case, the transition to the time reduction mode is determined. Although the wording of transition is used here, it is a big hit when in the high probability mode, and when an odd counter value is selected, the high probability mode will be continued across the big hit state, A big hit is made when the time reduction mode is originally set, and when an even number of counter values is selected, the time reduction mode is continued with the big win state. The mode determination counter C2 is updated periodically (once every timer interruption in this embodiment), and the value of the mode determination counter C2 is stored in the mode determination counter buffer. The value of the mode determination counter C2 stored in the mode determination counter buffer is stored in the first reserved ball storage area of the RAM 503 at the timing when the game ball wins the first opportunity corresponding unit 33.

  Further, the variation selection counter C3 is configured so that, for example, one by one is added in order within a range of 0 to 238, for example, and after reaching the upper limit value (that is, 238), it returns to 0 that is the lower limit value. In this embodiment, after the reach is generated with respect to the decorative symbol by the variation selection counter C3, the final stop symbol is shifted by one by one before and after the reach symbol and stopped, and the last stop after the occurrence of reach is also performed. “Reach other than front / rear detachment” where the symbol stops other than before and after the reach symbol and “completely disengagement” where reach does not occur are selected by lottery. For example, C3 = 0, 1 corresponds to front / rear outreach and C3 = 2 to 21 correspond to reach other than front / rear disengagement, and C3 = 22 to 238 corresponds to complete disengagement. The reach lottery may be individually set according to the state of the lottery probability, the number of starting reserved balls at the start of change, and the like. The fluctuation selection counter C3 is updated periodically (once every timer interruption in this embodiment), and the value of the fluctuation selection counter C3 is stored in the fluctuation selection counter buffer. Then, at the timing when the game ball wins the first opportunity corresponding unit 33, the value of the variation selection counter C3 stored in the variation selection counter buffer is stored in the first reserved ball storage area of the RAM 503.

  In addition, one of the two variation type counters CS1 and CS2 is incremented one by one within a range of 0 to 198, for example, and reaches the upper limit value (that is, 198), and then reaches the lower limit value. The other variation type counter CS2 is incremented one by one within a range of 0 to 240, for example, and reaches the upper limit value (that is, 240) and then returns to the lower limit value of 0. It has become. In the following description, CS1 is also referred to as “first variation type counter”, and CS2 is also referred to as “second variation type counter”. This is shown in FIG. The first variation type counter CS1 determines the reach type (reach pattern) of the decorative symbol such as so-called normal reach, super reach, premium reach, and other rough symbol variation modes, and the second variation type counter CS2 determines the final after the reach occurrence. A more detailed symbol variation mode such as an elapsed time (in other words, the number of variation symbols) until the stop symbol (in this embodiment, the middle symbol) stops is determined. Accordingly, a variety of variation patterns can be easily realized by combining these variation type counters CS1 and CS2. It is also possible to determine the symbol variation mode only by the first variation type counter CS1, or to determine the symbol variation mode in combination by combining the first variation type counter CS1 and the stop symbol.

  In the present embodiment, when “big hit” occurs, one of normal reach, super reach, and premium reach is selected, and when “out-of-front reach” occurs, normal reach and super reach are selected. When either one is selected and “reach other than front / rear out” occurs, normal reach is selected. In addition, in the case of “completely off”, none of normal reach, super reach, and premium reach is selected.

  Further, the variation type counters CS1 and CS2 are updated once every time a normal process described later is executed once, and are repeatedly updated even within the remaining time of the normal process. Then, the buffer values of CS1 and CS2 are acquired when determining the variation pattern at the start of variation of the decorative symbol by the decorative symbol display device 42.

  In addition, the magnitude | size and range of each counter are only examples, and can be changed arbitrarily. However, it is desirable that the big hit random number counter C1, the variation selection counter C3, and the variation type counters CS1 and CS2 are different prime numbers and are not synchronized in any case.

  Further, the normal symbol random number counter C4 is configured as a loop counter that is incremented one by one within a range of 0 to 250, for example, and reaches the upper limit value (that is, 250) and then returns to the lower limit value of 0. The normal symbol random number counter C4 is updated periodically (once every timer interruption in the present embodiment), and the value of the normal symbol random number counter C4 is acquired when the game ball passes through the left or right second opportunity corresponding port 34. Is done. Usually, the number of random number values to be won is 250, and the range is “5 to 153”. When the value of the normal symbol random number counter C4 to be won is acquired, after the variable display is performed for a predetermined time in the normal symbol display device 41, the symbol corresponding to the winning (in this example, “◯”) is stopped and displayed. Then, the first opportunity corresponding unit 33 is activated for a predetermined time. In this embodiment, the probability that the symbol corresponding to the winning is stopped and displayed on the normal symbol display device 41, that is, the winning probability of the open lottery for determining whether or not the first opportunity corresponding unit 33 is opened, and The fluctuation time of the fluctuation display performed by the normal symbol display device 41 is the same in any mode.

  Next, each control process executed by the CPU 501 in the main controller 261 will be described with reference to a flowchart. The processing of the CPU 501 is broadly divided into a main process that is started when the power is turned on, a timer interrupt process that is started periodically (in this embodiment, at a cycle of 2 msec), and a stop signal to the NMI terminal (non-maskable terminal). For convenience of explanation, the timer interrupt process and the NMI interrupt process will be described first, and then the main process will be described.

  FIG. 16 is a flowchart showing the timer interrupt process. This process is executed by the CPU 501 of the main controller 261 every 2 msec, for example.

  In FIG. 16, first, in step S301, reading processing of various winning switches is executed. That is, the state of various switches (except for the RAM erase switch 323) connected to the main controller 261 is read, and the state of the switch is determined and the detection information (winning detection information) is stored.

  In step S302, random number initial value update processing is executed. Specifically, the random number initial value counter CINI is incremented by 1 and cleared to 0 when the counter value reaches the maximum value (917 in this example).

  In step S303, random number update processing is executed. Specifically, the jackpot random number counter C1, the mode determination counter C2, the variation selection counter C3, and the normal symbol random number counter C4 are each incremented by 1 and their counter values are maximum values (in this embodiment, 917, 9 respectively). , 238, 250) is cleared to 0 respectively. Then, the updated values of the counters C1, C2, C3, and C4 are stored in the corresponding buffer area of the RAM 503.

  Thereafter, in step S304, a start winning process associated with winning the first opportunity corresponding unit 33 is executed, and in step S305, a second opportunity corresponding port passing process accompanying the passing of the game ball to the second opportunity corresponding port 34 is performed. Run. Thereafter, the timer interrupt process is temporarily terminated.

  Here, the start winning process in step S304 will be described with reference to the flowchart of FIG. In step S501, whether or not the game ball has won the first opportunity corresponding unit 33 is determined based on the detection information of the first opportunity corresponding unit switch 224. If it is determined that the game ball has won the first opportunity corresponding unit 33, in the subsequent step S502, it is determined whether or not the number of starting reserved balls Na is less than the upper limit value (4 in the present embodiment). The process proceeds to step S503 on the condition that there is a winning in the first opportunity corresponding unit 33 and the start reserved ball number Na <4, and the start reserved ball number Na is incremented.

  In subsequent step S504, a random number related to the success or failure is acquired. Specifically, the values of the jackpot random number counter C1, the mode determination counter C2, and the variation selection counter C3 updated by the random number update process in step S303 are used as the first free storage area in the first reserved ball storage area of the RAM 503. Store in the area. Thereafter, the start winning process is temporarily terminated. Therefore, a part of the lottery means (win / no lottery process) in the present embodiment is configured by the function of the start winning process.

  Next, the second opportunity corresponding port passing process in step S305 will be described with reference to the flowchart of FIG.

  In step S601, whether or not the game ball has passed through the second opportunity corresponding port 34 is determined based on the detection information of the second opportunity corresponding switch 225.

  If a negative determination is made in step S601, the present process is terminated as it is. On the other hand, if an affirmative determination is made in step S601, that is, if it is determined that the game ball has passed through the second opportunity corresponding port 34, the number Nb of reserved balls in the normal symbol display device 41 is set to the upper limit value (step S602). In this embodiment, it is determined whether it is less than 4). If a negative determination is made here, this processing is terminated as it is. On the other hand, if an affirmative determination is made in step S602, that is, if the passing of the game ball to the second opportunity corresponding port 34 is confirmed and the number of reserved balls is Nb <4, the process proceeds to step S603, where the reserved ball The number Nb is incremented by one.

  In subsequent step S604, a random number related to the success or failure is acquired. Specifically, the value of the normal symbol random number counter C4 updated by the random number update process in step S303 is stored in the first area of the free storage area of the second reserved ball storage area of the RAM 503. Thereafter, the second opportunity corresponding port passing process is terminated.

  FIG. 17 is a flowchart showing the NMI interrupt process. This process is executed by the CPU 501 of the main controller 261 when the power of the pachinko machine 10 is cut off due to the occurrence of a power failure or the like. By this NMI interruption, the state of the main controller 261 at the time of power-off is stored in the backup area 503a of the RAM 503.

  That is, when the power of the pachinko machine 10 is cut off due to the occurrence of a power failure or the like, the power failure signal SK1 is output from the power failure monitoring circuit 542 to the NMI terminal of the CPU 501 in the main controller 261. Then, the CPU 501 interrupts the control being executed and starts the NMI interrupt process. In step S401, the CPU 501 stores the power interruption occurrence information in the backup area 503a of the RAM 503 as the setting of the power interruption occurrence information, and performs the NMI interruption process. finish.

  The above NMI interrupt processing is executed in the same manner in the payout control device 311, and information on occurrence of power interruption is stored in the backup area 513 a of the RAM 513 by the NMI interrupt. That is, when the power of the pachinko machine 10 is cut off due to the occurrence of a power failure or the like, the power failure signal SK1 is output from the power failure monitoring circuit 542 to the NMI terminal of the CPU 511 in the payout control device 311 and the CPU 511 interrupts the control being executed. The NMI interrupt process of FIG. 17 is started. The contents are as described above.

  Next, the flow of the main process executed by the CPU 501 in the main controller 261 will be described with reference to the flowchart of FIG. This main process is started upon reset when power is turned on.

  First, in step S101, an initial setting process associated with power-on is executed. Specifically, for example, 1 is set in order to set a predetermined value in the stack pointer and wait for the sub-side control device (sub-control device 262, payout control device 311, etc.) to become operable. Wait processing is performed for about 2 seconds. In the subsequent step S102, RAM access is permitted.

  Thereafter, data backup processing is executed for the RAM 503 in the CPU 501. That is, in step S103, it is determined whether or not the RAM erase switch 323 provided in the power supply device 313 is pressed (ON), and if it is pressed, the process proceeds to step S112 to clear (erase) the backup data. To do. On the other hand, if the RAM erase switch 323 has not been pressed, it is determined in the subsequent step S104 whether or not occurrence information of power supply interruption is set in the backup area 503a of the RAM 503. Here, if it is not set, no backup data is stored, so in this case as well, the process proceeds to step S112. If power failure occurrence information is set in the backup area 503a, a RAM determination value is calculated in step S105, and in the subsequent step S106, whether or not the RAM determination value matches the RAM determination value stored when the power is turned off. That is, the effectiveness of the backup is determined. If the RAM determination value calculated here does not match the RAM determination value stored when the power is turned off, the backed up data has been destroyed, and in this case, the process also proceeds to step S112.

  In the process of step S112, an initialization command is transmitted in order to initialize the sub control device 262, the payout control device 311 and the like, which are the control devices on the sub side. Thereafter, the process proceeds to RAM initialization processing (step S113 and the like). Note that the RAM determination value is, for example, a checksum value at the work area address of the RAM 503. Instead of the RAM determination value, it is possible to determine the effectiveness of backup based on whether or not the keyword written in a predetermined area of the RAM 503 is correctly stored.

  As described above, the pachinko machine 10 is turned on while pressing the RAM erase switch 323 when it is desired to return to the initial state when the power is turned on, for example, when the hall starts business. Therefore, if the RAM erase switch 323 is ON, the process proceeds to a RAM initialization process (step S113, etc.). Similarly, when the information on occurrence of power interruption is not set, or when a backup abnormality is confirmed by a RAM determination value (checksum value or the like), the process proceeds to initialization processing of the RAM 503 (step S113 or the like). That is, the use area of the RAM 503 is cleared to 0 in step S113, and the initial value of the RAM 503 is set in subsequent step S114. Thereafter, interrupt permission is set in step S111, and the process proceeds to normal processing described later.

  On the other hand, if the RAM erase switch 323 has not been pressed (step S103: NO), it is a condition that the information on occurrence of power interruption is set and the RAM judgment value (checksum value etc.) is normal. In addition, the process at the time of power recovery (process at the time of power failure recovery) is executed. That is, in step S107, the stack pointer before the power interruption is restored, and in step S108, the information on the occurrence of the power interruption is cleared. In step S109, a command for returning the sub-side control device to the gaming state at the time of power-off is transmitted, and in step S110, the used register is returned from the backup area 503a of the RAM 503. Thereafter, interrupt permission is set in step S111, and the process proceeds to normal processing described later.

  Next, the flow of normal processing will be described with reference to the flowchart of FIG. In this normal process, the main process of the game is executed. As its outline, the processing of steps S201 to S210 is executed as a periodic processing with a period of 4 msec, and the counter update processing of steps S211 and S212 is executed with the remaining time.

  First, in step S201, a control signal based on the setting contents of the special display device 43 and the first opportunity corresponding unit 33 updated in the previous process is transmitted to each device, and output data such as a command is transmitted to each sub-side. External output processing that is transmitted to the control device is executed.

  For example, when the decorative symbol display device 42 displays the variation of the decorative symbol, a variation pattern command, a symbol command, or the like is transmitted to the sub-control device 262. That is, the variation pattern command and the symbol command are commands that are output to the sub-control device 262 in order to cause the decorative symbol display device 42 to perform a display effect in accordance with the display performed on the special display device 43. This corresponds to the command information in the form. Therefore, the function of this external output process constitutes the command information output means in this embodiment. On the other hand, the sub-control device 262 that has input the variation pattern command, the symbol command, etc. determines the variation mode of the decorative symbol display device 42 based on the various commands, and displays the variation mode on the decorative symbol display device 42. An instruction is issued to the display control device 45 so as to (variable display).

  For convenience, the variation pattern command and the like will be described here. The variation pattern command includes information for specifying the variation type of the decorative symbol such as normal reach, super reach, and premium reach. In the present embodiment, for example, in the normal mode, any one of “FF10”, “FF11”, “FF12”, “FF13”, “FF14”, “FF15”, and “FF16” is set as the variation pattern command. In the high probability mode, “FD10”, “FD11”, “FD12”, “FD13”, “FD14”, “FD15”, “FD16” are set, and in the time reduction mode, “FE10”, “FE11”. , “FE12”, “FE13”, “FE14”, “FE15”, “FE16” are set. On the other hand, the sub-control device 262 stores the relationship between these variation pattern commands and the variation types of the decorative symbols in a table. Then, the sub control device 262 executes the effect pattern corresponding to the variation pattern command.

  Hereinafter, the variation type of the decorative symbol and the correspondence between the variation type and the variation pattern command will be described.

  Normal reach is a reach pattern that does not display any special effects other than the variation of the decorative design. In the variation pattern command corresponding to the normal reach, “FF11” is set in the normal mode, “FD11” is set in the high probability mode, and “FE11” is set in the time reduction mode. In this embodiment, the variable display time for which the normal reach is derived is set to “20 seconds” in the normal mode, “8 seconds” in the high probability mode, and “10 seconds” in the time reduction mode.

  Super Reach is a reach pattern in which characters and the like are displayed on the decorative symbol display device 42 in addition to the decorative symbol during the variation display of the decorative symbol (after the reach state is established), thereby giving the player a sense of expectation. is there. In this embodiment, three types (super reach SR1, SR2, SR3) of 30 second, 40 second, and 50 second patterns are prepared for the super reach in the normal mode. Note that the variable display time in the high probability mode and in the time reduction mode is shortened compared to that in the normal mode, as in the normal reach. Corresponding to each reach pattern, in the case of the super reach SR1, “FF12” in the normal mode, “FD12” in the high probability mode, and “FE12” in the time reduction mode are set as the variation pattern commands. In the case of the super reach SR2, “FF13” in the normal mode, “FD13” in the high probability mode, and “FE13” in the time reduction mode are set. In the case of the super reach SR3, “FF14” in the normal mode, “FD14” in the high probability mode, and “FE14” in the time reduction mode are set.

  Premium reach is an effect that can be derived only when a big hit state occurs. During the decorative symbol variation display (after reaching the reach state), in addition to the decorative symbol, a character with a different pattern from the super reach is displayed. This is a reach pattern that makes the player have a sense of expectation. In the premium reach of this embodiment, two types (premium reach PR1, PR2) of 60-second and 70-second patterns are prepared in the normal mode. Note that the variable display time in the high probability mode and in the time reduction mode is shortened compared to that in the normal mode, as in the normal reach. Corresponding to each reach pattern, in the premium reach PR1, “FF15” in the normal mode, “FD15” in the high probability mode, and “FE15” in the time reduction mode are set as the variation pattern command. In the premium reach PR2, “FF16” in the normal mode, “FD16” in the high probability mode, and “FE16” in the time reduction mode are set.

  In addition, the fluctuation pattern command corresponding to “complete out” that does not reach any reach state is set to “FF10” in the normal mode, “FD10” in the high probability mode, and “FE10” in the time reduction mode. The In the present embodiment, the variable display time that is completely off is set to 10 seconds in the normal mode. Of course, the variable display time in the high probability mode and the time shortening mode is shortened compared to the normal mode as in the normal reach.

  Further, the sub-control device 262 determines a stop symbol (combination of stop symbols) based on the symbol command, and displays it after the fluctuation time has elapsed. The symbol command is a command for causing the sub-control device 262 to determine a stop symbol, a combination of probability variation symbols, a normal symbol combination, a front / rear off symbol combination, a front / rear off symbol combination, a complete out symbol design combination. Five classifications are designated, which are the combinations. These divisions are indicated by, for example, “A1”, “A2”, “A3”, “A4”, “A5”, and any of these is set as a symbol command. On the other hand, the sub-control device 262 stores the relationship between these commands and stop symbols in a table. Then, the sub control device 262 displays a stop symbol corresponding to the symbol command.

  Hereinafter, the stop symbol classification and the correspondence between the stop symbol and the symbol command will be described.

  The combination of probability variation symbols is a combination of symbols composed of numbers 1, 3, 5, 7, and 9 and “A1” is set in the symbol command corresponding to the combination of probability variation symbols. Then, when “A1” indicating the probability variation symbol is set in the symbol command, the sub-control device 262 is one of the combinations of symbols consisting of the numbers 1, 3, 5, 7, and 9 in the form of a slot. Is determined as a stop symbol.

  The combination of normal symbols is a combination of symbols consisting of numbers 0, 2, 4, 6 and 8, and “A2” is set in the symbol command corresponding to the combination of normal symbols. Then, when “A2” indicating the normal symbol is set in the symbol command, the sub-control device 262 is one of the combinations of symbols consisting of the numbers 0, 2, 4, 6, and 8. Is determined as a stop symbol.

  The combination of back and forth symbols corresponds to the combination of back and forth symbols, where after reaching, the final stop symbol is stopped by one shift before and after the reach symbol. “A3” is set in the symbol command. The combination of symbols other than front / rear detachment corresponds to the “reach other than front / rear detachment” that occurs after reach occurs, and the final stop symbol stops other than before / after the reach symbol. “A4” is set in the command. The combination of complete detachment symbols corresponds to “complete detachment” in which no reach occurs, and “A5” is set in the symbol command corresponding to the combination of complete detachment symbols. As will be described in detail later, when “A3” to “A5” are set in the symbol command, the sub-control device 262 stops the combination of symbols stored in the counter buffer of the corresponding RAM 553. Determine as. In the present embodiment, three commands “A3” to “A5” are prepared for the symbol command for detachment. However, the present invention is not limited to this. For example, a configuration having only one symbol command for detachment may be used.

  Returning to the description of FIG. 15, in step S202, the variation type counters CS1 and CS2 are updated. More specifically, like the other counters, the variation type counters CS1 and CS2 are incremented by 1 and cleared to 0 when the counter values reach the upper limit values (198 and 240 in this embodiment). To do. Then, the update values of the variation type counters CS1 and CS2 are stored in the corresponding buffer area of the RAM 503.

  In the subsequent step S203, the prize ball counting signal received from the payout control device 311 is read. Next, in step S204, the payout abnormality signal received from the payout control device 311 is read.

  Thereafter, in step S205, a first display control process is executed. In this process, the control content of the special display device 43 is set as to what kind of control is performed in the special display device 43, and the jackpot determination and the decorative pattern variation pattern (effect pattern) in the decorative design display device 42 are performed. Settings are made. Details of the first display control process will be described later.

  In step S206, variable winning device control processing is executed. In this process, the control content of the variable winning device 32 is set as to what control is performed in the variable winning device 32. As a result, when the big win state (special game state) is reached, the opening / closing process of the big winning opening of the variable winning device 32 is repeatedly executed for a predetermined number of rounds. Details of the variable winning device control process will be described later.

  In step S207, the second display control process is executed. In this process, the control contents of the normal symbol display device 41 are set as to what kind of control is performed in the normal symbol display device 41. Details of the second display control process will be described later.

  In step S208, an opportunity handling unit control process is executed. In this process, the control content of the first opportunity handling unit 33 is set as to what control is performed in the first opportunity handling unit 33.

  After that, in step S209, it is determined whether or not occurrence information of power interruption is set in the backup area 503a of the RAM 503. Here, if the occurrence information of power interruption is not set in the backup area 503a, it is determined in step S210 whether or not the next normal processing execution timing has been reached, that is, a predetermined time from the start of the previous normal processing (this embodiment) It is determined whether or not 4 msec) has elapsed. And if predetermined time has already passed, it will transfer to Step S201 and will repeat the processing after the above-mentioned Step S201.

  On the other hand, if the predetermined time has not yet elapsed from the start of the previous normal process, the random number initial value counter CINI and the variation type counters CS1 and CS2 are updated within the remaining time until the execution timing of the next normal process. Repeatedly execute (step S211, step S212).

  That is, in step S211, the random number initial value counter CINI is updated. Specifically, the random number initial value counter CINI is incremented by 1 and cleared to 0 when the counter value reaches the maximum value (917 in this example).

  In step S212, the variation type counters CS1 and CS2 are updated (similar to step S202). Specifically, the variation type counters CS1 and CS2 are incremented by 1, and are cleared to 0 when the counter values reach the maximum values (198 and 240 in this example). Then, the change values of the variation type counters CS1 and CS2 are stored in the corresponding buffer area of the RAM 503.

  Here, since the execution time of each process of steps S201 to S209 changes according to the state of the game, the remaining time until the next execution timing of the normal process is not constant and varies. Therefore, it is possible to update the random number initial value counter CINI (that is, the initial value of the big hit random number counter C1) at random by repeatedly executing the update of the random number initial value counter CINI using the remaining time, and similarly change The type counters CS1 and CS2 can also be updated at random.

  Now, if the occurrence information of power interruption is set in the backup area 503a of the RAM 503 (step S209: YES), the power is cut off, so that the processing after step S213 is performed as a power failure process at the time of power interruption. Is called. In the power failure process, first, the generation of each interrupt process is prohibited in step S213, the contents of each register used by the CPU 501 are saved in the stack area in step S214, and the value of the stack pointer is saved in the backup area 503a in step S215. To remember. Thereafter, in step S216, a power-off notification command indicating that the power has been cut off is transmitted to other control devices (such as the payout control device 311). In step S217, a RAM determination value is calculated and stored in the backup area 503a. The RAM determination value is, for example, a checksum value at the work area address of the RAM 503. Thereafter, RAM access is prohibited in step S218, and the infinite loop is continued until the power supply is completely shut down and processing cannot be executed.

  The process of step S209 is performed at the end of a series of processes corresponding to the game state change performed at steps S201 to S208, or at the end of one cycle of the processes of steps S211 and S212 performed within the remaining time. It is executed at the timing. Therefore, in the normal process of the main controller 261, the occurrence information of the power interruption is confirmed at the end of each process, so that the amount of data stored in the backup area 503a of the RAM 503 is less than that in the middle of each process. And can be easily memorized. Further, when returning to the state before power-off, since the amount of data stored in the backup area 503a is small, it can be easily restored and the processing load of the main control device 261 can be reduced. . Further, since the interruption processing is prohibited before the data is stored (step S213), it is possible to prevent the data from being changed when the power is shut off and to reliably store the state before the power is shut off. .

  Next, the first display control process of step S205 will be described with reference to the flowchart of FIG.

  In FIG. 20, in step S801, a jackpot flag, which will be described later, is referred to in detail to determine whether or not the jackpot is currently being hit. During the jackpot, during the jackpot state (special game state) and for a predetermined time after the jackpot state ends (the predetermined time after the jackpot state ends here is a normal game (special display device) after the jackpot state ends (Variable display at 43) is started, and in general, this time zone includes the display of the end of the jackpot state and the mode given after the jackpot on the decorative symbol display device 42) . In addition, a period from when the variable display is stopped and displayed on the special display device 43 and the decorative symbol display device 42 in a mode corresponding to the jackpot until the variable winning device 32 (big winning opening) is opened (generally this period) The time zone is also included in the jackpot for the decorative symbol display device 42 to display the start of the jackpot state).

  In the subsequent step S802, it is determined whether or not the special display device 43 is performing color change display (variable display) by looking at the setting state of the first display flag. Specifically, when the first display flag is set (on state), it is regarded as a variable display, and when the first display flag is released (off state), the variable is displayed. It is considered that the stop display corresponding to the display stop state is in progress. If it is not being a big hit and not being displayed in a variable manner, the process proceeds to step S803, where it is determined whether or not the starting reserved ball number Na is greater than zero. At this time, if it is a big hit or the number of starting reserved balls Na is 0, this processing is terminated as it is. As will be described in detail later, the first display flag is turned on when the variable display of the special display device 43 is started (see step S917), and the variable display of the special display device 43 is stopped and displayed ( In step S809).

  If neither the big hit or the variable display is being displayed and if the number of starting reserved balls Na> 0, the process proceeds to step S804. In step S804, 1 is subtracted from the starting reserved ball number Na. In step S805, processing for shifting the data stored in the first reserved ball storage area is executed. This data shift process is a process for sequentially shifting the data stored in the first to fourth areas on hold in the first holding ball storage area to the execution area side. Data in each area is shifted, such as area → holding first area, holding third area → holding second area, holding fourth area → holding third area.

  Thereafter, in step S806, a variable display setting process is executed. Here, the details of the variable display setting process will be described with reference to the flowchart of FIG.

  First, in step S901, it is determined whether or not a big hit is made based on the value of the big hit random number counter C1 stored in the execution area of the first reserved ball storage area. Specifically, whether or not the jackpot is hit is determined based on the relationship between the value of the jackpot random number counter C1 and the mode at that time. As described above, in the low probability state such as the normal mode, the numbers 0 to 917 of the jackpot random number counter C1. Among them, “147, 341, 533” is a winning value, and “141 to 150, 341 to 350, 531 to 540” are winning values in the high probability mode. If it is determined that the game is a big hit (step S901: YES), the process proceeds to step S902. On the other hand, when it is determined that it is not a big hit (step S901: NO), that is, when it is out of place, the process proceeds to step S909.

  In step S902, it is determined whether or not the probability variation jackpot. In the present embodiment, the system is configured to shift to the high probability mode or the time reduction mode with a probability of 1/2 in the case of a big hit. Specifically, whether or not to shift to the high probability mode is determined based on the value of the mode determination counter C2 stored in the execution area of the first reserved ball storage area. If the value of the stored mode determination counter C2 is an odd number “1, 3, 5, 7, 9” among the numerical values 0 to 9, the transition to the high probability mode is determined (probability large hit), and the even number “ If it is 0, 2, 4, 6, 8 ", the transition to the time reduction mode is determined (usually a big hit).

  Here, when it is determined that the probability variation jackpot (step S902: YES), the jackpot variation pattern is determined in step S904, and the probability variation symbol (“A1” in the present embodiment) is set to the symbol command in step S905. Then, the process proceeds to step S917.

  On the other hand, if it is determined in step S902 that it is not a probable big hit (step S902: NO), that is, if it is a normal big hit, a big hit variation pattern is determined in step S907, and a normal symbol (this embodiment) is determined in step S908. Then, “A2”) is set as the symbol command, and the process proceeds to step S917.

  In steps S904 and S907, the variation pattern at the time of the big hit is determined, and the variation pattern is set in the variation pattern command. At this time, the values of the variation type counters CS1 and CS2 stored in the counter buffer of the RAM 503 are checked, and the symbol variation mode of the decorative symbol is determined based on the values of the first and second variation type counters CS1 and CS2. . The relationship between the numerical value of the first variation type counter CS1 and the reach pattern (variation type) and the relationship between the numerical value of the second variation type counter CS2 and the variation time are defined in advance by a table or the like for each game mode. . Note that the mode determination in the present embodiment is performed by a combination of an on / off state of a high probability state flag, a time shortening state flag, and a high entry state flag, which will be described later. For example, if the high probability state flag, the time shortening state flag, and the high pitched state flag are all on (flag value “1”), it is determined that the mode is a high probability mode.

  Here, the correspondence between the numerical values of the first variation type counter CS1 and the second variation type counter CS2 and the variation type will be described. For example, at the big hit time during the normal mode, the correspondence is defined by the normal mode big hit table as shown in FIG. That is, when CS1 = 0 to 9, “FF11” (normal reach) is set in the variation pattern command regardless of the value of CS2. When CS1 = 10 to 196 and CS2 = 0 to 69, “FF12” (super reach SR1) is set in the variation pattern command. When CS1 = 10 to 196 and CS2 = 70 to 149, “FF13” (super reach SR2) is set in the variation pattern command. When CS1 = 10 to 196 and CS2 = 150 to 240, “FF14” (super reach SR3) is set in the variation pattern command. When CS1 = 197, 198 and CS2 = 0-120, “FF15” (premium reach PR1) is set in the variation pattern command. When CS1 = 197, 198 and CS2 = 121-240, “FF16” (premium reach PR2) is set in the variation pattern command.

  The symbol commands in step S905 and step S908 indicate the jackpot symbol in a predetermined section, and the sub controller 262 determines the stop symbol as will be described later. Specifically, when “A1” indicating the combination of probability variation symbols is set in the symbol command (step S905), the symbol combination of any one of the first, third, fifth, seventh, and ninth slots is sub-selected. The control device 262 determines the stop symbol. On the other hand, when “A2” indicating the combination of normal symbols is set in the symbol command (step S908), any combination of symbols 0, 2, 4, 6, and 8 is changed to the sub-control device 262. Is determined as a stop symbol. After the symbol command is set in step S905 and step S908, the process proceeds to step S917.

  In step S909, which is shifted when a negative determination is made in step S901, it is determined whether or not a reach is reached. This determination is made based on the value of the variation selection counter C3 stored in the execution area of the first reserved ball storage area. As described above, in the present embodiment, the fluctuation selection counter C3 causes the final stop symbol after the occurrence of reach to stop by shifting by one by one before and after the reach symbol, and the final stop after the occurrence of reach. “Reach other than front / rear detachment” where the symbol stops other than before and after the reach symbol and “completely disengagement” where reach does not occur are selected by lottery. For example, C3 = 0, 1 corresponds to front / rear outreach and C3 = 2 to 21 correspond to reach other than front / rear disengagement, and C3 = 22 to 238 corresponds to complete disengagement. Here, when it is determined that it is reach (step S909: YES), the process proceeds to step S910. On the other hand, if it is determined that it is not reach (step S909: NO), that is, if it is “completely out”, a dislocation variation pattern is determined in step S915, and a complete out symbol is set as a symbol command in step S916. Then, the process proceeds to step S917.

  In step S910, it is determined whether or not the front / rear reach is reached. If it is determined that the front / rear reach is out of step (step S910: YES), a deviation variation pattern is determined in step S911, the front / rear pattern is set as a symbol command in step S912, and the process proceeds to step S917. . On the other hand, when it is determined that it is not front / rear detachment (step S910: NO), that is, when it is reach other than front / rear detachment, a detachment variation pattern is determined in step S913, and symbols other than front / rear detachment are determined in step S914. The command is set, and the process proceeds to step S917.

  When the outlier variation pattern is determined in steps S911, S913, and S915, the variation pattern is determined based on the values of the variation type counters CS1 and CS2 stored in the counter buffer of the RAM 503. And so on.

  Here, the correspondence between the numerical value of the first variation type counter CS1 and the variation type will be described. For example, at the time of front / rear detachment during the normal mode, the correspondence is defined by a table for front / rear detachment during the normal mode as shown in FIG. That is, when CS1 = 0 to 9, “FF11” (normal reach) is set in the variation pattern command regardless of the value of CS2. When CS1 = 10 to 198 and CS2 = 0 to 90, “FF12” (super reach SR1) is set in the variation pattern command. When CS1 = 10 to 198 and CS2 = 91 to 170, “FF13” (super reach SR2) is set in the variation pattern command. When CS1 = 10 to 198 and CS2 = 171 to 240, “FF14” (super reach SR3) is set in the variation pattern command. At the time of reach other than forward / backward deviation (C3 = 2 to 21), the reach is normal regardless of the values of the variation type counters CS1 and CS2, and “FF11” is set in the variation pattern command. Further, at the time of complete deviation (C3 = 22 to 238), “FF10” is set in the variation pattern command regardless of the values of the variation type counters CS1 and CS2.

  Further, the symbol command in step S912, step S914, and step S916 indicates a predetermined division of the combination of symbols that are out of the same manner as in step S905 and the like. Specifically, when “A3” indicating a combination of front and rear symbols is set as a symbol command (step S912), the sub-control device 262 that has received the symbol command stores it in the front and rear error symbol buffer of the RAM 553. The combination of symbols corresponding to the front / rear out of reach is determined as the stop symbol. When “A4” indicating a combination of symbols other than front / rear detachment is set in the symbol command (step S914), a combination of symbols corresponding to reach other than front / rear detachment stored in the reach symbol buffer other than front / rear detachment of RAM 553 is selected. The sub-control device 262 determines the stop symbol. When “A5” indicating the combination of completely out of symbols is set in the symbol command (step S916), the combination of symbols corresponding to the complete out of the symbol stored in the complete out of symbol buffer of the RAM 553 is sub-control unit 262. Is determined as a stop symbol.

  In step S917, start setting processing is performed to indicate that a condition for performing color change display (variation display) is satisfied in the special display device 43. In the start setting process, the first display flag indicating whether or not the special display device 43 is performing the variable display is turned on, and the first display timer setting process is performed. The first display timer is a means for measuring the variation time (residual time for variation display) in the special display device 43, and is considered when determining whether or not a predetermined time has elapsed since the beginning of the variation display. In addition, the value corresponding to the variation pattern of the decorative design selected by the variation type counters CS1 and CS2 is set as the variation display time of the special display device 43 in the present embodiment. Based on the setting of the first display timer, when a control signal for starting color change display (variation display) is output to the special display device 43 in the next external output process of the normal process, Color change display is started in the special display device 43. The special display device 43 is a three-color LED as described above, and changes color to green if the lit color is red, blue if it is green, and red if it is blue. Then, after step S917 ends, the variable display setting process ends.

  Returning to the description of FIG. 20, if step S802 is YES, that is, if the variable display is being performed, the process proceeds to step S807, and the first display timer subtraction process is performed. Each time this process is performed, the value of the first display timer is decremented by 4 msec. For example, when the fluctuation time is 10 seconds (10000 msec), “2500” is set for the first display timer, and 1 is subtracted every 4 msec.

  Subsequently, the process proceeds to step S808, and it is determined whether or not a predetermined fluctuation time has elapsed with reference to the value of the first display timer after the subtraction. At this time, when a predetermined fluctuation time has elapsed, that is, when the value of the first display timer becomes “0”, an affirmative determination is made in step S808.

  If an affirmative determination is made in step S808, the first display flag is canceled (turned off) in step S809, and stop display setting for performing stop display on the special display device 43 is performed in step S810. Then, based on the setting contents of the stop display setting, a control signal for performing stop display is output to the special display device 43 in the next external output process in the normal process. In other words, if it is a promiscuous jackpot with a transition to the high probability mode, the red is stopped (for example, lighted only for a few seconds), and if it is a regular jackpot with a transition to the time reduction mode, the green is stopped and displayed. If it is off, blue is stopped and displayed. Again, the main display is such a stop display by the special display device 43, and the display of the decorative symbols by the decorative symbol display device 42 is only auxiliary.

  In step S811, discrimination information setting processing is performed. More specifically, as shown in FIG. 22, in step S1001, it is determined whether or not the stop display corresponds to a jackpot. Here, when it corresponds to jackpot, it transfers to step S1002 and performs jackpot setting. Specifically, setting processing such as a jackpot flag, a first variable flag, a first variable timer, a round number counter, and a winning counter is performed. And after completion | finish of step S1002, a discrimination | determination information setting process is complete | finished.

  The jackpot flag is state determination information for determining whether or not the jackpot state is a special gaming state, and here, “1” indicating the occurrence of the jackpot state is set as the flag value. The value of the jackpot flag is determined based on the value of the jackpot random number counter C1.

  The first variable flag is discrimination information for discriminating whether or not the variable winning device 32 (large winning opening) is in an open state.

  The first variable timer is a means for measuring the opening time or the like of the variable winning device 32, and is considered when determining whether or not a specified time has elapsed since the start of opening. In this example, “7500” is set as the value for the first variable timer. As a result, the maximum opening time per round (the longest time during which the variable winning device 32 is opened) is 30 seconds.

  The round number counter is discriminating information for discriminating the number of rounds executed during the jackpot state (the number of special prize occurrences, that is, the number of executions of the opening / closing process of the variable winning device 32). “15” shown is set as a value.

  The winning counter is means for counting the number of game balls that have entered the variable winning device 32. In this process, “8” indicating the maximum number of winning balls per round is set as a value. In addition, in the switch reading process (see FIG. 16) of the timer interrupt process, it is determined whether there is a ball entering the variable winning device 32 based on the detection information of the count switch 223, and there is a ball entering the variable winning device 32. When determined, the value of the winning counter is decremented by 1.

  If it is determined in step S1001 that the jackpot does not correspond, that is, it is determined that the game is out of place, the process proceeds to step S1003.

  In step S1003, it is determined whether or not a variation counter is set. The variation counter is a means for measuring the duration of the time-reduced state (how many variations are displayed). As will be described later, “100” is set as the counter value after the end of the normal jackpot.

  If the counter value of the variation counter is “0”, the process is terminated as it is. On the other hand, when the variation counter is set (when the counter value is other than “0”), it is regarded that the time reduction state is being set, and in step S1004, the value of the variation counter is decremented by 1. The process proceeds to step S1005.

  In step S1005, it is determined whether or not the counter value of the variation counter is “0”. That is, it is determined whether or not the current variation display is the 100th variation display after the end of the normal jackpot (after the provision of the time reduction state). Here, if the value of the variation counter is “0”, a process for turning off a high-ball entering state flag, which will be described later, is performed in step S1006, and a process for turning off a time reduction state flag, which will be described later, is performed in step S1007. The process ends.

  On the other hand, if it is determined in step S1005 that the counter value of the variation counter is not “0”, the present process is terminated.

  Returning to the description of FIG. 20, after the discrimination information setting process in step S811, the first display control process is terminated. If the determination in step S808 is negative, in step S812, the color change display setting for continuously performing the color change display (fluctuation display) of the LED of the special display device 43 is performed, and this process is terminated. To do. Based on the setting contents of the color change display setting, a control signal for performing color change display is output to the special display device 43 in the external output process in the next normal process. Specifically, it is set to change the color to green if the current lighting color is red, blue if it is green, and red if it is blue. Thereby, the color change display (variable display) of the LED of the special display device 43 is realized at the timing of the first display control process, that is, every 4 ms.

  Next, the variable winning device control process in step S206 will be described with reference to the flowchart of FIG.

  First, in step S1201, it is determined whether or not the jackpot flag is on. If a negative determination is made here, this processing is terminated as it is.

  When an affirmative determination is made in step S1202, 1 is subtracted from the count value of the first variable timer. In a succeeding step S1203, it is determined whether or not the first variable flag is ON.

  If a positive determination is made in step S1203, that is, if the variable winning device 32 is in the open state, the process proceeds to step S1204, whether or not the count value of the first variable timer is “0”, that is, one round. It is determined whether or not the open time of the winning variable winning device 32 remains.

  If a negative determination is made in step S1204, the process proceeds to step S1205, and whether or not the value of the winning counter is “0”, that is, the number of game balls won to the variable winning device 32 is per round. It is determined whether or not the prescribed number (eight in this example) has been reached. If a negative determination is made in step S1204, that is, if the timing for turning the variable prize-winning device 32 to the closed state (the timing of the end of the round) has not yet arrived, this processing is terminated as it is.

  On the other hand, if an affirmative determination is made in step S1204 or step S1205, the process proceeds to step S1206, and whether or not the counter value of the round number counter is “0”, that is, the number of rounds (the number of times the variable winning device 32 is released). ) Has reached the specified number of times.

  If an affirmative determination is made in step S1206, an end setting process is performed in step S1207, and this process ends. In the end setting process of step S1207, the first variable flag and the jackpot flag are turned off, and the high probability state flag setting process, the time shortening state flag setting process, the high pitching state flag setting process, and the variation counter setting Processing is performed.

  The high probability state flag is state determination information for determining whether or not the game mode is a high probability state. In the high probability state flag setting process, the high probability state flag is stored in the execution area of the first reserved ball storage area. The flag value is switched and set based on the value of the current mode determination counter C2. As a result, when the high probability mode is set after the jackpot ends (probability jackpot), “1” indicating the occurrence of a high probability state is set as the flag value, and the time reduction mode is set (normal jackpot) “0” indicating the occurrence of a low probability state is set as the flag value.

  The time reduction state flag is state determination information for determining whether or not the game mode is a time reduction state. In the time reduction state flag setting process, “1” indicating that a time reduction state is generated is set. Set as a flag value.

  The high entry state flag is state determination information for determining whether or not the game mode is a high entry state, and indicates that the high entry state is generated in the high entry state flag setting process. “1” is set as the flag value.

  The variation counter is a means for measuring the duration of the time-reduced state (how many variations are displayed) as described above. In the variation counter setting process, the high probability state flag setting process and Similarly, the change count counter is switched based on the value of the mode determination counter C2. As a result, when the time reduction mode is set (usually a big hit), “100” corresponding to 100 fluctuation displays is set as the value of the fluctuation counter.

  If a negative determination is made in step S1206, that is, if the number of rounds has not reached the prescribed number, round feed processing is performed in step S1208, and this processing is terminated. In the round feed process, 1 is subtracted from the value of the round number counter. That is, the opening / closing process is repeated until the number of executed rounds reaches a predetermined number of times set in advance. In the round feed process, the first variable flag is turned off, and the time (wait time) until the next round is started is set for the first variable timer.

  If a negative determination is made in step S1203, that is, if the wait period between rounds is in progress, the process proceeds to step S1209 to determine whether or not the value of the first variable timer is “0”. .

  If an affirmative determination is made in step S1209, that is, if the wait period ends and the timing for starting the next round is reached, a round start process is performed in step S1210. In the round start process, the first variable flag is turned on, the opening time (“7500” in this example) of the variable winning device 32 per round is set for the first variable timer, and the winning counter is set. The maximum number of winnings per round (in this example, “8”) is set. If a negative determination is made in step S1209, or if the round start process is completed in step S1210, this process ends.

  Various control signals are output to the variable winning device 32 in the next external output process of the normal process based on the ON / OFF state of the first variable flag. When the first variable flag is ON, a control signal for opening the big prize opening is output to the variable winning device 32, and the variable winning device 32 is opened. On the other hand, when the first variable flag is OFF, a control signal for closing the big prize opening is output to the variable winning device 32, and the variable winning device 32 is closed.

  Next, the second display control process of step S207 will be described with reference to the flowchart of FIG.

  In FIG. 25, in step S2101, the normal symbol display device 41 is in a switching display (variable display) while looking at the setting state of the second display flag indicating whether or not the variable symbol display device 41 is performing a variable display. It is determined whether or not there is. Specifically, when the second display flag is on, it is considered that the normal symbol display device 41 is performing variable display, and when the second display flag is off, the normal symbol display device 41 varies. It is considered that the stop display corresponding to the display stop state is in progress.

  If a negative determination is made in step S2101, the process proceeds to step S2102, and it is determined whether or not the number of retained balls Nb is greater than zero. At this time, if the number of reserved balls Nb is 0, this processing is terminated as it is.

  On the other hand, if the variable display is not being performed and the number of held balls Nb> 0, the process proceeds to step S2103. In step S2103, 1 is subtracted from the number of reserved balls Nb. In step S2104, a process for shifting the data stored in the second reserved ball storage area is executed. This data shift process is a process for sequentially shifting the data stored in the holding first to fourth areas of the second holding ball storage area to the execution area side. The holding first area → the execution area, the holding second Data in each area is shifted, such as area → holding first area, holding third area → holding second area, holding fourth area → holding third area.

  Thereafter, in step S2105, start setting processing is executed. In this process, the normal symbol display device 41 performs a process indicating that a condition for performing switching display (variable display) is established. Specifically, the second display timer flag is turned on, and the second display timer setting process is performed. The second display timer is a means for measuring the fluctuation time (residual time) of the fluctuation display performed by the normal symbol display device 41, and is used when determining whether or not a predetermined time has elapsed since the start of the fluctuation display. Is done. In the present embodiment, in the normal mode, since the variation time of the variation display performed by the normal symbol display device 41 is 0.4 seconds, “100” is set in the second display timer. Based on the setting in the start setting process, when a control signal for starting the switching display (variation display) is output to the normal symbol display device 41 in the next external output process of the normal process, the normal symbol display is performed. Switching display is started in the device 41. As described above, the normal symbol display device 41 is configured to light up and display “O” or “X” as an ordinary symbol. If the displayed symbol is “O”, “X”, “X” "Is switched to" ○ ". Then, after step S2105 ends, the second display control process ends.

  If the determination in step S2101 is affirmative, that is, if the normal symbol display device 41 is performing variable display, the process proceeds to step S2106 to perform a second display timer subtraction process. Each time this process is performed, the count value of the second display timer is decremented by one.

  In step S2107, it is determined whether or not the count value of the second display timer is “0”, that is, whether or not the variation time has elapsed. If an affirmative determination is made in step S2107, the second display flag is turned off in step S2108, and normal symbol stop display setting for performing stop display on the normal symbol display device 41 is performed in step S2109. Then, based on the setting contents of the normal symbol stop display setting, a control signal to stop display is output to the normal symbol display device 41 in the next external output processing in the normal processing. That is, in the case of winning, the “◯” symbol (winning symbol) is stopped (for example, lit only for a few seconds), and in the case of being off, the “x” symbol is stopped.

  As described above, it is determined whether or not the winning is made based on the value of the normal symbol random number counter C4 stored in the execution area of the second reserved ball storage area. Specifically, “5-153” is the winning value among the numerical values 0-250 of the normal symbol random number counter C4.

  Subsequently, the process proceeds to step S2110, a normal symbol discrimination information setting process is performed, and this process ends. In this process, when the stop display corresponds to winning, a setting process for performing the opening / closing process of the first opportunity handling unit 33 is performed. Specifically, the second variable flag is turned on, and the release time is set in the second variable timer.

  The second variable flag is determination information for determining whether or not the first opportunity handling unit 33 is in an open state.

  The second variable timer is a means for measuring the opening time (residual time) of the first opportunity handling unit 33, and is considered when determining whether or not a specified time has elapsed from the start of opening. In the present embodiment, the opening time of the first opportunity corresponding unit 33 is different between the high pitching state and the low pitching state. In the high pitching state, “1000” is set for the second variable timer. In the low entry state, “100” is set for the second variable timer.

  On the other hand, if a negative determination is made in step S2107, in step S2111 a switching display setting for continuously performing the switching display (variable display) of the normal symbol display device 41 is performed, and this process is terminated. Based on the setting contents of the switching display setting, a control signal for performing switching display is output to the normal symbol display device 41 in the external output processing in the next normal processing. Specifically, if the current lighting is “◯”, “×” is displayed, and if “×”, the display is switched to “◯”. Thereby, the switching display (variable display) of the normal symbol display device 41 is realized at the timing of the second display control process, that is, every 4 ms.

  Next, the opportunity handling unit control processing in step S208 will be described with reference to the flowchart in FIG.

  First, in step S2201, it is determined whether or not a second variable flag indicating whether or not the first opportunity handling unit 33 is in an open state is on. Here, when it is determined that the second variable flag is not on (the first opportunity handling unit 33 is in the closed state), the present process is terminated.

  On the other hand, if an affirmative determination is made in step S2201, that is, if the second variable flag is on, the first trigger handling unit 33 is considered to be open, and a second variable timer subtraction process is performed in step S2202. Each time this process is performed, the value of the second variable timer is decremented by one.

  Subsequently, the process proceeds to step S2203, and it is determined whether or not the specified open time has elapsed by taking into account the value of the second variable timer after the subtraction. Here, when the specified opening time has elapsed, that is, when the value of the second variable timer becomes “0”, an affirmative determination is made in step S2203. If a negative determination is made here, this processing is terminated as it is.

  On the other hand, if an affirmative determination is made in step S2203, the process proceeds to step S2204, and after an end setting process is performed in step S2204, this process ends. In the end setting process of step S2204, a process of turning off the second variable flag is performed.

  Various control signals are output to the first opportunity corresponding unit 33 in the next external output process of the normal process based on the ON / OFF state of the second variable flag. When the second variable flag is on, a control signal for opening the opening / closing member 33c is output to the first trigger corresponding unit 33, and the first trigger corresponding unit 33 is opened. On the other hand, when the second variable flag is OFF, a control signal for closing the opening / closing member 33c is output to the first trigger corresponding unit 33, and the first trigger corresponding unit 33 is closed.

  Next, payout control executed by the CPU 511 in the payout control device 311 will be described. For convenience of explanation, the reception interrupt process will be described first with reference to FIG. 27, and then the main process will be described with reference to FIG.

  FIG. 27 is a flowchart showing a reception interrupt process executed by the payout control device 311. The reception interrupt process is a process executed by interruption when the payout control device 311 receives a command transmitted from the main control device 261. When the payout control device 311 confirms that the command transmitted from the main control device 261 has been received, the other processing executed by the CPU 511 in the payout control device 311 is temporarily waited, and the reception interrupt process is executed. When the reception interrupt process is executed, the command transmitted from the main control device 261 in step S3001 is first stored in the command buffer of the RAM 513, and the command transmitted from the main control device 261 is stored in step S3002. Turns on the command reception flag and ends this reception interrupt processing. As described above, when a command is stored in the command buffer, the storage pointer is referred to and stored in a predetermined storage area, and the storage pointer is stored in order to store the next received command in the next storage area. Is updated.

  In the present embodiment, the reception process of the command transmitted from the main control device 261 is performed by the interrupt process executed when the command is received. For example, as illustrated in FIG. In the timer interrupt process, before the command determination process (step S3201) is performed, it is confirmed whether or not a command is received. If a command is received, the command is stored in the command buffer of the RAM 513. The command reception flag may be turned on, and if no command is received, the process may proceed to command determination processing. In such a case, it is confirmed whether or not a command has been received by confirming a port corresponding to the command input of the input / output port at predetermined intervals.

  Next, main processing of the payout control device 311 will be described with reference to FIG. FIG. 28 is a flowchart showing the main process of the payout control device 311. This main process is started upon reset when the power is turned on.

  First, in step S3101, an initial setting process associated with power-on is executed. Specifically, a predetermined value set in advance is set in the stack pointer, and an interrupt mode is set. In step S3103, the RAM access is permitted, and in step S3104, an external interrupt vector is set.

  Thereafter, in step S3106, it is determined whether or not occurrence information of power interruption is set in the backup area 513a of the RAM 513. If the information on occurrence of power interruption is set in the backup area 513a, a RAM determination value is calculated in step S3107, and in step S3108, whether the RAM determination value matches the RAM determination value stored when the power is turned off. No, that is, the validity of the backup is determined. The RAM determination value is, for example, a checksum value at a work area address in the RAM 513. Note that it is possible to determine the validity of the backup based on whether or not the keywords written in a predetermined area of the RAM 513 are correctly stored.

  If no power-off occurrence information is set in step S3106, or if a backup abnormality is confirmed by a RAM determination value (checksum value or the like) in step S3108, the process proceeds to initialization processing of the RAM 513 after step S3115. Transition.

  In step S3115, the entire area of the RAM 513 is cleared to 0, and in step S3116, the initial value of the RAM 513 is set. Thereafter, in step S3117, the CPU peripheral device is initialized, and the process proceeds to step S3114 to permit interruption.

  On the other hand, on the condition that the power failure occurrence information is set in step S3106 and the RAM judgment value (checksum value etc.) is normal in step S3108, the process at the time of power recovery (at the time of power failure recovery) Process). That is, in step S3109, the stack pointer before power-off is restored, power-off occurrence information is cleared in step S3110, and a payout permission flag that permits payout of prize balls is cleared in step S3111. In step S3112, the CPU peripheral device is initialized. In step S3113, the used register is restored from the backup area 513a of the RAM 513. In step S3114, an interrupt is permitted.

  After the interruption is permitted in step S3114, it is determined in the process of step S3122 whether power-off occurrence information is set in the backup area 513a. Here, if the information on occurrence of power supply interruption is set, the power supply is cut off. Therefore, the processing after step S3123 is performed as a power failure process at the time of power supply interruption. In the power failure process, first, the generation of each interrupt process is prohibited in step S3123, and a command determination process described later is executed in the next step S3124. Thereafter, the contents of each register used by the CPU 511 are saved in the stack area in step S3125, the stack pointer value is stored in the backup area 513a in step S3126, and the RAM determination value is calculated in step S3127 to calculate the backup area 513a. In step S3128, RAM access is prohibited, and the infinite loop is continued until the power supply is completely shut down and processing cannot be executed. Here, the RAM determination value is, for example, a checksum value in the stack area and work area to be backed up in the RAM 513.

  Note that since the process of step S3122 confirms the occurrence information of the power-off after the process performed at the time of turning on the power, the amount of data stored in the backup area 513a of the RAM 513 is smaller than that in the middle of each process. Less and can be easily memorized. Further, when returning to the state before power-off, since the amount of data stored in the backup area 513a is small, it can be easily restored and the processing load of the payout control device 311 can be reduced. .

  Next, timer interrupt processing of the payout control device 311 will be described with reference to the flowchart of FIG. This timer interrupt process is started periodically (in this embodiment, at a cycle of 2 msec).

  In the timer interrupt process, first, a command from the main control device 261 is acquired, and a determination process for the command is performed (step S3201). This command determination process will be described below with reference to FIG.

  FIG. 30 is a flowchart showing command determination processing performed by the payout control device 311. In the command determination process (steps S3124 and S3201), first, it is determined whether or not the command reception flag is turned on in step S3301. The command reception flag is turned on when a command transmitted from the main controller 261 is received in the above-described reception interrupt process (see FIG. 27).

  If it is determined in step S3301 that the command reception flag is OFF, a new command has not been received from the main control device 261, and thus this process is terminated. On the other hand, if it is determined in step S3301 that the command reception flag is on, the received command is read from the RAM 513 in step S3302, and the command reception flag is turned off in step S3303. By turning off the command reception flag in step S3303, the processing in steps S3302 to S3311 can be skipped until a new command is received, so that the control of the payout control device 311 can be reduced.

  The type of command read from the RAM 513 is determined in the processing of step S3304 to step S3306. In step S3304, it is determined whether or not the command transmitted from the main control device 261 is a payout initialization command. In step S3305, it is determined whether or not it is a payout return command. In step S3306, it is determined whether the command is a prize ball command. It is determined whether or not.

  If the command transmitted from the main controller 261 is a payout initialization command, it is determined in step S3307 whether or not the payout permission flag has already been turned on. If the payout permission flag has been turned off, the main power is turned on. Since the initialization of the RAM 513 is instructed from the control device 261, the work area (area) other than the stack area of the RAM 513 is cleared to 0 in step S3308, and the initial value of the RAM 513 is set in step S3309. Thereafter, in step S3311, the payout permission flag is turned on, and the payout permission for the winning ball is set.

  As described above, the main controller 261 performs initialization processing of the RAM 503 after transmitting the payout initialization command, and the payout control device 311 initializes processing of the RAM 513 after receiving the payout initialization command. Therefore, the timing at which the RAM 503 is initialized and the timing at which the RAM 513 is initialized are substantially at the same time. Therefore, even if the payout control device 311 receives a command transmitted from the main control device 261 due to a shift in the initialization timing, the RAM 513 is initialized, and control corresponding to the received command cannot be performed. The occurrence of adverse effects can be prevented. In addition, since the payout permission flag is turned on after the RAM 513 is initialized, it is possible to reliably set the payout allowance for prize balls.

  On the other hand, if the payout permission flag has already been turned on in step S3307, the command determination process is terminated without clearing the work area of the RAM 513 and the initialization process of the RAM 513. That is, the processing in step S3307 prohibits initialization of the RAM 513 with the payout permission flag set. The payout initialization command is a command that is transmitted only when the RAM erase switch 323 is turned on when the power is turned on. Therefore, the payout initialization command is not received in a state where the payout permission flag is turned on. It is conceivable that the payout control device 311 has recognized the payout initialization command due to the influence of noise or the like. Therefore, if the work area of the RAM 513 is cleared (step S3308) and the initial value setting of the RAM 513 (step S3309) is executed in a state where the payout permission flag is turned on, the payout is not made when a prize ball remains. Although an adverse effect occurs and causes a loss to the player, since the RAM 513 is prevented from being initialized while the payout permission flag is turned on, it is possible to prevent the player from being lost.

  Further, if the command transmitted from the main control device 261 is a payout return command (step S3304: NO, step S3305: YES), the main control device 261 and the payout control device 311 return to the state before the power cut-off. In order to permit the payout of the prize ball, the payout permission flag is turned on in step S3311. That is, when there is information on occurrence of power interruption and the main control device 261 and the payout control device 311 return to the state before the power interruption, the payout of the prize ball is permitted. When the payout permission flag is turned on in the process of step S3311, the process based on the command stored in the predetermined storage area of the command buffer is completed, so the read pointer is changed to the read pointer corresponding to the next storage area. Updated.

  Further, if the command transmitted from main controller 261 is a prize ball command (step S3305: NO, step S3306: YES), the received prize ball number is added to the total prize ball number and stored in step S3310. In order to permit the payout of prize balls, the payout permission flag is turned on in step S3311. At this time, the payout control device 311 sequentially reads out the prize ball commands stored in the command buffer (ring buffer), and adds the number of prize balls corresponding to the command to the total number of prize balls stored in a predetermined buffer area. And remember. Since a prize ball corresponding to the number of prize balls is paid out based on the prize ball command transmitted from the main controller 261, the prize ball command is a payout instruction command for instructing the prize ball to be paid out. . In addition, when a winning ball command is received, the payout permission is immediately set, so that the winning ball can be paid out early for winning. When the payout permission flag is turned on in the process of step S3311, the process based on the command stored in the predetermined storage area of the command buffer is completed, so the read pointer is changed to the read pointer corresponding to the next storage area. Updated.

  Note that the command transmitted from the main controller 261 is not a payout initialization command (step S3304: NO), is not a payout return command (step S3305: NO), and is not a prize ball command (step S3306: NO), The command determination process is terminated without turning on the payout permission flag.

  Returning to the flowchart of FIG. When the command determination process ends, it is determined in step S3202 whether or not the payout permission flag is turned on in the command determination process. Here, if the payout permission flag is not turned on, this processing is ended as it is. That is, it is possible to prevent award balls from being paid out before a command is transmitted from the main controller 261.

  On the other hand, if an affirmative determination is made in step S3202, the launch permission is set for the launch control device 312 in step S3203, the state return switch 321 is checked in step S3204, and the state return operation is determined to be started. Perform a return operation. With this process, when the state return switch 321 is pressed when a payout error occurs, for example, when the payout motor is clogged, the payout motor is rotated forward and reverse to eliminate the ball clogging (return to the normal state). .

  Thereafter, in step S3205, setting of the lower plate full state or the lower plate full state is performed according to the change in the state of the lower plate 15. That is, when the lower pan 15 is detected based on the detection signal of the lower pan full switch, when the lower pan is full, the lower pan full state is set, and when the lower pan full is not reached , Set the lower pan full release state. In step S3206, setting of a tank ball absence state (out of ball state) or a tank ball absence release state (ball state) is executed in accordance with a change in the state of the tank ball. In other words, the tank ball no switch state is determined based on the detection signal of the tank ball no switch, and the special setting for the absence of the tank ball and the setting for the no tank ball state are executed. Perform configuration.

  Thereafter, in step S3207, for example, the presence / absence of a state to be notified, such as an error state, is determined. If there is a state to be notified, a notification is made.

  Subsequently, a payout control process for prize balls and rental balls is executed. Specifically, a payout number setting process is performed in step S3208, a motor control state acquisition process is performed in step S3209, and a motor drive process is performed in step S3210.

  In step S3211, the state return switch 321 is checked to execute the ball removal process by driving the payout motor 358a on the condition that the ball removal disabled state is not set and the ball removal operation is not started. In a succeeding step S3212, the control of the vibrator 360 (vibration motor control) is executed on condition that the ball is clogged. Thereafter, the process returns to the beginning of the timer interrupt process.

  Next, normal processing of the sub-control device 262 will be described with reference to FIG. First, in step S3901, the port corresponding to the command input of the input / output port 554 is confirmed, and it is determined whether or not the command transmitted from the main controller 261 is received.

  If a command has been received, the command is stored in the command buffer of the RAM 553 in step S3902. The command buffer of the RAM 553 is a ring buffer that temporarily stores commands transmitted from the main control device 261. The ring buffer has a predetermined storage area, and commands are stored with regularity from the beginning to the end of the storage area. When commands are stored in all storage areas, the ring buffer is at the start of the storage area. The return command is configured to be updated. Therefore, when the command is stored and when the command is read, the storage pointer and the read pointer in the command buffer are updated, and the command is stored and read based on each pointer.

  In the present embodiment, when information indicating that the jackpot is stored in the command buffer of the RAM 553 in step S3902, the button effect random number counter for determining whether or not to rotate the motor 405 of the effect button 125 is determined. Process to get the value. Note that it is not always necessary to transmit information indicating that the jackpot is from the main control device 261 to the sub-control device 262. For example, when the main control device 261 starts a variable display that teaches the grant of the jackpot state, The configuration may be such that information indicating that the process of obtaining the value of the button effect random number counter is performed is transmitted to the sub-control device 262.

  The button effect random number counter is configured, for example, as a loop counter that is incremented one by one within a range of 0 to 99, for example, and reaches the upper limit value (that is, 99) and then returns to 0 that is the lower limit value. The button effect random number counter is periodically updated (for example, the process of updating the button effect random number counter is performed after the counter update process in step S3904 described later), and the value of the button effect random number counter is stored in the counter buffer. The Then, as described above, when the information indicating that the jackpot is stored in the command buffer of the RAM 553, the value of the button effect random number counter stored in the counter buffer is acquired. There are 10 random numbers that will cause the motor 405 to rotate, and the range is “1-10”.

  In step S3902, if the acquired value of the button random number counter is one of the values ("1" to "10" in this example) that causes the motor 405 to rotate, the motor 405 is displayed during the change display. Is turned on, and a button effect timer for measuring the timing of rotating the motor 405 is set. In this embodiment, when the value of any one of the button effect random number counters “1” to “10” is acquired, the motor 405 rotates after the variable display is performed for a predetermined time on the decorative symbol display device 42. The motor 405 is started together with the stop display of the fluctuation display, and a value corresponding to the time from the start of the fluctuation display to the rotation of the motor 405 is set in the button effect timer. .

  After step S3902 or when a negative determination is made in step S3901, the process proceeds to step S3903, whether or not the execution timing of the next normal process has been reached, that is, a predetermined time from the start of the previous normal process (in this embodiment, It is determined whether or not 1 msec) has elapsed. If the predetermined time has already elapsed, the process proceeds to step S3904. On the other hand, if the predetermined time has not yet elapsed since the start of the previous normal process, the process proceeds to step S3910.

  In step S3904, various counter update processes are executed. The CPU 551 of the sub-control device 262 uses various counter information when displaying decorative symbols. Specifically, as shown in FIG. 32, the upper, middle, and lower symbols used for setting the off-set symbols of the big symbol decoration symbol counter C5, the upper symbol display area, the middle symbol display area, and the lower symbol display area. Each off symbol counter CL, CM, CR is used. The off symbol counters CL, CM, CR are configured such that register values are added using an R register (refresh register) in the CPU 551, and as a result, the numerical values change randomly.

  The jackpot decorative symbol counter C5 determines the symbol when the variation of the decorative symbol display device 42 stops when the jackpot is hit (the jackpot symbol). In the present embodiment, the decorative symbol display device 42 determines the decorative symbol. There are 5 patterns and 5 normal symbols. Accordingly, five (0 to 4) counter values are prepared as the big hit decoration symbol counter C5. That is, the jackpot decoration symbol counter C5 is incremented by 1 in order within the range of 0 to 4, and reaches 0 to the upper limit value (that is, 4). When the symbol command transmitted from the main control device 261 is “A1” indicating a combination of probability variation symbols, for example, based on a table (a table that associates counter values with decorative symbols), the counter value is If it is 0, it is “1”. ) If it is 4, the combination of probability variation symbols is determined in such a manner as “9” (the flat eye). When the symbol command is “A2” indicating a combination of normal symbols, for example, if the counter value is 0, “0” (based on a table (not shown) that associates the counter value with the decorative symbol) ( 1) “2” (for the doublet), 2 for “4” (for the doublet), 3 for “6” (for the doublet), 4 for “8” ”(The doublet) and the normal symbol combination is determined. The jackpot decorative symbol counter C5 is periodically updated in the counter update process in step S3902, and is read from the counter buffer of the RAM 553 at the timing when the sub-control device 262 receives the symbol command as will be described later. In this embodiment, the jackpot decorative symbol counter C5 is stored in the jackpot decorative symbol counter buffer of the RAM 553, but is not stored in the buffer, and the counter value is referred to at the timing of receiving the symbol command. It may be.

  The upper, middle, and lower off symbol counters CL, CM, and CR determine the stop symbols (combinations of off symbols) in the upper, middle, and lower symbol display areas when the big hit lottery is missed. Yes, each of the 10 decorative symbols is displayed in each column, so 10 counter values (0 to 9) are prepared for each. The stop symbol in the upper symbol display area is determined by the up / down symbol counter CL, the stop symbol in the middle symbol display area is determined by the middle / off symbol counter CM, and the stop symbol in the lower symbol display area is determined by the bottom / off symbol counter CR. Is determined.

  In the present embodiment, the values of the counters CL, CM, and CR are randomly updated by using the value of the R register built in the CPU 551. That is, when each outlier symbol counter CL, CM, CR is updated, the value of the lower 3 bits of the R register is added to the previous value, and when the addition result exceeds the upper limit value, 10 is subtracted to determine the current value. The Each outlier symbol counter CL, CM, CR is updated so that the update times do not overlap, and the combination of these outlier symbol counters CL, CM, CR is the front / rear outreach symbol buffer of RAM 553, the reach symbol buffer other than front / rear out, and It is stored in one of the completely off symbol buffers.

  Here, the update process of each off symbol counter CL, CM, CR will be described in detail. As shown in FIG. 33, in step S4001, it is determined whether or not it is time to update the up / down symbol counter CL. In step S4002, it is determined whether or not it is time to update the center / out symbol symbol CM. The upper, middle, and lower outlier counters CL, CM, and CR are configured to be sequentially updated one by one in one update process. Therefore, if the down / out symbol counter CR has been updated in the previous update process, an affirmative determination is made in step S4001. If the up / down symbol counter CL has been updated in the previous update process, an affirmative determination is made in step S4002. If it is time to update the up / down symbol counter CL (YES in step S4001), the flow advances to step S4003 to update the up / down symbol counter CL. If it is the time to update the middle / outgoing symbol counter CM (YES in step S4002), the process proceeds to step S4004 to update the middle / outlier symbol counter CM. Further, if it is time to update the down / out symbol counter CR (both steps S4001 and S4002 are NO), the process proceeds to step S4005, and the down / out symbol counter CR is updated. In updating the outlier symbol counters CL, CM, and CR in steps S4003 to S4005, the lower 3 bits of the R register are added to the previous counter value, and 10 is subtracted when the addition result exceeds the upper limit value. The calculation result is set as the current value of the off symbol counters CL, CM, CR.

  According to the above-described CL, CM, and CR update processing, the up, middle, and lower outlier counters CL, CM, and CR are updated one by one in one update processing, and the update times of the counter values overlap. There is nothing. As a result, every time the update process is executed three times, the set symbol counters CL, CM, and CR are updated for one set.

  Thereafter, in step S4006, the combination of the updated symbol counters CL, CM, CR is a combination of reach symbols (the symbols in the upper symbol display area and the symbols in the lower symbol display area are the same, and the upper and lower symbol display areas And the symbol in the middle symbol display area are different from each other), and in the case of a combination of reach symbols (S4006 is YES), in step S4007, it is a back-and-forth outreach. It is determined whether or not there is. If the out symbol counters CL, CM, CR are a combination of front / rear out of reach (front / rear out symbol) (YES in S4007), the process proceeds to step S4008, and the combination of the out symbol counters CL, CM, CR at that time is stored in the RAM 553. Is stored in the front / rear reach reach symbol buffer. If the out symbol counters CL, CM, CR are a combination of reach other than front / rear disengagement (design other than front / back disengagement) (NO in S4007), the process proceeds to step S4009, and the out symbol counters CL, CM, CR at that time The combination is stored in the reach symbol buffer other than the front and rear deviation of the RAM 553.

  If the combination is other than the reach symbol (NO in S4006), the process proceeds to step S4010 to determine whether or not the combination of the symbol symbols CL, CM, and CR is out of the combination, and the symbol is separated. If it is a combination of symbols (completely deviated symbols) (YES in S4010), the process proceeds to step S4011, and the combination of deviated symbol counters CL, CM, CR at that time is stored in the completely deviated symbol buffer of the RAM 553. If NO in both steps S4006 and S4010, the symbols are aligned at the top, middle, and bottom, that is, it corresponds to a combination of jackpot symbols. In this case, the off symbol counters CL, CM, CR are used as buffers. This process is terminated without storing.

  Returning to the description of FIG. 31, in step S3905, display setting processing is performed. Here, based on the information stored in the command buffer of the RAM 553, various arithmetic processes such as generating a display command to be output to the display control device 45 and command output setting are performed. Accordingly, the display mode to be displayed on the decorative symbol display device 42 is determined here, and a value corresponding to the variation time of the variation pattern command is set in the variation time timer. At this time, the sub-control device 262 performs processing based on a table that associates the variation types of the decorative symbols with the variation pattern commands. In step S3905, the presence / absence of the operation of the effect button 125 is also checked. If the operation of the effect button 125 is confirmed, settings corresponding to the operation are performed. Processing related to the effect button 125 will be described in detail later.

  The display command is, for example, a command for designating a series of display effects from the start to the end of variable display, or a command for designating a display effect during a jackpot, based on information stored in the command buffer. Each time a necessary display command is generated. Usually, the display commands related to the variable display generated by the sub-control device 262 are roughly divided into a normal variable data group, a reach effect data group, and the like. Basically, each data constituting these data groups is the variable time timer. Are sequentially output in accordance with a predetermined time order, thereby providing display effects according to various variation patterns. For example, the normal fluctuation data group includes normal fluctuation data 1, normal fluctuation data 2,..., And normal fluctuation data m, and the reach effect data group includes reach effect data 1, reach effect data 2,. In the case of n, data output is sequentially performed in the order of normal fluctuation data 1 → 2 →... → m with the start of normal fluctuation, and subsequently reach effect data 1 → 2 → with the start of reach effect. ... → Data is sequentially output in the order of n.

  In the display setting process in step S3905, the stop symbol is also determined based on the symbol command. As described above, when “A1” is set in the symbol command, any combination of symbols 1, 3, 5, 7, and 9 is determined as a stop symbol. On the other hand, when “A2” is set in the symbol command, a combination of symbols 0, 2, 4, 6, and 8 is determined as a stop symbol. If “A3” is set in the symbol command, the combination of symbols stored in the front / rear reach symbol buffer (see FIG. 32) of the RAM 553 is determined as a stop symbol. When “A4” is set in the symbol command, the combination of symbols stored in the reach symbol buffer other than front / rear deviation is determined as a stop symbol. When “A5” is set in the symbol command, the combination of symbols stored in the completely off symbol buffer is determined as a stop symbol.

  Note that the display control device 45 performs a drawing process in response to a command from the sub-control device 262, and starts a variable display of symbols on the decorative symbol display device. Once the variation pattern command is received from main controller 261, sub-control is performed until the variation time corresponding to the variation pattern has elapsed (until the variation time timer set in step S3905 becomes 0). Under the cooperation of the device 262 and the display control device 45, the variable display of symbols is continued.

  Here, of the display setting process in step S3905, a process related to the effect button 125 (button setting process) will be described with reference to FIG. The effect button 125 is provided for the purpose of improving the player's interest by reflecting the operation of the player's effect button 125 (operation unit 404) in various effects. In response to the operation of the operation unit 404, control is performed to cause some kind of change, such as changing the display content on the decorative symbol display device 42 or playing the corresponding sound. However, if the production button 125 is operated at any time, some change does not occur, and there is a timing at which no change occurs even if the operation button 125 is operated. In the present embodiment, when any change occurs when the effect button 125 is operated (hereinafter referred to as “button enabled”), and no change occurs even when the effect button 125 (operation unit 404) is operated (hereinafter referred to as the button). The light emission color of the effect button 125 is changed. In addition, the light emission color of the effect button 125 also changes when the effect button 125 is operated when the button is valid. Furthermore, in the present embodiment, as described above, a light hit state in which the light portion visually recognized by the effect button 125 is rotationally displaced is given a big hit state in the special display device 43 and the decorative symbol display device 42. Fluctuation display that teaches that (the special display device 43 is a variable display in which red or green is stopped and the decorative symbol display device 42 is a variable display in which the same symbol is stopped and displayed in each symbol display area) It is the structure derived | led-out in the middle of being performed.

  First, in step S5101, it is determined whether or not the button effect flag is on. If an affirmative determination is made in step S5101, that is, if the motor 405 of the effect button 125 is driven (rotated), it is determined in step S5102 whether or not the value of the button effect timer is “0”. If an affirmative determination is made in step S5102, that is, if it is time to rotate the motor 405, it is determined in step S5103 whether or not the value of the variable display timer is “0”.

  If a negative determination is made in step S5103, that is, if the timing for stopping the variable display on the decorative symbol display device 42 (special display device 43) has not yet arrived, the motor 405 is continued in step S5104. A motor drive process for driving is performed, and this process ends.

  If an affirmative determination is made in step S5103, that is, if it is time to stop the variable display on the decorative symbol display device 42, motor stop processing is performed in step S5105. The drive of the motor 405 is stopped based on the setting performed in the motor stop process. At this time, the motor 405 is not stopped unnecessarily, but based on the detection information of the encoder, the motor 405 is stopped. When the phase of the rotating shaft 461 is shifted from the reference phase, the driving is stopped after the motor 405 is driven until they coincide. After step S5105, the process proceeds to step S5106, the button effect flag is turned off, and the process is terminated.

  If the determination in step S5102 is negative, that is, if the timing for rotating the motor 405 has not yet arrived, the value of the button effect timer is subtracted in step S5107. After step S5107 or when a negative determination is made in step S5101, the process proceeds to step S5108, and after performing the color changing process, the present process is terminated.

  Here, the color changing process in step S5108 will be described with reference to FIG. A button valid flag for determining whether or not the button is valid when the button is valid based on information stored in the command buffer of the RAM 553, a value corresponding to the variation time set in the variation time timer, or the like. When the button is turned on and the period when the button is valid ends (when the button becomes invalid), the button valid flag is turned off.

  In step S5201, the button valid flag is checked to determine whether the button is valid. When an affirmative determination is made in step S5201, the process proceeds to step S5202, and it is determined whether or not the effect button 125 is operated based on the detection information of the operation detection switch 407.

  If an affirmative determination is made in step S5202, it is determined in step S5203 whether or not the motor 405 (upper substrate 402) of the effect button 125 is rotating.

  When a negative determination is made in step S5203, that is, when the operation unit 404 is being operated when the button is valid and the motor 405 is not rotating, the light emitting elements B1 to B3 are turned on in step S5204. Then, after performing the process of turning off the light emitting elements R1 to R3 and G1 to G3, the present process is terminated. Specifically, in step S5204, switching elements (not shown) connected to the main body side terminal portions Q3, Q6, Q7 are turned on, and switching elements (not shown) connected to the main body side terminal portions Q1, Q2, Q4, Q5 are turned on. Turn it off (see FIG. 11). As a result, the light emitting means L1, L2, and L3 emit blue light while still.

  When an affirmative determination is made in step S5203, that is, when the operation unit 404 is being operated when the button is valid and the motor 405 is rotating, in step S5205, the light emitting elements R1, G1, B1 to B1. This process is terminated after performing the process of turning on B3 and turning off the light emitting elements R2, R3, G2, and G3. Specifically, in step S5205, switching elements (not shown) connected to the main body side terminal portions Q1 to Q3, Q6, Q7 are turned on, and switching elements (not shown) connected to the main body side terminal portions Q4, Q5 are turned off. (See FIG. 11). As a result, the light emitting means L1 rotates while changing color, and the light emitting means L2 and L3 rotate while emitting blue light.

  If a negative determination is made in step S5202, that is, if the effect button 125 is not operated, it is determined in step S5206 whether the motor 405 is rotating.

  When a negative determination is made in step S5206, that is, when the operation unit 404 is not operated when the button is valid and the motor 405 is not rotating, the light emitting elements R1 to R3 are turned on in step S5207. Then, after performing the process of turning off the light emitting elements G1 to G3 and B1 to B3, the present process is terminated. Specifically, in step S5207, switching elements (not shown) connected to the main body side terminal portions Q1, Q4, Q7 are turned on, and switching elements (not shown) connected to the main body side terminal portions Q2, Q3, Q5, Q6 are turned on. Turn it off (see FIG. 11). As a result, the light emitting means L1, L2, and L3 emit red light while still.

  When an affirmative determination is made in step S5206, that is, when the operation unit 404 is not operated when the button is valid and the motor 405 is rotating, the light emitting elements R1 to R3, G1,. This process is terminated after performing a process of turning on B1 and turning off the light emitting elements G2, G3, B2, and B3. Specifically, in step S5208, switching elements (not shown) connected to the main body side terminal portions Q1 to Q3, Q4, Q7 are turned on, and switching elements (not shown) connected to the main body side terminal portions Q5, Q6 are turned off. (See FIG. 11). As a result, the light emitting means L1 rotates while changing color, and the light emitting means L2 and L3 rotate while emitting red light.

  If a negative determination is made in step S5201, that is, if the button is invalid, it is determined in step S5209 whether the motor 405 is rotating.

  If a negative determination is made in step S5209, that is, if the motor 405 is not rotating when the button is disabled, processing for turning on the light emitting elements R1 to R3, G1 to G3, and B1 to B3 is performed in step S5210. This process is finished. Specifically, in step S5210, switching elements (not shown) connected to the main body side terminal portions Q1 to Q7 are turned on (see FIG. 11). As a result, the light emitting means L1, L2, and L3 emit white light while still.

  When an affirmative determination is made in step S5209, that is, when the motor 405 is rotating when the button is disabled, the light emitting elements R1 to R3 are turned on in step S5211, and the light emitting elements R2, R3, G2, G3, B2, This process is terminated after the process of turning off B3 is performed. Specifically, in step S5211, switching elements (not shown) connected to the main body side terminal portions Q1 to Q3, Q7 are turned on, and switching elements (not shown) connected to the main body side terminal portions Q4 to Q6 are turned off (step S5211). FIG. 11). As a result, the light emitting means L1 rotates while changing color, and the light emitting means L2 and L3 rotate in a state where the light is turned off.

  When the motor 405 is rotating in the reverse direction (the upper substrate 402 is rotating counterclockwise), all the light emitting units L1 to L3 or the light emitting unit L1 may be turned off.

  In the present embodiment, the effect button 125 is normally in a state in which the movable body 473 is held at the first position below, but when a specific display effect is made on the decorative symbol display device 42. In some cases, the movable body 473 is displaced to the second upper position, and a force required to push down the operation unit 404 of the effect button 125 is larger than that in the normal state. Hereinafter, a process (operation adjustment process) for displacing the movable member 473 in accordance with a display effect performed in the decorative symbol display device 42 (based on the content of the display command set in the display setting process in step S3905) will be described. This will be described with reference to FIG.

  In the present embodiment, as a specific display effect, the treasure box and the character are displayed on the decorative symbol display device 42, and the character inserts his / her hand into the treasure box. If there is a treasure, a display effect such as “big hit” is performed. Furthermore, if the display setting process determines that a display effect such as a character inserting his hand into the treasure box and picking up a treasure in the treasure box is performed, is a specific display effect performed on the decorative symbol display device 42? The operation adjustment flag for determining whether or not is turned on.

  First, in step S5301, it is determined whether or not the operation adjustment flag is on. If a negative determination is made in step S5301, this processing is terminated as it is. On the other hand, if an affirmative determination is made in step S5301, the button valid flag is checked in step S5302, and it is determined whether or not the button is valid. In this example, when the button is activated when the decorative symbol display device 42 displays that the character inserts his / her hand into the treasure box. When the effect button 125 is operated when the button is valid, the character is taken out of the treasure chest from the treasure chest in the decorative symbol display device 42 in the case of “big hit”, and what is in the hand in the case of “out”. A display effect that is not possessed is also performed.

  If a negative determination is made in step S5302, this processing is terminated as it is. On the other hand, if an affirmative determination is made in step S5302, the detection information of the contact detection switch 491 is confirmed in step S5303, and whether or not the movable body 473 is in the second position (the movable terminal portion 492 and the upper terminal). Whether or not the portion 493 is in contact.

  If a negative determination is made in step S5303, in step S5304, the adjustment motor 474 is driven until the movable terminal portion 492 and the lower terminal portion 494 come into contact (the gear 490 is rotated counterclockwise in FIG. 7). A process of displacing the movable body 473 to the second position is performed, and thereafter (after the state shown in FIG. 10), this process is terminated. When the movable body 473 is displaced to the second position, the upper end portion of the coil spring 406b comes into contact (pressure contact) with the top wall portion 433a of the spring accommodating portion 433, and a total of six coil springs 406 (406a, 406a, The operation unit 404 is biased upward by 406b). That is, when the effect button 125 is operated, the operation unit 404 is difficult to be pushed to remind that a treasure is in the treasure box.

  On the other hand, if an affirmative determination is made in step S5303, the process advances to step S5305 to determine whether or not the operation button 125 has been operated based on the detection information of the operation detection switch 407.

  When an affirmative determination is made in step S5305, the operation adjustment flag is turned off in step S5306, and in step S5307, the adjustment motor 474 is driven (the gear 490 is rotated in the clockwise direction in FIG. 10) to move the movable body 473. After returning to the first position (after the state shown in FIG. 7), the present process is terminated. When the movable body 473 is displaced to the first position, the coil spring 406b is separated from the top wall portion 433a of the spring accommodating portion 433, and the operating portion 404 is biased upward only by the three coil springs 406a. State.

  If a negative determination is made in step S5305, it is determined in step S5308 whether or not the value of the variable display timer is “0”, thereby displaying the variable display on the decorative symbol display device 42 (special display device 43). It is determined whether or not it is time to stop display. If a negative determination is made in step S5308, the present process is terminated. If an affirmative determination is made, the process proceeds to step S5306.

  When the operation adjustment flag is in an off state, that is, when the display of inserting a hand into the treasure box is made on the decorative symbol display device 42, the movable body 473 is in the first state. It remains held in position. That is, in the case of “disengagement”, the operation unit 404 is easy to be pushed in to remind that the inside of the treasure box is empty.

  Returning to the description of FIG. 31, in the lamp setting process of step S3906, a lighting pattern of lamps / lights is set in order to synchronize with the display effect performed by the decorative symbol display device 42. In addition, when a command related to lamps such as lighting control of the holding lamps 44 and 46 according to the start holding ball number Na and Nb is transmitted from the main control device 261, settings for performing these controls are also set in step S3906. Done in

  In the sound setting process in step S3907, the output pattern of the speaker 24 is set to synchronize with the display effect performed on the decorative symbol display device 42. In addition, when a voice-related command such as an error notification is transmitted from the main control device 261, settings for performing these controls are also performed in step S3907.

  In step S3908, other processing such as control setting of a waiting-for-waiting effect (for example, a demonstration screen display set to be displayed when a predetermined time elapses without the decorative symbol display device 42 being changed) is performed. Do.

  In step 3909, external output processing for transmitting a control signal based on the setting contents in steps S3904 to 3908 to each device is executed. For example, a display command is transmitted to the display control device 45 when the decorative symbol display device 42 displays the variation of the decorative symbol.

  After the processing of steps S3904 to S3909 performed every 1 msec is performed, or when a negative determination is made in step S3903, the process proceeds to step S3910, and whether or not the information on occurrence of power interruption is stored in the RAM 553 is determined. Is determined. The information on the occurrence of power interruption is stored when a power interruption command is received from the main controller 261.

  If no power off occurrence information is stored, the process advances to step S3911 to determine whether or not the RAM 553 is destroyed. If the RAM 553 is not destroyed here, the process returns to step S3901 and the normal process is repeatedly executed. On the other hand, if the RAM 553 is destroyed, the processing is looped infinitely in order to stop the subsequent processing.

  On the other hand, if it is determined in step S3910 that the information on occurrence of power interruption is stored, power interruption processing is executed in step S3912. In power-off processing, interrupt processing is prohibited and each output port is turned off. Further, the storage of the information on occurrence of power interruption is also erased. After executing the power-off process, the process loops infinitely.

  As described above in detail, according to the present embodiment, the effect button 125 is provided with six coil springs 406 that can urge the operation unit 404 upward, and three of them are provided. As for 406 (406b), the lower end portion thereof is supported by a movable body 473 that is vertically displaced between the first position and the second position. Then, when the movable body 473 is displaced between the first position and the second position, the pressing portion 432 is pressed and pushed downward into the operation portion 404 (the top wall portion 433a of the spring accommodating portion 433). On the other hand, the state is switched between the state in which the coil spring 406b is in pressure contact and the state in which the coil spring 406b is not in contact. That is, when the movable body 473 is displaced, a coil spring that can apply an upward biasing force to the operation unit 404 when the pressing unit 432 is pressed to displace the operation unit 404 downward. The number of 406 increases and decreases, and the magnitude of the force acting on the operation unit 404 when the operation unit 404 is pushed downward changes. Therefore, when the movable body 473 is at the lower first position, the operation unit 404 is easily displaced downward (operation position side). When the movable body 473 is at the upper second position, the movable body 473 is the first position. The magnitude of the force required to displace the operation unit 404 downward is changed, for example, it becomes more difficult to displace the operation unit 404 downward than when the operation unit 404 is in the position. Therefore, it is possible to obtain a novel effect button 125 in which the force required to operate the effect button 125 changes and the feel when the player operates the operation unit 404 changes. Therefore, by installing the effect button 125 in the pachinko machine 10, the effect of the effect can be enhanced and further enhancement of interest for the player can be achieved.

  Further, even if the movable body 473 is displaced, the appearance of the effect button 125 does not change. Therefore, it is impossible to grasp the position of the movable body 473 simply by visually recognizing the appearance of the effect button 125. . For this reason, it is possible to prevent a situation in which the interest in operating the operation unit 404 is diminished due to the fact that the touch when the operation unit 404 is pushed in can be grasped in advance. Can do.

  In addition, regardless of whether the movable body 473 is in the first position or the second position, the operation side 404 can be operated to bring the operation side terminal part 438 and the base side terminal part 439 into contact with each other. Thus, the function as the production button 125 can be maintained. Therefore, for example, although the player has operated the operation unit 404, the operation of the operation unit 404 is not detected by the operation detection switch 407 and should be derived by operating the operation unit 404. It is possible to avoid a situation in which it is impossible to fully enjoy the production.

  Further, in the present embodiment, when the character is searched for in the treasure chest on the decorative symbol display device 42, and then the empty treasure chest is displayed, the movable body 473 is displaced. However, when the character is displayed to take out the treasure from the treasure chest, the movable body 473 is displaced to the second position and the operation unit 404 is pushed. A larger force is required than when the movable body 473 is in the first position. In this manner, the performance can be improved by linking the operation of the effect button 125 and the behavior of the display object displayed on the decorative symbol display device 42. In addition, the movable body 473 is displaced according to the display object (the contents of the treasure box) displayed on the decorative symbol display device 42, and the feel when operating the operation unit 404 is changed according to the display object. On the other hand, the display object (the contents of the treasure chest) displayed on the decorative symbol display device 42 can be made to feel as if it was actually touched. Therefore, as compared with a configuration in which the touch upon operation of the effect button 125 is changed regardless of the display of the decorative symbol display device 42, a dramatic improvement in interest can be achieved.

  Further, according to the present embodiment, the effect button 125 is equipped with the motor 405, and when the motor 405 is driven, the upper substrate 402 to which the light emitting means L1 to L3 are fixed rotates and the light emitting means L1 to L3. Displace itself. Thereby, the light part of the production button 125 visually recognized via the operation part 404 (press part 432) can be displaced. Further, with the displacement of the upper substrate 402, the combination of the light emitting elements R1, G1, B1 that are turned on among the light emitting elements R1, G1, B1 of the light emitting means L1 changes. That is, the emission color of the light emitting means L1 can be changed, and the color of the light portion of the effect button 125 visually recognized via the operation unit 404 can be changed. For this reason, it is possible to obtain an effect button 125 from which a novel aspect is derived in which the color of the effect button 125 visually recognized via the operation unit 404 changes while moving. Therefore, by mounting such a production button 125 on the pachinko machine 10, it is possible to enhance the decoration effect and the production effect, and to further improve the interest for the player.

  Furthermore, since the innovative button as described above is derived in the production button 125 that has been low in decoration and has not been closely watched by the player, the player feels fresh surprise and the production button. You can be interested in 125 itself. As a result, a dramatic improvement in interest can be achieved. Furthermore, it is possible to perform an effect using the form of the effect button 125 (such as suggestion or teaching of various game states), and the possibilities of effects that can be performed with the pachinko machine 10 can be expanded.

  In addition, the effect button 125 is configured such that the operation side terminal portion 438 and the base side terminal portion 439 can be brought into contact with each other by operating the operation unit 404 even when the motor 405 is driven. . For this reason, for example, the operation-side terminal unit 438 and the base-side terminal unit 439 cannot be brought into contact with each other even if the operation unit 404 is operated while the motor 405 is driven. It is possible to avoid a situation in which it becomes impossible to enjoy the effect that should be derived by operating the unit 404. Further, in comparison with a configuration in which the mode of the effect button 125 is merely visually recognized such that the color changes while the light unit moves and the operation unit 404 is displaced, the operation button 125 in this mode can be operated. It can dramatically improve the player's sense of superiority and satisfaction.

  Further, in the present embodiment, an effect button that is visually recognized through the operation unit 404 by displacing the light emitting means L1, L2, and L3 itself by rotating the upper substrate 402 to which the light emitting means L1, L2, and L3 are fixed. The positions of the 125 light portions are displaced. For example, when a plurality of light emitting elements are arranged adjacent to each other so that the light portion of the effect button 125 is displaced (continuously or in an analog manner), the light emitting elements are sequentially turned on / off. There is a concern that the light emitting element is required and the control is complicated. On the other hand, in this embodiment, since the light emitting means L1 to L3 themselves are displaced, a large number of light emitting elements are required to displace the light portion, and lighting control of the effect button 125 is complicated. It is possible to avoid situations such as falling. Furthermore, the movement of the light part such as continuous displacement can be made smoother.

  Further, in the present embodiment, with respect to the light emitting means L1, the combination of the light emitting elements R1, G1, and B1 that are turned on changes as the upper substrate 402 rotates. Specifically, when the upper substrate 402 is rotated, the light emitting side terminal portions P1 to P3 themselves move and come into contact with the corresponding main body side terminal portions Q1 to Q3 or are not in contact with each other. That is, the light emitting side terminal portions P1 to P3 and the main body side terminal portions Q1 to Q3 have a switching function, and the energization states of the light emitting elements R1, G1, and R1 are incidentally switched. Further, with the rotation of the upper substrate 402, the combination of the light emitting side terminal portions P1 to P3 in contact with the corresponding main body side terminal portions Q1 to Q3 among the light emitting side terminal portions P1 to P3 changes. Therefore, it is possible to change the emission color of the light emitting means L1 only by rotating the upper substrate 402. For example, a displacement detecting means for detecting the displacement (phase) of the upper substrate 402 is provided, and detection of the displacement detecting means is performed. The configuration and control can be simplified as compared with the case where the energization states of the light emitting elements R1, G1, and R1 are individually switched and controlled based on the information.

  In addition, for example, in order to displace the light portion of the effect button 125 without displacing the light emitting means, a rotatable reflecting member is provided around the light emitting means so that the light reflected by the reflecting member is visible. In addition to the control for displacing the reflecting member, the control for changing the emission color of the light emitting means is required. On the other hand, in the present embodiment, only by performing the control for rotating the upper substrate 402 (drive control of the motor 405), the light emitting means L1 itself is displaced and the light emission color of the light emitting means L1 is also changed. Simplification can be achieved. In addition, when the light of the light emitting means is reflected by the reflecting member, the light part may become dark or the light part may be blurred, so that the desired light mode cannot be derived. Since it is possible to derive a light mode in which the light portion is displaced by directly viewing the light of the means L1, the above-described problems can be avoided.

  When the light emitting means L1 to L3 (light emitting elements R1 to R3, G1 to G3, B1 to B3) and a predetermined power source are connected by wiring such as a connector cable, the light emitting means is caused by the rotation of the upper substrate 402. There is a possibility that the wiring connected to L1 to L3 is twisted and the rotation of the upper substrate 402 is hindered. For this reason, the rotation of the upper substrate 402 is limited, and it is necessary to reversely rotate the upper substrate 402 at predetermined intervals in order to return the twist. On the other hand, according to the present embodiment, the light emitting side terminal portions P1 to P7 and the main body side terminal portions Q1 to Q7 are brought into contact with each other and are electrically connected. There is nothing. Therefore, the upper substrate 402 can be displaced along a certain direction without hindrance.

  Furthermore, the main body side terminal portions Q1 to Q7 are extended along the track of the light emitting side terminal portions P1 to P7 that are displaced relative to the main body side terminal portions Q1 to Q7 when the upper substrate 402 is displaced. Thereby, the light emitting elements R1 to R3, G1 to G3, and B1 to B3 can be rotationally displaced while being lit while adopting a relatively simple configuration. In addition, the light emitting side terminal portions P1 to P3 and the main body side terminal portions Q1 to Q3 can be brought into a contact state or in a non-contact state relatively easily.

  Moreover, since the upper board | substrate 402 and the lower board | substrate 403 are unitized by the support metal fitting 451, positioning of the light emission side terminal parts P1-P7 and the main body side terminal parts Q1-Q7 can be performed reliably. Therefore, the above-described light mode can be reliably derived.

  In addition, an encoder is mounted on the motor 405 of the effect button 125, and in this embodiment, the phase of the rotating shaft 461 (upper substrate 402) when the motor 405 is not driven indicates the light emitting side terminal portions P1 to P1. P3 is controlled so as to be in a phase in contact with the corresponding main body side terminal portions Q1 to Q3. For this reason, when the motor 405 is not driven, the light emitting means L1 is set in the same manner as the other light emitting means L2 and L3, such as white when the button is disabled, red when the button is enabled, and blue when the effect button 125 is operated. The color can be changed accordingly. Therefore, when the button is disabled and the motor 405 is not driven, the light emitting means L2 and L3 are white, whereas the light emitting means L1 is white, yellow, light blue, or purple. It is possible to prevent a situation in which the correspondence between the emission color of the button 125 and the situation relating to the production button 125 is lost, and to reliably teach the player the situation relating to the production button 125 by the color of the production button 125. Can do.

  In addition, it is not limited to the description content of embodiment mentioned above, For example, you may implement as follows.

  (A) In the above embodiment, among the light emitting means L1 to L3, only the light emitting means L1 is configured to change color with the rotation of the upper substrate 402, but the light emission colors of the other light emitting means L2 and L3 are also included. The color may be changed as the upper substrate 402 rotates. For example, the main body side terminal portions Q4 to Q6 may be provided partially (intermittently) along the trajectory of the light emitting side terminal portions P4 to P6 that are displaced as the upper substrate 402 rotates. Further, when the configuration is adopted, for example, the light emitting means L1 changes to white in the section a in FIG. 8B, purple in the section b, yellow in the section c, and light blue in the section d, but the light emitting means L2 (L3) may be configured to change in color to white in section a, yellow in section b, light blue in section c, and purple in section d. Of course, the light emitting means L2 and the light emitting means L3 may be independently changed in color (in this case, the light emitting side terminal portion and the main body side terminal portion are increased by three).

  Moreover, in the said embodiment, the main body side terminal parts Q1-Q3 are extended in the substantially C shape, and at least two of the main body side terminal parts Q1-Q3 overlap in the centrifugal direction of the lower board | substrate 403. However, it is not particularly limited to such a configuration. For example, each of the main body side terminal portions Q1 to Q3 may be provided intermittently so as to be divided into a plurality in the circumferential direction of the lower substrate 403, or in the centrifugal direction of the lower substrate 403, There may be a section where Q3 does not overlap (a section where only one of the light emitting side terminal portions P1 to P3 contacts the corresponding main body side terminal portions Q1 to Q3), and any main body in the centrifugal direction of the lower substrate 403 There may be a section where the side terminal portions Q1 to Q3 do not exist (a section where the light emitting side terminal portions P1 to P3 and the main body side terminal portions Q1 to Q3 do not contact each other: the light emitting means L1 is always turned off in this section).

  In addition, the number of light emitting means mounted on the upper substrate 402 is not particularly limited, and may be two or less, or four or more. When the number of light emitting means mounted on the upper substrate 402 is increased, the light emitting means is divided into a plurality of sets in order to suppress an increase in the size of the effect button 125, and the light emitting side terminal portion and the main body side terminal are provided for each set. It is desirable to share parts.

  (B) In the said embodiment, although the light emission side terminal parts P1-P7 are each comprised by calling a some copper wire (in wire shape), it is not limited to such a structure in particular. For example, the light emitting side terminal portions P1 to P7 may be configured in a leaf spring shape. Further, when the light emitting side terminal portions P1 to P7 are configured in a leaf spring shape, the light emitting side terminal portions are inclined in a direction opposite to the displacement direction of the light emitting side terminal portions P1 to P7 (the rotation direction of the upper substrate 402). It is desirable to attach the upper substrate 402 and the lower substrate 403 so that the light emitting side terminal portions P1 to P7 and the lower substrate 403 (main body side terminal portions Q1 to Q7) are in contact with each other while bending P1 to P7. In this way, the light emitting side terminal portions P1 to P7 are bent and brought into contact with the main body side terminal portions Q1 to Q7, thereby improving the contact state between the light emitting side terminal portions P1 to P7 and the main body side terminal portions Q1 to Q7. Can keep. Further, by tilting the main body side terminal portions Q1 to Q7 in the direction opposite to the rotation direction of the upper substrate 402, the light emitting side terminal portions P1 to P7 interfere with the lower substrate 403 (main body side terminal portions Q1 to Q7), A situation in which the rotation of the upper substrate 402 is hindered can be prevented.

  Moreover, in the said embodiment, although the light emission side terminal parts P1-P7 are comprised by wire shape, and the main body side terminal parts Q1-Q7 are comprised as a printed wiring (print pattern), light emission side terminal parts P1-P7 are comprised. It is good also as printed wiring, and it is good also considering the main body side terminal parts Q1-Q7 as a wire form.

  (C) Further, in the above embodiment, the light emitting means L2 and L3 and the light emitting means L1 when the upper substrate 402 is not displaced (stationary state) are connected to the main body side terminal portions Q1 to Q6. Although the on / off of the switching element (not shown) is switched to switch the emission color of the light emitting means L1 to L3, it is not particularly limited to such a configuration. For example, the main body side terminal portions Q1 to Q7 are extended so that the light emitting means L1 to L3 can develop a red color phase, a blue color phase, and a white color phase. The light emission color of the means L1 to L3 is red, the light emission color of the light emission means L1 to L3 is blue when the effect button 125 is operated when the button is enabled, and the light emission color of the light emission means L1 to L3 is white when the button is disabled. The motor 405 may be driven based on the detection information of the encoder (the upper substrate 403 is rotated and displaced).

  In the above embodiment, the rotational phase of the upper substrate 402 can be adjusted based on the detection information of the encoder built in the motor 405. For example, a photo sensor that can detect the rotational phase of the upper substrate 402, etc. (For example, a light emitting portion is provided at a predetermined position of the upper substrate 402 and a light receiving portion is provided at a predetermined position of the lower substrate 403), and the rotational phase of the upper substrate 402 is determined based on the detection information of the phase detection sensor. May be adjustable.

  (D) In the above embodiment, the upper substrate 402 is rotated and displaced to switch the light emission color of the light emitting means L1 (lights on / off of the light emitting elements R1, G1, and B1). The light emission color of the light emitting means L1 may be switched by displacing in the front-rear direction or the vertical direction.

  Hereinafter, the example of an aspect shown in FIG. 37 is demonstrated. FIG. 37A is a bottom view showing the upper substrate 402 in the case where the configuration in which the upper substrate 402 is slid left and right is employed, and FIG. 37B is the case in which the configuration in which the upper substrate 402 is slid left and right is employed. 4 is a top view showing a lower substrate 403. FIG. For the sake of convenience, description will be made using basically the same member names and member numbers as in the above embodiment.

  As shown in FIG. 37A, on the lower surface of the upper substrate 402, three light emitting side terminal portions P1 to P3 are provided so as to be arranged in the front-rear direction (upper and lower in the figure). Further, light emitting means (not shown) that is a three-color LED is provided on the upper surface of the upper substrate 402, and the light emitting side terminal portions P1 to P3 are connected to the light emitting elements of the light emitting means. Specifically, the light emitting side terminal part P1 is connected to the anode side of the light emitting element whose emission color is red, and the light emission side terminal part P2 is connected to the anode side of the light emitting element whose emission color is green, P3 is connected to the anode side of the light emitting element whose emission color is blue. In addition, the upper substrate 402 is connected to driving means (not shown) (solenoid, stepping motor, etc.) and can be displaced in the left-right direction by driving of the driving means.

  As shown in FIG. 37 (b), on the upper surface of the lower substrate 403, the main body side connected to the input / output port 554 of the sub-control device 262 at a position where it can contact the corresponding light emitting side terminal portions P1 to P3. Terminal portions Q1 to Q3 are provided. The main body side terminal portions Q1 to Q3 are extended along the displacement direction of the upper substrate 402 that slides left and right. Specifically, with the displacement of the upper substrate 402, the light emission side terminal portions P1 to P3 are displaced within the range of the virtual lines Z1 to Z8 in FIG. It does not extend over the entire range, but extends partially. Although not shown, the upper substrate 402 is provided with a light emitting side terminal portion connected to the cathode side of each light emitting element of the light emitting means, and the lower substrate 403 corresponds to the light emitting side terminal portion. A main body side terminal portion is provided, and the main body side terminal portion extends over the entire range of the virtual lines Z1 to Z8 in FIG.

  Only the main body side terminal portion Q3 extends in the section of the virtual lines Z1 to Z2, and when the light emitting side terminal portions P1 to P3 are in this section, only the light emitting side terminal portion P3 is energized to emit light. The emission color of becomes blue.

  The body side terminal portions Q2 and Q3 extend in the section of the virtual lines Z2 to Z3, and when the light emitting side terminal portions P1 to P3 are in this section, the light emitting side terminal portions P2 and P3 are energized, The emission color of the light emitting means is light blue.

  The main body side terminal portions Q1, Q2, and Q3 extend in the section of the virtual lines Z3 to Z4. When the light emitting side terminal portions P1 to P3 are in this section, the light emitting side terminal portions P1, P2, and P3. Is energized, and the emission color of the light emitting means becomes white.

  The body side terminal portions Q1 and Q2 extend in the section of the virtual lines Z4 to Z5, and when the light emitting side terminal portions P1 to P3 are in this section, the light emitting side terminal portions P1 and P2 are energized, The emission color of the light emitting means is yellow.

  Only the main body side terminal portion Q1 extends in the section of the virtual lines Z5 to Z6, and when the light emitting side terminal portions P1 to P3 are in this section, the light emitting side terminal portion P1 is energized and the light emitting means. The emission color is red.

  In the section of the virtual lines Z6 to Z7, the main body side terminal portions Q1 and Q3 extend. When the light emitting side terminal portions P1 to P3 are in this section, the light emitting side terminal portions P1 and P3 are energized, The emission color of the light emitting means is purple.

  Only the main body side terminal part Q2 extends in the section of the virtual lines Z7 to Z8, and when the light emitting side terminal parts P1 to P3 are in this section, the light emitting side terminal part P2 is energized, and the light emitting means The emission color is green.

  Accordingly, when the upper substrate 402 is slid in the left-right direction based on the driving of the driving unit, the color of the light-emitting unit is changed while sliding left and right.

  Next, the example of an aspect shown in FIG. 38 is demonstrated. FIG. 38 is a schematic cross-sectional view showing a part of the effect button 700 when the configuration in which the upper substrate 402 is slid up and down is employed. It should be noted that the effect button 700 of FIG. 38 has basically the same configuration as the effect button 125 of the above embodiment, although there are changes as described below.

  The light emitting means 702 that is a three-color LED is provided on the upper surface of the substrate 701 of the effect button 700 shown in FIG. 38, and the light emitting means (not shown) of the light emitting means 702 is connected to the outer peripheral surface of the substrate 702. Light emitting side terminal portions P1 to P3 (the light emitting side terminal portion P2 is not shown in the figure) are provided. Specifically, the light emitting side terminal part P1 is connected to the anode side of the light emitting element whose emission color is red, and the light emission side terminal part P2 is connected to the anode side of the light emitting element whose emission color is green, P3 is connected to the anode side of the light emitting element whose emission color is blue. In addition, the substrate 701 is connected to driving means (for example, a solenoid) 705 and can be displaced in the vertical direction by driving of the driving means 705.

  In addition, the body portion 711 of the effect button 700 is provided with a peripheral wall portion 721 so as to surround the outer periphery of the substrate 701. On the inner surface of the peripheral wall portion 721, main body side terminal portions Q1 to Q3 (main body side terminal portions) connected to the input / output ports 554 of the sub-control device 262 at positions where they can contact the corresponding light emitting side terminal portions P1 to P3, respectively. Q2 is not shown). The main body side terminal portions Q1 to Q3 are extended along the displacement direction of the substrate 701 that slides up and down. Specifically, as the substrate 701 is displaced, the light emitting side terminal portions P1 to P3 are displaced within the range of the virtual lines Z1 to Z4 in FIG. 38, but the body side terminal portions Q1 and Q3 are within this range. It does not extend over the whole area, but extends partially. Although not shown, the base 701 is provided with a light emitting side terminal portion connected to the cathode side of each light emitting element of the light emitting means 702, and the peripheral wall portion 721 corresponds to the light emitting side terminal portion. A main body side terminal portion is provided, and the main body side terminal portion extends over the entire range of the virtual lines Z1 to Z4 in FIG. In this example, since the main body side terminal portions Q1 to Q3 are provided on the peripheral wall portion 721, the lower substrate 403 as in the above embodiment does not exist.

  The main body side terminal portions Q1 and Q2 extend in the section of the virtual lines Z1 and Z2, and when the substrate 701 (light emitting side terminal sections P1 to P3) is in this section, the light emitting side terminal sections P1 and P2 are provided. Is energized, and the emission color of the light emitting means 702 becomes yellow.

  The main body side terminal portions Q1, Q2, and Q3 extend in the section of the virtual lines Z2 to Z3. When the substrate 701 (light emitting side terminal sections P1 to P3) is in this section, the light emitting side terminal section P1. , P2 and P3 are energized, and the emission color of the light emitting means 702 becomes white.

  The body side terminal portions Q2 and Q3 extend in the section of the virtual lines Z3 to Z4. When the substrate 701 (light emitting side terminal sections P1 to P3) is in this section, the light emitting side terminal sections P2 and P3. Is energized, and the light emission color of the light emitting means 702 becomes light blue.

  Therefore, when the substrate 701 is slid in the vertical direction based on the driving of the driving unit 705, the color of the light emitting unit 702 is changed while sliding up and down.

  However, when the configuration in which the upper substrate 402 is rotated as in the above embodiment is employed, the increase in the size of the effect button 125 is suppressed as compared with the case where the upper substrate 402 is reciprocated as in the above-described example. The light part of the production button 125 can be displaced more greatly.

  (E) In the above embodiment, the rotation speed of the upper substrate 402 (motor 405) may not be constant, and may be configured to be switchable to another stage, for example. In this case, it is possible to diversify the light modes of the effect button 125, and to improve the effect by changing the rotation speed of the motor 405 between, for example, the probable big hit and the normal big win. You can also.

  (F) The timing of starting the rotation of the motor 405 of the effect button 125 is not particularly limited, and can be set for each model of the pachinko machine. Also, the rotation start timing of the motor 405 may not be one pattern. For example, there are a plurality of timings such as one selected immediately after the start of fluctuation, immediately after reaching the reach state, and immediately before the stop display. There may be.

  Further, the button setting process of FIG. 34 may be changed as shown in FIG. 39 so that the motor 405 may be rotated by the operation of the effect button 125 (operation unit 404).

  In the above embodiment, when the acquired value of the button effect random number counter is “1” to “10” in step S3902 in the normal process of the sub-control device 262 of FIG. 31, the button effect flag is turned on. However, in this example, the first button effect flag is turned on when the value of the acquired button effect random number counter is “1” to “5”, and the value is changed to “6” to “10”. The 2-button effect flag is turned on.

  As shown in FIG. 39, first, in step S6101, it is determined whether or not the first button effect flag is on. If an affirmative determination is made in step S6101, the button valid flag is confirmed in step S6102, and it is determined whether or not the button is valid. If an affirmative determination is made in step S6102, it is determined in step S6103 whether or not the effect button 125 is operated based on the detection information of the operation detection switch 407. If a negative determination is made in step S6103 (no operation of the effect button 125) or a negative determination is made in step S6102 (when the button is invalid), the process proceeds to step S6104.

  In step S6104, it is determined whether or not the value of the button effect timer is “0”. If an affirmative determination is made in step S6104, that is, if it is time to rotate the motor 405, the process proceeds to step S6106.

  If an affirmative determination is made in step S6103, that is, if the first button effect flag is on and the effect button 125 is operated when the button is valid, the button effect timer is reset in step S6105. After the value of the button effect timer is set to “0”, the process proceeds to step S6106.

  In step S6106, it is determined whether or not the value of the variable display timer is “0”. If a negative determination is made in step S6106, that is, if the timing for stopping the variable display on the decorative symbol display device 42 (special display device 43) has not yet arrived, the motor 405 is continued in step S6107. A motor drive process for driving is performed, and this process ends.

  On the other hand, if an affirmative determination is made in step S6106, that is, if it is time to stop the variable display on the decorative symbol display device 42, motor stop processing is performed in step S6108. After step S5108, the process proceeds to step S6109, where the first and second button effect flags are turned off and the process is terminated.

  If a negative determination is made in step S6101, it is determined in step S6110 whether the second button effect flag is on. If a positive determination is made in step S6110, the process proceeds to step S6104. In other words, when the first effect button is on, if the effect button 125 is operated when the button is valid, the motor 405 immediately rotates. However, when the second effect button is on, when the button is valid, Even if the production button 125 is operated, the motor 405 does not rotate based on the operation.

  On the other hand, if a negative determination is made in step S6110, the process proceeds to step S6112. Also, if a negative determination is made in step S6104 (the value of the button effect timer is not “0”), the value of the button effect timer is subtracted in step S6111, and the process proceeds to step S6112. In step S6112, a color change process is performed, and then this process ends.

  As described above, in the case where the motor 405 may be rotated by the operation of the effect button 125, the player can find the fun of operating the effect button 125 itself interesting, Improvements can be made.

  (G) In the above embodiment, when the movable body 471 is displaced and the pressing portion 432 is pressed to displace the operation portion 404 downward, a biasing force directed upward is applied to the operation portion 404. Although the magnitude of the force required to push down the operation unit 404 is changed by increasing / decreasing the number of coil springs 406 that can be formed, it is not particularly limited to such a configuration. Hereinafter, exemplary embodiments shown in FIGS. 40 and 41 will be described.

  The spring force adjusting means 801 shown in FIGS. 40 and 41 includes a solenoid 802 and a movable body 804 fixed to the distal end portion of the plunger 803 of the solenoid 802. The solenoid 802 is arranged so that the plunger 803 extends toward the peripheral wall 431 of the operation unit 404. The movable body 804 includes a resin-made fixing portion 805 that is fixed to the distal end portion of the plunger 803, and a rubber lip portion 806 that protrudes from the fixing portion 805 to the operation portion 404 side (the peripheral wall portion 431 side). Yes. Four lip portions 806 are provided at a predetermined interval in the vertical direction. Each lip portion 806 extends while being inclined downward toward the operation portion 404 side.

  As shown in FIG. 40, the solenoid 802 is normally in a non-excited state, and in this state, the lip portion 806 and the operation portion 404 (the peripheral wall portion 431) are separated from each other. On the other hand, as shown in FIG. 41, when the solenoid 802 is energized, the plunger 803 protrudes toward the peripheral wall portion 431, and the lip portion 806 and the operation portion 404 (peripheral wall portion 431) are brought into pressure contact with each other. At this time, when the operation portion 404 (pressing portion 432) is pressed, the peripheral wall portion 431 and the lip portion 806 are brought into sliding contact with each other, and a frictional force acts between them.

  As described above, even when the production button 125 is configured, the movable body 804 is displaced, and the frictional force acting between the movable body 804 and the operation unit 404 changes (the state where the frictional force is applied and the state where the frictional force is not applied). By changing the state, the magnitude of the force required to displace the operation unit 404 downward can be changed. Therefore, the same operation effect as the above-mentioned embodiment is produced. Further, since the rubber-made lip portion 806 is brought into contact with the operation portion 404 instead of bringing the resin-made fixing portion 805 into contact with the operation portion 404, damage to the operation portion 404 and the spring force adjusting means 801 can be suppressed. In addition, it is possible to suppress a situation in which the displacement of the operation unit 404 is significantly inhibited by pressing the fixing unit 805 against the operation unit 404. Furthermore, since the movable body 804 is configured to be displaced in a direction (left-right direction) orthogonal to the displacement direction of the operation unit 404, the movable body 473 is displaced in accordance with the displacement direction of the operation unit 404. In adopting a configuration in which a plurality of upper and lower lip portions 806 are switched between a state in which the lip portion 806 is in contact with the peripheral wall portion 431 and a state in which the lip portion 806 is not in contact with the peripheral wall portion 431, the displacement amount of the movable body 804 can be reduced, And complication of the configuration can be suppressed.

  42A, the lip portion 806 may be provided not on the movable body 804 but on the operation portion 404 (peripheral wall portion 431). In this case, it is assumed that the lip portion 806 extends obliquely upward toward the movable body 804. In the above-described embodiment, the lip portion 806 and the peripheral wall portion 431 are separated from each other at normal times. However, the lip portion 806 and the peripheral wall portion 431 may be in contact with each other even at normal times. In this case, by changing the degree of pressure contact between the lip portion 806 and the operation portion 404 such as bringing the lip portion 806 and the peripheral wall portion 431 into stronger pressure contact by setting the solenoid 802 in an excited state, the operation portion The stress acting on 404 is changed.

  Moreover, it is good also as mounting both the spring force adjustment means 801 as described in the said (g), and the spring force adjustment means 471 of the said embodiment with respect to one production | presentation button 125. FIG. In this case, the magnitude of the biasing force of the coil spring 406 acting on the operation unit 404 can be made relatively large without displacing the movable bodies 804 and 473 of the spring force adjusting means 801 and the spring force adjusting means 471 so much. It can be changed greatly. Therefore, the force (operation required for the pressing operation of the operation unit 404 between the time when the operation unit 404 is easily pressed down and the time when the operation unit 404 is difficult to press down is suppressed while suppressing the enlargement of the effect button 125. It is possible to apply an emphasis to the feel during operation of the unit 404.

  (H) Further, as shown in FIG. 42 (b), the operation portion 404 (peripheral wall portion 431) has a convex portion that is in contact with the lip portion 806 (protrusion portion) of the movable body 804 described in (g) above. A portion 831 may be provided. In this case, when the operation portion 404 is operated, when the lip portion 806 of the movable body 804 is in sliding contact with the convex portion 831 of the operation portion 404, and when the lip portion 806 is a portion (concave portion) other than the convex portion 831 of the operation portion 404. The frictional force acting between the movable body 804 and the operation unit 404 changes depending on the sliding contact. For this reason, the feel (response) when pushing in the operation unit 404 changes in the middle (a crisp feel), and the fun is further improved.

  Since the lip portion 806 of the movable body 804 (the sliding contact surface with the operation portion 404 of the lip portion 806) is inclined downward toward the peripheral wall portion 431 side, the lip portion in the displacement direction of the operation portion 404 When 806 and the convex part 831 of the operation unit 404 come into contact with each other, a situation in which the displacement of the operation unit 404 is restricted can be suppressed.

  (I) In the above embodiment, a distance (maximum displacement of the operation unit 404) that allows the operation unit 404 to be displaced downward (in the direction of immersing into the main body unit 401) by pressing the pressing unit 432 of the operation unit 404. (Amount) may be changed. Hereinafter, exemplary embodiments shown in FIGS. 43 and 44 will be described.

  43 and 44 include a rubber restriction block 861 (regulation member) that can come into contact with the lower end of the operation unit 404, and a restriction solenoid 862 (regulation body) that can displace the restriction block 861. Displacement amount adjusting means including a driving means) is provided. As shown in FIG. 44, when the regulating solenoid 862 is in an excited state, the regulating block 861 is at a position off the track of the operating unit 404 that is displaced up and down, and the operating unit 404 is pressed by pressing the pressing unit 432. The operation portion 404 can be pushed in until the base portion 413 comes into contact. On the other hand, as shown in FIG. 43, when the restriction solenoid 862 is in a non-excited state, the restriction block 861 is positioned below the operation unit 404. For this reason, when the pressing portion 432 is pressed, the operation portion 404 and the restriction block 861 come into contact with each other, and the operation portion 404 cannot be pushed in until the operation portion 404 and the base portion 413 come into contact with each other.

  As described above, by adopting a configuration in which the maximum amount of downward displacement of the operation unit 404 is changed, the effect of the effect button 125 can be enhanced, and further enhancement of interest for the player can be achieved. . In addition, since the restriction block 861 is made of rubber, the impact when the restriction block 861 collides with the operation unit 404 can be alleviated, and the stress acting on the player and the effect button 125 at the time of the collision can be reduced. Can do.

  In addition, the display effect using the said structure is illustrated. For example, as a specific display effect, a door is displayed on the decorative symbol display device 42, and an effect display such as a big hit if the door is opened and a release if the door is not opened is performed. The effect button 125 is always in a state in which the restriction solenoid 862 is in a non-excited state, the restriction block 861 is at a position below the operation unit 404 (the state shown in FIG. 43), and the maximum displacement amount of the operation unit 404 is small. It has become.

  When the door is displayed on the decorative symbol display device 42 and guidance indicating that the effect button 125 should be pressed is displayed, the control block 861 is not displaced and the operation unit 404 is not moved much when the door is released. Although the state where it cannot be pushed in is maintained, if it is a big hit, the regulation solenoid 862 is excited, the regulation block 861 comes out from below the operation unit 404, and the operation unit 404 can be pushed all the way back (FIG. 44). State shown in). When the operation unit 404 is pushed in all the way (by detecting the operation of the operation unit 404 with the operation detection switch 407 in a state where the operation unit 404 is pushed all the way back), it is displayed on the decorative symbol display device 42. The door is opened and a display teaching the jackpot is derived. Incidentally, when it comes off, the change display ends with the door closed.

  In FIGS. 43 and 44, when the regulating solenoid 862 is in a non-excited state, it is illustrated that the operation detection unit 407 does not detect the operation unit 404 even if the operation unit 404 is operated. Regardless of the position of the restriction block 861, it may be configured to be displaceable between an operation position where detection by the operation detection switch 407 is performed and a non-operation position where detection by the operation detection switch 407 is not performed. Good. In this case, even if the maximum displacement amount of the operation unit 404 changes, the function as the effect button 125 can be maintained. The operation detection switch 407 includes an operation side terminal portion provided in the operation portion 404 and a movable side terminal portion provided in the restriction block 861, and the operation side terminal portion and the movable side terminal portion come into contact with each other, The operation of the operation unit 404 may be detected. In this case, even when the maximum displacement amount of the operation unit 404 changes relatively greatly, the operation of the operation unit 404 can be reliably detected in a state where the restriction block 861 is at each position.

  The restriction block 861 may be provided so as to be vertically displaceable below the operation unit 404, and the maximum displacement amount of the operation unit 404 may be changed in accordance with the displacement of the restriction block 861. Further, the operation unit 404 may not be displaced at all even when the pressing unit 432 is pressed.

  (J) In the embodiment described above, there are only two stationary positions, the first position and the second position, at which the movable body 473 is in a stationary state. However, even if three or more stationary positions are set. Good. In this case, it is possible to diversify the production.

  Further, for example, as shown in FIGS. 45A and 45B, the movable body 473 is configured to be displaceable until the mount 484 (contact portion) is positioned above the base portion 413 (support portion), and You may comprise so that the mount frame 484 and the lower end part of the spring accommodating part 433 can contact | abut (refer FIG.45 (b)). In this case, when the movable body 473 is displaced to the position (regulation position) shown in FIG. 45, the gantry 484 and the operation unit 404 come into contact with each other, and further displacement of the operation unit 404 is regulated (the base unit 413 and the base unit 413). It cannot be displaced until it abuts). On the other hand, when the movable body 473 is displaced to the position (allowable position) shown in FIGS. 7 and 10, the operation unit 404 can be displaced until it comes into contact with the base part 413. Therefore, in addition to the same effects as the above (i), in addition to the adjustment means (movable body 473 and adjustment motor 474) for changing the force required for the pressing operation of the operation unit 404, the operation unit 404 It is not necessary to provide displacement amount adjusting means (restriction block 861 and restriction solenoid 862) for changing the maximum displacement amount, and the configuration can be simplified. In addition, since the movable body 473 having the same function as that of the restriction block 861 is displaced along the displacement direction of the operation portion 404, the pressing portion 432 is pressed, and the operation portion 404 and the movable body 473 are moved. Even in the pressed state, the movable body 473 at the restriction position can be easily displaced to the allowable position side. For this reason, it is possible to change the state from the state where the operation unit 404 cannot be pushed in to the state where it can be pushed into the back without imposing such a large burden on the effect button 125. Can be done smoothly. It is assumed that the adjustment motor 474 of this embodiment has an encoder built therein.

  In addition, when the restriction block 861 is provided separately from the movable body 473 as in (i) above, it is not necessary to bring the operating portion 404 (spring accommodating portion 433) into contact with the mount 484. When operated, the spring accommodating portion 433 can be configured to abut against the base portion 413 without abutting against the gantry 484. With this configuration, it is possible to prevent a situation in which the spring force adjusting means 471 (such as the adjusting motor 474) is damaged due to the platform 484 colliding with the operation unit 404.

  In addition, a contact portion that protrudes toward the operation portion 404 at a position higher than the lip portion 806 is provided in the fixed portion 805 of the movable body 804 in (g), and an upper surface of the contact portion is provided with respect to the operation portion 404. A contactable portion that can be contacted is provided, and the movable body 804 has a lip portion 806 and a non-contact position where the contact portion does not contact the operation portion 404 (allowable position), and only the lip portion 806 contacts the operation portion 404. The first contact position (allowable position) may be displaced to the second contact position (regulatory position) where the lip portion 806 contacts the operation portion 404 and the contact portion contacts the contacted portion.

  (K) Although not specifically mentioned in the above embodiment, a specific display object is displayed on the decorative symbol display device 42 based on the displacement direction of the operation unit 404 that is displaced by pressing the pressing unit 432 and the operation of the operation unit 404. The direction in which the character moves (in the above example, the direction in which the character places his hand in the treasure box) may be the same. In this case, the sense of jointness between the operation of the effect button 125 and the display effect on the decorative symbol display device 42 can be improved, and a specific display displayed on the decorative symbol display device 42 by operating the effect button 125. It becomes easier for the player to empathize with the display effect that the object moves. Therefore, the interest can be improved.

  (L) In the embodiment described above, the pressing portion 432 of the effect button 125 is arranged so as to face upward and obliquely forward. However, the configuration is not particularly limited to this configuration, and the direction of the pressing portion 432 is pachinko. It can be set for each machine model.

  Moreover, in the said embodiment, the operation part 404 (effect button 125) may be comprised so that tilting displacement is possible, and it may be comprised so that the displacement direction of the operation part 404 may change with the said tilting displacement. In this case, the displacement direction of the operation unit 404, that is, the direction in which the pressing unit 432 is pressed can be changed. For this reason, when the operation direction of the effect button 125 and the operation direction of the specific display object displayed on the decorative symbol display device 42 are matched as in (k), the decorative symbol display device 42 displays the operation direction. The operation direction of a specific display object can be set to a plurality of directions instead of a single direction, and display effects can be diversified. The entire production button 125 is provided so as to be tiltable with respect to the main body of the pachinko machine 10 (front frame set 14) (the main body 401 is pivotally supported by the front frame set 14 and a motor for tilting the main body 401 is provided. ) It's good.

  (M) In the embodiment described above, the contact detection switch 491 can be omitted. In this case, the adjustment motor 474 may be configured to rotate by a predetermined angle or be driven for a predetermined time so that the gantry 484 contacts the base part 413 or the guide part 477, or an encoder is mounted on the adjustment motor 474. A configuration in which the position of the movable body 473 can be grasped without the contact detection switch 491 may be employed.

  In the above embodiment, the movable body 473 has a first position (see FIG. 7) where the upper end portion of the guide portion 477 and the lower surface of the gantry 484 abut, and the gantry 484 is separated from the guide portion 477. Is configured to be displaceable between a second position (see FIG. 10) where the upper surface of the base portion 413 contacts the lower surface of the base portion 413, but is not particularly limited to such a configuration. And the structure which the guide part 477 and the mount frame 484 do not contact | abut may be employ | adopted. For example, the position of the movable body 473 in which the gantry 484 is positioned inside the spring insertion hole 487 and the upper surface of the gantry 484 and the upper surface of the base portion 413 are flush may be set as the second position. Further, for example, the position of the movable body 473 in which the gantry 484 is positioned above the base portion 413 and the gantry 484 is positioned inside the spring accommodating portion 433 when the operation unit 404 is pressed down is set to the second position. It is good also as a position.

  In addition, in the above embodiment, the movable body 473 is displaced using the adjustment motor 474. However, the movable body 473 may be displaced using other driving means (solenoid or the like). In addition, when the coil spring 406b contracts, the movable body 473 in the second position is disposed on the rotating shaft of the adjustment motor 474 in order to prevent the situation where the movable body 473 is displaced to the first position side. A link mechanism may be interposed between the gear 490 and the slide piece 481, or a holding unit capable of regulating the displacement of the movable body 473 at the second position may be provided. For example, a hole is formed in the slide piece 481 and the guide part 477, and when the movable body 473 is in the second position, the hole part of the slide piece 481 and the hole part of the guide part 477 communicate with each other. When the solenoid is mounted on the mounting base 472 and the movable body 473 is in the second position, the plunger of the solenoid (the metal piece attached to the plunger) is the hole of the slide piece 481 and the guide part 477. You may comprise so that it may be set as the insertion state in a hole.

  (N) In the above embodiment, the specific display effect in which the movable body 473 is displaced to the second position is not particularly limited. Further, the movable body 473 may be displaced to the second position regardless of the display on the decorative symbol display device 42 (any display). Further, in the above-described embodiment, the movable body 473 is returned to the first position when the operation unit 404 is operated once when the movable body 473 is at the second position. For example, the movable body 473 may be held at the second position until the change display ends (until the stop display is performed), and returned to the first position after the end of the change. In the decorative symbol display device 42, the movable body 473 is held in the second position until a predetermined display is performed (for example, until the contents of the treasure box are displayed in the above embodiment), and the predetermined pattern is displayed. It is good also as a structure returned to a 1st position after a display is performed. The decorative symbol display device 42 can be omitted.

  (O) In the above embodiment, the force required for the pushing operation of the operation unit 404 is changed by operating the movable body 473. For example, an electromagnet is provided on the upper surface of the base unit 413, and the operation unit 404 is operated. By providing a magnet at a position facing the electromagnet with respect to the lower end of the magnet, changing the magnetic force of the electromagnet (changing the magnitude of the current flowing through the coil of the electromagnet), and changing the repulsive force between the electromagnet and the magnet The force required for the pushing operation of the operation unit 404 may be changed. In this case, the force required for the pushing operation of the operation unit 404 can be changed without displacing the electromagnet and the magnet as the adjusting means. Further, it is possible to change the maximum displacement amount of the operation unit 404 by utilizing the repulsive force between the electromagnets.

  It should be noted that the magnet and the electromagnet are attracted against the urging force of the coil spring 406 by flowing a current through the electromagnet or by changing the direction of the current flowing through the coil of the electromagnet, and the operation unit 404 is pushed. It is good also as changing the force required for operation. Further, when an electromagnet (or a magnet instead of an electromagnet) is provided on the movable body 473 and the position of the electromagnet is moved up and down (when the relative position between the electromagnet and the magnet is changed), the magnetic force of the electromagnet is not changed. The force required for the pushing operation of the operation unit 404 can be changed. Further, as described with reference to FIGS. 45A and 45B in (j) above, the movable body 473 is configured to be displaceable until the gantry 484 is positioned above the base portion 413, and then the gantry 484. An electromagnet (or a magnet) may be provided on the control unit 404, and the maximum displacement amount of the operation unit 404 may be changed by repelling the magnet provided in the operation unit 404 (the lower end of the spring accommodating unit 433).

  (P) In the above embodiment, when the operation unit 404 (the pressing unit 432) is not operated (the operation side terminal unit 435 and the base side terminal unit 436 of the operation detection switch 407 are separated from each other). From the non-operating position to the operating position when the operation unit 404 is operated (when the operation-side terminal unit 435 and the base-side terminal unit 436 of the operation detection switch 407 are in contact). During normal times, a total of six coils are energized by a total of three coil springs 406a, and when a specific display effect (display in which a character takes out a treasure from a treasure chest) is performed on the decorative symbol display device 42. The structure is biased by the springs 406a and 406b, and the number of coil springs 406 biasing the operation unit 404 does not change during the operation, but the operation unit 404 is displaced. The number of coil springs 406 for biasing the operating portion 404 in the middle and have changes (the number of coil springs 406 in contact with the operation unit 404 is changed) may be configured. For example, in a normal state, the operation unit 404 is attached by three coil springs 406a until the operation unit 404 at the operation position is displaced until the operation side terminal unit 435 and the base side terminal unit 436 come into contact with each other. After that, the operation unit 404 may be urged by the six coil springs 406a and 406b. Further, for example, when a specific display effect is performed on the decorative symbol display device 42, when the player touches the pressing portion 432 and starts to displace the operation portion 404 to the operation position side, the operation portion 404 has three coil springs 406a. However, immediately after that (when the operation unit 404 is slightly displaced toward the operation position, the operation unit 404 is biased by the six coil springs 406a and 406b). It is good.

  In the above embodiment, the number of coil springs 406 that bias the operation unit 404 is merely changed to three and six. However, for example, the number of coil springs 406 that bias the operation unit 404 is two. It is good also as a structure changed into a book, four, and six. Of course, the total number of coil springs 406 mounted on the effect button 125 is not particularly limited, and may be 5 or less, or 7 or more.

  (Q) Although not specifically mentioned in the above embodiment, even when the big hit state does not occur (when the variable display of the symbols on the decorative symbol display device 42 is stopped and displayed by a combination of detachment), the movable body 473 is You may comprise so that it may displace to a 2nd position. In this case, if it is difficult for the operation unit 404 to be pushed, it is possible to avoid gameability such as finding out that it is a big hit.

  (R) In the above embodiment, the pressing portion 432 protrudes outward (upward) from the main body portion 401 regardless of whether the operation portion 404 is in the non-operation position or the operation position. It is not limited to a simple configuration. For example, when the operation unit 404 is in the non-operation position, the pressing unit 432 protrudes outward from the main body 401, but when the operation unit 404 is in the operation position, the pressing unit 432 is an edge wall portion of the main body 401. It may be flush with 423 or located inside the main body 401. Further, for example, even when the operation unit 404 is in the non-operation position, the pressing unit 432 is flush with the edge wall portion 423 of the main body unit 401 or is located inside the main body unit 401, and the operation unit 404 is in the operation position. The pressing portion 432 may be further displaced to the back side (downward) of the main body portion 401 by being pressed to the side.

  (S) You may implement as a pachinko machine of a different type from the above-mentioned embodiment. In addition to pachinko machines, various ball games, similar sparrow balls and other gaming machines, slot machines as revolving game machines, and other types of gaming machines that combine slot machines and pachinko machines, etc. May be. Note that in a gaming machine of a type in which a slot machine or a slot machine and a pachinko machine are combined, for example, a bet button for betting a credited medal or a reel with identification information is stopped as an operation means. A stop button or the like may be applied.

  (T) In the above embodiment, the adjustment motor 474 may be omitted, and the movable body 473 may be displaced up and down in conjunction with the motor 405 (rotating shaft 461). Hereinafter, exemplary embodiments will be described with reference to the drawings. For convenience of explanation, description will be made basically using the same member numbers as the effect buttons 125 of the above embodiment. 46 is a schematic cross-sectional view showing the effect button 125 in a state where the motor 405 is not driven and the operation unit 404 is not operated, and FIG. 47 is a diagram where the motor 405 is not driven and the operation unit 404 is operated. FIG. 48 is a schematic cross-sectional view showing the effect button 125 when the motor 405 is driven (the operation unit 404 is not operated). FIG. 49A is a schematic side view showing the movable body 905, and FIG. 49B is a schematic side view showing the transmission member 904. The basic configuration of the effect button 125 is the same as that of the above embodiment, and the coil spring 406a, the spring accommodating portion 433 (433a) on which the coil spring 406a is supported, and the spring support portion 415 are also described in the above embodiment. It has the same configuration.

  The spring force adjusting means 901 according to the present embodiment includes an original gear 902 fixed to the rotating shaft 461 of the motor 405, a play wheel 903 that meshes with the original gear 902, a transmission member 904 that is linked to the play wheel 903, and a coil spring 406b. And a movable body 905 that can slide up and down. The adjusting means of this example is configured by an original gear 902, a play wheel 903, a transmission member 904, and a movable body 905. In addition, the light emitter driving means (driving means) is constituted by the motor 405.

(Original gear 902)
The original gear 902 has a through hole 911 that penetrates up and down at the center, and the through hole 911 is inserted through the rotating shaft 461 at a position lower than the lower substrate 403 (position close to the motor 405 main body). The rotation shaft 461 is fixed.

  More specifically, the rotation shaft 461 includes a support plate portion 913 that supports the lower surface of the original gear 902 inserted through the rotation shaft 461, and a displacement protrusion that protrudes from the outer peripheral surface of the rotation shaft 461 directly above the support plate portion 913. Part 914 and a fixing hole (not shown) penetrating in a direction perpendicular to the longitudinal direction of the rotation shaft 461 at a position above the original gear 902 supported by the support plate part 913. In addition, a fitting recess 916 that fits the slip prevention protrusion 914 is formed on the inner peripheral wall portion of the through hole 911 of the original gear 902. Further, a substantially cylindrical retaining member 918 that supports the upper surface of the original gear 902 supported by the support plate 913 is attached to the rotating shaft 461. The retaining member 918 has a pair of screw holes (not shown) facing each other. Then, the original gear 902 is inserted into the rotary shaft 461 so that the slip-preventing convex portion 914 is fitted in the fitting concave portion 916, the original gear 902 and the support plate portion 913 are brought into contact with each other, and the rotary shaft 461 is detached. After the stopper member 918 is inserted and the stopper member 918 and the original gear 902 are brought into contact with each other, the screw hole of the stopper member 918 and the fixing hole of the rotating shaft 461 are aligned and screw-fixed. As described above, the original gear 902 is fixed to the rotating shaft 461.

(Play car 903)
The play wheel 903 has a through-hole 921 that penetrates up and down in the center. In addition, the base portion 413 is formed with a support base portion 922 that protrudes upward corresponding to the installation position of the play wheel 903 and supports the lower surface of the play wheel 903 (the peripheral edge of the through hole 921). A fixing hole 923 is formed on the upper surface of the base portion 413. Further, the support base part 922 includes an umbrella part 925 that supports the upper surface of the play wheel 903 supported by the support base part 922, and a shaft that protrudes downward from the umbrella part 925 and is inserted into the through hole 921 of the play wheel 903. A retaining member 924 having a portion 926 is attached. The retaining member 924 is formed with a screw hole 927 penetrating vertically in the central portion. Then, after the retaining member 924 is inserted into the through hole 921 of the play wheel 903, the play wheel 903 is placed on the upper surface of the support base 922 so that the teeth of the play wheel 903 and the teeth of the original gear 902 are engaged with each other. While installing, the screw hole 927 of the retaining member 924 and the fixing hole 923 of the support base 922 are aligned and screw-fixed. As described above, the play wheel 903 is provided so as to be rotatable with respect to the base portion 413.

(Transmission member 904)
As shown in FIG. 49B and the like, the transmission member 904 includes a gear-like pinion portion 931 that meshes with the play wheel 903, and a substantially cylindrical shaft column portion 932 that protrudes downward from a substantially central portion of the pinion portion 931. , And a rod-shaped transmission portion 933 that protrudes upward from a substantially central portion of the pinion portion 931. The pinion portion 931 and the shaft column portion 932 are made of resin. The transmission portion 933 is configured by a metal member that is insert-molded so that a part thereof is embedded in the pinion portion 931 and the shaft column portion 932 when the pinion portion 931 and the shaft column portion 932 are formed.

  Further, as shown in FIG. 46 and the like, the base portion 413 is formed with a through hole 934 that penetrates up and down corresponding to the installation position of the transmission member 904 and through which the shaft column portion 932 is inserted. A cylindrical support portion 935 that protrudes upward from the peripheral edge portion of 934 and supports the lower surface of the pinion portion 931 is formed. Further, a retaining member 936 that substantially contacts the lower surface of the base portion 413 (the peripheral edge portion of the through hole 934) is attached to the lower end portion of the shaft column portion 932 that is inserted into the through hole 934. A fixing hole 932a is formed in the lower surface of the shaft column portion 932, and a screw hole 936a penetrating vertically is formed in the retaining member 936. Then, the shaft column portion 932 is inserted into the through-hole 934, the fixing hole 932a of the shaft column portion 932 and the screw hole 936a of the retaining member 936 are aligned and screw-fixed, so that the transmission member 904 is a base. It is provided so as to be rotatable with respect to the portion 413. Further, by inserting the shaft column portion 932 into the through hole 934, the teeth of the pinion portion 931 and the teeth of the play wheel 903 are engaged with each other. When the motor 405 is driven, the original gear 902 and the play wheel 903 are moved. Thus, the driving force of the motor 405 is transmitted to the transmission member 904, and the transmission member 904 rotates.

  The transmission portion 933 is configured in a substantially cylindrical shape, and a male screw is formed on the outer peripheral surface thereof. In this embodiment, the pinion part 931 and the shaft column part 932 are made of resin, and the transmission part 933 is made of metal. However, the entire transmission member 904 may be made of metal.

(Movable body 905)
As shown in FIG. 49A, the movable body 905 includes a substantially cylindrical gantry 941 extending in the vertical direction, a columnar support protrusion 942 projecting upward from a substantially central portion of the upper surface of the gantry 941, and the gantry 941. And a pair of guide protrusions 943 projecting outward from the upper part of the outer peripheral surface. The outer diameter of the support protrusion 942 is smaller than that of the gantry 941, and when the lower part of the coil spring 406 b is inserted into the support protrusion 942, the lower end portion of the coil spring 406 b is supported on the upper surface of the gantry 941. . In this embodiment, the gantry 941 in which the female screw is formed corresponds to the interlocking portion. In addition, an interlocking means is configured by the original gear 902, the play wheel 903, the transmission member 904, and the mount 941 of the movable body 905.

  Further, in the assembled state of the effect button 125, the movable body 905 is housed inside the spring housing portion 433b that supports the upper portion of the coil spring 406b. More specifically, as shown in FIG. 46 and the like, a guide that extends upward from a lower end portion of the spring accommodating portion 433b on the inner surface of the spring accommodating portion 433b and can be inserted through the guide convex portion 943 of the movable body 905. A slit 945 is formed. Since the guide convex portion 943 is inserted into the guide slit 945, a situation in which the movable body 905 is rotationally displaced relative to the spring accommodating portion 433b (operation portion 404) is prevented.

  Note that the lower end of the spring accommodating portion 433b that supports the upper portion of the coil spring 406b is positioned higher than the spring accommodating portion 433a that supports the upper portion of the coil spring 406a (the vertical width is shorter). Further, with respect to the peripheral wall portion 431, a notch portion that allows insertion of the transmission member 904 and the like when the operation portion 404 is pushed down is formed at a position corresponding to the spring accommodating portion 433b.

  On the inner peripheral surface of the gantry 941, a female screw that can be screwed with a male screw formed in the transmission portion 933 of the transmission member 904 is formed. In the assembled state of the production button 125, the transmission portion 933 of the transmission member 904 is inserted into the mount 941 of the movable body 905. In the present embodiment, the movable body 905 has a first position when the screwing range between the transmission portion 933 and the gantry 941 is the longest and a first position when the transmission portion 933 and the gantry 941 are in a non-screwed state. It is configured to be displaceable between the two positions. Moreover, in this example, the external thread formed in the transmission part 933 is extended and inclined upward toward the right side.

  For this reason, when the motor 405 rotates in the direction in which the upper substrate 402 of FIG. 8A is rotated in the clockwise direction in a state where the transmission portion 933 and the mount 941 are screwed together, as shown in FIG. 933 moves relative to the direction in which the base 934 comes out from the base 941 (the direction in which the screwing range between the transmission portion 933 and the base 941 becomes short), and the base 941 is displaced upward. Then, when the gantry 941 is displaced upward (range to the second position) until the screwing state between the transmission unit 933 and the gantry 941 is released, the operation unit 404 is not operated (the spring housing portion 433). In the state where the edge wall portion 423 and the edge wall portion 423 are in contact with each other, the upper end portion of the coil spring 406b is in contact (pressure contact) with the top wall portion 434 of the spring accommodating portion 433b. That is, the operation unit 404 is biased upward by a total of six coil springs 406a and 406b. In this example, in this state (the movable body 905 is in the second position), the operation unit 404 (operation unit 432) is operated, and the lower end portion of the operation unit 404 and the base unit 413 come into contact with each other. At this point, the upper edge portion of the guide slit 945 and the guide convex portion 943 are configured to substantially contact each other. For this reason, the displacement of the operation portion 404 is not hindered by the guide convex portion 943.

  On the other hand, when the motor 405 rotates in the opposite direction (the direction in which the upper substrate 402 is rotated counterclockwise in FIG. 8A), the direction in which the transmission unit 933 is inserted into the mount 941 (the transfer portion 933 and the mount 941 The movable body 905 is displaced downward by relative movement in the direction in which the screwing range becomes longer. As shown in FIG. 46, the screwing range between the transmission portion 933 and the gantry 941 is the longest (the gantry 941 is displaced to the first position, and the gantry 941 and the base portion 413 are closest to each other). The coil spring 406b is not moved until the coil spring 406b and the top wall portion 434 come into contact with each other (see FIG. 47) until the lower end portion of the operation portion 404 and the base portion 413 come into contact with each other. It will be in the state spaced apart from the top wall part 434 of the spring accommodating part 433b. That is, the operation unit 404 is biased upward by only the three coil springs 406a.

  Therefore, when the movable body 905 is in the second position (see FIG. 48) compared to the state where the movable body 905 is in the first position (see FIG. 46), the coil spring 406 acting on the operation unit 404 is attached. Since the force increases, a larger force is required to press the pressing portion 432 and displace the operation portion 404 downward.

  In this embodiment, the movable body 905 is held at the first position in a normal state where the motor 405 is not driven. In addition, each movable body 905 of the three spring force adjustment means 901 installed in the base part 413 carries out the same movement synchronously. In addition, in this embodiment, the contact detection switch 491 is omitted because the movable body 905 is displaced by the motor 405 with a built-in encoder.

  Note that a female screw is not formed at the lower end of the gantry 941, and the upper substrate 402 rotates in the clockwise direction, and the threaded state between the transmission member 904 (transmission unit 933) and the movable body 905 (the gantry 941). Even if released, the tip of the transmission portion 933 is positioned inside the gantry 941. For this reason, even if the transmission unit 933 is completely removed from the gantry 941 and the transmission unit 933 and the gantry 941 are displaced, and the motor 405 is rotated in the opposite direction (the upper substrate 402 is rotated counterclockwise) The situation where it becomes impossible to screw the transmission part 933 and the mount 941 can be avoided. Therefore, the motor 405 (upper substrate 402) can be rotated in the same direction (clockwise direction) without any trouble even after the screwed state of the transmission portion 933 and the mount 941 is released.

  Further, as described above, since the operation portion 404 is biased downward by the coil spring 406b, even if the transmission portion 933 and the mount 941 are not screwed, the male screw formed on the transmission portion 933 Is in a state where the lower end of the female screw formed on the gantry 941 is in pressure contact (the gantry 941 is pressed against the transmission portion 933). Therefore, when the transmission portion 933 and the gantry 941 are in the non-screwed state, the upper substrate 402 rotates counterclockwise, so that the transmission portion 933 and the gantry 941 are securely screwed, and the movable body 905 is attached. It can be displaced downward.

  Note that the operation detection switch 951 of this embodiment is configured by a photosensor including a light projecting unit and a light receiving unit, and is provided on the upper surface of the base unit 413. When the operation unit 404 is pressed, the lower part of the operation unit 404 enters between the light projecting unit and the light receiving unit, and the light from the light projecting unit to the light receiving unit is blocked.

  As described above, according to this embodiment, when the motor 405 is driven, the upper substrate 402 rotates and the movable body 905 is displaced up and down. For this reason, it is not necessary to provide driving means (adjustment motor 474) for displacing the movable body 905 separately from the motor 405, and the configuration and control can be simplified, the cost can be reduced, and the like. In addition, since the idler wheel 903 is interposed between the original gear 902 and the transmission member 904, the original gear 902 and the transmission member 904 (pinion portion 931) can be configured to be small, and the production button 125 can be enlarged. While suppressing, the internal space of the production button 125 can be used more effectively.

  Furthermore, since the male part and the female thread are not formed at the transmission part 933 of the transmission member 904 and the tip part of the mount 941, the motor 405 is driven until the screwed state between the transfer part 933 and the mount 941 is released. Even so, the transmission portion 933 is inserted inside the mount 941. For this reason, even if the transmission part 933 is completely removed from the gantry 941 and the leading ends thereof are displaced, and the motor 405 is rotated in the opposite direction, the transmission part 933 and the gantry 941 are screwed together. It is possible to prevent such a situation that cannot be performed. In this way, the transmission portion 933 (transmission member 904) and the gantry 941 (movable body 905) in the non-screwing state can be screwed again, so that the transmission portion 933 and the gantry 941 are screwed together. Even after canceling, the motor 405 (upper substrate 402) can be rotated in the same direction without hindrance.

  Further, since the movable body 905 is biased downward by the coil spring 406b, the male screw and the female screw formed on the transmission portion 933 and the mount 941 even when the transfer portion 933 and the mount 941 are not screwed. Is brought into a pressure contact state, so that the transmission portion 933 and the mount 941 in the non-screwed state can be reliably screwed.

  (U) In the example (see FIG. 48) described in (t) above, the internal thread is not formed at the lower end of the gantry 941, and the screwed state between the transmission member 904 and the movable body 905 is released. Although the upper substrate 402 continues to rotate in a state in which the distal end portion of the transmission portion 933 is positioned inside the gantry 941, it is not particularly limited to such a configuration. For example, the motor 405 may be driven (the upper substrate 402 is rotated) within a range in which the transmission member 904 and the mount 941 are screwed (for example, 1 to 5 rotations). Specifically, for example, when the variation display teaching the occurrence of the big hit state is being performed on the decorative symbol display device 42, the upper substrate 402 is rotated three times and then stopped, and the variable symbol display on the decorative symbol display device 42 is performed. When STOP is displayed, the motor 405 may be rotated three times in the reverse direction.

  For example, when the decorative symbol display device 42 is performing a variable display that teaches the occurrence of the big hit state, the motor 405 (within the range in which the transmission member 904 and the movable body 905 are screwed together). The upper substrate 402) is continuously rotated by the same number in the forward and reverse directions, and the motor 405 is driven so that the movable body 905 returns to the first position when the variable display on the decorative symbol display device 42 is stopped and displayed. It is good also as a structure controlled.

  (V) In (t) above, the motor 405 and the movable body 905 are interlocked with each other by the original gear 902, the play wheel 903, the transmission member 904, and the mount 941, but this is not particularly limited to such a configuration. Absent. Further, in (t) above, the movable body 905 is displaced with the drive of the motor 405. However, with the drive of the motor 405, the restriction block 861 (see FIG. 43 and FIG. 44) of the above (i). It may be displaced. Hereinafter, the exemplary embodiments shown in FIGS. 50 and 51 will be described. FIG. 50 is a schematic cross-sectional view showing the effect button 125 when the motor 405 is not driven. FIG. 51 is a schematic cross-sectional view showing the effect button 125 in a state where the motor 405 is driven.

  A movable member 961 that can slide along the centrifugal direction of the upper substrate 402 is provided on the upper substrate 402 of the effect button 125 shown in FIGS. 50 and 51. The movable member 961 is provided on the lower surface of the upper substrate 402 and is installed on the inner peripheral side of a substantially cylindrical guide rail 962 extending along the centrifugal direction of the upper substrate 402. Further, the upper substrate 402 is provided with a movable coil spring 963 as a movable urging means. The movable coil spring 963 has an end portion on the center direction side of the upper substrate 402 fixed to a spring fixing portion 964 protruding from the lower surface of the upper substrate 402, and an end portion on the centrifugal direction side of the upper substrate 402 is movable. The member 961 is connected to the end portion on the center direction side of the upper substrate 402.

  Further, a movable terminal portion 965 is provided at the end of the movable member 961 on the centrifugal direction side of the upper substrate 402. The upper substrate 402 is provided with a fixed terminal portion 966 at a position where it can come into contact with the movable terminal portion 965. As shown in FIG. 50, in a state where the motor 405 is not driven, the movable member 961 is displaced toward the center of the upper substrate 402, and the movable terminal portion 965 and the fixed terminal portion 966 are in a separated state. ing. On the other hand, as shown in FIG. 51, when the motor 405 is driven and the upper substrate 402 is rotated, the movable member 961 is centrifuged by the upper substrate 402 against the movable coil spring 963 by the centrifugal force acting on the movable member 961. Displace in the direction. Therefore, when the upper substrate 402 is rotating at a predetermined speed, the movable terminal portion 965 and the fixed terminal portion 966 are in contact with each other.

  In this example, the regulation solenoid 862 is electrically connected to the input / output port 554 of the sub control device 262, but only constant power is supplied from the input / output port 554. Therefore, the regulation solenoid 862 is not controlled. In addition, the regulation solenoid 862 is electrically connected to the fixed terminal portion 966 via a wiring (not shown).

  When the fixed terminal portion 966 and the movable terminal portion 965 are not in contact with each other, the restriction solenoid 862 is in a non-excited state, and the restriction block 861 is located below the operation portion 404. That is, the operation unit 404 cannot be pushed all the way.

  On the other hand, when the fixed terminal portion 966 and the movable terminal portion 965 are in contact with each other, the restriction solenoid 862 is in an excited state, and the restriction block 861 is removed from the slide track of the operation portion 404. That is, the operation unit 404 can be pushed all the way down.

  When the configuration described in detail above is employed, when the upper substrate 402 rotates, the movable member 961 is displaced toward the centrifugal direction of the upper substrate 402 against the movable coil spring 963 by the centrifugal force acting on the movable member 961. The fixed terminal portion 966 and the movable terminal portion 965 are in contact with each other. Further, based on the contact between the fixed terminal portion 966 and the movable terminal portion 965, the restriction solenoid 862 is in an excited state, and accordingly, the operation portion 404 cannot be pushed in all the way.

  When the motor 405 is stopped, the movable member 961 is displaced toward the center of the upper substrate 402 by the urging force of the movable coil spring 963, and the fixed terminal portion 966 and the movable terminal portion 965 are separated from each other. Further, based on the separation of the fixed terminal portion 966 and the movable terminal portion 965, the restriction solenoid 862 is de-energized, and the restriction block 861 is displaced below the operation portion 404.

  Therefore, by driving the motor 405, it is possible to change the color while rotating the light emitting means L1 to L3 and to change the maximum displacement amount of the operation unit 404. Further, when the upper substrate 402 is rotated, the restriction solenoid 862 is automatically operated and the restriction block 861 is displaced. Therefore, it is not necessary to control the restriction solenoid 862 by the control device (for example, the sub-control device 262). Simplification can be achieved.

  (W) Further, by driving the motor 405, the light emitting means L1 to L3 can be changed in color while being rotationally displaced, and the magnitude of the force required to operate the operation unit 404 can be changed. The maximum amount of displacement may be changed. For example, in the above (t), the upper and lower lengths of the guide slit 945 are shortened by lowering the position of the upper end of the guide slit 945 formed on the inner surface of the spring accommodating portion 433b. That is, when the screwing range between the transmission portion 933 and the gantry 941 is shortened and the movable body 905 is displaced upward, the stage before the operation portion 404 and the base portion 413 come into contact with each other when the operation portion 404 is operated. Thus, the upper edge portion of the guide slit 945 and the upper surface of the guide convex portion 943 are in contact with each other. Further, three stationary positions where the movable body 473 is in a stationary state are set. Specifically, when the operation unit 404 is pressed and the operation unit 404 and the base unit 413 come into contact with each other, the first position where the coil spring 406b comes into contact with the top wall 434, and the operation unit 404 When the operation portion 404 is pressed and the second position where the coil spring 406b and the top wall portion 434 are in pressure contact with each other when the operation portion 404 is pressed, the operation portion 404 and the base portion 413 are brought into contact with each other. At this stage, the movable body 905 is configured to be displaceable to a third position where the upper edge portion of the guide slit 945 and the upper surface of the guide convex portion 943 come into contact with each other. Thus, by driving the motor 405, the force required for operation of the operation unit 404 is relatively small and the force required for operation of the operation unit 404 is relatively large, but the maximum pushing amount of the operation unit 404 is changed. It is possible to obtain the effect button 125 whose state changes to the state in which the operation unit 404 is operated and the force required to operate the operation unit 404 is relatively large and the maximum pressing amount of the operation unit 404 is also reduced.

  (X) The effect button 125 may be configured as shown in FIGS. FIG. 52 is a schematic cross-sectional view showing the effect button 125 when the interlocking member 1410 is extended. FIG. 53 is a schematic cross-sectional view showing the effect button 125 when the interlocking member 1410 contracts.

  52 and 53, the effect button 125 includes a main body 1401 fixed to the front frame set 14, an upper board 1402 on which light emitting means L1, L2, and L3 (L3 is not shown) are mounted, and an upper board 1402. A lower substrate 1403 disposed opposite to the upper substrate 1402 below, an operation unit 1404 made of a transparent material and covering the upper portion of the upper substrate 1402, a motor 1405 for rotating the upper substrate 1402, and a motor 1405 are mounted. An intermediate body 1406, a first coil spring 1407 that biases the intermediate body 1406 upward, a second coil spring 1408 that biases the operation section 1404 downward, and an operation detection switch 1409 that detects the operation of the operation section 1404 And an interlocking member 1410 for interlocking the operation unit 1404 with the displacement of the upper substrate 1402.

(Intermediate 1406)
The intermediate body 1406 is formed in a substantially disk shape, and protrudes upward from the base portion 1471 so as to surround the motor installation portion 1472 and a base portion 1471 in which a motor installation portion 1472 that fits the lower portion of the motor 1405 is formed at the center. , A support wall portion 1474 that supports the outer peripheral portion of the lower substrate 1403 at a position spaced apart from the base portion 1471 by a predetermined distance, and a first spring housing portion 1477 that supports the upper portion of the first coil spring 1407. . The motor installation portion 1472 is formed so as to protrude downward from the lower surface of the base portion 1471. The first spring accommodating portion 1477 is a bottomed concave portion formed on the lower surface of the base portion 1471, and the base portion 1471. A plurality (for example, four) are provided at equal positions around the central portion of each. The upper part of the first coil spring 1407 is inserted inside the spring accommodating portion 1433, thereby supporting the upper part of the first coil spring 1407.

(Main body 1401)
The main body 1401 includes a base plate 1411 that constitutes the bottom surface of the effect button 125 and a substantially cylindrical frame 1421 that is configured separately from the base plate 1411.

  The base plate 1411 includes a bottom wall portion 1412 configured in a substantially disk shape and a first spring support portion 1415 that supports a lower portion of the first coil spring 1407. An installation hole 1413 into which the motor installation part 1472 of the intermediate body 1406 can be inserted is formed in the center part of the bottom wall part 1412. In the assembled state of the production button 125, the motor installation portion 1472 penetrates the bottom wall portion 1412 vertically through the installation hole 1413. In addition, the installation hole 1413 is formed in a quadrangular shape, and when the intermediate body 1406 is displaced up and down relative to the main body part 1401, the square box-shaped motor installation part 1472 and the inner peripheral surface of the installation hole 1413 are separated from each other. It comes in sliding contact. Thereby, the rotational displacement of the intermediate body 1406 with respect to the main body 1401 is restricted.

  The bottom wall portion 1412 is provided with a rubber cushion member 1414 at a position facing the base portion 1471 of the intermediate body 1406. Thereby, the impact when the intermediate body 1406 collides with the bottom wall portion 1412 of the main body 1401 can be reduced, and adverse effects on the motor 1405, the upper substrate 1402, the lower substrate 1403, and the like can be suppressed. .

  The first spring support portion 1415 is a substantially cylindrical protrusion that protrudes upward from the base portion 1471, and a plurality of (for example, a plurality of first spring accommodating portions 1477 provided on the base portion 1471 of the intermediate body 1406 (for example, 4) provided. The lower portion of the first coil spring 1407 is inserted into the first spring support portion 1415, thereby supporting the lower portion of the first coil spring 1407. That is, both ends of the first coil spring 1407 are supported by the first spring support portion 1415 and the first spring housing portion 1477 so that the first coil spring 1407 is interposed between the base plate 1411 and the intermediate body 1406. By doing so, the intermediate body 1406 is biased upward. In a state where the operation unit 1404 is not operated, the base portion 1471 of the intermediate body 1406 and the bottom wall portion 1412 (cushion member 1414) of the base plate 1411 are separated vertically by the biasing force of the first coil spring 1407. It has become a state. Although described later in detail, the urging force of the first coil spring 1407 is configured to act on the operation unit 1404 via the intermediate body 1406 and the like.

  The frame body 1421 includes a cylindrical base portion 1422 that extends in the vertical direction, an annular edge wall portion 1423 that is provided so as to close the periphery of the opening on the upper side of the base portion 1422, and an outer surface from the outer peripheral surface of the base portion 1422. And a second spring accommodating portion 1426 that supports the upper portion of the second coil spring 1408. A mounting hole 1425 is formed in the mounting piece 1424 so as to penetrate vertically. Then, by aligning the mounting hole 1425 and the screw hole (not shown) formed in the front frame set 14 (the lower plate unit constituting the lower plate 15) and fixing the screw, the effect button 125 is attached to the front frame. It is attached to the set 14.

  The second spring accommodating portion 1426 is a cylindrical portion that protrudes downward from the lower surface of the edge wall portion 1423, and a plurality of the second spring accommodating portions 1426 are arranged at equal positions around the center portion of the opening formed on the inner peripheral side of the edge wall portion 1423. For example, three) are provided. The upper part of the second coil spring 1408 is inserted inside the second spring accommodating portion 1426, thereby supporting the upper part of the second coil spring 1408.

  The outer peripheral portion of the bottom wall portion 1412 of the base plate 1411 has a stepped shape, and the base plate 1411 is assembled to the frame body 1421 so as to close the lower opening of the frame body 1421 (base portion 1422). When attached, the lower portion of the frame body 1421 (base portion 1422) is supported at the stepped portion. Further, screw fixing portions 1418 protruding upward are provided on the outer peripheral portion of the bottom wall portion 1412 at predetermined intervals (for example, five) along the circumferential direction. The screw fixing portion 1418 is formed with a screw hole 1418a penetrating along the centrifugal direction of the bottom wall portion 1412. Then, after assembling the base plate 1411 and the frame body 1421, the screw hole 1418 a and the fixing hole 1427 formed in the frame body 1421 (base portion 1422) are aligned and fixed by screws. 1421 is attached to the base plate 1411 to constitute a main body 1401.

(Operation unit 1404)
The operation unit 1404 is provided on a cylindrical peripheral wall portion 1431 extending in the vertical direction, a pressing portion 1432 that closes an opening on the upper side of the peripheral wall portion 1431, and an outer peripheral surface of the peripheral wall portion 1431. And a second spring support portion 1433 that supports the lower portion. The operation part 1404 is installed in a state where the peripheral wall part 1431 penetrates the edge wall part 1423 of the frame body 1421 up and down, and the pressing part 1432 protrudes upward from the frame body 1421. Further, the lower edge portion of the peripheral wall portion 1431 and the portion of the base portion 1471 of the intermediate body 1406 that are on the outer peripheral side of the support wall portion 1474 are configured to be able to contact each other.

  The second spring support portion 1433 includes a support base 1434 that protrudes outward from an intermediate position in the vertical direction of the peripheral wall portion 1431, and a support protrusion 1435 that protrudes upward from the upper surface of the support base 1434. A plurality (for example, three) are provided corresponding to the plurality of second spring accommodating portions 1426 provided on the edge wall portion 1423. The lower portion of the second coil spring 1408 is inserted into the second spring support portion 1433 (support protrusion 1435), and thereby the lower portion of the second coil spring 1408 is supported. That is, both ends of the second coil spring 1408 are supported by the second spring support portion 1433 and the second spring accommodating portion 1426 so that the second coil spring 1408 is interposed between the frame body 1421 and the operation portion 1404. By doing so, the operation unit 1404 is urged downward. In addition, the support base 1434 of the second spring support portion 1433 is substantially in contact with the inner peripheral surface of the base portion 1422 of the frame body 1421, and the operation portion 1404 moves up and down relative to the main body portion 1401. In this case, the support 1434 and the base 1422 are in sliding contact.

  Further, the inner surface of the peripheral wall portion 1431 of the operation unit 1404 is substantially in contact with the outer peripheral surface of the support wall portion 1474 of the intermediate body 1406, and the operation unit 1404 is displaced up and down relative to the intermediate body 1406. The peripheral wall portion 1431 and the support wall portion 1474 are in sliding contact with each other. Furthermore, although illustration is omitted, a guide protrusion that protrudes toward the inner periphery is provided on the inner surface side of the peripheral wall portion 1431, and a guide slit through which the guide protrusion can be inserted is provided in the support wall portion 1474. Is formed. When the intermediate body 1406 and the operation unit 1404 are assembled, the guide protrusion is inserted inside the guide slit, thereby guiding the relative displacement of the operation unit 1404 in the vertical direction with respect to the intermediate body 1406. Therefore, the rotational displacement of the operation unit 1404 with respect to the intermediate body 1406 is restricted.

  The operation portion 1404 can be displaced upward to a position where the second spring accommodating portion 1426 and the second spring support portion 1433 (support base 1434) come into contact with each other, and the base portion 1471 of the intermediate body 1406 and the base The plate 1411 can be displaced downward to a position where it comes into contact with the cushion member 1414.

  In addition, the first coil spring 1407 has a stronger urging force (elastic force) than the second coil spring 1408, and the total number of first coil springs 1407 mounted on the effect button 125 is the second coil spring. It is more than the total of 1408. As a result, even when the weight of the operation unit 1404 and the intermediate body 1406 on which the motor 1405 supported by the first coil spring 1407, the upper substrate 1402, the lower substrate 1403, and the like are added, the operation unit 1404 is pushed down. The required force is configured to be larger than the force required when lifting the operation unit 1404.

  However, the first coil spring 1407 is configured to lift the intermediate body 1406 until the second spring support portion 1433 and the second spring accommodating portion 1426 come into contact with each other against the urging force of the second coil spring 1408. However, the operation unit 1404 is in a tension state at an intermediate position where it can be displaced both upward and downward by the first coil spring 1407 and the second coil spring 1408. Even if the second coil spring 1408 is removed, the second spring accommodating portion 1426 and the second spring support portion 1433 may be separated from each other vertically, or the second coil spring 1408 may be separated. The second spring accommodating portion 1426 and the second spring supporting portion 1433 may be separated vertically by pressing and contracting the first coil spring 1407 with the urging force.

  Note that when the pressing portion 1432 of the operating portion 1404 is pressed, the first coil spring 1407 contracts, and the operating portion 1404 (pressing portion) until the base portion 1471 of the intermediate body 1406 and the cushion member 1414 of the base plate 1411 come into contact with each other. 1432) is displaced in a direction (downward) in which the main body 1401 (edge wall 1423) is immersed. At this time, the second coil spring 1408 extends in a tracking manner so that the second coil spring 1408 does not come out of the second spring accommodating portion 1426. Further, when the operation of the pressing portion 1432 is released (when the hand is released from the operation portion 1404), the first coil spring 1407 is extended, and the operation portion 1404 is displaced in a direction protruding from the main body portion 1401 to return to the original state. .

(Operation detection switch 1409)
The operation detection switch 1409 is electrically connected to the operation side terminal portion 1438 provided on the outer peripheral surface of the base portion 1471 of the intermediate body 1406 and the input / output port 554 of the sub-control device 262, and the bottom wall portion of the base plate 1411. 1412 and a base-side terminal portion 1439 provided at 1412. When the operation unit 1404 is not pressed, the operation side terminal unit 1438 and the base side terminal unit 1439 are separated from each other. When the operation unit 1404 is pressed, the operation side terminal unit 1438 and the base side terminal unit 1439 are separated. Are in contact with each other. When the operation side terminal portion 1438 and the base side terminal portion 1439 are in contact with each other, the circuit including the operation side terminal portion 1438 and the base side terminal portion 1439 is energized, and the operation of the operation portion 1404 is detected. ing. The configuration of the operation detection switch 1409 is not particularly limited, and for example, the operation of the operation unit 1404 may be detected using an optical sensor or the like.

  Note that the position of the operation unit 1404 when the pressing unit 1432 is pressed and the operation-side terminal unit 1438 and the base-side terminal unit 1439 are in contact corresponds to the operation position, and the pressing unit 1432 is not pressed. The position when the operation side terminal portion 1438 and the base side terminal portion 1439 are not in contact corresponds to the non-operation position.

(Upper board 1402, lower board 1403, support bracket 1451)
Since the upper substrate 1402, the lower substrate 1403, and the support fitting 1451 have the same configuration as the upper substrate 402, the lower substrate 403, and the support fitting 451 in the above embodiment, description thereof is omitted. The parts of the upper substrate 1402 and the lower substrate 1403 will be described using the same member names as those of the upper substrate 402 and the lower substrate 403 in the above embodiment. In this embodiment, the upper substrate 1402 is connected to the rotating shaft 1461 of the motor 1405 via an interlocking member 1410 described later in detail, and the upper substrate 1402 rotates when the motor 1405 is driven. . Further, an interlocking member 1410 described later in detail is inserted into the insertion hole 1441 of the lower substrate 1403. That is, the driving force of the motor 1405 is not transmitted to the lower substrate 1403, and the lower substrate 1403 is provided so as not to be displaced with respect to the intermediate body 1406.

(Motor 1405)
The rotating shaft 1461 of the motor 1405 has a substantially D-shaped cross section at the tip. The rotation shaft 1461 is connected to the upper substrate 1402 via an interlocking member 1410 described in detail later, and when the motor 1405 is driven, the upper substrate 1402 is rotationally displaced. The motor 1405 has a built-in encoder capable of detecting the rotational phase of the rotating shaft 1461. Therefore, the rotational phase of the upper substrate 1402 can be adjusted by driving the motor 1405 based on the detection information of the encoder.

(Interlocking member 1410)
In this embodiment, an interlocking member 1410 for interlocking the motor 1405, the upper substrate 1402, and the operation unit 1404 is provided. Hereinafter, the interlocking member 1410 will be described with reference to the drawings. 54A is a schematic cross-sectional view showing the member to be transmitted 1486, and FIG. 54B is a schematic cross-sectional view showing the transmission member 1481.

  The interlocking member 1410 is provided on a substantially rod-shaped transmission member 1481 attached to the upper substrate 1402 in a state of penetrating a shaft hole 1447 formed in the central portion of the upper substrate 1402 and a pressed portion 1432 of the operation unit 1404. And a transmission member 1486.

  As shown in FIG. 54B and the like, the transmission member 1481 has a connection portion 1482 connected to the rotation shaft 1461 of the motor 1405, and an attachment portion 1484 that is positioned above the connection portion 1482 and fixed to the upper substrate 1402. And a transmission portion 1485 that protrudes upward from the mounting portion 1484. The connection portion 1482 and the attachment portion 1484 are made of resin. The transmission portion 1485 is formed of a metal member that is insert-molded so that a part thereof is embedded in the attachment portion 1484 when the connection portion 1482 and the attachment portion 1484 are formed.

  The connecting portion 1482 has a connecting recess 1483 that opens downward and into which the tip of the rotating shaft 1461 of the motor 1405 can be inserted (fitted). Further, as described above, the tip of the rotating shaft 1461 of the motor 1405 has a substantially D-shaped cross section, and the shape of the connection recess 1483 is a shape corresponding thereto.

  The attachment portion 1484 is formed with a screw hole 1484 a penetrating in a direction orthogonal to the longitudinal direction of the transmission member 1481. On the other hand, the upper substrate 1402 is provided with a cylindrical fixed wall portion 1448 that protrudes downward from the peripheral edge portion of the shaft hole 1447 so as to surround the shaft hole 1447. Fixed holes 1448a are formed to face each other. Then, the transmission member 1481 is inserted into the shaft hole 1447 of the upper substrate 1402, and the fixing hole 1448 a of the fixed wall portion 1448 and the screw hole 1484 a of the mounting portion 1484 are aligned and screw-fixed, whereby the transmission member 1481 is Attached to the substrate 1402.

  The attachment portion 1484 has a smaller diameter than the connection portion 1482, and a step is formed at the boundary between the attachment portion 1484 and the connection portion 1482. When the transmission member 1481 is inserted into the shaft hole 1447 from the lower side of the upper substrate 1402, the step comes into contact with the lower edge portion of the fixed wall portion 1448, and the transmission member 1481 is positioned with respect to the upper substrate 1402.

  The transmission portion 1485 is configured in a substantially cylindrical shape, and a male screw is formed on the outer peripheral surface thereof. It should be noted that, in a state where the transmission member 1481 is attached to the upper substrate 1402, the lower end portion of the portion of the attachment portion 1484 where the metal member is embedded is positioned below the upper surface of the upper substrate 1402. In this example, the connection portion 1482 and the attachment portion 1484 are made of resin and the transmission portion 1485 is made of metal. However, the entire transmission member 1481 may be made of metal.

  As shown in FIG. 54A, the transmitted member 1486 includes a cylindrical tubular portion 1487 and a connecting projection 1488 protruding upward from the tubular portion 1487. On the inner peripheral surface of the cylindrical portion 1487, a female screw that can be screwed with a male screw formed in the transmission portion 1485 of the transmission member 1481 is formed. In addition, a screw hole 1488a is formed in the connecting protrusion 1488 so as to penetrate in a direction orthogonal to the longitudinal direction of the transmitted member 1486. On the other hand, the pressing portion 1432 of the operation portion 1404 is provided with a cylindrical mounting wall portion 1436 that protrudes downward at a position facing the central portion (shaft hole 1447) of the upper substrate 1402, and the mounting wall portion. A pair of mounting holes 1436a are formed in the 1436 so as to face each other. Then, the connecting projection 1488 of the transmitted member 1486 is inserted inside the mounting wall 1436, and the mounting hole 1436a of the fixed wall and the screw hole 1488a of the connecting projection 1488 are aligned and fixed by screws. A transmitted member 1486 is attached to the operation unit 1404.

  In the assembled state of the production button 125, the transmission portion 1485 of the transmission member 1481 is inserted into the cylindrical portion 1487 of the transmitted member 1486. When the upper substrate 1402 rotates in a certain direction (for example, the clockwise direction in FIG. 8A) in a state where the transmission portion 1485 and the cylindrical portion 1487 are screwed together, the transmission portion 1485 is shown in FIG. Relatively move in the direction of exiting the cylindrical portion 1487, and the screwing range between the transmission portion 1485 and the cylindrical portion 1487 is shortened. That is, the interlocking member 1410 extends, and the pressing portion 1432 of the operation unit 1404 and the upper substrate 1402 are separated from each other.

  On the other hand, when the upper substrate 1402 rotates in the opposite direction (for example, the counterclockwise direction in FIG. 8A), as shown in FIG. 53, the transmission portion 1485 is inserted into the cylindrical portion 1487 (the transmission portion 1485). In the direction in which the screwing range between the cylindrical portion 1487 and the cylindrical portion 1487 is increased), and the screwing range between the transmission portion 1485 and the cylindrical portion 1487 is increased. That is, the interlocking member 1410 contracts, and the pressing portion 1432 of the operation unit 1404 and the upper substrate 1402 gradually approach each other. Note that, regardless of whether the interlocking member 1410 is in the extended state or the contracted state, the pressing portion 1432 of the operation portion 1404 that is not operated protrudes upward from the main body portion 1401. Therefore, regardless of whether the interlocking member 1410 is in the extended state or the contracted state, the pressing portion 1432 is pressed to move the operation portion 1404 downward (the operation side terminal portion 1438 and the base side terminal portion of the operation detection switch 1409). 1439 to the point of contact with 1439).

  It should be noted that a female screw is not formed at the lower end portion of the cylindrical portion 1487 of the transmitted member 1486, and the upper substrate 1402 rotates to transmit the transmitting member 1481 (transmitting portion 1485) and the transmitted member 1486 (cylindrical portion 1487). Even if the screwed state is released, the distal end portion of the transmission portion 1485 is positioned inside the tubular portion 1487. For this reason, even if the transmission part 1485 is completely removed from the cylindrical part 1487 and the transmission part 1485 and the cylindrical part 1487 are misaligned, and the motor 1405 (upper board 1402) is rotated in the opposite direction, the transmission is performed. It is possible to avoid a situation in which the portion 1485 and the tubular portion 1487 cannot be screwed together. Therefore, even in the state where the screwed state of the transmission portion 1485 and the cylindrical portion 1487 is released, the motor 1405 (upper substrate 1402) can be moved in the same direction (the direction in which the transmission member 481 and the transmitted member 486 are not screwed). ) Can be rotated.

  In addition, as described above, since the operation unit 1404 is biased downward by the second coil spring 1408, even if the transmission unit 1485 and the cylindrical unit 1487 are in the non-screwed state, The upper end portion of the formed male screw and the lower end portion of the female screw formed on the cylindrical portion 1487 are in pressure contact (the cylindrical portion 1487 is pressed against the transmission portion 1485). Therefore, when the transmission portion 1485 and the cylindrical portion 1487 are in the non-screwed state, the upper substrate 1402 is rotated to securely screw the transmission portion 1485 and the cylindrical portion 1487 and contract the interlocking member 1410. be able to. Further, since the transmission portion 1485 and the cylindrical portion 1487 are in contact with each other, the biasing force of the first coil spring 1407 that biases the intermediate body 1406 upward is transmitted via the motor 1405 and the transmission member 1481. 1404 will also be affected. In addition, when the pressing portion 1432 is pressed, the stress acts on the intermediate body 1406 via the interlocking member 1410, and the intermediate body 1406 is displaced downward together with the operating portion 1404.

  Furthermore, as described above, in this example, the biasing force of the first coil spring 1407 is stronger than the biasing force of the second coil spring 1408, and when the interlocking member 1410 expands and contracts, the intermediate body 1406 is almost displaced. Without this, the operation unit 1404 is displaced up and down. More specifically, when the interlocking member 1410 is in a contracted state, the operation unit 1404 is held at an intermediate position that can be displaced both upward and downward by the first coil spring 1407 and the second coil spring 1408. Further, when the interlocking member 1410 is extended, the first coil spring 1407 is hardly contracted, the operation unit 1404 is relatively displaced upward, and the second coil spring 1408 is contracted in a follow-up manner. . Then, when the interlocking member 1410 is in the most extended state (the transmission portion 1485 and the cylindrical portion 1487 are not screwed together), the second spring accommodating portion 1426 and the second spring support portion 1433 (support base 1434) Is substantially in contact.

(Contact detection switch 1491)
The effect button 125 of this example is provided with a contact detection switch 1491 that detects that the lower edge portion of the operation unit 1404 (the peripheral wall portion 1431) and the base portion 1471 of the intermediate body 1406 are substantially in contact. Yes. The contact detection switch 1491 is electrically connected to the upper terminal portion 1492 provided at the lower edge portion of the operation portion 1404 (peripheral wall portion 1431) and the input / output port 554 of the sub-control device 262. The lower terminal portion 1493 provided in the portion 1471 is configured. When the interlocking member 1410 contracts, the upper terminal portion 1492 and the lower terminal portion 1493 come into contact with each other, and when the interlocking member 1410 extends, the upper terminal portion 1492 and the lower terminal portion 1493 are separated from each other in the vertical direction. When the upper terminal portion 1492 and the lower terminal portion 1493 are in contact with each other, the circuit including the upper terminal portion 1492 and the lower terminal portion 1493 is energized, and the lower edge portion of the operation portion 1404 and the base portion 1471 of the intermediate body 1406 Is substantially in contact (the pressing portion 1432 of the operation unit 1404 and the upper substrate 1402 are in the closest state: the state shown in FIG. 53). In this embodiment, the detection signal of the contact detection switch 1491 is taken into account when stopping the driving of the motor 1405 when the interlocking member 1410 is contracted, and the separated upper terminal portion 1492 and lower terminal portion 1493 The motor 1405 is stopped when it touches. This prevents the motor 1405 and the interlocking member 1410 from being damaged due to the motor 1405 being driven even after the lower edge portion of the peripheral wall portion 1431 and the base portion 1471 come into contact with each other. it can.

  Now, in this embodiment, a third coil spring 1501 is provided that can urge the operation unit 1404 upward only when the interlocking member 1410 is contracted. More specifically, the base plate 1411 is provided with a substantially cylindrical third spring support portion 1502 that protrudes upward from the bottom wall portion 1412 at a position facing the edge wall portion 1423 of the frame body 1421 in the vertical direction. Yes. A plurality of (for example, three) third spring support portions 1502 are provided at equal positions around the center portion of the bottom wall portion 1412. The lower portion of the third coil spring 1501 is supported by the third spring support portion 1502 being inserted into the lower portion of the third coil spring 1501.

  Further, on the outer surface side of the operation portion 1404 (the peripheral wall portion 1431), a third spring accommodating portion 1503 for supporting the upper portion of the third coil spring 1501 is provided corresponding to each of the plurality of third spring support portions 1502. Yes. Each of the third spring accommodating portions 1503 has a substantially cylindrical shape that extends vertically from the intermediate position in the vertical direction of the peripheral wall portion 1431 to the lower end portion, with the lower portion opened and the upper portion closed. The upper part of the third coil spring 1501 is supported by the third coil spring 1501 being inserted into the third spring accommodating part 1503.

  In this example, when the interlocking member 1410 is in the extended state (the state shown in FIG. 52), the third coil spring 1501 is the bottom surface of the third spring accommodating portion 1503 (upper wall portion: hereinafter referred to as the top wall portion 1505). ), And when the operation unit 1404 is operated to contact the operation-side terminal unit 1438 and the base-side terminal unit 1439 of the operation detection switch 1409 (when the operation unit 1404 is displaced to the operation position), The upper end portion of the third coil spring 1501 and the top wall portion 1505 are in contact with each other. On the other hand, when the interlocking member 1410 is in the contracted state (the state shown in FIG. 53), the upper end portion of the third coil spring 1501 and the top wall portion 1505 are in contact (pressure contact) even when the operation portion 1404 is not operated. It is configured. The first coil spring 1407 is always in contact (pressure contact) with the top wall portion 1477a of the first spring accommodating portion 1477.

  For this reason, when the interlocking member 1410 is in the extended state, the operation unit 1404 is displaced from the non-operation position to the operation position (the intermediate body 1406 is displaced downward together with the operation unit 1404, and the operation side terminal unit 1438 and the base are Until the side terminal portion 1439 comes into contact and detection by the operation detection switch 1409 is performed), it is biased upward only by the first coil spring 1407. On the other hand, when the interlocking member 1410 is in the contracted state, the operation unit 1404 is biased upward by the first coil spring 1407 and the third coil spring 1501 until it is displaced from the non-operation position to the operation position. Will be. Therefore, when the interlocking member 1410 is in the contracted state, the urging force acting upward on the operation unit 1404 is larger before the detection by the operation detection switch 1409 is performed than when the interlocking member 1410 is in the extended state. Thus, a larger force is required to press the pressing portion 1432 and displace the operation portion 1404 to the lower operation position. In this embodiment, the third coil spring 1501, the third spring support portion 1502, and the third spring housing portion 1503 constitute spring force adjusting means.

  In this embodiment, as shown in FIG. 52, the interlocking member 1410 is normally extended (the transmission member 1481 and the transmitted member 1486 are not screwed together). When the upper substrate 1402 is rotated without changing the force required to operate the operation unit 1404, and the color is changed while rotating the light emitting units L1 to L3, the transmission member 481 and the transmitted member 486 The upper substrate 1402 is rotated in such a direction that does not screw. When the force required for operating the operation unit 1404 is increased, the upper substrate 1402 is rotated in the direction in which the transmission member 481 and the transmitted member 486 are screwed together, and the contact detection switch 1491 detects Based on the information, the motor 1405 is stopped. As a result, as shown in FIG. 53, the top wall 1505 of the third spring housing 1503 and the third coil spring 1501 are in contact with each other even when the operation unit 1404 is not operated.

  As described above, according to this embodiment, the magnitude of the force required to operate the operation unit 1404 can be changed by driving the motor 1405. Therefore, it is not necessary to provide a driving unit (adjustment motor 474) for changing the force required for operating the operation unit 1404 separately from the motor 1405, and the configuration and control can be simplified, the cost can be reduced, and the like.

  (Y) Although not specifically mentioned in the above embodiment, when the operation unit 404 is pressed while the button is valid and the upper substrate 402 is rotating, the decorative symbol display device 42 or the like is used. Of the effect displays that are derived, an effect display that is less likely to be selected or not selected when the upper substrate 402 is not rotating may be derived. In this case, the effect button 125 becomes a novel aspect as described above, and the user is surprised. Further, when the effect button is operated, an unusual effect display is derived, which gives an unprecedented sense of excitement and satisfaction. Can be improved dramatically. The “effect display with a low possibility of being selected” includes, for example, an effect display that teaches that the occurrence of the big hit state is confirmed.

[Appendix]
The technical idea that can be grasped from the above embodiment will be described below.

One type of gaming machine is a pachinko machine. In the pachinko machine, for example, whether or not a big hit state is generated when a game ball enters a starting ball entering means provided in a game area where a game ball launched by a launching device is guided is determined. . When the winning / losing lottery is won, a big hit state advantageous to the player is generated, and the player can acquire a lot of game values (prize balls).

In recent years, there have been provided operation means such as buttons for changing display contents on a liquid crystal display device or playing a corresponding sound from a speaker by a player's operation (for example, Patent Document 1). reference).

By adopting a configuration in which the operation of the player's operation means is reflected in the effect as in Patent Document 1, a monotonous feeling in the game can be suppressed. However, the effects performed in response to the operation of the operation means are display effects in the liquid crystal display device, sound flowing from the speaker, and the like. In other words, even if the operation means is provided, whether or not to improve the interest of the player depends on the production performed by other members according to the operation of the operation means, and providing the operation means directly improves the interest. It was not related to.

Note that the above-described problem is not limited to pachinko machines, but also applies to other gaming machines such as slot machines.

The present invention has been made to solve the above-described problems and the like, and an object thereof is to provide a gaming machine provided with a novel operation means.

Means 1. An operation unit that is provided on a front surface portion of the gaming machine and that displaces between an operation position when operated (pressing) and a non-operation position when not operated;
Urging means for urging the operation portion toward the non-operation position;
An operation means comprising an operation detection means for detecting that the operation unit has been displaced to the operation position,
The operating means can change the magnitude of the stress acting on the operating portion when the operating portion at the non-operating position is (pressed) to displace the operating portion toward the operating position. A gaming machine comprising an adjusting means.

  According to the means 1, the stress that acts on the operation portion when the operation portion is displaced toward the operation position can be changed by the adjusting means. For this reason, it is possible to obtain a novel operation means in which the feeling when the player operates the operation unit changes. Therefore, by mounting the operation means on the gaming machine, it is possible to enhance the production effect and further enhance the interest for the player.

  In addition, since a novel phenomenon as described above (change in feel when operating the operation unit) can occur in the operation means that the player has been less interested in, conventionally, the player has a fresh surprise, Interested in the operation means itself. As a result, a dramatic improvement in interest can be achieved. Furthermore, it is possible to perform an effect (such as suggestion or teaching of various game states) using a change in feel when the operation unit is operated, and the possibility of an effect that can be performed on the gaming machine can be expanded.

  As the operation means, for example, in a pachinko machine, for example, a display button for changing the display content of a predetermined display device or a predetermined sound depending on the operation can be cited. For example, a bet button or the like for betting a credited medal.

  Mean 2. The adjusting means includes an electromagnet provided on one side of the main body of the operating means and the operating part, and a magnet provided at a position facing the electromagnet with respect to the other side, and the magnetic force of the electromagnet The means 1 is characterized in that the stress acting on the operating portion changes when the operating portion at the non-operating position is operated to displace the operating portion toward the operating position. The gaming machine described.

  According to the means 2, by changing the magnetic force of the electromagnet, for example, when the magnetic force of the electromagnet is strong (the repulsive force acting between the electromagnet and the magnet is large), it becomes difficult to displace the operation portion to the operation position side. When the electromagnet has a weak magnetic force (or no magnetic force), the magnitude of the force required to displace the operating portion to the operating position changes, for example, the operating portion is easily displaced to the operating position. Therefore, it is possible to obtain a novel operation means such that the feel when the player operates the operation unit due to the change in the force required to operate the operation means. Played reliably. Note that the main body of the operating means may be fixed to a mounted portion provided on the front surface of the gaming machine.

Means 3. The adjusting means is
A movable body relatively displaceable with respect to the operation unit;
Drive means capable of displacing the movable body,
As the movable body is displaced by the driving of the driving means, the magnitude of the force required to operate the operating unit at the non-operating position to displace the operating unit toward the operating position changes. The gaming machine according to means 1, characterized in that:

  According to the means 3, by displacing the movable body, for example, when the movable body is at a predetermined position, it is easy to displace the operation unit to the operation position side, and when the movable body is at another position, the movable body is The magnitude of the force required to displace the operation unit toward the operation position changes such that it is more difficult to displace the operation unit toward the operation position than when it is at the predetermined position. Therefore, it is possible to obtain a novel operation means such that the feel when the player operates the operation unit due to the change in the force required to operate the operation means. Played reliably.

  In addition, even if the movable body is displaced, the displacement direction of the operation unit that is displaced between the non-operation position and the operation position may be the same. Further, even if the movable body is displaced, the appearance of the operation means does not change (the operation unit at the non-operation position is not displaced). In this case, the position of the movable body cannot be grasped only by visually recognizing the appearance of the operation means. For this reason, it is possible to prevent a situation in which the interest in operating the operation unit is diminished due to the fact that the touch when the operation unit is displaced toward the operation position can be grasped in advance. can do.

Means 4. A plurality of the urging means are provided, and each urging means is constituted by an elastic body, and one end side of the urging means is in pressure contact with the operation part, so that the non-operation position side with respect to the operation part It is the composition which can give the urging power which goes to,
A part of the plurality of urging means has the other end side supported by the movable body,
The operation means is configured such that when the movable body is displaced, the one end side of the urging means supported by the movable body is pressed against the operation portion when the operation portion is displaced toward the operation position. The gaming machine according to claim 3, wherein the state changes between a possible state and a non-contactable state.

  According to the means 4, when the movable body is displaced, the number of urging means capable of applying the urging force toward the non-operation position side with respect to the operation part is increased or decreased, and the operation part is displaced to the operation position side. The magnitude of the force acting on the operation unit changes. Therefore, it is possible to obtain an operation means that can change the magnitude of the force required to operate the operation portion while suppressing the complication of the configuration, and the operational effect of the means 3 is reliably exhibited.

Means 5. The movable body is configured to be slidable with respect to the operation portion that is displaced from the non-operation position to the operation position,
4. A gaming machine according to claim 3, wherein a frictional force acting between the movable body and the operation portion is changed by the displacement of the movable body.

  According to the means 5, the magnitude | size of the force required when displacing an operation part to the operation position side can be changed by changing the frictional force which a movable body displaces and a movable body and an operation part change. it can. Therefore, it is possible to obtain an operation means that reliably achieves the operational effects of the means 1 while suppressing the complication of the configuration.

  It should be noted that at least one of a portion of the movable body that comes into contact with the operation portion and a portion of the operation portion that comes into contact with the movable body may have flexibility (elasticity). In this case, it is possible to suppress a situation in which the movable body and the operation unit are damaged due to the sliding contact between the movable body and the operation unit.

Note that the movable body and the operation unit may always be in contact with each other regardless of the position of the movable body, or the movable body and the operation unit are separated from each other. It may be configured to change the state to the state to be performed. When the former configuration is adopted, the stress acting on the operation unit is changed by changing the degree of pressure contact between the movable body and the operation unit. Moreover, it is desirable to provide the movable body with a lip-shaped protrusion that has flexibility and protrudes toward the operation section. In this case, it is possible to suppress a situation in which the displacement of the operation unit is significantly inhibited by pressing the movable body against the operation unit.

Note that “the movable body may be configured to be displaceable in a direction intersecting the displacement direction of the operation unit”. In this case, it is possible to reduce the amount of displacement of the movable body when the movable body is accurately displaced so that the function and effect of the means 2 can be surely achieved, thereby increasing the size of the operation means and the complexity of the configuration. Can be suppressed.

  In addition, both the movable body of the means 5 and the movable body of the means 4 are mounted on one operating means, or both the movable body of the means 5 and the adjusting means of the means 2 are mounted. It is good to do. In this case, even if the displacement amount of each movable body is reduced, the force required for operation of the operation unit can be changed relatively large. Therefore, it is possible to apply an emphasis on the difference in touch when operating the operation unit while suppressing an increase in the size of the operation means.

Means 6. The movable body includes a protrusion that protrudes toward the operation portion, a contact position where the protrusion slides against the operation portion that is displaced from the non-operation position to the operation position, and the operation portion. It is configured to displace between a non-contact position that does not contact,
6. The gaming machine according to claim 5, wherein the operation portion has a concavo-convex shape at a portion that contacts the protrusion of the movable body.

  According to the means 6, when operating the operation portion, the protrusion of the movable body is in sliding contact with the protrusion of the operation portion, and the protrusion is in contact with the recess of the operation portion (or the protrusion is the operation portion. The frictional force that acts between the movable body and the operation unit changes when it is located at a position corresponding to the recess of the control unit. For this reason, the feeling (response) when pushing the operating portion into the operating position changes in the middle (a crisp feel), and the fun is further improved.

  The concave / convex shape is configured, for example, by forming a concave portion or a convex portion on the side surface of the operation portion. Further, the number of the concave portions and the convex portions is not particularly limited, and it is sufficient that at least one concave portion (for example, a substantially arc-shaped concave portion) or convex portion (for example, a lip-shaped or hemispherical convex portion) is formed. . Moreover, it is desirable that the sliding contact surface with the operation portion among the protrusions of the movable body is an inclined surface inclined toward the operation position side. Further, it is desirable that the surface that can be brought into contact with the protrusion of the movable body in the displacement direction of the operation portion among the uneven portions of the operation portion is an inclined surface that is inclined toward the non-operation position side. In the case of adopting with these configurations, it is possible to suppress a situation in which the displacement of the operation unit toward the operation position side is restricted due to the contact between the protrusion and the operation unit (uneven portion) in the displacement direction of the operation unit. Can do.

  Mean 7 The operation unit is configured to be displaceable between the operation position detected by the operation detection unit and the non-operation position not detected by the operation detection unit regardless of the position of the movable body. A gaming machine according to any one of means 3 to 6, characterized in that:

  According to the means 7, the function as the operation means can be maintained even if the magnitude of the force required to displace the operation portion toward the operation position changes. Therefore, for example, even though the player has operated the operation unit, the operation of the operation unit is not detected by the operation detection means, and he can enjoy the effect that should have been originally derived by operating the operation unit. It is possible to avoid the situation where it becomes impossible.

  Means 8. The operation means includes a displacement amount adjusting means for changing a distance (maximum displacement amount) by which the operation section at the non-operation position can be displaced toward the operation position by operating the operation section. A gaming machine according to any one of means 1 to 7, characterized in that:

  According to the means 8, it is possible to obtain a novel operation means in which the maximum displacement amount of the operation portion (the amount by which the operation portion is pushed toward the operation position) is changed by the displacement amount adjustment means. By mounting on, it is possible to enhance the production effect and further enhance the interest for the player.

  Means 9. The displacement amount adjusting means includes an electromagnet provided on one side of the main body part and the operation part of the operating means, and a magnet provided at a position facing the electromagnet with respect to the other side, and the electromagnet The distance (maximum displacement amount) by which the operation unit can be displaced to the operation position side by operating the operation unit at the non-operation position is changed by changing the magnetic force of A gaming machine according to claim 8.

  According to the means 9, by changing the magnetic force of the electromagnet, for example, when the magnetic force of the electromagnet is strong (the repulsive force acting between the electromagnet and the magnet is large), the maximum displacement amount of the operation unit is reduced, When the magnetic force is weak (or there is no magnetic force), the amount by which the operation unit is pushed to the operation position side can be changed such that the maximum displacement amount of the operation unit is increased. Therefore, it is possible to obtain an operating means that exhibits the operational effects of the means 8.

  The displacement amount adjusting means includes a main body side magnet that is slidable with respect to the main body portion of the operation means, and an operation side magnet that is provided at a position facing the main body side in the operation portion. The operation unit is operated by operating the operation unit in the non-operation position by displacing the main body side magnet and changing a relative position between the main body side magnet and the operation side magnet. The distance (maximum displacement amount) that can be displaced toward the position side may be changed. By adopting this configuration, it is possible to obtain an operating means that exhibits the operational effects of the means 8.

  It should be noted that the force required for operation of the operation means is changed by changing the magnetic force of the electromagnet of the means 9 or by displacing the main body side magnet provided so as to be slidable with respect to the main body of the operation means of the above embodiment. It can also be changed. In this case, the adjustment means and the displacement amount adjustment means can be shared, and the configuration can be simplified.

Means 10. The displacement amount adjusting means is
A restricting member configured to be relatively displaceable with respect to the operation portion and capable of contacting the operation portion;
A regulating body driving means capable of displacing the regulating member,
A distance that allows the operation part to be displaced toward the operation position side by operating the operation part at the non-operation position as the restriction member is displaced by driving the restriction body drive means ( The gaming machine according to means 8, wherein the maximum displacement amount is changed.

  According to the means 10, for example, when the restricting member is at a predetermined position, the operation unit can be displaced to the operation position side by a predetermined distance, but when the restricting member is at another position, the operation unit is moved to the operation position side. The maximum amount of displacement of the operating portion at the non-operating position toward the operating position changes, for example, only by a distance shorter than the predetermined distance. For this reason, the operation means in which the effect of the said means 8 is show | played can be obtained reliably.

  It should be noted that “a buffer member made of an elastic material may be provided in a portion of the regulating member that contacts the operating portion or a portion of the operating portion that contacts the regulating member”. In this case, it is possible to mitigate the impact when the regulating member collides with the operation portion, and it is possible to reduce the stress acting on the player and the operation means during the collision. Further, it may be configured such that even if the operation unit is operated, the operation unit cannot be displaced to the operation position side at all.

  In addition, when the operation part is displaced to the operation position side irrespective of the position of the restriction member, the restriction member and the operation part may be in a contact state, or the operation part may be placed on the operation position side. The state may be changed between a state in which the restricting member and the operation unit are in contact with each other and a state in which the restriction member and the operation unit are not in contact with each other even if the operation unit is displaced to the operation position side. When the former configuration is adopted, the restricting member may be configured to be displaceable along the displacement direction of the operation unit. Incidentally, when the latter configuration is adopted, “the restriction member is in contact with the operation portion when the operation portion at the non-operation position is operated and the operation portion is displaced to the operation position side, It is configured to be displaceable between a restriction position that restricts further displacement of the operation portion toward the operation position side and a permissible position that does not contact the operation portion when the operation portion is displaced. It is good also as.

Means 11. The operation means is configured to be relatively displaceable with respect to the operation portion, and includes a restriction member that can contact the operation portion, and a restriction body drive means that can displace the restriction member. With means,
A distance that allows the operation part to be displaced toward the operation position side by operating the operation part at the non-operation position as the restriction member is displaced by driving the restriction body drive means ( The maximum displacement amount) changes,
The restriction member is constituted by the movable body,
The regulating body driving means is constituted by the driving means,
The movable body includes a contact portion that can contact the operation portion in a displacement direction of the operation portion, and
The allowable position where the contact portion does not contact the operation portion, and the contact portion comes into contact with the operated operation portion, and the operation portion is further displaced toward the operation position side. The gaming machine according to any one of means 3 to 7, wherein the gaming machine is configured to be displaceable between a restriction position to be restricted.

  According to the means 11, the adjusting means and the displacement amount adjusting means are made common, and it is necessary to provide the displacement amount adjusting means (the regulating member and the regulating body driving means) separately from the adjusting means (the movable body and the driving means). Therefore, the configuration can be simplified.

Means 12. The operation means is configured to be relatively displaceable with respect to the operation portion, and includes a restriction member that can contact the operation portion, and a restriction body drive means that can displace the restriction member. With means,
A distance that allows the operation part to be displaced toward the operation position side by operating the operation part at the non-operation position as the restriction member is displaced by driving the restriction body drive means ( The maximum displacement amount) changes,
The operation means includes a support portion that supports the operation portion when the operation portion is displaced to the operation position.
The restriction member is constituted by the movable body,
The regulating body driving means is constituted by the driving means,
The movable body includes a contact portion that can contact the operation portion in a displacement direction of the operation portion, and
The regulation position where the contact portion is positioned closer to the operation portion than the support portion, and the contact portion is at the same height as the support portion in the displacement direction of the operation portion, or the contact portion Is configured to be displaceable between an allowable position located on the opposite side of the operation unit across the support unit,
When the movable body is in the restriction position, the operation portion and the contact portion abut before the operation portion abuts on the support portion, and the operation position side beyond the operation portion Displacement to the
8. The gaming machine according to any one of means 3 to 7, wherein when the movable body is in the allowable position, displacement of the operation portion until it comes into contact with the support portion is allowed.

  According to the means 12, the same operational effects as those of the means 11 are basically obtained. Further, since the movable body (regulating member) is displaced along the displacement direction of the operating means, the operating portion is operated, and the operating portion and the movable body (regulating member) are in pressure contact with each other. It is easy to displace the movable body (regulation member) at the restriction position to the allowable position side. For this reason, it is possible to change the state from a state where the operation unit cannot be pushed all the way into the state where the operation unit can be pushed into the back without imposing so much burden on the operation means, and it is possible to smoothly produce an effect using such a state change. It can be carried out.

  Means 13. The operation unit is configured to be displaceable between the operation position detected by the operation detection unit and the non-operation position not detected by the operation detection unit regardless of the position of the regulating member. A gaming machine according to any one of means 10 to 12, characterized in that the gaming machine is provided.

  According to the means 13, even if the maximum displacement amount of the operation unit changes, the function as the operation means can be maintained.

  In addition, “the operation detecting means includes an operation side terminal portion provided in the operation portion and a moving body side terminal portion provided in the movable body, and the operation side terminal portion and the moving body side terminal portion are in contact with each other. Thereby, it is good also as detecting the displacement to the said operation position of the said operation part. In this case, even when the maximum displacement amount of the operation unit changes relatively large, it is possible to reliably obtain an operation unit that exhibits the effect of the unit 13.

  Means 14. A display unit having a display unit, and a display effect such that a specific display object displayed on the display unit shows a predetermined behavior (change) based on an operation of the operation unit; After the mode of the specific display object (form, size, material, etc.) displayed on the display unit or the operation of the operation means for the specific display object displayed on the display unit is performed When the adjusting means is controlled according to the behavior (change) (the displacement amount of the movable body is determined), and the operation unit at the non-operation position is operated to displace the operation unit to the operation position side. The game machine according to any one of means 1 to 13, wherein a stress acting on the operation portion changes.

  According to the means 14, the operation of the operation means and the behavior of the specific display object displayed on the display unit can be linked, and the performance can be improved. In addition, the adjusting means is controlled according to the specific display object displayed on the display unit (the movable body is displaced), and the feel when operating the operation unit changes according to the specific display object. On the other hand, the user can be made to feel as if he / she actually touched a specific display object displayed on the display unit. Therefore, as compared with a configuration in which the feeling when the operating means is simply pushed is changed, a dramatic improvement in interest can be achieved.

  As for the above means 8 to 13, “the mode of the specific display object displayed on the display unit, or the operation unit of the specific display object displayed on the display unit has been operated. Depending on the later behavior, the stress acting on the operating portion when the operating portion at the non-operating position is operated to displace the operating portion toward the operating position changes, and the non-operating position is The distance (maximum displacement amount) at which the operation unit can be displaced toward the operation position by operating the certain operation unit may be changed.

  Means 15. 15. The gaming machine according to claim 14, wherein a displacement direction of the operation portion of the operation means matches a direction in which the specific display object operates based on an operation of the operation portion.

  According to the means 15, it becomes easy for the player to empathize with the display effect that a specific display object displayed on the display unit operates by operating the operation means. Therefore, the function and effect of the means 14 can be achieved more reliably.

  Means 16. 16. The means 15 according to claim 15, wherein at least the operation portion of the operation means is provided so as to be tiltable and displaceable with respect to the gaming machine main body, and the displacement direction of the operation portion changes in accordance with the tilt displacement. Gaming machine.

  According to the means 16, the displacement direction of the operation unit, that is, the operation direction of the operation unit can be changed. For this reason, the operation direction of the specific display object displayed on a display part can be made into multiple directions instead of one direction, and the diversification of a display effect can be aimed at. The entire operation means may be provided so as to be tiltable with respect to the gaming machine main body.

Means 17. The operation means includes
A light-emitting means that is provided opposite to the operation unit and includes a plurality of light-emitting units having different emission colors;
A light emitter block on which the light emitting means is mounted and is relatively displaceable with respect to the operation section;
A light emitter driving means capable of displacing the light emitter block;
The operation unit has translucency at least in part.
As the light emitter block is displaced by the driving of the light emitter driving means, the light emitting portions to be turned on among the plurality of light emitting portions having different emission colors or a combination thereof change. A gaming machine according to any one of means 1 to 16.

  According to the means 17, the light emitting means itself is displaced by displacing the light emitter block to which the light emitting means is fixed. Thereby, the light part of the operation means visually recognized via an operation part can be displaced. Furthermore, with the displacement of the light emitter block, the light emitting section to be turned on or a combination thereof changes. That is, the light emission color of the light emitting means can be changed, and the color of the light portion of the operation means visually recognized via the operation portion can be changed. For this reason, it is possible to obtain an operating means from which a novel mode is derived in which the color of the operating means visually recognized via the operating section changes while moving. Therefore, by mounting the operation means on the gaming machine, it is possible to enhance the decoration effect and the production effect and further improve the interest for the player.

  In addition, for example, when a plurality of light emitting units are arranged adjacent to each other so that the light unit of the operation unit is displaced, and the light emitting units are sequentially turned on / off, there is a concern that the control may be complicated. Is done. On the other hand, according to this means, since the light emitting means itself is displaced, a large number of light emitting parts are required to displace the light part, and lighting control of the operation means is complicated. It is possible to avoid such a situation. Furthermore, the movement of the displacing light part can be made smoother.

  Note that the number of light emitting units that are turned on at a time is not particularly limited, and the light emitting color of the light emitting means is changed by changing the light emitting units that are turned on or a combination thereof. Just do it. In addition, the number of light-emitting means that displace itself with the displacement of the light-emitting body block is not particularly limited, and a configuration in which a plurality of light portions are displaced can be derived. In addition, the displacement speed of the light emitter block may not be constant, and may be configured to be switchable to another stage. In this case, the production effect can be improved. Further, when the light emitter driving means is driven by the operation of the operating means, the player can find the fun of operating the operating means itself, and the interest is improved. be able to.

  Further, in the operation means, a mode in which the color changes while the light unit moves and the operation unit is displaced is derived. Therefore, the operation unit has such a mode compared to a configuration in which the same mode is merely visually recognized. It is possible to dramatically improve the player's superiority and satisfaction by operating the operation means.

  It should be noted that “if the light emitter driving means is driven and the light emitter block is displaced, the operation unit is operated and displaced to the operation position. It is good also as deriving | presenting the production | presentation display with a low possibility that it will not be selected in the state where the said light-emitting body block is not displaced among the production | presentation display which is not selected. In this case, the operation means become novel as described above, and it is surprising, and furthermore, when the operation means is operated, an unusual presentation display is derived, so that an unprecedented sense of excitement and satisfaction is given. Can be improved dramatically. The “effect display with a low possibility of being selected” includes, for example, an effect display that teaches that the occurrence of the big hit state is confirmed.

Means 18. The operation means includes
A light-emitting means that is provided opposite to the operation unit and includes a plurality of light-emitting units having different emission colors;
A light emitter block on which the light emitting means is mounted and is relatively displaceable with respect to the operation section;
A light emitter driving means capable of displacing the light emitter block;
The operation unit has translucency at least in part.
The adjusting means includes interlocking means interlocking with the light emitter driving means,
As the light emitter block is displaced by the driving of the light emitter driving means, the light emitting portion to be turned on among the plurality of light emitting portions having different emission colors or a combination thereof is changed.
Along with the displacement of the interlocking means, the magnitude of the stress acting on the operating portion changes when the operating portion at the non-operating position is operated to displace the operating portion toward the operating position. A gaming machine according to any one of the means 1 to 16.

  According to the means 18, the same operation effect as the means 17 is obtained basically. Further, it is possible to avoid a situation in which the control of the light emitter block and the control of the adjusting means must be performed separately, and the control can be simplified.

Means 19. The operation means includes
A light-emitting means that is provided opposite to the operation unit and includes a plurality of light-emitting units having different emission colors;
A light emitter block on which the light emitting means is mounted and is relatively displaceable with respect to the operation section;
A light emitter driving means capable of displacing the light emitter block;
The operation unit has translucency at least in part.
The adjusting means is
A movable body relatively displaceable with respect to the operation unit;
Interlocking means for interlocking the movable body with the driving of the light emitter driving means,
As the light emitter block is displaced by the driving of the light emitter driving means, the light emitting portion to be turned on among the plurality of light emitting portions having different emission colors or a combination thereof is changed.
Along with the displacement of the movable body, the magnitude of a force required to operate the operation unit at the non-operation position to displace the operation unit to the operation position side is changed. A gaming machine according to any one of means 1 to 16.

  According to the means 19, the same operational effects as the means 3 and 17 are basically obtained. Further, by driving the light emitter driving means for rotating the light emitter block, the driving force of the light emitter driving means is transmitted to the movable body via the interlocking means, and the movable body is displaced. For this reason, it is not necessary to provide a driving means for displacing the movable body separately from the light emitter driving means for displacing the light emitter block (in this means, the driving means of the means 3 is constituted by the light emitter driving means. ) The light emitter block and the adjusting means can be operated by one drive source. Therefore, simplification of configuration and control, cost reduction, and the like can be achieved.

Means 20. The interlocking means includes an original gear fixed to a rotating shaft of a motor constituting the light emitter driving means, a transmission member that rotates in conjunction with the original gear, and an interlocking part provided on the movable body. Prepared,
One of the transmission member and the interlocking portion is provided with a protrusion formed with a male screw, and the other is provided with a recess formed with a female screw that can be screwed to the male screw, and the one is inserted into the other The transmission member and the interlocking portion can be screwed together,
20. The gaming machine according to claim 19, wherein when the light emitter driving means is driven, a screwing range between the transmission member and the interlocking portion becomes longer and shorter, and the movable body is displaced.

  According to the means 20, when the light emitter driving means is driven and the light emitter block rotates in one direction, the screwing range between the transmission member and the interlocking portion is shortened, and when the light emitter block is rotated in the opposite direction, the transmission member And the screwing range between the connecting portions becomes longer. As a result, the movable body can be displaced in accordance with the driving of the driving means, and an operating means in which the effect of the means 19 can be obtained.

  Note that another gear may be interposed between the original gear and the transmission member. In this case, the original gear and the transmission member can be made small, and the internal space of the operation means can be used more effectively while suppressing the increase in size of the operation means.

Means 21. A plurality of the urging means are provided, and each urging means is constituted by an elastic body, and one end side of the urging means is in pressure contact with the operation part, so that the non-operation position side with respect to the operation part It is a configuration that can give the urging force toward
A part of the plurality of urging means has the other end side supported by the movable body,
The operation means is configured such that when the movable body is displaced, the one end side of the urging means supported by the movable body is pressed against the operation portion when the operation portion is displaced toward the operation position. It is configured to change between a possible state and a non-contactable state,
The interlocking portion provided in the movable body is urged to the side pressed against the transmission member by the urging means,
21. The gaming machine according to claim 20, wherein a male screw and a female screw are not formed at a tip portion on at least one side of the transmission member and the interlocking portion.

  According to the means 21, the same effect as the above means 4 is exhibited. Further, according to this means, since the male screw and the female screw are not formed at the tip of at least one side of the transmission member and the interlocking portion, the light emitter is released until the screwed state between the transmission member and the interlocking portion is released. Even when the driving means is driven, one end portion of the transmission member and the interlocking portion where the male screw is formed is inserted inside the recess where the other female screw is formed. For this reason, it is assumed that one of the transmission member and the interlocking portion in which the male screw is formed is completely pulled out of the other recess and the tip portions of both are displaced, and the light emitter driving means is rotated in the opposite direction. In addition, it is possible to prevent a situation in which the transmission member and the interlocking portion cannot be screwed together. In addition, since the transmission member and the interlocking portion that are in the non-screwing state can be set to the screwing state again in this way, the light emitter driving means after the screwing state between the transmission member and the interlocking portion is released. The (light emitter block) can be rotated in the same direction without hindrance.

  Further, since the interlocking portion is biased by the biasing means, even if the transmission member and the interlocking portion are in a non-screwed state, the male screw formed on one of the transmission member and the interlocking portion is formed on the other. Since the female screw thus made is in a pressure-contact state, the transmission member and the interlocking portion that are in the non-screwed state can be reliably screwed.

Means 22. The interlocking means is provided on a movable member provided to be relatively displaceable with respect to the light emitter block rotating by driving a motor constituting the light emitter drive means, and provided at one end of the movable member, and the light emitter block A fixed terminal portion provided so as not to be relatively displaceable with respect to the movable terminal portion capable of contacting,
The movable member is configured to be displaceable between a contact position where the fixed terminal portion and the movable terminal portion are in contact with each other and a non-contact position where the fixed terminal portion and the movable terminal portion are separated from each other,
Connected to the other end of the movable member is movable urging means (coil spring and support base) for urging the movable member to one side of the contact position or the non-contact position.
The operation means includes
A movable body relatively displaceable with respect to the operation unit;
Driving means that is electrically connected to the fixed terminal portion and the movable terminal portion and can displace the movable body;
As the movable body is displaced by the driving of the driving means, the magnitude of the force required to operate the operating unit at the non-operating position to displace the operating unit toward the operating position changes. A configuration to
When the motor is driven, the movable member resists the urging force of the movable urging means by the centrifugal force acting on the movable member as the light emitter block rotates, and the contact position or the non-contact position is While displacing from one to the other,
19. The means 18 is characterized in that the driving means operates based on switching of the contact state between the fixed terminal portion and the movable terminal portion, and the movable body is displaced in accordance with the operation of the driving means. Game machines.

  According to the means 22, when the light emitter block rotates, the movable member is displaced by the centrifugal force acting on the movable member, and the contact state (on / off) between the fixed terminal portion and the movable terminal portion is switched. Furthermore, the driving means operates based on the switching of the contact state between the fixed terminal portion and the movable terminal portion, and accordingly, the movable body is displaced. Therefore, it is possible to obtain an operating means in which the magnitude of the force required for operating the operating portion changes as the light emitter driving means is driven. Further, when the light emitter block rotates, the driving means automatically operates and the movable body is displaced, so that it is not necessary to control the driving means by the control means, and the operational effect of the means 18 is reliably achieved. The

Means 23. The operation means includes
A light-emitting means that is provided opposite to the operation unit and includes a plurality of light-emitting units having different emission colors;
A light emitter block on which the light emitting means is mounted and is relatively displaceable with respect to the operation section;
Light emitter driving means capable of displacing the light emitter block;
A displacement amount adjusting means for changing a distance (maximum displacement amount) by which the operation portion can be displaced toward the operation position by operating the operation portion at the non-operation position;
The operation unit has translucency at least in part.
The displacement amount adjusting means includes interlocking means interlocking with the light emitter driving means,
As the light emitter block is displaced by the driving of the light emitter driving means, the light emitting portion to be turned on among the plurality of light emitting portions having different emission colors or a combination thereof is changed.
Along with the displacement of the interlocking means, the distance (maximum displacement amount) at which the operation unit can be displaced toward the operation position side by operating the operation unit at the non-operation position changes. A gaming machine according to any one of means 1 to 16.

  According to the means 23, basically the same effects as the above means 8 and 17 can be obtained. Further, it is possible to avoid a situation in which the control of the light emitter block and the control of the displacement adjustment means must be performed separately, and the control can be simplified.

Means 24. The displacement amount adjusting means is
It is configured to be able to come into contact with the operation portion, and includes a regulating member that interlocks with the interlocking means,
A distance (maximum displacement) by which the operation part can be displaced toward the operation position by operating the operation part at the non-operation position as the regulating member is displaced by the drive of the drive means. The gaming machine according to means 23, characterized in that the amount) changes.

  According to the means 24, basically the same effect as the means 10 is obtained. Further, the restricting member is displaced by driving the light emitter driving means for rotating the light emitter block. For this reason, it is not necessary to provide driving means for displacing the regulating member separately from the luminous body driving means for displacing the luminous body block (in this means 24, the regulating body driving means of means 10 is constituted by the luminous body driving means. The light emitter block and the displacement adjusting means can be operated by one drive source. Therefore, simplification of configuration and control, cost reduction, and the like can be achieved.

Means 25. A plurality of light-emitting side terminal portions that are provided in the light-emitting body block and are electrically connected to different light-emitting portions among the light-emitting portions; A main body side terminal portion provided corresponding to the terminal portion individually,
The light emitting side terminal portion is in contact with the corresponding main body side terminal portion, whereby the light emitting portion electrically connected to the light emitting side terminal portion can be turned on,
When the light emitter block is displaced, the light emitting side terminal portion is relatively displaced with respect to the main body side terminal portion, and among the plurality of light emitting side terminal portions, the corresponding main body side terminal portion is in contact with the main body side terminal portion. The gaming machine according to any one of means 17 to 24, wherein a combination of the light emitting side terminal portions is changed.

  According to the means 25, when the light emitter block is displaced, the light emitting side terminal portion itself moves, and the light emitting side terminal portion comes into contact with the corresponding main body side terminal portion or is not in contact therewith. That is, the light emitting side terminal portion and the main body side terminal portion have a switching function, and the energization state (lighting / extinguishing) of each light emitting portion is incidentally switched with the displacement of the light emitter block. Therefore, it is possible to change the emission color of the light emitting means simply by displacing the light emitter block. For example, a displacement detection means for detecting the displacement of the light emitter block is provided separately, and based on detection information of the displacement detection means. Therefore, the configuration and control can be simplified compared to the case where the energization state of each light emitting unit is individually switched and controlled.

  In addition, for example, in order to displace the light part of the operation means without displacing the light emitting means, a rotatable reflecting member is provided around the light emitting means so that the light reflected by the reflecting member is visible. In addition to the control for displacing the reflecting member, the control for changing the emission color of the light emitting means is required. On the other hand, this means simply controls the displacement of the light emitter block (drive control of the light emitter drive means), so that the light emission means itself is displaced and the light emission color of the light emission means is also changed. Can be achieved.

  In addition, when the light emitting unit and a predetermined power source are connected by wiring such as a connector cable, if the light emitter block is displaced, the wiring connected to the light emitting means is entangled and the displacement of the light emitter block is hindered. There is a risk that. Specifically, when the light emitter block is rotationally displaced, the wiring connected to the light emitting unit is twisted with the rotation of the light emitter block, so that the rotation of the light emitter block is restricted and the twist is restored. In addition, it is necessary to reversely rotate the light emitter block at predetermined intervals. In addition, when the light emitter block is slid, the wiring connected to the light emitting portion is pulled out in accordance with the displacement of the light emitter block in the predetermined direction, and the light emitter block is displaced in the direction opposite to the predetermined direction. The wiring may interfere with the light emitter block. In contrast, according to this means, the light emitting side terminal portion and the main body side terminal portion are electrically connectable (contactable), but since the so-called wiring connection is not made, the light emitter block is displaced. Even if it makes it, wiring does not get tangled. Therefore, the light emitter block can be displaced without hindrance.

  In addition, the light emission part and the light emission side terminal part do not need to correspond 1 to 1, for example, it is good also as one light emission side terminal part being electrically connected with two light emission parts. Note that, regardless of the position of the light emitter block, at least one of the plurality of light emitting side terminal portions may be in contact with the corresponding main body side terminal portion. In this case, it is possible to always keep the light emitting means lit. However, it is necessary that at least one of the plurality of light emitting side terminal portions is always in contact with the corresponding main body side terminal portion regardless of the position of the light emitter block. For example, when the light emitter block performs periodic motion based on driving of the light emitter driving means, at least one of the plurality of light emitting side terminal portions corresponds to any phase of the light emitter block. The main body side terminal portion is in contact with the main body side terminal portion, while the phase of the light emitter block is in one cycle, all the light emitting side terminal portions are in contact with the corresponding main body side terminal portion. A configuration may be adopted in which the state is switched to a state where it is not.

  Note that, “a connection block provided with the main body side terminal portion and an attachment means for attaching the light emitter block to the connection block so as to be relatively displaceable, and the light emitter block and the connection block are attached by the attachment means. It is good also as "and being unitized." In this case, the light emitting side terminal portion and the main body side terminal portion can be reliably positioned.

Means 26. The light emitter block performs periodic motion based on driving of the light emitter drive means, and one of the light emission side terminal portion and the main body side terminal portion is extended along the displacement direction of the light emitter block. The other is provided so as to be in contact with the one,
At least one of the plurality of light emitting side terminal portions corresponds to the main body side according to the phase of the light emitter block during one cycle of the light emitter block displaced by driving of the light emitter drive means. The gaming machine according to means 25, wherein the gaming machine is switched between a state in contact with the terminal portion and a state in which the terminal portion is not in contact.

  According to the means 26, one of the light emitting side terminal portion and the main body side terminal portion is extended along the other track that is relatively displaced with respect to the one when the light emitter block is displaced. As a result, the light emitting unit can be displaced by a predetermined distance while the lighting unit is lit while adopting a relatively simple configuration. State.

  In addition, when said one side is extended without interruption corresponding to the whole region of the track | truck drawn by said other during one cycle of a light-emitting body block, a corresponding light emission part can be always made into a lighting state. On the other hand, when the one side is extended corresponding to a part of the orbit drawn by the other side during one cycle of the light emitter block, the corresponding light emitting unit is temporarily displayed during one cycle of the light emitter block. Is turned off. That is, in this means 26, since there is at least one light emitting section that switches between the lighting state and the extinguishing state during one cycle of the light emitter block, a plurality of light emission colors having different emission colors during one cycle of the light emitter block. Among the light emitting units, the combination of the light emitting units that are turned on is changed, whereby the emission color of the light emitting means is changed. In addition, since the light emitting unit to be turned on is switched by the one extending pattern, the light emitting unit to be turned on is determined in advance according to the phase of the light emitter block, and the light emitting means is periodically the same. The emission color will be derived.

  Means 27. 27. The gaming machine according to any one of means 17 to 26, wherein the light emitter block is configured to be rotatable and the light emitter block is rotated by driving the light emitter drive means.

  According to the means 27, compared with the case where the light emitter block is reciprocated, the light portion of the operation means can be displaced more greatly while suppressing the enlargement of the operation means.

  Means 28. The gaming machine according to any one of means 17 to 27, wherein the light emitter driving means includes an encoder.

  According to the means 28, the position (phase) of the light emitter block can be adjusted by driving the light emitter drive means based on the detection information of the encoder, and the light emitting means can be adjusted by adjusting the position of the light emitter block. The light emission color (the color of the light part of the operating means) can be set to a desired color. Thereby, it is possible to associate the situation of the gaming machine (gaming state, production, etc.) with the light mode of the operation means, and depending on the light mode of the operation means, the effect effect by the operation means can be enhanced or the operation means On the other hand, it is possible to provide a teaching function for teaching the player the situation of the gaming machine.

  The basic configuration of various gaming machines to which the above means are applied is shown below.

  A. The gaming machine in each of the above means is a ball game machine. As a more detailed mode example, “an operation means (game ball launching handle) operated by a player, a launching means (shot motor, etc.) for playing and launching a game ball based on an operation of the operation means, A ball ball game machine including a game area where a game ball is guided and each ball entry means (general prize opening, variable prize winning device, operation opening, etc.) arranged in the game area.

  B. The gaming machine in each of the above means is a bullet ball gaming machine having a gaming area extending in a substantially vertical direction. As a more detailed mode example, “an operation means (game ball launching handle) operated by a player, a launching means (shot motor, etc.) for playing and launching a game ball based on an operation of the operation means, The game balls are guided and extended along a substantially vertical direction (for example, the game area is constituted by a game board surface), and each ball entry means (general winning mouth, And a ball game machine configured to be able to visually recognize the behavior of a game ball flowing down the game area.

  C. The gaming machine in each of the above means or each of the above ball game machines is a pachinko machine or a gaming machine equivalent to a pachinko machine.

  D. The gaming machine in each of the above means is a revolving type gaming machine such as a slot machine. As a more detailed mode example, “a discriminating information string (a symbol string; specifically a rotating body such as a reel or a belt with a symbol) made up of a plurality of identification information (symbols) is variably displayed (specifically, a reel Variable display means (specifically, a rotating unit such as a reel unit) that stops and displays the identification information sequence after the rotation of the starting information means. The identification information (symbol) starts to fluctuate and the identification information (symbol) fluctuates due to the operation of the stop operation means (specifically, the stop button). A spinning-type gaming machine configured to be given game value on condition that the information is specific identification information.

  E. The gaming machine in each of the above means is a gaming machine of a type in which a slot machine and a pachinko machine are fused (especially a gaming machine of a slot machine specification that uses a gaming ball as a gaming medium). As a more detailed mode example, “a discriminating information string (a symbol string; specifically a rotating body such as a reel or a belt with a symbol) made up of a plurality of identification information (symbols) is variably displayed (specifically, a reel Variable display means (specifically, a rotating unit such as a reel unit) that stops and displays the identification information sequence after the rotation of the starting information means. The identification information (symbol) starts to fluctuate and the identification information (symbol) fluctuates due to the operation of the stop operation means (specifically, the stop button). The game value is provided on the condition that the information is specific identification information, and a ball receiving tray (upper plate or the like) is further provided, taking-in means for taking the game ball from the ball receiving tray, and the ball receiving tray Payout means for paying out game balls Comprising a configuration and gaming machine "and the like as starting condition of the game is satisfied by the game ball is captured by the capturing means.

It is a front view which shows the pachinko machine in one Embodiment. It is a perspective view which shows a pachinko machine. It is a perspective view which shows the state which open | released the inner frame and the front frame set. It is a front view which shows structures, such as an inner frame and a game board. It is a rear view which shows the structure of a pachinko machine. It is a perspective view which shows the state which open | released the inner frame, the back pack unit, etc. FIG. It is sectional drawing which shows an effect button. (A) is a top view of the upper substrate, (b) is a top view of the lower substrate, and (c) is a cross-sectional view of the support fitting. It is a schematic cross section which shows a spring force adjustment means. It is sectional drawing which shows an effect button. It is an explanatory diagram for explaining the circuit configuration of the effect button. It is a block diagram which shows the main electrical structures of a pachinko machine. It is explanatory drawing which shows the outline | summary of the various counters used for game control. It is a flowchart which shows the main process by the main controller. It is a flowchart which shows the normal process by the main controller. It is a flowchart which shows a timer interruption process. It is a flowchart which shows a NMI interruption process. It is a flowchart which shows a start winning process. It is a flowchart which shows a 2nd opportunity corresponding | compatible opening passage process. It is a flowchart which shows a 1st display control process. It is a flowchart which shows a fluctuation | variation display setting process. It is a flowchart which shows discrimination | determination information setting processing. (A), (b) is explanatory drawing which shows various table structures. It is a flowchart which shows a variable winning apparatus control process. It is a flowchart which shows a 2nd display control process. It is a flowchart which shows an opportunity corresponding unit control process. It is a flowchart which shows a reception interruption process. It is a flowchart which shows the main process of the payout control apparatus. It is a flowchart which shows a timer interruption process. It is a flowchart which shows a command determination process. It is a flowchart which shows the normal process of a sub control apparatus. It is explanatory drawing which shows the outline | summary of the various counters used for the determination of a decoration design. It is a flowchart which shows the update process of a counter. It is a flowchart which shows a button setting process. It is a flowchart which shows a color change process. It is a flowchart which shows an operation adjustment process. (A) is a bottom view which shows the upper board | substrate in another embodiment, (b) is a top view which shows the lower board | substrate in another embodiment. It is a schematic cross section which shows a part of effect button in another embodiment. It is a flowchart which shows the button setting process in another embodiment. It is sectional drawing of the production button in another embodiment. It is sectional drawing of the production button in another embodiment. It is sectional drawing which shows the spring force adjustment means in another embodiment. It is sectional drawing of the production button in another embodiment. It is sectional drawing of the production button in another embodiment. It is sectional drawing which shows the spring force adjustment means in another embodiment. It is sectional drawing of the production button in another embodiment. It is sectional drawing of the production button in another embodiment. It is sectional drawing of the production button in another embodiment. (A) is a side view which shows the movable body in another embodiment, (b) is a side view which shows the transmission member in another embodiment. It is sectional drawing of the production button in another embodiment. It is sectional drawing of the production button in another embodiment. It is sectional drawing of the production button in another embodiment. It is sectional drawing of the production button in another embodiment. (A) is a schematic cross section which shows the to-be-transmitted member in another embodiment, (b) is a schematic cross section which shows the transmission member in another embodiment.

DESCRIPTION OF SYMBOLS 10 ... Pachinko machine, 14 ... Front frame set as front part, 42 ... Decorative design display device, 43 ... Special display device, 125 ... Production button as operation means, 261 ... Main control device, 262 ... Sub control device, 401 DESCRIPTION OF SYMBOLS ... Main part, 402 ... Upper board as light emitter block, 403 ... Lower board, 404 ... Operation part, 405 ... Motor as light emitter drive means, 406 ... Coil spring as biasing means, 407 ... As operation detection means 411 ... base plate, 413 ... base part, 415 ... spring support part, 431 ... peripheral wall part, 432 ... pressing part, 433 ... spring accommodating part, 451 ... support fitting, 471 ... spring force as adjusting means Adjusting means, 473 ... movable body, 474 ... adjusting motor as drive means, 484 ... mount, 485 ... support protrusion, 491 ... contact detection switch, L1, L2, 3 ... light emitting means, R1~R3, G1~G3, B1~B3 ... light-emitting element as a light emitting portion, P1 to P7 ... emitting side terminal portion, Q1 to Q7 ... body-side terminal section.

Claims (1)

An operation unit that is provided on a front surface portion of the gaming machine and is displaced between an operation position when operated and a non-operation position when not operated;
Urging means for urging the operation portion toward the non-operation position;
An operation means comprising an operation detection means for detecting that the operation unit has been displaced to the operation position,
The operation means includes
A movable body relatively displaceable with respect to the operation unit;
Drive means capable of displacing the movable body,
The operation unit is detected by the operation detection unit when the operation unit at the non-operation position is operated to the operation position side as the movable body is displaced by driving of the drive unit. It is configured to be restricted from being displaced to the operation position ,
Comprising lottery means capable of performing lottery on whether or not the displacement of the operation unit is restricted by the movable body;
Even when the displacement of the operation unit is restricted by the movable body, the operation unit is configured to be operable by a predetermined amount when the operation unit is operated with a predetermined operation force. A gaming machine.

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