JP2019111440A - Game machine - Google Patents

Abstract

To provide a game machine capable of preventing player's interest in a game from being decreased.SOLUTION: In a special game state, a performance display is executed with priority given to an overflow performance to be executed when the number of game medium that has passed a big winning port exceeds a predetermined number in each round game where the big winning port can be passed and an acquired number display performance according to the imparted number of a game value which is imparted to a player in the special game state.SELECTED DRAWING: Figure 93

Description

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

  In a gaming machine such as a pachinko gaming machine, the symbol is varied in response to establishment of a variable display start condition such that the gaming ball has won (passed) a predetermined area provided on the gaming board, and the player is There is something which is expressed with the halt feature of the design which fluctuates the result of the decision of whether or not to shift the game state to the special game state which is advantageous for (big hit game state).

  As this type of gaming machine, Patent Document 1 proposes that a point is obtained in response to depression of a button, and the type of the jackpot gaming state is notified according to the obtained point.

JP, 2013-106670, A

  Although the conventional gaming machine as described above can provide various information to the player by the effect, when there are too many types of effect indication executed in the same period, which effect indication indicates what It becomes difficult for the player to grasp whether or not the game is played back, and conversely, there is a risk that the interest of the player for the game will be reduced.

  The present invention has been made in view of the above-described circumstances, and it is an object of the present invention to provide a gaming machine capable of preventing the player's interest in gaming from being reduced.

  In order to achieve the above object, the gaming machine according to the present invention can shift the gaming state to the special game state where the game medium can be moved and the player can be granted a predetermined gaming value Game state transition means (main CPU 101) and effect execution means (sub CPU 201) for executing effects, and the game area is a predetermined area (large winning opening) through which game media can pass in the special game state 418), and the effect execution means determines that the number of game media having passed the predetermined area exceeds at least a predetermined number in at least one period in which the predetermined area can pass in the special game state. A special display (image display of overflow effect) to be executed, and a special display (image display of acquired number display effect) according to the number of game values provided to the player in the special game state. It is possible to execute the specific display and the special display as an image display on the same display device, and when the display positions of the specific display and the special display overlap, the image of the effect to be executed with low priority An image of an effect to be executed with high priority is superimposed and displayed on the front.

  With this configuration, the gaming machine according to the present invention gives the player the content that the effect display represents by giving priority to the effect display of a plurality of types executed in the special game state. Since it is made to grasp easily, it can prevent that the interest of the player to a game falls.

  In the gaming machine according to the present invention, there is provided a gaming area (41) in which gaming media can be moved, and a gaming state transitioning means (in which the gaming state can be shifted to a special gaming state capable of giving a predetermined gaming value to the player) The main CPU 101), effect executing means (sub CPU 201) for executing effects, and a predetermined area (large winning opening 418) through which game media can pass in the special gaming state, the effect executing means at least A specific display (image display of overflow effect) to be executed when game media pass through the predetermined area during the special gaming state and the first condition is satisfied, and the second condition is during the special gaming state When it is established, it is possible to execute special display (image display of the acquired number display effect) according to the game value given to the player, and drawing the specific display and the special display on the same display device. It is performed as a display, and when the display positions of the images of the specific display and the special display overlap, the image of the effect to be executed with high priority is superimposed and displayed on the front of the image of the effect performed with low priority. Have.

  With this configuration, the gaming machine according to the present invention gives the player the content that the effect display represents by giving priority to the effect display of a plurality of types executed in the special game state. Since it is made to grasp easily, it can prevent that the interest of the player to a game falls.

  According to the present invention, it is possible to provide a gaming machine capable of preventing the player's interest in gaming from being lowered.

BRIEF DESCRIPTION OF THE DRAWINGS It is a perspective view which shows the external appearance in the pachinko game machine of the 1st Embodiment of this invention. BRIEF DESCRIPTION OF THE DRAWINGS It is a front view which shows the external appearance in the pachinko game machine of the 1st Embodiment of this invention. FIG. 1 is an exploded perspective view showing an overview of a pachinko gaming machine according to a first embodiment of the present invention. It is a front view showing an outline of a game board in a pachinko gaming machine of a first embodiment of the present invention. It is a disassembled perspective view which shows the component of the distribution apparatus in the pachinko game machine of the 1st Embodiment of this invention. It is a perspective view showing the appearance of a distribution drum concerning a distribution device in a pachinko game machine of a 1st embodiment of the present invention. It is a perspective view which shows the external appearance which attached the 1st cam lock to the distribution drum which concerns on the distribution apparatus in the pachinko game machine of the 1st Embodiment of this invention. BRIEF DESCRIPTION OF THE DRAWINGS It is a front view of the distribution apparatus in the pachinko game machine of the 1st Embodiment of this invention. It is explanatory drawing which shows operation | movement of the distribution apparatus in the pachinko game machine of the 1st Embodiment of this invention. It is explanatory drawing which shows schematic structure of the illumination array in the pachinko game machine of the 1st Embodiment of this invention. It is explanatory drawing which shows the modification of the illumination array in the pachinko game machine of the 1st Embodiment of this invention. FIG. 6 is an explanatory view showing a flow-down path of the game ball in the pachinko gaming machine of the first embodiment of the present invention. FIG. 6 is an explanatory view showing a flow-down path of the game ball in the pachinko gaming machine of the first embodiment of the present invention. It is a figure showing composition of a rear ball passage unit in a pachinko game machine of a 1st embodiment of the present invention. It is a front view in the state where the lower side movable effect member in a pachinko game machine of a 1st embodiment of the present invention was located in a waiting position. It is the disassembled perspective view which looked at the lower side movable presentation member in the pachinko game machine of the 1st Embodiment of this invention from right front. It is the disassembled perspective view which looked at the lower side movable presentation member in the pachinko game machine of the 1st Embodiment of this invention from left rear. It is a rear view which shows the state in which the lower side movable presentation member in the pachinko game machine of the 1st Embodiment of this invention was located in the standby position. It is a rear elevation of the state where the lower side movable effect member in the pachinko game machine of the first embodiment of the present invention is located at the drive position. It is a figure which shows the state which the lower side movable presentation member in the pachinko game machine of the 1st Embodiment of this invention moved to the drive position with respect to the game board. It is a front view of the upper side movable presentation member in the pachinko game machine of the 1st Embodiment of this invention. It is the disassembled perspective view which looked at the upper side movable presentation member in the pachinko game machine of the 1st Embodiment of this invention from right front. It is the disassembled perspective view which looked at the upper side movable presentation member in the pachinko game machine of the 1st Embodiment of this invention from left rear. It is a figure which shows the state which the movable slider in the pachinko game machine of the 1st Embodiment of this invention presses the rib of a gear. It is a figure which shows the state which the base rib in the pachinko game machine of the 1st Embodiment of this invention presses the rib of a gear. It is a front view in the state where the upper side movable effect member in a pachinko game machine of a 1st embodiment of the present invention was located between a waiting position and a drive position. It is a front view in the state where the upper side movable effect member in a pachinko game machine of a 1st embodiment of the present invention was located in a drive position. It is a front view in the state where a movable arm opened in the state where the upper side movable presentation member in a pachinko game machine of a 1st embodiment of the present invention was located in a drive position. It is a figure which shows the state which the upper side movable presentation member in the pachinko game machine of the 1st Embodiment of this invention moved to the drive position with respect to the game board. It is a front view which shows the other aspect of the fixed cage | basket member and movable cage | basket member in the pachinko game machine of the 1st Embodiment of this invention. FIG. 26 is a front view showing a first modified example of the second engaging portion of the movable arm shown in FIG. 25, showing the upper slide base moving from the first movement position to the second movement position. It is a front view which shows the 1st modification of the 2nd engaging part in the movable arm shown in FIG. 25, and is a figure which shows the state which the upper slide base moved to the 2nd movement position. FIG. 26 is a front view showing a second modified example of the second engaging portion of the movable arm shown in FIG. 25, showing the upper slide base moving from the first movement position to the second movement position. It is a front view which shows the 2nd modification of the 2nd engaging part in the movable arm shown in FIG. 25, and is a figure which shows the state which the upper slide base moved to the 2nd movement position. It is a front view showing the state where the right side movable effect member in the pachinko gaming machine of the first embodiment of the present invention has moved to the standby position. It is the disassembled perspective view which looked at the right side movable presentation member in the pachinko game machine of the 1st Embodiment of this invention from right front. It is the disassembled perspective view which looked at the right side movable presentation member in the pachinko game machine of the 1st Embodiment of this invention from left rear. It is a front view which shows the state in which the right side movable presentation member in the pachinko game machine of the 1st Embodiment of this invention was located in the drive position. It is a front view showing the state where the left side movable effect member in a pachinko game machine of a 1st embodiment of the present invention was located in a waiting position. It is the disassembled perspective view which looked at the left side movable presentation member in the pachinko game machine of the 1st Embodiment of this invention from right front. It is the disassembled perspective view which looked at the left side movable presentation member in the pachinko game machine of the 1st Embodiment of this invention from left rear. It is a front view showing the state where the left side movable effect member in a pachinko game machine of a 1st embodiment of the present invention was located in a drive position. It is a figure which shows the state which the right side movable presentation member and the left side movable presentation member in the pachinko game machine of the 1st Embodiment of this invention moved to the drive position with respect to the game board. It is the perspective view which looked at the distribution drum in the 1st modification of the distribution apparatus of the 1st Embodiment of this invention from right front. It is the perspective view which looked at the distribution drum in the 1st modification of the distribution apparatus of the 1st Embodiment of this invention from rear left. It is the perspective view which looked at the distribution drum to which the 1st cam lock in the 1st modification of the distribution apparatus of the 1st Embodiment of this invention was seen from left rear. It is a front view of the distribution drum in the 1st modification of the distribution apparatus of the 1st Embodiment of this invention. FIG. 52 is a front view showing a state in which the distributing drum shown in FIG. 47 is 90 ° out of phase in the direction opposite to the rotating direction. It is the disassembled perspective view which looked at the distribution drum in the 2nd modification of the distribution apparatus of the 1st Embodiment of this invention from left rear. It is a side view of the distributing drum shown in FIG. It is a block diagram showing a control circuit in a pachinko game machine of a 1st embodiment of the present invention. It is a flowchart which shows the control processing performed in the pachinko game machine of the 1st Embodiment of this invention. It is a flowchart which shows the control processing performed in the pachinko game machine of the 1st Embodiment of this invention. It is a flowchart which shows the control processing performed in the pachinko game machine of the 1st Embodiment of this invention. It is a flowchart which shows the control processing performed in the pachinko game machine of the 1st Embodiment of this invention. It is a flowchart which shows the control processing performed in the pachinko game machine of the 1st Embodiment of this invention. It is a flowchart which shows the control processing performed in the pachinko game machine of the 1st Embodiment of this invention. It is a flowchart which shows the control processing performed in the pachinko game machine of the 1st Embodiment of this invention. It is a flowchart which shows the control processing performed in the pachinko game machine of the 1st Embodiment of this invention. It is a flowchart which shows the control processing performed in the pachinko game machine of the 1st Embodiment of this invention. It is a flowchart which shows the control processing performed in the pachinko game machine of the 1st Embodiment of this invention. It is a flowchart which shows the control processing performed in the pachinko game machine of the 1st Embodiment of this invention. It is a flowchart which shows the control processing performed in the pachinko game machine of the 1st Embodiment of this invention. It is a flowchart which shows the control processing performed in the pachinko game machine of the 1st Embodiment of this invention. It is a flowchart which shows the control processing performed in the pachinko game machine of the 1st Embodiment of this invention. It is a flowchart which shows the control processing performed in the pachinko game machine of the 1st Embodiment of this invention. It is a flowchart which shows the control processing performed in the pachinko game machine of the 1st Embodiment of this invention. It is a flowchart which shows the control processing performed in the pachinko game machine of the 1st Embodiment of this invention. It is a flowchart which shows the control processing performed in the pachinko game machine of the 1st Embodiment of this invention. It is a flowchart which shows the control processing performed in the pachinko game machine of the 1st Embodiment of this invention. It is a flowchart which shows the control processing performed in the pachinko game machine of the 1st Embodiment of this invention. It is a flowchart which shows the control processing performed in the pachinko game machine of the 1st Embodiment of this invention. It is a figure which shows the big hit random number determination table in the pachinko game machine of the 1st Embodiment of this invention. It is a figure which shows the big hit symbol random number determination table in the pachinko game machine of the 1st Embodiment of this invention. It is a figure which shows the fluctuation pattern determination table in the pachinko game machine of the 1st Embodiment of this invention. It is a figure which shows the big hit kind determination table in the pachinko game machine of the 1st Embodiment of this invention. It is a figure which shows the presentation table in the pachinko game machine of the 1st Embodiment of this invention. It is a transition diagram of a pre-reading advance notice effect in a pachinko game machine of a 1st embodiment of the present invention. It is a figure which shows the other structure of the pachinko game machine of the 1st Embodiment of this invention. It is a flowchart which shows the control processing performed in the modification of the pachinko game machine of the 1st Embodiment of this invention. It is a flowchart which shows the control processing performed in the modification of the pachinko game machine of the 1st Embodiment of this invention. It is a flowchart which shows the command analysis process performed in the pachinko game machine of the 2nd Embodiment of this invention. It is a flowchart following FIG. It is a flowchart which shows the point provision effect setting process performed in the pachinko gaming machine of the 2nd Embodiment of this invention. It is a flowchart following FIG. It is a flow chart which shows pre-notice notice production setting processing performed in a pachinko game machine of a 2nd embodiment of the present invention. It is a flowchart which shows the prefetch continuation production setting process performed in the pachinko game machine of the 2nd Embodiment of this invention. It is a flowchart which shows the out entrance ball presentation process performed in the pachinko game machine of the 2nd Embodiment of this invention. It is a flowchart which shows the demonstration-in-provision latent notification alert production | generation process performed in the pachinko game machine of the 2nd Embodiment of this invention. It is a flowchart which shows the touch sensor effect process performed in the pachinko game machine of the 2nd Embodiment of this invention. It is a flowchart which shows the touch sensor state control processing performed in the pachinko game machine of the 2nd Embodiment of this invention. It is a flowchart which shows big hit inside production control processing which is executed in the pachinko game machine of the 2nd execution form of this invention. It is a flowchart following FIG. It is a conceptual diagram which shows the 1st change production | presentation selection table referred in the pachinko game machine of the 2nd Embodiment of this invention. It is a conceptual diagram which shows the 2nd change production selection table referred in the pachinko game machine of the 2nd Embodiment of this invention. It is a conceptual diagram which shows the after-touch item selection table referred in the pachinko game machine of the 2nd Embodiment of this invention. It is a conceptual diagram which shows the item selection table before a touch referred in the pachinko game machine of the 2nd Embodiment of this invention. It is a conceptual diagram which shows the prefetch continuous presentation effect table referred in the pachinko game machine of the 2nd Embodiment of this invention. It is a conceptual diagram which shows the latent probability change alerting | reporting table referred in the pachinko game machine of the 2nd Embodiment of this invention. It is a conceptual diagram which shows the reservation series alerting effect selection table referred in the pachinko game machine of the 2nd Embodiment of this invention. It is a conceptual diagram which shows the specific example of the prefetch advance notice production | presentation setting process performed in the pachinko game machine of the 2nd Embodiment of this invention. It is a conceptual diagram which shows the 1st specific example of the prefetch continuous production | presentation setting process performed in the pachinko game machine of the 2nd Embodiment of this invention. It is a conceptual diagram which shows the 2nd specific example of the prefetch continuous production | presentation setting process performed in the pachinko game machine of the 2nd Embodiment of this invention. It is a conceptual diagram which shows the modification of the prefetch continuous rendering table referred in the pachinko game machine of the 2nd Embodiment of this invention. It is a conceptual diagram which shows the 1st specific example of the modification of the prefetch continuous production | presentation setting process performed in the pachinko game machine of the 2nd Embodiment of this invention. It is a conceptual diagram which shows the 2nd specific example of the modification of the prefetch continuous production | presentation setting process performed in the pachinko game machine of the 2nd Embodiment of this invention. FIG. 107 is a conceptual diagram following FIG. 106; It is a 1st conceptual diagram for demonstrating the cancellation of the prefetching performed in the pachinko game machine of the 2nd Embodiment of this invention. It is a 2nd conceptual diagram for demonstrating the cancellation of the prefetching performed in the pachinko game machine of the 2nd Embodiment of this invention. It is a figure which shows the example of the image of the acquisition number display effect displayed in the pachinko game machine of the 2nd Embodiment of this invention. It is a figure which shows the example of the image of the effect of the other hole prize displayed in the pachinko game machine of the 2nd Embodiment of this invention. It is a figure which shows the example of a display of the image of the acquisition number display effect displayed in the pachinko gaming machine of the 2nd Embodiment of this invention, and the image of the effect of other hole winning a prize. It is a figure which shows the example of the image of the overflow production | presentation displayed in the pachinko game machine of the 2nd Embodiment of this invention. It is a flowchart which shows the touch sensor effect process performed in the pachinko game machine of the 3rd Embodiment of this invention. It is a conceptual diagram which shows the holding time concealment image selection table for a touch referred in the pachinko machine of the 3rd Embodiment of this invention. It is a conceptual diagram which shows the latent notification alert effect selection table referred in the pachinko game machine of the 3rd Embodiment of this invention. It is a flowchart which shows the point provision effect setting process performed in the pachinko gaming machine of the 4th Embodiment of this invention. It is a flowchart following FIG. It is a flowchart which shows the touch sensor presentation process performed in the pachinko game machine of the 4th Embodiment of this invention. It is a conceptual diagram which shows the after-touch item selection table referred in the pachinko game machine of the 4th Embodiment of this invention. It is a conceptual diagram which shows the holding time concealment image selection table for a touch referred in the pachinko game machine of the 4th Embodiment of this invention. It is a flowchart which shows the RTC production | presentation process performed in the pachinko game machine of the 5th Embodiment of this invention. It is a flowchart which shows the touch sensor presentation process performed in the pachinko game machine of the 5th Embodiment of this invention.

First Embodiment
[Configuration of pachinko gaming machine 1]
The outline of the pachinko gaming machine 1 will be described with reference to FIGS. 1 to 4. FIG. 1 is a perspective view showing an overview of a pachinko gaming machine 1 according to the present embodiment. FIG. 2 is a front view showing an overview of the pachinko gaming machine 1 in the present embodiment. FIG. 3 is an exploded perspective view showing an overview of the pachinko gaming machine 1 according to the present embodiment. FIG. 4 is a front view of the game board 40 of the pachinko gaming machine 1 according to the present embodiment.

  As shown in FIGS. 1 to 3, the pachinko gaming machine 1 has a glass door 10, a launcher 20, a base door 30, a game board 40, a crate 60, a liquid crystal display device 50 for displaying an image, a payout unit 70, and a substrate. A unit 80 and a spacer 90 are provided.

  The glass door 10 is pivotally attached to the base door 30 in an openable / closable manner. Further, an opening 11 is formed at the center of the glass door 10, and a transparent protective glass 12 is disposed in the opening 11. The protective glass 12 is disposed to face the front of the game board 40 with the glass door 10 closed.

  Further, below the opening 11, the glass door 10 is provided with a plate unit 13, a speaker 14 (see FIG. 51), and an effect button 16. The pan unit 13 is a unit body in which the upper pan 131 and the lower pan 132 positioned below the upper pan 131 are integrated. The upper tray 131 and the lower tray 132 are provided with payout openings for lending game balls and paying out balls (prize balls), and when predetermined payout conditions are satisfied, the game balls are discharged. In particular, in the upper tray 131, gaming balls to be fired to the game area 41 (see FIG. 4) described later are stored. The speaker 14 (see FIG. 51) is disposed inside the lower plate 132. Further, the effect button 16 is disposed on the upper portion of the upper plate 131.

  The launcher 20 is disposed at the lower right of the base door 30. The launcher 20 includes a launch handle 21 operable by the player and a panel 22 fitted to the lower right portion of the tray unit 13. The firing handle 21 is pivotable and is provided on the front side of the panel body 22. The panel body 22 is integrated with the lower right portion of the pan unit 13 when the pan unit 13 and the launcher 20 are disposed on the base door 30. Then, the player can advance the pachinko game by operating the launch handle 21.

  The back side of the panel body 22 is provided with a firing solenoid (not shown) for firing the gaming ball. Furthermore, a touch sensor (not shown) is provided at the peripheral edge of the firing handle 21. Inside the firing handle 21, a firing volume is provided which changes the resistance according to the amount of rotation of the firing handle 21 and changes the power supplied to the firing solenoid (not shown).

  When the touch sensor (not shown) is touched by the player, it is detected that the player holds the firing handle 21. When the release handle 21 is held by the player and turned clockwise, the resistance value of the discharge volume (not shown) changes according to the rotation angle, and the resistance value at this time is changed. Power corresponding to is supplied to the firing solenoid (not shown). As a result, the gaming balls stored in the upper tray 131 are sequentially fired to the later-described gaming area 41 of the gaming board 40, and the game is advanced. When the firing stop button (not shown) is pressed, the firing of the gaming ball is stopped even when the shooting handle 21 is held and turned.

  The base door 30 is pivotally attached to the wooden frame 60 so as to be openable and closable. A game board 40 is disposed on the base door 30 behind the protective glass 12 via a spacer 90. The spacer 90 is interposed between the base door 30 and the game board 40 and is a member for attaching the game board 40 to the base door 30. Further, as described later, gaming members such as various prizes are attached to the spacer 90.

  As shown in FIG. 4, the game board 40 is formed of a plate-shaped resin, and is formed of, for example, various materials such as acrylic resin, polycarbonate resin, and methacrylic resin. At least a part of the game board 40 has translucency or light guiding property, and the rear of the light transmitting or light guiding area is visible from the front, and is translucent or light guiding property. The back of the area which does not have is hard to see from the front. In the game board 40, the plate-shaped portion (the portion where the game area 41 to be described later is formed) may be made of, for example, a material such as metal or wood which does not have translucency or light guiding property. . In this case, the opening formed in the central portion of the game board 40 is an area having a light transmitting property or a light guiding property.

  In addition, the game board 40 is provided on the front side thereof with a game area 41 where the released game balls can roll and flow down, and an LED unit 43 disposed at the lower right side outside the game area 41.

  The game board 40 is provided with an arc-shaped guide rail 411 which defines a game area 41, and a plurality of game nails 412 are punched into the game area 41. Further, in the game area 40, in the game area 41, the central base plate 413, the first start opening 414a, the second start opening 414b, the ordinary electric jack 415, the ball passage detector 416, the big winning opening 418, and the general winning opening 419a, 419b, 419c, 419d, normal out port 420a, first special out port 420b, second special out port 420c, third special out port 420d, distribution device 421, shutter device 422, outflow path plate 423, easy winning Game members such as the mechanism 424, the touch sensor 425, and the illumination array 426 are disposed.

  The guide rail 411 includes an outer rail 411a and an inner rail 411b disposed inside the outer rail 411a.

  The central base plate 413 is a frame-shaped member made of a resin material, and is disposed at an opening formed in the central portion of the game board 40. The central base plate 413 includes a right rail portion 413a, a left rail portion 413b, a passage opening 413c, a stage 413d, and a right guide portion 413e. The right rail portion 413 a and the left rail portion 413 b are formed on the upper portion of the central base plate 413 and guide the game balls fired to the board of the game board 40. The gaming ball beyond the top portion of the gaming area 41 flows down to the right area of the gaming area 41 while drawing an arc-like track by the guide of the right rail portion 413a. The game ball which has not exceeded the top part of the game area 41 moves to the left area of the game area 41 by the guide of the left rail portion 413 b. Here, the display area 51 of the liquid crystal display device 50 (see FIG. 3) is disposed in the frame of the central base plate 413 behind the gaming board 40 when the gaming board 40 is viewed from the front.

  The passage opening 413 c is a portion formed on a predetermined portion on the left side of the center base plate 413 and through which the game ball can pass. The stage 413 d is formed at the lower part of the central base plate 413 and extends to the opening side of the game board 40. The gaming balls having passed through the passage opening 413 c from the left side of the central support plate 413 roll on the stage 413 d of the gaming board 40 and flow down from the stage 413 d to the board of the gaming board 40. The right guide portion 413e is formed on the right side of the central base plate 413, and is formed of a pair of guide plates which flow downward while guiding both sides of the gaming ball. The game ball having passed through the right rail portion 413a flows down the right side area in the game area 41 while being guided by the right guide portion 413e.

  The game ball fired by the launcher 20 (see FIG. 1 etc.) is guided by the guide rail 411, moves to the upper part of the game area 41, and advances due to a collision with the game nail 412 or the central base plate 413 etc. It flows downward toward the lower part of the game area 41 while changing the direction. The player, for example, drives a game ball to the left side of the central base plate 413 and causes the game ball to flow down the left side of the central base plate 413 (so-called left-handed), and the launch handle 21 of the launch device 20 (FIG. 1 etc.) Rotate the game ball to the right of center base plate 413 by turning it to the right to the right, and let the game ball flow down the right side of center base plate 413 through right rail part 413a and right guide part 413e (see It is possible to advance pachinko gaming by selecting so-called right strike). In addition, the game ball shot to the game area 41 of the game board 40 does not move to the inside of the central base plate 413 from a place other than the passage opening 413 c.

  The first start opening 414 a is disposed below the center base plate 413 below the center of the game area 41. Here, a recess is formed at the center of the stage 413d, and the first starting port 414a is disposed immediately below the recess. That is, the gaming ball placed on the recess in the center of the stage 413d is likely to enter the first starting opening 414a. A winning area is provided in the first starting opening 414a. In this winning area, a first starting opening winning ball sensor 116a (see FIG. 51) is provided.

  The second start port 414b is disposed below the downstream end of the right rail portion 413a. A winning area is provided in the second starting opening 414b. In this winning area, a second starting opening winning ball sensor 116b (see FIG. 51) is provided. In the present embodiment, various game members are arranged on the game board 40 so that winning on the first start opening 414a can be achieved only by hitting the left and winning on the second starting opening 414b can be achieved only by hitting the right. It is done.

  The normal motorized combination 415 is provided immediately above the second starting opening 414b, and is a flat plate member 415a which can be pulled out and pulled into the plate surface of the game board 40, and a common voltage combination solenoid 111 which drives the flat plate 415a. (See FIG. 51). The flat plate member 415a has a slope inclined to the right, and in a state where the flat plate member 415a of the ordinary motor-operated part 415 protrudes, the gaming ball on the flat plate member 415a moves to the right and the flat plate member The gaming ball which has passed through the flat plate member 415a when the 415a is retracted is likely to enter the second starting opening 414b.

  The ball passage detector 416 includes a passage gate through which the game balls can pass one by one, and a ball passage detection sensor 115 (see FIG. 51) disposed in the passage gate. The ball passage detector 416 is disposed directly above the motorized workpiece 415, and the passage gate of the ball passage detector 416 is disposed opposite to the downstream end of the right guide portion 413e. That is, since the gaming ball which has fired the gaming ball to the right area in the gaming area 41 passes through the right guide portion 413 e and flows down toward the passing gate, it easily passes the ball passage detector 416.

  In addition, the ordinary motor-operated part 415 and the ball passage detector 416 are configured as one unit. Thereby, the work concerning attachment to the game board 40, removal and maintenance becomes easy.

  The special winning opening 418 is disposed below the second start opening 414 b and the general winning opening 419 d in the right area of the game area 41. In the special winning opening 418, a winning area is provided, and in the winning area, a count sensor 113 (see FIG. 51) is provided.

  The general winning opening 419a, 419b, 419c is disposed in the left area of the gaming area 41, and the general winning opening 419d is below the second starting opening 414b in the right area of the gaming area 41 from the large winning opening 418 Is also disposed above. The gaming balls having entered the general winning opening 419a, 419b, 419c pass through a common path, and a general winning ball sensor 114a (see FIG. 51) is provided at a predetermined portion of this common path. Similarly, a general winning ball sensor 114b (see FIG. 51) is also provided in the general winning opening 419d.

  The normal out port 420a is disposed below the first start port 414a and the general winning ports 419a, 419b, and 419c in the area on the left side of the game area 41. The game balls that have not entered any of the first starting opening 414a and the general winning openings 419a, 419b, 419c are usually sent from the out port 420a to the back of the game board 40 and collected by the collection device. As described above, in the gaming media in which the normal out port 420a rolls the second area (the left area of the gaming area 41), an area that triggers the provision of a predetermined gaming value by the gaming value giving means (the payout device 71). This is an example of a second out port that passes game media that does not pass through and sends it out of the game area.

  The first special out port 420 b and the second special out port 420 c are respectively disposed on both sides of the special winning port 418. In particular, the first special out port 420b is disposed on the left side of the special winning port 418, and the first out ball detection sensor 117a (see FIG. 51) is provided in the first special out port 420b. In the second special out port 420c, a second out sphere detection sensor 117b (see FIG. 51) is provided. The third special out port 420 d is disposed next to the general winning port 419 d.

  The sorting device 421 is disposed below the second start opening 414b and above the general winning opening 419d and does not enter the second start opening 414b in the left direction (first path 423b side). Or it is an apparatus which guides in the right direction (the 2nd course 423c side), and distributes a game ball. The details of the sorting device 421 will be described later, but for example, when four game balls move to the sorting device 421 in a row, the three balls are assigned to the right and one ball is assigned to the left.

  In addition, the distribution apparatus 421 may be included in one unit including the ordinary motorized product 415 and the ball passage detector 416. For example, as shown in FIG. 79, in a unit body in which the ordinary motor-operated part 415 and the ball passage detector 416 are fixed to the base plate 430, the distributor 421 is further detachably fixed to the base plate 430. It is also good. Thus, the distributing device 421 is detachably attachable to the unit body having the first passage area forming member (the ball passage detector 416) and the first displacement member (the ordinary electric part 415). The game console 40 is installed on the game board 40 in a state of being attached to As a result, operations such as positioning and temporary fixing of the ordinary electric utility product 415, the ball passage detector 416 and the distribution device 421 in mounting on the game board 40 become easy, and the efficiency of the operation can be further improved. .

  The shutter device 422 is disposed below the distribution device 421, and has a shutter member 422a which can be pulled out and pulled into the surface of the game board 40, and a special winning opening solenoid 112 (for driving the shutter member 422a) See FIG. 51). In the shutter device 422, the shutter member 422a has a slope inclined downward to the left, and the large winning opening 418 can be easily entered by drawing in the shutter member 422a by the large winning opening solenoid 112 (see FIG. 51). As the shutter member 422a protrudes, it is difficult to enter the big winning opening 418.

  The down flow path plate 423 is made of resin, and has a plurality of ridges on the plate surface. These ridges define the path of the game ball flowing down from the downstream end of the right guide portion 413e. The flow path board 423 is disposed on the lower right side of the game area 41 of the game board 40, and a ball passage detector 416, an ordinary electric character 415, a sorting device 421, a shutter device 422, a general winning opening 419d, a special winning opening Holes through which the game balls can pass are formed at positions facing the first special out port 420b, the second special out port 420c, and the third special out port 420d. A ball passing detector 416, an ordinary motorized character 415, a sorting device 421 and a shutter device 422 are fixed to the back of the game board 40, and the ball passing detector 416 is a passing gate through which the gaming ball passes, one of the sorting devices 421. The projecting portion, the flat plate member 415a in the projecting state, and the shutter member 422a in the projecting state protrude from the board surface of the game board 40 through the holes formed in the flow-down path plate 423.

  The flow-down path plate 423 is a third path formed by a plurality of protrusions, receiving the game ball having passed the reception path 423a, the first path 423b and the second path 423c branching from the reception path 423a, and the second path 423c. It is equipped with 423d.

  The reception path 423a is a path through which all the game balls flowed out from the downstream end of the right guide portion 413e pass, and in this path, the ball passage detector 416, the ordinary electric part 415 and the second starting opening 414b Is placed. The game ball that has not entered the ball passage detector 416 and the game ball that has flowed down to the right by the flat plate member 415a of the ordinary electric actor 415 protruding has a first path 423b and a second path 423c. Move to the bifurcation position of. In addition, the game ball which flowed down downwards by drawing in the flat plate member 415a passes the 2nd starting opening 414b, moves to the back side of the game board 40, and is collect | recovered by the collection | recovery apparatus.

  The sorting device 421 is disposed at a branch position between the first path 423b and the second path 423c, and the sorting device 421 has game balls on the first path 423b on the left side and the second path 423c on the right side. It is distributed.

  The first path 423b is a path for guiding the gaming balls to the general winning opening 419d and the third special out port 420d, and the gaming balls having passed the first path 423b are the general winning opening 419d and the third special out port 420d. It is divided into the case of entering into any of the cases and the case of not entering into any of the cases. The game balls having passed the general winning opening 419 d and the third special out port 420 d move to the back side of the game board 40 and are collected by the collection device. The game ball which does not enter in any joins the 2nd course 423c. The lower end portion of the second path 423c after merging is communicated with the third path 423d.

  The third path 423d has a gentle slope which falls to the left, and on this slope is formed a substantially rectangular large drop opening 423e of a size that allows a plurality of gaming balls to fall simultaneously. Furthermore, small drop openings 423 f and 423 g of a size that allows one game ball to fall one by one are formed on both sides of the large drop opening 423 e. The small drop port 423f is formed on the lower side of the slope, and the small drop port 423g is formed on the upper side of the slope.

  The game ball dropped to the large drop opening 423e is to the large winning opening 418, the game ball dropped to the small drop opening 423f is to the first special out port 420b, and the game ball dropped to the small drop opening 423g is the second special out port 420c Each will be guided.

  A slit-like hole is formed in a portion of the flow-down path plate 423 facing the shutter device 422, and the slit-like hole is formed in the upper opening of the large drop port 423e. The shutter member 422a of the shutter device 422 is loosely fitted in this hole, and is driven so as to protrude and withdraw from the slit-like hole by the large winning opening solenoid 112 (see FIG. 51). When the shutter member 422a protrudes, the large drop opening 423e is closed, and the slope of the third path 423d and the upper surface of the shutter member 422a are flush with each other. Therefore, the gaming ball rolling on the slope of the third path 423d passes the top surface of the shutter member 422a and moves to the first special out port 420b. When the shutter member 422a is retracted, the large drop opening 423e is in the open state, and the game ball can enter the large winning opening 418. The shutter member 422a constitutes a variable winning means of the present invention capable of transitioning to an open state in which the large falling opening 423e and the large winning opening 418 are opened and a closed state in which the large falling opening 423e and the large winning opening 418 are closed. Since the special winning opening 418 has a winning area inside, the special winning opening 418 constitutes a winning area of the present invention.

  In addition, when the game ball which falls from the upper part of the shutter member 422a occurs, for example, when a large amount of game balls rest on the shutter member 422a when the shutter member 422a of the shutter device 422 protrudes, the game ball is , And from the upper part of the slope of the third path 423d to the second special out port 420c via the small drop port 423g.

  Thus, the ball passage detector 416 functions as a first passage area forming member that forms a first passage area through which game media ejected to a predetermined area in the game area can pass, and the second starting opening 414b It functions as a second passing area through which game media having passed the first passing area can pass, and the ordinary motorized part 415 is unitized with the first passing area forming member, and the game medium to the second passing area The general winning opening 419d functions as a first displacement member that can be displaced to either of a first position that facilitates passage and a second position that makes passage of gaming media to the second passage area difficult. The large winning opening 418 functions as a fourth passing area through which the game media distributed to the second route can pass, and the shutter device 422 Second The third position which allows the game media distributed to the path to roll and facilitates the passage of the game media to the fourth passage area, and the third makes the passage of the game media to the fourth passage area difficult. The first special out port 420b corresponds to an example of the second displacement member that can be displaced to any of the four positions, and the first special out port that passes game media that does not pass through the fourth passing area and sends out to the outside of the gaming area Act as.

  In FIG. 4, the winning mechanism 424 is constituted by a plurality of ribs 424a formed at equal intervals in the large drop opening 423e of the flow down path plate 423 and the game area 41 above the shutter member 422a. The rib 424 a has a shape obtained by dividing an elongated circular cylinder into two, and extends in the vertical direction when the winning easy mechanism 424 is viewed from the front. Therefore, in a state where the shutter member 422a closes the large drop opening 423e, the gaming ball passing through the slope of the shutter member 422a, that is, the gaming ball rolling toward the shutter member 422a flows down while contacting the rib 424a. Do. Thereby, the rolling speed of the gaming ball is decelerated while passing the slope by the shutter member 422a. In other words, the time of being on the shutter member 422a becomes longer. As described above, in the winning a prize mechanism 424, when the second displacement member (shutter member 422a) is at the fourth position (in the state where the large drop opening 423e is closed), the game medium passing the upper portion of the second displacement member is At the time of displacement from the fourth position of the second displacement member to the third position (the state where the large drop opening 423e is opened), it is easily possible to easily move to the fourth passing area (large winning opening 418) side Act as a mechanism.

  A plurality of ribs 424b formed at equal intervals are provided at the large drop port 423e inside the shutter member 422a. The rib 424 b has a shape obtained by dividing an elongated circular cylinder into two in the same manner as the rib 424 a, and extends in the vertical direction when the rib 424 b is viewed from the front.

  The rib 424b is a game ball not detected by the count sensor 113 (see FIG. 51) among the game balls guided from the game area 41 outside the shutter member 422a to the large drop opening 423e inside the shutter member 422a. If it does, it contacts with the game sphere which passes inside the large falling mouth 423e which is not winning in the large winning a prize mouth 418, decelerating the rolling speed of this game ball.

  The shutter member 422a is provided between the rib 424a and the rib 424b in the vertical direction, and the rib 424a can decelerate the game ball rolling on the outside of the shutter member 422a when the shutter member 422a is in the closed state. When the shutter member 422a is in the open or closed state (the closed state immediately after the opening), the rib 424b can decelerate the game ball rolling in the large drop opening 423e. The rib 424a of the present embodiment constitutes a first decelerating means of the present invention, and the rib 424b constitutes a second decelerating means of the present invention.

  The touch sensor 425 is a non-contact type touch sensor, and is disposed at a predetermined portion in the area on the right side of the game area 41, for example, above the winning mechanism 424. The touch sensor 425 outputs a detection signal when the player holds the hand over the protective glass 12 (see FIG. 3) or touches the protective glass 12 toward the touch sensor 425.

  The illumination array 426 is composed of a transparent light guide plate 426a (see FIG. 10) on which a latent image is formed and a light source 426b (see FIG. 10) disposed to the side of the light guide plate 426a. Ru. The illumination array 426 is disposed in the vicinity of the touch sensor 425 at the right of the play area 41. Then, the light source 426b (see FIG. 10) emits light to visualize the latent image, and the light guide plate 426a (see FIG. 10) performs illumination display. In the present embodiment, information indicating that the touch sensor 425 can be operated is displayed.

  The LED unit 43 includes a special symbol display device 431, a round number display device 432, a first special symbol hold display device 433a, a second special symbol hold display device 433b, a normal symbol display device 434, and a normal symbol hold display device 435. It is set up.

  The special symbol display device 431 is constituted by a 7-segment LED, and the special symbol (also referred to as an identification symbol) indicated by the 7-segment LED is repeatedly turned on / off of the 7-segment LED after establishment of a predetermined variable display start condition. It changes and displays it by stop. Specifically, the special symbol display device 431 has a game ball winning in the first starting opening 414a or the second starting opening 414b, and this gaming ball is the first starting opening winning ball sensor 116a (see FIG. 51) or the second When detected by the starting opening winning ball sensor 116b (see FIG. 51), the special symbol is variably displayed, and after a predetermined time has elapsed, the special symbol is stopped and displayed in a predetermined stop display mode.

  The number-of-rounds display device 432 is constituted by a 7-segment LED, and displays the number of rounds of round games in the jackpot gaming state described later.

  In the present embodiment, sixteen display lamps are provided on the side of the round number display device 432. These display lamps constitute the first special symbol hold display device 433a, the second special symbol hold display device 433b, the normal symbol display device 434, and the normal symbol hold display device 435.

  The first special symbol hold display device 433a is constituted by four display lamps, and the number of times of execution of variable display in the special symbol display device 431 (so-called, “held number of holdings” triggered by winning in the first starting opening 414a) ", The number of reserved for special symbol" is displayed by lighting, turning off or blinking.

  The second special symbol hold display device 433b is composed of four display lamps, and the number of times of execution of variable display in the special symbol display device 431 (so-called, "number of hold pending") triggered by winning in the second starting opening 414b. ", The number of reserved for special symbol" is displayed by lighting, turning off or blinking. Specifically, the first special symbol hold display device 433a and the second special symbol hold display device 433b are, for example, one display when the number of times of execution of the variable display in the special symbol display device 431 is held for one time The lamp for the lamp lights up, and when the number of times of execution of the variable display in the special symbol display device 431 is suspended for two times, the two display lamps are lighted.

  The normal symbol display device 434 is composed of two display lamps, and after the predetermined variable display start condition is established, the normal symbol shown by these display lamps is alternately repeated turning on / off the display lamp It changes and displays it by stop. Specifically, when the gaming ball passes the ball passage detector 416, and the gaming ball is detected by the ball passage detection sensor 115 (see FIG. 51), the normal symbol display device 434 changes the normal symbol and displays it. After the predetermined time has elapsed, the normal symbol is stopped and displayed in the predetermined stop display mode.

  The normal symbol holding display device 435 is constituted by four display lamps, and the number of times of execution of the variable display in the normal symbol display device 434 triggered by the game ball passing through the ball passage detector 416 (so-called, "hold" "Number", "Normal number of held for the symbol" is displayed by lighting, extinguishing or blinking. Specifically, when the number of times of execution of the variable display in the normal symbol display device 434 is suspended for one time, for example, the normal symbol storage display device 435 turns on one display lamp, and the normal symbol display device 434 When the number of times of execution of the variable display in 2 is suspended for two times, the two display lamps are turned on.

  Returning to FIG. 3, the liquid crystal display device 50 is an example of a display means, and is disposed behind (on the back side of) the game board 40, and as shown in FIG. It is arranged higher. In the display area 51, various images such as derived symbols which are identification symbols for effects, effect images, and decoration images for decoration are displayed. Although the liquid crystal display device 50 is described as an example of the display means in the present embodiment, the present invention is not limited to this. The display means may be a plasma display, a rear projection display, a CRT display, a lamp or the like.

  The payout unit 70 includes a payout device 71 (see FIG. 51) described later, and game balls are present at the first start opening 414a, the second start opening 414b, the general winning openings 419a to 419d, and the large winning opening 418 shown in FIG. When winning, the number of game balls set in advance according to the type of each winning opening is paid out to the upper plate 131 or the lower plate 132.

  The substrate unit 80 stores a main control circuit 100 (see FIG. 51), a secondary control circuit 200 (see FIG. 51), and the like, which will be described later, and controls the pachinko gaming machine 1.

[Configuration of Distribution Device 421]
FIG. 5 is an exploded perspective view showing components of the sorting device 421, FIG. 6 is a perspective view showing an appearance of the sorting drum 501 according to the sorting device 421, and FIG. 6 (a) is a sorting drum. FIG. 6 (b) shows an appearance in which the sorting drum 501 is viewed from the right side. 7 is a perspective view showing the appearance of the first cam lock 504 attached to the distributing drum 501, FIG. 8 is a front view of the distributing device 421, and FIG. 8 (a) is a first cam lock 504 and a second FIG. 8B shows a state in which the engagement between the first cam lock 504 and the second cam lock 505 is released. FIG. 9 is an explanatory view showing the operation of the distributing drum 501. As shown in FIG.

  The distribution device 421 includes a base 500, a distribution drum 501, a distribution shaft 502, a bush 503, a first cam lock 504, a second cam lock 505, a spring member 506, a design lens 507, and a seal 508. And a cover left 509 and a cover right 510.

  The base 500 extends from the edges of both sides of the case portion 500a formed in a semi-cylindrical shape and the case portion 500a formed in a semicircular flat plate shape to the outside of the case portion 500a in a direction perpendicular to the side. And extending portions 500b and 500c.

  The case portion 500 a is formed in a size that can accommodate the distribution drum 501. The extension portion 500 b extends from the left side surface of the distribution drum 501, and the extension portion 500 c extends from the right side surface of the distribution drum 501. The extension portions 500 b and 500 c are formed with holes through which screws for fixing to the game board 40 are passed. Further, the extension portion 500b is formed with a small case portion 500d formed in a semi-cylindrical shape smaller than the case portion 500a and a bearing portion 500e in which one end portion of the distribution shaft 502 is accommodated. The small case portion 500d communicates with the case portion 500a, and the bearing portion 500e communicates with the small case portion 500d. In the extension portion 500c, a bearing portion 500f in which the other end portion of the distribution shaft 502 is accommodated is formed. The bearing 500f communicates with the case 500a. The case portion 500a, the small case portion 500d, the bearing portion 500e, and the bearing portion 500f are disposed on the same axis.

  The distribution drum 501, as shown in FIG. 6, is formed of a cylindrical (drum-shaped) drum body 501a having a central hole 501e into which the distribution shaft 502 (see FIG. 5) can be inserted, and the drum body 501a Four grooves 501b extending along the central axis of the drum main body 501a, a protrusion 501c protruding from one end of the drum main body 501a, and a protrusion 501d protruding from the other end of the drum main body 501a Have.

  The four groove portions 501b are formed in the drum main body 501a between wall surfaces extending at 90 degrees with respect to the central axis, and a blade portion 501f is formed between the adjacent groove portions 501b. That is, the distributing drum 501 includes the four blade portions 501f extending in the radial direction from the drum main body 501a, and the four blade portions 501f are viewed from the front in the axial direction of the drum main body 501a. It has a cruciform shape. The maximum length of the wing portion 501f extending from the drum main body 501a is set to be smaller than the diameter of the gaming ball.

  The projecting portion 501c is formed in a frusto-conical shape inclining toward the inside of the drum main body 501a. Further, a notch communicating with one groove portion 501b among the four groove portions 501b is formed in the projecting portion 501c.

  The projecting portion 501d is formed in a truncated cone shape which is inclined toward the inside of the drum main body 501a. The projecting portion 501 d is formed with a notch communicating with the other three groove portions 501 b among the four groove portions 501 b. A recessed portion 501k is formed on the side surface of the protruding portion 501d, and the design lens 507 (see FIG. 5) is attached to the recessed portion 501k.

  That is, one groove portion 501b among the four groove portions 501b formed in the distribution drum 501 is closed on the right side by the protrusion portion 501d and open on the left side, and the other three sets of groove portions 501b are the left side. Is closed by the protrusion 501 c and the right side is open. In the following description, the groove 501b closed on the right side by the protrusion 501d and opened on the left side is the left receiving portion 501g, the left side is closed by the protrusion 501c, and the three groove portions 501b opened on the right are right It is called receiving part 501h. That is, the left receiving portion 501g and the right receiving portion 501h are formed between the adjacent blade portions 501f.

  As shown in FIG. 5, the bush 503 is a flange body in which a cylindrical body 503b is formed at the center of the disc body 503a. The inner diameter of the disk body 503a is set smaller than the inner diameter up to the root portion of the protrusions 501c and 501d (see FIG. 6) in the drum main body 501a. Further, the outer diameter of the cylindrical body 503b is such a size that the cylindrical body 503b can be inserted into the central hole 501e (see FIG. 6), and the inner diameter is larger than the distribution shaft 502 to such an extent that the distribution shaft 502 can be inserted. It is set slightly larger. Then, the bush 503 is attached to the right side of the distribution drum 501 by inserting the cylindrical body 503 b into the center hole 501 e.

  As shown in FIGS. 5 and 7, the first cam lock 504 includes a disc body 504a having a fan-shaped missing portion 504b having a central angle of 90 °, and a cylindrical body 504c erected at the center of the disc body 504a. And a gear portion 504e formed on the surface opposite to the surface of the disc body 504a on which the cylindrical body 504c is erected.

  The diameter of the disc body 504a is set to be slightly smaller than the diameter of the left side surface of the distribution drum 501, and the cylindrical body 504c has a size capable of being inserted into the central hole 501e (see FIG. 6). The inner diameter of 504 c is set to be slightly larger than the distribution shaft 502 to such an extent that the distribution shaft 502 can be inserted. The hole 504d formed inside the cylindrical body 504c penetrates the center of the disc body 504a, and the gear portion 504e surrounds the periphery of the hole 504d formed at the center of the disc body 504a. It is formed as. The inner diameter and the outer diameter of the cylindrical body 504 c are the same as the inner diameter and the outer diameter of the cylindrical body 503 b of the bush 503.

  As shown in FIG. 7, the first cam lock 504 inserts the cylindrical body 504c into the center hole 501e from the left side of the distributing drum 501, the disc body 504a in the left side surface of the distributing drum 501, the groove portion 501b and the missing portion It fixes by screwing in the state which adjusted so that 504b may correspond. Thus, the gear portion 504 e is disposed at the center of the left side surface of the distribution drum 501.

  The gear portion 504 e is formed of a corrugated shape in which the upward slope and the downward slope are switched every 45 ° from a line extending in a predetermined radial direction around the hole portion 504 d. Here, since the angle between the upslope and the downslope is an obtuse angle, the unevenness in the gear portion 504 e is formed gently.

  In the gear portion 504e, since the upward slope and the downward slope are switched every 45 °, the convex portion of the gear portion 504e is formed at four places, and the distribution drum 501 rotates 90 ° at these four convex portions. Each time, a concave portion of a gear portion 505d (see FIG. 5) of a second cam lock 505 described later is engaged.

  As shown in FIG. 5, the second cam lock 505 includes a cylindrical body 505a, a hole 505c formed on a central axis of the cylindrical body 505a, and a pair of radial extending from a circumferential surface on one end side of the cylindrical body 505a. And a gear portion 505d formed on the other end surface of the cylindrical body 505a.

  The pair of extending pieces 505b are each formed in a rectangular plate shape, and the root portion extends along the axial direction of the cylindrical body 505a, and extends in the radial direction and the opposite direction with respect to the central axis of the cylindrical body 505a. There is. The gear portion 505d has the same shape as the gear portion 504e of the first cam lock 504, and the gear portion 504e and the gear portion 505d can mesh with each other. The spring member 506 is a coil spring which is disposed on the left side of the second cam lock 505 and biases the second cam lock 505 toward the first cam lock 504.

  The design lens 507 is a decorative member mounted on the concave portion 501k (see FIG. 6B) of the protrusion 501d. The seal 508 is a flat plate-like member disposed inside the recess 501 k of the protrusion 501 d. After the seal 508 is inserted into the recess 501k of the protrusion 501d, the design lens 507 is mounted.

  The cover left 509 is fixed to the extension 500 b of the base 500, and the cover right 510 is fixed to the extension 500 c of the base 500. The cover left 509 and the cover right 510 are members for holding the distribution shaft 502 so as not to come off the base 500. In FIG. 8, the descriptions of the cover left 509 and the cover right 510 are omitted.

  Moreover, in each member which comprises the distribution apparatus 421, the member except the distribution axis | shaft 502, the spring member 506, and the screw which is not shown in figure is comprised by the member which has transparency.

  Next, assembly of the distribution device 421 will be described with reference to FIGS. 5 and 8. First, the seal 508 is inserted in advance into the concave portion 501k of the distribution drum 501, and the design lens 507 is mounted in advance. Next, the bush 503 is passed through the distribution shaft 502, and the distribution shaft 502 is further inserted into the center hole 501e of the distribution drum 501, and the cylindrical body 503b of the bush 503 is inserted into the center hole 501e. The bush 503 is mounted on the right side of the distribution drum 501.

  Next, the cylindrical body 504c of the first cam lock 504 is inserted into the distributing shaft 502 extending from the right side of the distributing drum 501, and the cylindrical body 504c is fitted into the central hole 501e. The first cam lock 504 is attached to the In this state, the distribution shaft 502 is disposed on the central axis of the distribution drum 501. Next, the second cam lock 505 is inserted into the distribution shaft 502 extending from the first cam lock 504 so that the gear portion 504 e and the gear portion 505 d face each other, and the spring member 506 is further inserted.

  Thus, after inserting each member to the distributing shaft 502, the distributing drum 501 is stored in the case portion 500a of the base 500, and the second cam lock 505 and the spring member 506 are stored in the small case portion 500d. The left end of the distribution shaft 502 is accommodated in the bearing 500e, and the right end of the distribution shaft 502 is accommodated in the bearing 500f. In this state, since the spring member 506 is slightly compressed, the biasing force from the spring member 506 acts on the second cam lock 505. Therefore, as shown in FIG. 8A, the second cam lock 505 is urged toward the first cam lock 504, and is maintained in a state in which the gear portion 504e and the gear portion 505d mesh with each other.

  Then, the cover left 509 and the cover right 510 are fixed to the extension parts 500 b and 500 c of the base 500, respectively. At this time, an elongated gap is formed between the cover left 509 and the extending portion 500b, and the extending pieces 505b and 505b of the second cam lock 505 are disposed in the gap. For this reason, the rotation of the second cam lock 505 around the distribution shaft 502 is restricted, and the sliding movement of the second cam lock 505 along the distribution shaft 502 is permitted. For example, by sliding the second cam lock 505 in the left direction, as shown in FIG. 8B, it is possible to release the meshing state of the gear portion 504e and the gear portion 505d. When the operation of the second cam lock 505 is released from the state shown in FIG. 8B, the gear portion 504e and the gear portion 505d automatically return to the meshed state.

  The sorting device 421 configured as described above is disposed on the back side of the game board 40, and the base 500 is inserted with the sorting drum 501 inserted in the opening formed in the predetermined region of the right area of the game board 40. Is fixed to the game board 40. At this time, the distribution axis 502 is disposed horizontally along the game board 40, and only one of the four blade portions 501f formed on the distribution drum 501 is the board surface of the game board 40. Project vertically to the

  Next, the operation of the distribution device 421 will be described. As shown in FIG. 9A, when the protruding portion 501d is positioned on the upper right side, the left receiving portion 501g is configured to be able to receive the game ball. At this time, the player can easily visually recognize the seal 508 because the player visually recognizes the seal 508 in a state in which the seal 508 housed inside the protrusion 501 d is enlarged by the design lens 507. It becomes possible to determine whether or not the left receiving portion 501g is in an acceptable mode.

  When the left receiving portion 501g is capable of receiving the game ball, when it flows down from above the game ball, the left receiving portion 501g receives the game ball, and the distributing drum 501 is rotated by the weight of the game ball. At that time, the gaming ball moves to the left by the slope of the protruding portion 501d. In addition, the rotation of the distribution drum 501 causes the first cam lock 504 to rotate. At this time, as the top portion of the gear portion 504e moves toward the top portion of the gear portion 505d, the gear portion 505d slides in a direction to resist the bias of the spring member 506 (see FIG. 5). Then, when the rotation angle of the distribution drum 501 exceeds 45 °, the top of the gear portion 504e exceeds the top of the gear portion 505d. At this time, the second cam lock 505 moves toward the first cam lock 504 by the biasing of the spring member 506, and the gear portion 504e and the gear portion 505d mesh. In conjunction with this operation, the distributing drum 501 is rotated, and as shown in FIG. 9B, the distributing drum 501 is temporarily held in a state of being rotated by 90 °. At this time, the gaming ball of the left receiving portion 501g flows down to the left side of the sorting drum 501, passes through the first path 423b (see FIG. 4), and receives the general winning hole 419d (see FIG. 4) and the third special out hole. It is led to the side 420 d (see FIG. 4). Moreover, while the protrusion part 501d is located in the lower right side, it becomes an aspect which the right receiving part 501h can receive.

  Furthermore, when the gaming ball flows down from above, the right receiving portion 501h receives the gaming ball, and the distribution drum 501 is rotated by the weight of the gaming ball. At that time, the gaming ball moves to the right by the slope of the protruding portion 501c. Further, as the distribution drum 501 rotates, the first cam lock 504 and the second cam lock 505 operate as described above, and as shown in FIG. 9C, the distribution drum 501 rotates 90 °. Once held. At this time, the gaming ball of the right receiving portion 501h flows down to the right side of the sorting drum 501, passes through the second path 423c and the third path 423d (see FIG. 4), and the large drop port 423e (see FIG. 4) side. Led to In addition, the protruding portion 501d moves to the back side of the game board 40, and the second right receiving portion 501h can receive it.

  Furthermore, when the next gaming ball flows down to the sorting device 421 from the upper side, the sorting drum 501 is rotated to be able to receive the third right receiving portion 501h, and the next gaming ball is sorted from the upper side When it flows down to 421, the distributing drum 501 makes one rotation, and as shown in FIG. 9A, the left receiving portion 501g can be received.

  As described above, the sorting device 421 has four game balls that did not win the second starting opening 414b, in the order of the first path 423b, the second path 423c, the second path 423c, and the second path 423c. One of them is distributed to the first route 423b. In addition, when the left receiving portion 501g becomes an aspect capable of receiving the game ball, the player can visually recognize the seal 508 stored in the inside of the projecting portion 501d in a state where the seal lens 507 is enlarged. By visually recognizing the seal 508, the person can determine whether or not the left receiving portion 501g is in an acceptable mode. As a result, when it is determined that the left receiving portion 501g is in the acceptable mode, there is a possibility that the general winning opening 419d will be won by hitting one game ball right, temporarily, the general winning opening If you win 419 d, you can get a prize ball even for a small amount. In addition, even if the general winning hole 419d is not won, the sorting drum 501 can be rotated to make it possible to receive the right receiving portion 501h. As a result, the player can end the game by the pachinko gaming machine 1 without hesitation.

[Schematic configuration of illumination array 426]
FIG. 10 is an explanatory view showing a schematic configuration of the illumination array 426. FIG. 10 (a) shows a state in which the light source does not emit light, and FIG. 10 (b) shows a state in which the light source emits light. The illumination array 426 includes a light guide plate 426a and a light source 426b formed of an LED lamp. The light guide plate 426a is formed with a plurality of projections having a reflection surface for reflecting the light beam along the plate surface to the player side, and a latent image 426c is formed by the plurality of projections. The light source 426b is disposed to the side of the light guide plate 426a and emits a light beam along the plate surface. When the light source 426b does not emit light, the player recognizes the light guide plate 426a as a transparent plate, and can not visually recognize the latent image 426c shown in FIG. 10 (a). When the light source 426 b emits light, the plurality of projections reflect light to the player side, whereby the latent image 426 c is visualized as shown in FIG. become.

  In the present embodiment, the illumination array 426 is disposed in the vicinity of the touch sensor 425, and information prompting the operation of the touch sensor 425 as a latent image 426c on the light guide plate 426a, for example, as shown in FIG. Character information "!!" is formed.

  The light source 426b is controlled to emit light during a period in which the operation of the touch sensor 425 is valid, the details of which will be described later. That is, the fact that the latent image 426c is visualized means that the player is informed that the operation of the touch sensor 425 is effective.

  In the illumination array 426 shown in FIG. 10, although the light guide plate 426a and the touch sensor 425 do not overlap, a part may overlap, and as shown in FIG. 11, the entire light guide plate 426a and touch sensor 425 May overlap. In addition, the display of the illumination array 426 may be switchable by arranging two illumination arrays 426 having latent images 426 c of different display modes in a row in the front-rear direction. For example, the character information "Touch !!" is displayed before operating the touch sensor 425, but the light source 426b to be lit after the touch sensor 425 is operated is switched, for example, "Complete !!" Other display modes such as displaying text information may be used.

  The character information may also be displayed as kanji, katakana, hiragana, etc., or a combination thereof. Further, not limited to the character information, an image of a character image, a person image, a building, a vehicle or the like may be displayed, and the present invention is not limited to these images.

[Game in pachinko gaming machine 1]
Next, the game in the pachinko gaming machine 1 will be described. In the gaming state in the present embodiment, the large drop opening 423e is closed by the projection of the shutter member 422a of the shutter device 422, and the normal gaming state in which the game ball can not be accepted in the large winning opening 418; The large drop opening 423 e is opened by the retraction of the 422 a, and a special gaming state in which the gaming ball can be received in the large winning opening 418 and can give a predetermined game value to the player is included. The special game state includes a small hit game state and a big hit game state capable of providing more game value than the small hit game state. The normal gaming state includes a first gaming state, which is a gaming state advantageous to the player, and a second gaming state, which is a gaming state more disadvantageous to the player than the first gaming state. In the present embodiment, in the second gaming state, the probability of shifting to the special gaming state is a normal gaming state (so-called non-deterministic change state), and the first gaming state is in the special gaming state compared to the second gaming state. It is a gaming state (a so-called probability change state) in which the probability of transition is high.

  A player generally starts a game from the normal gaming state, and shoots a game ball into the game area 41 of the game board 40 by the launcher 20. When the game ball that has been driven in wins in the first starting opening 414a or the second starting opening 414b, the special symbol of the special symbol display device 431 and the identification symbol (derived symbol) for effect displayed on the liquid crystal display device 50 change. indicate. Also, when the game ball enters the first starting opening 414a or the second starting opening 414b during the variation display of the special symbol, the first starting opening 414a or the first starting opening until the special symbol in the variation display is stopped. 2) The execution (start) of the variation display of the special symbol based on the entry of the game ball to the starting opening 414b is suspended. Thereafter, when the special symbol that has been variably displayed stops displaying, the variation display of the special symbol that has been suspended is started.

  In addition, the upper limit is set to the number of times that the execution of the fluctuation display of the special symbol is suspended, and in this embodiment, the fluctuation of the special symbol due to the ball entering the first starting opening 414a and the second starting opening 414b. The number of pending displays is limited to 4 times each. Therefore, it is possible to hold up to eight times.

  Moreover, as another (a predetermined special symbol variation display start) condition, the start condition of the special symbol is satisfied when the special symbol is stopped and displayed. That is, the variable display of the special symbol is started each time the variable display start condition of the predetermined special symbol is satisfied.

  Then, in the case of the specific stop display mode, the special symbol displayed stop in the special symbol display device 431 is shifted from the normal gaming state to the special gaming state. Among the specific stop display modes, the stop display mode for transitioning to the big hit gaming state is a big hit, and the stop display mode for shifting to the small hit gaming state is a small hit. Further, the stop display mode of the special symbol other than the big hit or the small hit is a lost symbol, and when the lost symbol is stopped and displayed, the normal gaming state is maintained without shifting to the special gaming state. As described above, after the special symbol is variably displayed, the stop display is performed, and the game in which the gaming state is shifted or maintained as a result is referred to as a "special symbol game".

  Further, in the display area 51 of the liquid crystal display device 50, an effect image associated with the special symbol displayed in the special symbol display device 431 is displayed. For example, during the variable display of the special symbol display device 431, in the display area 51 of the liquid crystal display device 50, except for a specific case, a derived symbol consisting of a number which is an example of the identification symbol is variably displayed. Further, the special symbol display device 431 is stopped and displayed, and the special symbol is displayed, and the derived symbol is also stopped and displayed in the display area 51 of the liquid crystal display device 50.

  Further, in the special symbol display device 431, when the special symbol displayed in the stop state is a specific stop display mode, an effect image for making the player grasp that it is a hit is displayed in the display area 51 of the liquid crystal display device 50. Ru. Specifically, when the special symbol is displayed on the special symbol display device 431, for example, in a specific display mode corresponding to a big hit that many balls can be obtained, the display area 51 of the liquid crystal display device 50 is displayed. The combination of the identification symbols for effects displayed in the display becomes a specific display mode (for example, a mode in which the stop symbols are displayed in a state where all the same symbols are aligned in each of a plurality of symbol rows) Is displayed in the display area 51 of the liquid crystal display device 50.

  Then, when the special symbol in the special symbol display device 431 becomes a specific stop display mode and the gaming state is shifted to the special gaming state, the shutter member 422a is driven to be pulled in from the board. As a result, the large drop opening 423 e is in an open state in which the game ball is easily received, and the gaming ball received by the large drop opening 423 e passes through the large winning opening 418.

  The special winning opening 418 has an area (not shown) having a count sensor 113 (see FIG. 51), and a predetermined number (for example, 10) of game balls are won in the area or a predetermined time (for example, The shutter member 422a is driven such that the large drop port 423e is in the open state until about 30 seconds has elapsed. Then, in the open state, when any of the conditions for winning a predetermined number of gaming balls to the big winning opening 418 or the elapse of a predetermined time is satisfied, the shutter member 422a is driven, and the large falling opening 423e is hard to receive the gaming balls. It will be closed. In the present embodiment, in the special game state, the large drop opening 423e repeats the transition from the closed state to the open state 15 times by the drive of the shutter member 422a, but the invention is not limited thereto, and the game ball is received. The easy open state may be an arbitrary number of times such as once or twice. The count sensor 113 of the present embodiment constitutes the detection means of the present invention.

  When the specific stop display mode in the special symbol display device 431 is a big hit, the gaming state shifts to the big hit gaming state of the special gaming state. In the big hit game state, a game in which the transition from the close state to the open state of the big winning opening 418 is repeated 15 times is regarded as one round, and a round game in which this round is repeated is performed. Such round games are counted as the number of rounds such as "one round" and "two rounds". For example, the first round game may be referred to as the first round, and the second round game may be referred to as the second round. In the present embodiment, the number of rounds in the jackpot gaming state is 10 rounds or 16 rounds, but the number of rounds is not limited to this, and the number of rounds can be any number.

  When the specific stop display mode in the special symbol display device 431 is a small hit, the gaming state shifts to the small hitting gaming state of the special gaming state. Then, in the small hit gaming state, a game in which the transition from the closed state to the open state of the large drop opening 423 e is repeated 15 times is performed only once. That is, in the small hit gaming state, the round game is not performed as in the big hit gaming state. When the big hit gaming state ends, the first gaming state or the second gaming state may be controlled as the normal gaming state. In addition, when the small hitting gaming state ends, it does not become the gaming state which is more advantageous than the gaming state when winning in the small hitting gaming state. Therefore, there is no transition of the gaming state in the normal gaming state triggered by winning in the small hitting gaming state, for example, when the gaming state when winning in the small hitting gaming state is the first gaming state, small The game state after the end of the hit game state is the first game state, and when the game state when the small hit game state is elected is the second game state, the game state after the end of the small hit game state is the second game It is a state. Further, in the present embodiment, after the end of the big hit gaming state, there may be a transition to a time saving state in which the time of the variation display of the special symbol becomes short. Such a special game state is an example of a special game state capable of giving the player a predetermined game value.

  In addition, when the game ball wins in the first starting opening 414a, the second starting opening 414b, the general winning openings 419a to 419d, and the large winning opening 418, the number of games set in advance according to the type of each winning opening The balls are dispensed by the dispensing unit 70 onto the upper tray 131 or the lower tray 132.

  Further, when the game ball driven into the game area 41 by the player passes the ball passage detector 416, the display lamp of the normal symbol display device 434 is variably displayed. Also, when the game ball passes the ball passage detector 416 during the variable symbol display of the normal symbol, the display mode by the normal symbol hold display device 435 is switched, and the normal symbol in the variable display is stopped and displayed, Execution (start) of the variation display of the normal symbol based on the passage of the gaming ball to the ball passage detector 416 is suspended. After that, when the normal symbol which has been variably displayed is stopped and displayed, the variable display of the normal symbol which has been suspended is started. Then, in the case where the normal symbol stopped and displayed in the normal symbol display device 434 shows a hit, the flat plate member 415a of the normal motorized actor 415 provided in the second starting opening 414b is pulled in for a predetermined time It becomes a state. As described above, a game in which the normal electric symbol 415 (see FIG. 4) changes in open and closed states according to the result is referred to as a "normal symbol game".

[The number of winning balls and the flow path of gaming balls]
As described above, according to the pachinko gaming machine 1 of the present embodiment, the first starting opening 414a, the second starting opening 414b, the large winning opening 418, and the general winning opening 419a, 419b, 419c, 419d are inserted. In the case of a ball, a prize ball is paid out from the payout opening.

  In the present embodiment, there are three winning balls by the winning on the first starting opening 414a, one winning ball by the winning on the second starting opening 414b, and prizes by the winning on general winning openings 419a, 419b and 419c. The number of balls is set to 10, the number of balls obtained by winning to the general winning hole 419 d is set to 3, and the number of balls obtained by winning to the large winning hole 418 is set to 15.

  FIG. 12 is an explanatory view showing the flow-down path of the game ball in the pachinko gaming machine 1 of the present embodiment. According to the pachinko gaming machine 1 of the present embodiment, normally, the player rotates the firing handle 21 (see FIG. 1) so as to enter the first starting opening 414a, and the game ball is displayed. Fire to the left area of the game area 41 as shown in middle a1 (striking left). However, in the big hit game state, it is necessary to fire the game ball toward the big winning opening 418, and in the short time state, to shoot the game ball toward the ball passage detector 416. Therefore, in the big hit gaming state and the time saving state, the player rotates the firing handle 21 largely to the right to fire the gaming ball to the right area of the gaming area 41 as shown by a2 in the figure (right Will).

  In the big hit game state, when the player shoots the game ball to the right area of the game area 41, most of them pass the ball passage detector 416, but the flat plate member 415a of the ordinary electric character 415 starts the second start Since the mouth 414 b is often closed, the gaming ball moves toward the distribution device 421. Then, one out of four gaming balls having passed through the distribution device 421 may enter the general winning opening 419 d. If the player enters the general winning opening 419d, three winning balls can be obtained, so three quarters of the game balls having passed through the sorting device 421 will return to the player.

  In addition, the game balls that have not entered the general winning opening 419 d or the third special out opening 420 d go to the shutter member 422 a side. During the round game, since the shutter member 422a is pulled in, as shown in FIG. 13, the gaming ball falls to the large drop opening 423e and goes to the large winning opening 418. In the interval time between the round game and the next round game, since the shutter member 422a protrudes, the gaming ball passes over the shutter member 422a and easily enters the first special out port 420b. Here, when the gaming ball passes over the shutter member 422a, the gaming ball collides with the rib 424a of the winning a prize mechanism 424 so as to move slowly over the shutter member 422a. Therefore, when the next round game is started, the number of game balls placed on the shutter member 422a is larger than that in the case where the rib 424a of the easy-to-win mechanism 424 does not exist. Therefore, in the pachinko gaming machine 1 of the present embodiment, the number of gaming balls entering the first special out port 420b decreases, and the number of gaming balls entering the large winning opening 418 increases.

  In the state where the shutter member 422a is open, the gaming ball slowly moves through the large drop opening 423e by colliding with the rib 424b (see FIG. 4) when passing through the large drop opening 423e.

  As described above, the pachinko gaming machine 1 according to the present embodiment can decelerate the game ball rolling on the outside of the shutter member 422a by the rib 424a when the shutter member 422a is in the closed state, and the shutter member 422a When in the open or closed state, the rib 424b (see FIG. 4) can decelerate the gaming ball rolling on the large drop opening 423e inside the shutter member 422a.

  Thereby, the game ball is in the big winning opening 418 before the game ball (a predetermined number of game balls for which the condition for closing the shutter member 422a is satisfied: for example, the tenth game ball) is detected by the count sensor 113 Before winning), it is possible to win many game balls by the large falling opening 423e. Therefore, many game balls can be paid out, and more profits can be given to the player.

  Here, the pachinko gaming machine 1 of the present embodiment has only one large winning opening, a large falling opening, and a shutter member (hereinafter, these are referred to as an "attacker"), but has a plurality of attackers. It is good also as composition which provides rib 424b in a large fall mouth of an attacker, and does not provide rib 424b in a large fall mouth of other attackers. In this case, a special winning of the predetermined attacker in which the rib is provided rather than the remaining winning ball monitoring time in the special winning opening of the other attacker who does not have the rib 424b (the residual ball monitoring time in the special winning opening will be described later). It is preferable to increase the intraoral residual sphere monitoring time. According to this, since it is possible to detect many game balls decelerated in the large fall mouth of a predetermined attacker by the count sensor, it is possible to pay out many game balls and to give the player more profit. Can.

  Also, the V winning area may be provided inside the large drop opening 423e having the rib 424b, and the gaming ball may win in the V winning area on the upstream side of the rib 424b. In this case, the game balls for winning in the V pay area can be made to win quickly in the V pay area without being decelerated, but more game balls can be paid for in the big winning opening 418.

  Here, the V winning area is, for example, a winning area in which, when the winning of the gaming ball is successful in the big hit gaming state, the gaming state shifts to a gaming state advantageous to the player such as the probability variation gaming state after the big hitting gaming state ends. On the other hand, when the game ball does not succeed in the V pay area, it shifts to the normal gaming state which is the non probability variation gaming state, the non probability variation gaming state and the non time saving gaming state, or the non probability variation gaming state and the time saving gaming state Do. The non-probable variation gaming state and the non-time-short gaming state may be referred to as a normal gaming state, and the non-probability variation gaming state and the short-time gaming state may be referred to as a short-time gaming state. It should be noted that when winning in the V winning area at the time of small hit, it may be made to shift to the big hit gaming state.

  According to the pachinko gaming machine 1 of the present embodiment, there are gaming balls entering the first special out port 420b and the third special out port 420d in the big hit gaming state, and there are four game balls Since there are three prize balls when entering the general winning opening 419d for the launch of the game, the increase in the number of balls held by the player is temporarily all the games that have been launched to the game area 41 in the big hit gaming state. The number of game balls fired from the increase number when the ball wins in the big winning opening 418, that is, 2400 balls (16R × 15 winning balls × 10 winnings) by the winning in the big winning hole 418 (16R × 10) less than 2240 subtracted.

  Also, in the time saving state, when the player shoots the game ball to the right area of the game area 41 (right strikes), according to the pachinko gaming machine 1 of the present embodiment, all the game balls fired are ball passing detectors It is arranged to pass 416. Furthermore, since the probability of hitting the symbol game is high, the flat plate member 415a of the ordinary motorized workpiece 415 operates frequently, and the number of balls entering the second starting opening 414b increases. Therefore, the progress of the special symbol game is accelerated. Further, when the player enters the second starting opening 414b, one winning ball can be obtained, so that the game balls corresponding to the amount of entering the second starting opening 414b will return. Further, similarly to the big hit gaming state, one out of four game balls having passed through the distribution device 421 enters the general winning opening 419 d. Therefore, in the pachinko gaming machine 1 of the present embodiment, it is possible to suppress the consumption of possession balls in the time saving state, for example, the special symbol game in the time saving state while the gaming balls remain on the upper plate 131. It is possible to advance. In the pachinko gaming machine 1 according to the present embodiment, all right-handed game balls pass the ball passage detector 416, so when there is no need to hit the right as in the normal gaming state, 1 It becomes possible to detect that the ball has been hit from the ball of the ball. As a result, it is possible to promptly notify by voice or image that "Please return to the left".

  In the time saving state, whether or not the sorting device 421 is in a state of sorting the gaming ball to the general winning opening 419d side is easy by confirming the position of the seal 508 (see FIG. 5) of the sorting device 421. Can be determined. For example, it is assumed that the player has stopped firing the game ball in order to end the game when the time saving state ends. At this time, when the position of the seal 508 is confirmed, and it is determined that the sorting device 421 is in the state of sorting the gaming balls to the general winning opening 419d side, three prizes can be obtained by hitting only one right. It becomes possible to obtain the interest of whether or not you can get a ball. Thus, the game can be ended without leaving an advantageous state for the next player who is about to start playing the game with the same pachinko gaming machine 1.

  In addition, three prize balls may be important. For example, if you have 2499 balls and you want to get 2500 for the prize you want, or if you have a single ball, you have a so-called super attrition, and you want to secure a game ball for a small hit. Etc., it becomes possible to easily increase the number of balls by confirming the position of the seal 508.

  Also, in the small hit gaming state, as described above, there is a possibility that the game ball having passed through the distribution device 421 may return to the player, and the game ball moves slowly on the shutter member 422a. Thus, even if the opening of the large drop opening 423 e is instantaneous, if it is one or two balls, there is a possibility of entering the ball. For this reason, there is a possibility that it is possible to slightly increase the number of balls by right-handing in the small hit gaming state. In this way, it is possible to give the player an interest even if it is a small hit.

  Further, in the pachinko gaming machine 1 according to the present embodiment described above, in the pachinko gaming machine 1 according to the present embodiment, all the game balls hit to the right pass the ball passing detector 416, and the sorting device 421 Therefore, although all the game balls distributed to the general winning opening 419 d side enter the general winning opening 419 d, the invention is not limited thereto. For example, the game nail 412 or the like may be disposed in the flow path of the game ball hit to the right, and a part of the game ball may deviate from the ball passage detector 416 or the general winning hole 419d.

[Configuration of rear ball passage unit]
As shown in FIG. 14, a rear ball passage unit 600 is provided on the back surface (rear surface) of the game board 40 (see FIG. 4). The rear ball passage unit 600 has a plurality of ball passages 601 and 602 which respectively constitute a winning area.

  The ball passage 601 extends in the vertical direction of the game board 40 (see FIG. 4), and the upper end of the ball passage 601 is in communication with the second start port 414b. As a result, the gaming ball having won the second starting opening 414 b is discharged to the inside of the ball passage 601.

  The ball passage 602 is inclined obliquely from the upper left to the lower right of the game board 40 (see FIG. 4), and the upper end of the ball passage 602 is in communication with the general winning opening 419d. As a result, the gaming balls having won the general winning opening 419 d are discharged to the inside of the ball passage 602.

  A ball passage 603 is provided downstream of the ball passage 601 and the ball passage 602, and a merging portion 604 for joining the ball passage 601 and the ball passage 602 is provided on the upstream side of the ball passage 603. The ball passage 603 is inclined downward and to the left from the merging portion 604, and the downstream end 603a of the ball passage 603 is located near the lower end of the game board 40 (see FIG. 4).

  The width of the merging portion 604 is formed such that two game balls can pass side by side in the left-right direction, that is, a width twice or more the diameter of the game balls. The game balls discharged from the ball passages 601 and 602 join together at the merging portion 604 and are discharged to the ball passage 603, and the game balls discharged to the ball passage 603 flow down the inside of the ball passage 603 to the downstream end 603a. It is discharged downward from the

  A divider plate 605 is provided at the downstream end of the ball passages 601 and 602. The divider plate 605 is comprised of a common wall forming ball passages 601, 602 and extends downwardly from the downstream end of the ball passages 601, 602.

  The extending direction of the partition plate 605 and the extending direction of the ball passage 601 are the same direction, and the extending direction of the ball passage 602 is obliquely inclined to the extending direction of the partition plate 605. Thereby, the gaming balls flowing down from the ball passage 602 to the merging portion 604 collide with the partition plate 605, and the traveling direction A thereof is substantially the same as the traveling direction B of the gaming balls flowing down from the ball passage 601 to the merging portion 604 It is guided by the partition plate 605 so that the directions A and B are parallel. The partition plate 605 of the present embodiment constitutes the partition portion of the present invention.

  In the middle of the ball passage 602, a general winning ball sensor 114b is provided, and the gaming ball flowing down the inside of the ball passage 602 is detected by the general winning ball sensor 114b (see FIG. 51). Here, the general winning ball sensor 114b is provided in the general winning opening 419d (see FIG. 4). Further, as described above, the general winning ball sensor 114a (see FIG. 51) is provided on a common passage (not shown) in which the game balls winning in the general winning openings 419a, 419b and 419c flow.

  As described above, in the rear ball passage unit 600 of the present embodiment, the traveling direction A of the gaming ball flowing down from the ball passage 602 to the merging portion 604 is the traveling direction B of the gaming ball flowing down the merging portion 604 from the ball passage 601 And a partition plate 605 for guiding the game ball in the same direction of travel.

  Thereby, it is possible to prevent the game balls flowing down from each of the ball passages 601 and 602 in the merging portion 604 from coming into contact with each other. For this reason, it can prevent that ball clogging generate | occur | produces and can continue a game smoothly.

  In particular, the partition plate 605 is such that the traveling direction A of the game ball colliding with the partition plate 605 from the ball passage 602 and the traveling direction B of the game ball flowing down from the ball passage 601 to the merging portion 604 are parallel. Since the gaming balls are guided to the merging portion 604, the gaming balls flowing down from the ball passages 601 and 602 can be more effectively prevented from contacting each other.

  Further, since it is possible to prevent the game balls flowing down from the plurality of ball passages 601 and 602 from coming into contact in the merging portion 604, the gaming balls flowing down from the ball passage 602 to the merging portion 604 flow down from the ball passage 601 to the merging portion 604 It is possible to prevent the ball from colliding with the game ball and pushing it back to the ball passage 602.

  As a result, it is possible to prevent one game ball from being detected twice or more by the general winning ball sensor 114 b (so-called chattering) inside the ball passage 602. Therefore, the payout of the game balls more than necessary can be prevented, and the reliability of the pachinko gaming machine 1 can be prevented from being deteriorated.

  Further, according to the rear ball passage unit 600 of the present embodiment, since the partition plate 605 is formed of the common wall portion forming the ball passages 601 and 602, the partition plate 605 is formed with respect to the ball passages 601 and 602. It is possible to simplify the configuration of the ball passages 601 and 602 by eliminating the need to add a dedicated member that makes up the.

[Configuration and operation of lower movable effect member 610]
As shown in FIGS. 4 and 20, a lower movable effect member 610 is provided in the pachinko gaming machine 1 of the present embodiment. The lower movable effect member 610 is provided below the display area 51 behind the gaming board 40. Note that FIG. 4 shows a state in which the lower movable effect member 610 is positioned behind and below the stage 413 d (a state in which it is positioned at a standby position described later). Therefore, as shown in FIG. 4, in the standby position, control can be performed so that a part or all of the lower movable effect member 610 is not visually recognized by the player. On the other hand, FIG. 20 shows a state in which the lower movable effect member 610 is positioned behind and above the stage 413 d (a state in which it is positioned at a driving position described later). For this reason, as shown in FIG. 20, in the drive position, control can be performed so that a part or all of the lower movable effect member 610 can be viewed from the player.

  The lower movable presentation member 610 of the present embodiment constitutes a product of the present invention. Note that the drawings attached with the front, rear, upper, lower, left, and right directions represent directions based on the player located in front of the pachinko gaming machine 1.

  As shown in FIG. 15, the lower movable effect member 610 includes a lower fixed base 611, and the lower fixed base 611 is fixed to the spacer 90 (see FIG. 3). The spacer 90 (see FIG. 3) of the present embodiment constitutes the support member of the present invention.

  As shown in FIG. 16, a motor 612 is provided on the front surface (front surface) of the lower fixed base 611. The motor shaft (not shown) of the motor 612 is provided with a gear 613 (see FIG. 17). As shown in FIG. 17, the gear 613 is rotatably supported on the rear surface of the lower fixed base 611.

  As shown in FIG. 16, a gear 614 is rotatably supported on the front surface of the lower fixed base 611. As shown in FIG. 18, the gear 614 is in mesh with the gear 613. In FIG. 18, the lower fixed base 611 is indicated by an imaginary line.

  As shown in FIG. 16, a fitting protrusion 614A is formed on the gear 614, and the fitting protrusion 614A protrudes forward from the gear 614. The lower fixed base 611 is formed with vertically elongated protrusions 611A and 611B that extend in the vertical direction and project forward from the lower fixed base 611, and a slit 611c. The slit 611c is provided at a position adjacent to the protrusion 611A between the protrusion 611A and the protrusion 611B.

  Slits 611a and 611b are formed in the protrusions 611A and 611B, and rack teeth 611G are formed on the side surfaces of the protrusions 611A. A lower movable base 615 and a movable arm 618 are provided on the front side of the lower fixed base 611. The lower fixed base 611 of this embodiment constitutes the fixed member of the present invention, and the movable arm 618 constitutes the arm member of the present invention.

  A slit 615A is formed in the lower part of the lower movable base 615, and the slit 615A extends in the left-right direction. As shown in FIG. 17, relay gears 616A and 616B and a disk member 617 are rotatably supported on the rear surface of the lower movable base 615.

  As shown in FIG. 17, the relay gear 616A is rotatably supported by the fitting projection 615c of the lower movable base 615. The relay gear 616A is in mesh with the relay gear 616B.

  As shown in FIG. 18, on the front surface of the disk member 617, a gear portion 617A that meshes with the relay gear 616B is formed. Further, as shown in FIG. 17, on the rear surface of the disc member 617, a protrusion 617B that protrudes rearward from the disc member 617 is formed.

  As shown in FIG. 16, at one end of the movable arm 618, a fitting hole 618a into which the protrusion 611D formed on the lower fixed base 611 is fitted is formed. The movable arm 618 is rotatably supported by the protrusion 611D via a fitting hole 618a formed at one end. Thereby, the movable arm 618 swings with the protrusion 611D as a fulcrum.

  As shown in FIG. 17, a fitting projection 618A is provided at the other end of the movable arm 618, and the fitting projection 618A slides on the slit 615A of the lower movable base 615 via the sliding bush 619F. It is freely fitted.

  As shown in FIG. 16, a slit 618B is formed at the longitudinal middle portion of the movable arm 618, and a fitting projection 614A of the gear 614 is slidably fitted in the slit 618B.

  As shown in FIG. 17, on the rear surface of the lower movable base 615, a plurality of fitting projections 615a to 615e that project rearward from the lower movable base 615 are formed, and the fitting projections 615a to 615e slide It is slidably fitted to the slits 611a, 611b and 611c of the lower fixed base 611 via the bushes 619A to 619E.

  Thereby, as shown in FIGS. 18 and 19, when the motor 612 is driven, the gear 613 rotates the gear 614, and along with the rotation of the gear 614, the fitting projection 614A is along the slit 618B of the movable arm 618. The movable arm 618 swings up and down with the protrusion 611D as a fulcrum.

  When the movable arm 618 swings in the vertical direction, the fitting projection 618A of the movable arm 618 moves along the slit 615A of the lower movable base 615, thereby pressing the lower movable base 615 in the vertical direction.

  When the lower movable base 615 is pressed in the vertical direction, the fitting projections 615a to 615e of the lower movable base 615 move along the slits 611a to 611c via the slide bushes 619A to 619E, thereby the lower side The movable base 615 moves in the vertical direction with respect to the lower fixed base 611.

  As shown in FIG. 15, one end of the movable arm 618 and the lower fixed base 611 are elastically connected by a coil spring 620. The coil spring 620 has one end attached to one end of the movable arm 618 and the other end attached to the lower fixed base 611. The coil spring 620 biases the movable arm 618 such that the movable arm 618 swings upward, that is, presses the lower movable base 615 upward.

  As shown in FIG. 16, a rotating body 621 is provided on the front side of the lower movable base 615, and the rotating body 621 includes an electric decoration substrate 622A and an inner lens 622B provided on the front side of the electric decoration substrate 622A. And. An LED (not shown) is provided on the electric decoration substrate 622A, and the light is controlled by the electric decoration substrate 622A to emit light through the inner lens 622B.

  As shown in FIG. 17, the rotating body 621 is provided with a rotating shaft 621A, and the rotating shaft 621A protrudes rearward from the rotating body 621. The rotary shaft 621A is rotatably supported by a bearing portion 615D (see FIG. 16) formed on the lower movable base 615. The rear end (the tip in the projecting direction) of the rotating shaft 621 A is fixed to the disc member 617, and the rotating body 621 rotates integrally with the disc member 617.

  In the lower movable effect member 610, as shown in FIG. 18, when the lower movable base 615 moves in the vertical direction, the relay gear 616A that meshes with the rack teeth 611G is rotated. When the relay gear 616A rotates, power is transmitted from the relay gear 616A to the gear portion 617A via the relay gear 616B, and the disc member 617 rotates. For this reason, the rotating body 621 rotates with the disc member 617. As a result, as the lower movable base 615 moves in the vertical direction, an effect of rotating the rotating body 621 is performed.

  As shown in FIG. 16, a curved groove 611 </ b> E is formed on the front surface of the lower fixed base 611. The curved groove 611E has a curved shape that matches the rotation trajectory of the protrusion 617B (see FIG. 18) when the disk member 617 (see FIG. 17) rotates. Thereby, as shown in FIG. 18, when the disc member 617 rotates integrally with the rotating body 621, the protrusion 617B is guided along the curved groove 611E, and the disc member 617 and the rotating body 621 are rotated. It is possible to prevent the obstruction by the projection 617B.

  Here, the lower fixed base 611 of the present embodiment constitutes the fixed body of the present invention, and the lower movable base 615 and the rotating body 621 constitute the movable body of the present invention. The state where the rotating body 621 is positioned lowermost with respect to the lower fixed base 611 (the state shown in FIG. 18) corresponds to the standby position of the present invention, and the rotating body 621 is the most for the lower fixed base 611. The upper position (the state shown in FIG. 19) corresponds to the drive position of the present invention.

  As shown in FIG. 16, an L-shaped locking piece 611 F is provided on the front surface of the lower fixed base 611, and the lower movable base 615 has a direction opposite to that of the locking piece 611 F described above. An L-shaped locking piece 615B is formed.

  As shown in FIG. 18, the locking piece 611 F locks the lower movable base 615 to the lower fixed base 611 by locking to the locking piece 615 B at the standby position where the lower fixed base 611 is located at the lowermost position. It locks and regulates that the lower movable base 615 moves forward in the standby position. The locking piece 611F of the present embodiment constitutes a first locking portion of the present invention, and the locking piece 615B constitutes a second locking portion of the present invention. Further, the locking piece 611F and the locking piece 615B constitute the locking means of the present invention.

  As shown in FIG. 16, a base cover 623 is provided on the front side of the rotating body 621, and the base cover 623 is fixed to the lower fixed base 611 by a screw (not shown). The base cover 623 extends in the left-right direction of the pachinko gaming machine 1, and is provided on the front side of the rotating body 621 (see FIG. 15) with the rotating body 621 positioned at the standby position. In this case, the rotating body 621 is restricted from moving forward by contacting the rotating body 621.

  A relay substrate 624 is attached to the base cover 623, and the relay substrate 624 is connected to the electric decoration substrate 622 A of the rotating body 621 via a flexible cable 625. The electric decoration board 622A performs lighting control of a not-shown LED based on a control signal transmitted from the LED control circuit 250 (see FIG. 51).

  The flexible cable 625 is disposed along the front surface of the base cover 623. A pressing member 623A is provided on the front surface of the base cover 623, and the flexible cable 625 is supported and protected by the pressing member 623A on the base cover 623. The base cover 623 of the present embodiment constitutes the guide member of the present invention, and the flexible cable 625 constitutes the wiring of the present invention.

  A rib 626 extending in the vertical direction is provided on the upper portion of the lower fixed base 611, and the rib 626 is such that the projection 617B of the disk member 617 contacts the upper side surface 626A and the lower side surface 626B. ing. The rib 626 of the present embodiment constitutes the first rib and the second rib of the present invention.

  Specifically, as shown in FIG. 18, the protrusion 617 B is below the rib 626 in a state where the rotating body 621 is rotated and positioned at the standby position as the lower movable base 615 moves downward. It abuts the side surface 626B. Thereby, the rotation (movement) of the rotating body 621 is restricted in the direction (counterclockwise direction in FIG. 18) opposite to the rotation direction when moving from the standby position to the driving position.

  When the rotating body 621 is stopped at the standby position, the motor 612 is driven to bias the rotating body 621 so as not to move from the drive position toward the standby position. That is, when the rotating body 621 is stopped at the standby position, the motor 612 is driven to rotate the motor 612 forward to drive the rotating body 621 from the drive position in the direction opposite to the standby position (in FIG. Counterclockwise)) is applied. Here, since the rotating body 621 only needs to be biased so as not to move from the driving position toward the standby position, the rotating body 621 is in the direction opposite to the driving position or the standby position. It suffices to be biased so as to be at the shifted position.

  Here, the left end portion (the end portion on the side of the protrusion 611D) of the slit 618B has a shape bent downward (see FIG. 19). Thus, when the fitting protrusion 614A is at the left end of the slit 618B (when in the state shown in FIG. 18), the fitting protrusion 614A can be prevented from easily moving rightward in the slit 618B. . Therefore, the rotating body 621 can be stably held at the standby position by bending the left end portion of the slit 618B.

  On the other hand, as shown in FIG. 19, with the lower movable base 615 moving upward, the rotating body 621 is rotated and positioned at the driving position, the protrusion 617 B is the side 626 A on the upper side of the rib 626. Abut on. This restricts the rotation (movement) of the rotating body 621 in the direction (clockwise direction in FIG. 19) opposite to the rotation direction when moving from the drive position to the standby position.

  Furthermore, when the rotating body 621 is stopped at the driving position, by driving the motor 612, at least the rotating body 621 is watched in FIG. 19 so that it does not move from the driving position toward the standby position. A driving force is applied that biases in the circumferential direction. The motor 612 of the present embodiment constitutes the drive means of the present invention.

  The protrusion 617B of the present embodiment constitutes a first contact portion of the present invention, and the rib 626 constitutes a second contact portion of the present invention. In the present embodiment, the lower movable effect member 610 causes the projection 617B to abut on the upper side surface 626A and the lower side surface 626B of one rib 626 in the standby position and the drive position. Two ribs may be provided, and the projection 617B may be in contact with one rib in the standby position, and the projection 617B may be in contact with the other rib in the drive position.

  As shown in FIG. 18, a detection piece 615C is formed at the left end of the lower movable base 615, and the detection piece 615C is detected by an optical home position sensor 627. The home position sensor 627 is provided below the front surface of the lower fixed base 611, and detects the detection piece 615C when the lower fixed base 611 is positioned at the standby position.

  The home position sensor 627 outputs a detection signal to the main control circuit 100 (see FIG. 51) when detecting the detection piece 615C. The main control circuit 100 determines that the lower movable base 615 and the rotating body 621 are positioned at the standby position based on the detection signal input from the home position sensor 627, and the sub control circuit 200 (see FIG. The motor control command is transmitted to FIG.

  When receiving the motor control command from the main control circuit 100, the sub control circuit 200 outputs a motor control signal to the movable effect device control circuit 205 (see FIG. 51). The movable effect device control circuit 205 drives the motor 612 based on the motor control signal to move the lower movable base 615 and the rotary body 621 to the standby position and the drive position, and at the standby position and the drive position, the rotary body Control to activate 621 is performed.

  Next, the operation of the lower movable effect member 610 will be described with reference to FIGS. 18 and 19.

  As shown in FIG. 18, when the lower movable base 615 and the rotating body 621 are in the standby position, the locking piece 611F of the lower fixed base 611 locks to the locking piece 615B of the lower movable base 615. Thus, the lower movable base 615 is locked to the lower fixed base 611, and the lower movable base 615 is restricted from moving forward.

  When the motor 612 is driven in one direction with the lower movable base 615 and the rotating body 621 positioned at the standby position (the state shown in FIG. 18), power is transmitted from the gear 613 to the gear 614.

  When the gear 614 rotates, the fitting protrusion 614A moves along the slit 618B of the movable arm 618, whereby the movable arm 618 pivots upward with the protrusion 611D as a fulcrum.

  As a result, the fitting projection 618A of the movable arm 618 slides along the slit 615A of the lower movable base 615, and presses the lower movable base 615 upward. Further, when the movable arm 618 pivots upward with the protrusion 611D as a fulcrum, one end of the movable arm 618 is biased downward by the coil spring 620. As a result, the biasing force of the coil spring 620 becomes an assist force when pressing the lower movable base 615 and the rotating body 621 which are heavy objects upward.

  When the lower movable base 615 is pressed upward, the fitting projections 615a to 615e of the lower movable base 615 move upward along the slits 611a to 611c via the slide bushes 619A to 619E, thereby causing the lower The side movable base 615 moves upward with respect to the lower fixed base 611.

  When the lower movable base 615 moves upward, the relay gear 616A engaged with the rack teeth 611G rotates, and power is transmitted from the relay gear 616A to the gear portion 617A of the disk member 617 via the relay gear 616B. . Accordingly, as the lower movable base 615 is lifted, the rotary body 621 rotates integrally with the disc member 617, and the protrusion 617B moves along the curved groove 611E of the lower fixed base 611. Therefore, the rotating body 621 smoothly rotates to the drive position (see FIGS. 19 and 20). FIG. 20 shows a state in which the lower movable effect member 610 has moved to the drive position with respect to the game board 40.

  As shown in FIG. 19, when the lower movable base 615 is raised and the rotating body 621 moves to the drive position, the protrusion 617B abuts on the upper side surface 626A of the rib 626, and the rotating body 621 further rotates from the drive position. Being regulated.

  In addition, when the rotating body 621 is stopped at the driving position, the motor 612 is driven to move the rotating body 621 from the driving position to the standby position in the opposite direction (clockwise direction in FIG. 19). Energize. The biasing force at this time may be smaller than the driving force of the motor 612 when moving the lower movable base 615 and the rotating body 621 from the standby position to the driving position. As described above, by biasing the rotary body 621 at the drive position, it is possible to prevent the rotary body 621 from being shaken at the drive position, and the posture of the rotary body 621 can be stabilized.

  Next, as shown in FIG. 19, the motor 612 is moved in the other direction (the lower movable base 615 and the rotating body 621 are moved from the standby position to the driving position) from the state where the lower movable base 615 and the rotating body 621 are positioned When it is driven in the direction opposite to the direction of rotation (in the direction opposite to the direction of rotation), power is transmitted from the gear 613 to the gear 614.

  When the gear 614 rotates, the fitting protrusion 614A moves along the slit 618B of the movable arm 618, whereby the movable arm 618 swings downward about the protrusion 611D.

  As a result, the fitting projection 618A of the movable arm 618 slides along the slit 615A of the lower movable base 615, and presses the lower movable base 615 downward. When the lower movable base 615 is pressed downward, the fitting projections 615a to 615e of the lower movable base 615 move downward along the slits 611a to 611c via the slide bushes 619A to 619E, thereby causing the lower The side movable base 615 moves downward with respect to the lower fixed base 611.

  When the lower movable base 615 moves downward, the relay gear 616A engaged with the rack teeth 611G rotates, and power is transmitted from the relay gear 616A to the gear portion 617A of the disk member 617 via the relay gear 616B. . Thereby, as the lower movable base 615 descends, the rotary body 621 rotates integrally with the disc member 617, and the protrusion 617B moves along the curved groove 611E of the lower fixed base 611. For this reason, the rotating body 621 smoothly rotates to the standby position.

  As shown in FIG. 18, when the lower movable base 615 descends and the rotating body 621 moves to the standby position, the protrusion 617B abuts on the lower side surface 626B of the rib 626, and the rotating body 621 further from the standby position It is regulated to rotate.

  When the rotating body 621 is stopped at the standby position, the motor 612 is driven to move the rotating body 621 from the standby position to the drive position in the opposite direction (counterclockwise direction in FIG. 18). Bias). The biasing force at this time may be smaller than the driving force of the motor 612 when moving the lower movable base 615 and the rotating body 621 from the driving position to the standby position.

  As described above, the lower movable effect member 610 according to the present embodiment includes the lower fixed base 611 and the lower movable base 615 movable with respect to the lower fixed base 611 and the rotating body 621. The side movable base 615 and the rotating body 621 are movable between the standby position and the drive position (see FIGS. 18 and 19).

  The lower movable effect member 610 includes a locking piece 611F provided on the lower fixed base 611 and a locking piece 615B provided on the lower movable base 615, and engages with the locking piece 611F in the standby position. The locking pieces 615 B and the locking pieces 615 B are configured to restrict swinging of the lower movable base 615 and the rotating body 621 (see FIG. 18).

  Furthermore, the lower movable effect member 610 is provided with a base cover 623 for guiding the flexible cable 625 connected to the rotary body 621. The lower cover 623 and the rotary body 621 are positioned at the standby position. In the above state, it is provided in front of the rotating body 621, and restricts the lower movable base 615 and the rotating body 621 from moving forward (see FIG. 15).

  Thus, the lower movable base 615 and the rotary body 621 can be prevented from swinging forward with respect to the lower fixed base 611 in the standby position, and the lower movable base 615 and the rotary body 621 can be stably held. Can.

  Furthermore, since the lower movable base 615 and the rotary body 621 can be restricted from moving forward by the base cover 623 in the state where the lower movable base 615 and the rotary body 621 are positioned at the standby position, the pachinko gaming machine The lower movable base 615 and the rotary body 621 can be prevented from moving forward with respect to the lower fixed base 611 when excessive vibration is applied to the lower movable presentation member 610, for example, during conveyance of 1.

  As a result, the locking between the locking piece 611F and the locking piece 615B is not released in the state where the lower movable base 615 and the rotary body 621 are positioned at the standby position. For this reason, it is possible to prevent the occurrence of a problem in the operation of the lower movable presentation member 610 due to the locking between the locking piece 611F and the locking piece 615B being released. Therefore, the rendering effect can be improved while ensuring that the lower movable presentation member 610 is smoothly operated.

  In addition to this, since the base cover 623 is constituted by a guide member for guiding the flexible cable 625 connected to the electric decoration substrate 622 A of the rotating body 621 (see FIG. 16), the lower movable base 615 and the rotating body 621 Can eliminate the need for a dedicated member that regulates forward movement of the For this reason, it can prevent that the number of parts of the lower side movable effect member 610 increases, and it can prevent that the manufacturing cost of the lower side movable effect member 610 increases.

  In addition, the lower movable effect member 610 of the present embodiment includes the motor 612 for moving the lower movable base 615 and the rotating body 621 to the standby position and the drive position, and the lower movable base 615 is lower at the drive position. The lower fixed base 611 has a rib 626 with which the protrusion 617B abuts when the lower movable base 615 and the rotary member 621 are in the driving position (FIG. 18). And FIG. 19).

  Further, the motor 612 is configured such that at least the rotor 621 does not move from the drive position toward the standby position when the lower movable base 615 and the rotor 621 are stopped at the drive position, as shown in FIG. A drive force is applied that biases in the clockwise direction.

  Thus, the lower movable base 615 and the rotary body 621 can be prevented from swinging at the drive position, and the lower movable base 615 and the rotary body 621 can be stably stopped at the drive position. As a result, it is possible to improve the effect of the lower movable effect member 610 while guaranteeing that the lower movable effect member 610 is smoothly operated.

  Further, the lower movable effect member 610 of the present invention is connected to the lower movable base 615, and transmits the driving force of the motor 612 to the lower movable base 615 so that the lower movable base 615 and the rotating body 621 are in the standby position. And a drive position to move the movable arm 618 (see FIGS. 18 and 19).

  Accordingly, when the lower movable base 615 and the rotary body 621 are positioned at the drive position (the position shown in FIG. 19), excessive load is applied to the lower movable base 615 and the rotary body 621 from the motor 612 via the movable arm 618. The movable arm 618 is flexed to absorb the load applied from the rib 626 to the projection 617B. As a result, it is possible to prevent the excessive load from being applied to the lower movable base 615, the rotating body 621 and the motor 612.

  Furthermore, when the lower movable base 615 and the rotating body 621 are positioned at the drive position (the position shown in FIG. 19), the driving gear 613 provided between the lower movable base 615 and the lower fixed base 611 When the play of the gear portion 617A and the relay gears 616A and 616B is generated, the play of the movable arm 618 can be eliminated by bending the moveable arm 618 by the play.

  Further, according to the lower side movable effect member 610 of the present embodiment, the rib 626 has the upper side surface 626A with which the projection 617B abuts when the lower side movable base 615 and the rotary body 621 are in the driving position, When the lower movable base 615 and the rotary body 621 are moved to the drive position, the lower movable base 615 and the rotary body 621 have the lower side 626B with which the projection 617B abuts when the side movable base 615 and the rotary body 621 are in the standby position. The projection 617B preferably abuts on the lower side surface 626B when the projection 617B abuts on the upper side surface 626A and the lower movable base 615 and the rotary body 621 move to the standby position (FIG. 18 and FIG. 18). 19).

  Thereby, the lower movable base 615 and the rotating body 621 can be stably stopped at any of the drive position and the standby position.

  In the lower movable effect member 610 of the present embodiment, at least one of the rib 626 and the projection 617B is provided with an elastic member such as rubber, soft resin or the like that abuts on the other of the rib 626 and the projection 617B. It is also good.

  In this way, when the rotating body 621 is positioned at the driving position, the elastic member is bent when an excessive load is applied to the rotating body 621 and the lower movable base 615 from the motor 612 via the movable arm 618. The load applied to the rib 626 from the protrusion 617B can be absorbed.

  As a result, it is possible to prevent an excessive load from being applied to the motor 612, the rotating body 621, and the lower movable base 615. Further, by combining the elastic deformation of the elastic member and the movable arm 618, the load applied from the protrusion 617B to the rib 626 can be absorbed more effectively.

  In the present embodiment, the protrusion 617B rotates about one and a half rotations when the rotating body 621 moves from the standby position to the drive position, so an elastic member is provided on at least one side of the protrusion 617B. It may be provided. If such a structure is used, the lateral width can be prevented from becoming wider than when the elastic members are provided on both side surfaces of the protrusion 617B.

  Further, according to the lower side movable effect member 610 of the present embodiment, when moving the rotating body 621 from the standby position to the driving position, the rotating body 621 slightly advances from the driving position (the regular stop position). By driving the motor 612 so as to rotate to the position, control is performed to urge the rotary body 621 to be pushed from the drive position (the regular stop position). Thereby, it is possible to prevent the rotating body 621 from being shaken at the drive position, and the posture of the rotating body 621 can be stabilized. For this reason, the rendering effect by the lower side movable rendering member 610 can be enhanced.

  Here, when moving the rotating body 621 from the standby position to the driving position, the movable effect device control circuit 205 drives several pulses in the number of pulses of the motor 612 until the rotating body 621 moves from the standby position to the driving position. By applying a pulse to drive the motor 612, control may be performed to urge the rotary body 621 to be pushed from the drive position. In addition, when there is a sensor that detects that the rotating body 621 is in the drive position, the driving of the motor 612 is not stopped at the time of detection by the sensor, but after the detection by the sensor By stopping the driving of the motor 612, control may be performed to bias the rotating body 621 so as to push it from the driving position (the normal stopping position).

  Alternatively, a permanent magnet may be provided on one of the rib 626 and the protrusion 617B, and an armature may be provided on either the rib 626 or the protrusion 617B. In this case, even when the rotating body 621 is in either the drive position or the standby position, the rib 626 and the projection 617B can be attracted by the magnetic force of the permanent magnet. Thereby, the lower movable base 615 and the rotating body 621 can be stably stopped at any of the drive position and the standby position.

[Configuration and operation of upper movable presentation member 650]
As shown in FIG. 4, an upper movable effect member 650 is provided in the pachinko gaming machine 1 of the present embodiment. The upper movable effect member 650 is provided above the display area 51 behind the gaming board 40. Note that FIG. 4 shows a state in which the upper movable effect member 650 is positioned behind the central base plate 413 (a state in which it is positioned at a standby position described later). For this reason, as shown in FIG. 4, the upper movable presentation member 650 is configured such that the entire player is not visually recognized at the standby position. The upper movable presentation member 650 of the present embodiment constitutes a product of the present invention.

  As shown in FIG. 21, the upper movable effect member 650 is formed in a shape imitating a long sword, and includes an upper fixed base 651. The upper fixed base 651 is fixed to the spacer 90 (see FIG. 3) at the rear of the game board 40.

  As shown in FIG. 22, a motor 652 is attached to the front of the upper fixed base 651. A gear 653 (see FIG. 23) is attached to a motor shaft (not shown) of the motor 652, and the gear 653 is rotatably supported on the rear surface of the upper fixed base 651.

  A gear 654 is rotatably supported on the rear surface of the upper fixed base 651, and the gear 654 meshes with the gear 653 (see FIG. 23). A fitting projection 654A is provided on the front surface of the gear 654, and the fitting projection 654A protrudes forward from the gear 654.

  A slit 651A is formed on the upper portion of the upper fixed base 651, and the slit 651A is curved from the upper left to the lower right. A rocking shaft 651B is formed on the front surface of the upper fixed base 651, and the rocking shaft 651B protrudes forward from the upper fixed base 651.

  An upper movable base 655 is provided on the front side of the upper fixed base 651. A boss 655A (see FIG. 23) is formed at the lower left portion of the upper movable base 655, and the pivot shaft 651B is rotatably fitted to the boss 655A. Accordingly, the upper movable base 655 swings up and down with respect to the upper fixed base 651 with the swing shaft 651B as a fulcrum.

  In the upper movable presentation member 650 of the present embodiment, the swing shaft 651B of the upper movable base 655 constitutes the base end portion of the present invention. Further, as shown in FIG. 21, the state in which the upper movable base 655 extends horizontally in the upper direction is the standby position of the upper movable effect member 650, and as shown in FIG. The inclined state is the drive position of the upper movable effect member 650.

  As shown in FIG. 23, a fitting protrusion 655D is formed on the upper left portion of the rear surface of the upper movable base 655, and the fitting protrusion 655D is slidably fitted in the slit 651A via the swinging bush 656A. It is done.

  A slit 655 B is formed at the lower left portion of the upper movable base 655, and the slit 655 B extends in the longitudinal direction (left and right direction) of the upper movable base 655. A fitting protrusion 654A (see FIG. 22) of the gear 654 is slidably fitted to the slit 655B via a slide bush 656B.

  A slit 655 C is formed in the upper left portion of the upper movable base 655, and the slit 655 C extends longer than the slit 655 B in the longitudinal direction of the upper movable base 655.

  As shown in FIG. 22, in the upper movable base 655 of this embodiment, when the gear 654 rotates, the fitting projection 654A of the gear 654 moves along the slit 655B (see FIG. 23) of the upper movable base 655. Thus, the fitting projection 655D (see FIG. 23) moves along the slit 651A. Thereby, the upper movable base 655 swings up and down along the curved shape of the slit 651A, with the swing shaft 651B as a fulcrum.

  An upper slide base 657 is provided on the front surface of the upper movable base 655, and the upper slide base 657 is formed in a shape imitating a blade, and a decoration imitating a blade is provided.

  A fitting protrusion 657A is provided on the upper left portion of the upper slide base 657, and the fitting protrusion 657A protrudes rearward from the upper slide base 657. The fitting protrusion 657A is slidably fitted in the slit 655C of the upper movable base 655 via the sliding bush 656C.

  The upper movable base 655 is formed with a pair of vertically spaced apart slits 655E and 655F, and the slits 655E and 655F both extend in the longitudinal direction of the upper movable base 655. The slits 655 E and 655 F are formed to be offset from each other in the longitudinal direction of the upper movable base 655, the slit 655 E is closer to the longitudinal center of the upper movable base 655, and the slit 655 F is in the longitudinal direction of the upper movable base 655. It is formed near the end of the

  As shown in FIG. 23, a fitting protrusion 657B is provided on the rear surface of the upper slide base 657. The fitting protrusion 657B protrudes rearward from the upper slide base 657, and is slidably fitted in the slit 655E via the slide bush 656D.

  The rear surface of the upper slide base 657 is provided with a pair of fitting projections 657C. The fitting projection 657C protrudes rearward from the upper slide base 657, and is slidably fitted in the slit 655F via a pair of sliding bushes 656E (see FIG. 22).

  A movable slider 658 is provided on the rear surface of the upper slide base 657, and the aforementioned pair of sliding bushes 656E (see FIG. 22) are attached to the front surface side of the movable slider 658. Therefore, the movable slider 658 slides in the slit 655F integrally with the pair of sliding bushes 656E (see FIG. 22).

  The upper slide base 657 is integrated with the upper movable base 655 by fitting the fitting projections 657A, 657B, 657C to the slits 655C, 655E, 655F, respectively, and the upper movable base 655 swings in the vertical direction. When moving, it swings integrally with the upper movable base 655.

  As shown in FIG. 22, a rack 659 is provided on the rear surface of the upper slide base 657, and the rack 659 is fixed to the upper slide base 657 and integrated with the upper movable base 655.

  The upper movable base 655 is formed with a guide groove 655G extending along the longitudinal direction of the upper movable base 655, and a guide protrusion 659a formed on the rack 659 is slidably fitted in the guide groove 655G. .

  Rack teeth 659A are formed in the lower part of the rack 659, and a gear 660 is engaged with the rack teeth 659A. The gear 660 is rotatably supported on the front surface of the upper slide base 657. The gear 660 is attached to a rotating shaft (not shown) of a motor 661 (see FIG. 23) provided on the rear surface of the upper slide base 657.

  When motor 661 (see FIG. 23) is driven, power is transmitted from gear 660 to rack teeth 659A, and rack 659 is integrated with upper slide base 657 in the longitudinal direction of upper movable base 655 relative to upper movable base 655. Moving.

  At this time, the rack 659 moves while the gear 660 and the rack teeth 659A are stably meshed as the guide protrusion 659a moves along the guide groove 655G of the upper movable base 655.

  Further, as shown in FIG. 23, the fitting protrusions 657A, 657B, 657C move in the longitudinal direction of the upper movable base 655 along the slits 655C, 655E, 655F, respectively. Accordingly, the upper slide base 657 moves smoothly with respect to the upper movable base 655 without the upper movable base 655 and the upper slide base 657 being shifted in the vertical direction. The upper movable base 655 of the present embodiment constitutes the base body of the present invention, and the upper slide base 657 constitutes the movable body of the present invention. The upper movable base 655 constitutes a first moving member of the present invention, and the upper slide base 657 constitutes a second moving member of the present invention.

  The upper slide base 657 has a first movement position (for example, the positions shown in FIGS. 26 and 27) with the largest area overlapping the upper movable base 655 in the front-rear direction of the pachinko gaming machine 1 (for example, the positions shown in FIGS. The pachinko gaming machine 1 is moved to the second movement position (for example, the position shown in FIG. 28) having the smallest area overlapping in the front-rear direction.

  As shown in FIG. 23, on the rear surface of the upper movable base 655, a pair of movable arms 662 and 663 that simulate the shape of a blade is provided. A plurality of protrusions 655H, 655I, 655J, and 655K are formed on the rear surface of the upper movable base 655, and the base ends of the movable arms 662 and 663 are rotatably fitted to the protrusions 655H and 655I, respectively. . As a result, the movable arms 662 and 663 move in the direction in which the tip end portion approaches and separates with the protrusions 655H and 655I as a fulcrum.

  As shown in FIG. 24, gear portions 662A and 663A are formed at proximal ends of the movable arms 662 and 663, and gears 664 and 665 are engaged with the gear portions 662A and 663A.

  As shown in FIG. 23, the gears 664 and 665 are rotatably supported by the protrusions 655J and 655K, and when the gears 664 and 665 rotate, the movable arms 662 and 663 swing around the protrusions 655H and 655I. Do.

  As shown in FIG. 24, the gear 664 is formed with a rib 664 A, and the rib 664 A protrudes outward in the radial direction of the gear 664.

  The movable slider 658 can contact the rib 664A. Specifically, as shown in FIG. 22, when the power of the motor 661 (see FIG. 23) is transmitted to the rack teeth 659A via the gear 660, the upper slide base 657 is integrated with the rack 659 to the first movement position. From the upper movable base 655 to one side (for example, a direction in which the upper movable base 655 protrudes).

  At this time, the movable slider 658 is also moved to one side in the longitudinal direction of the upper movable base 655 (see FIG. 23) from the first movement position toward the second movement position. The movable slider 658 is opposed to the rib 664A of the gear 664 positioned at a first operation position (rotational position shown in FIG. 24) described later in the longitudinal direction of the upper slide base 657 (see FIG. 23). The movable slider 658 presses the rib 664A to rotate the gear 664 when the upper slide base 657 (see FIG. 23) moves from the first movement position to the second movement position.

  As a result, the gear 665 meshing with the gear 664 also rotates with the gear 664, and the gears 664, 665 move closer to the movable arms 662, 663 via the gear portions 662A, 663A (first movable position (movable arms 662, 663). It can move to a second movable position (a position where the movable arms 662 and 663 are open) which is most separated from the closed position). That is, the movable arms 662 and 663 move from the closed state to the open state.

  The gears 664 and 665 are movable by rotating (moving) from the first operation position (rotational position shown in FIG. 24) to the second operation position (rotational position when the movable arms 662 and 663 are in the open state). The arms 662 and 663 are moved from the first movable position to the second movable position. Further, the gears 664, 665 move the movable arms 662, 663 from the second movable position to the first movable position by rotating from the second operating position to the first operating position.

  The movable slider 658 operates the gears 664 and 665 as the first movement when the upper slide base 657 (see FIG. 23) moves from the first movement position to the second movement position with respect to the upper movable base 655 (see FIG. 23). Rotate from the position to the second operating position. The gears 664 and 665 of the present embodiment constitute the actuating member of the present invention, and the movable slider 658 constitutes the first engagement portion of the present invention.

  As shown in FIG. 23, the movable arm 663 and the upper movable base 655 are elastically connected by a coil spring 667, and the coil spring 667 biases the movable arm 663 in the direction toward the movable arm 662. There is.

  Thus, when the upper slide base 657 moves from the second movement position to the first movement position with respect to the upper movable base 655, and the movable slider 658 moves in the direction opposite to the direction in which the rib 664A (see FIG. 24) is pressed. The biasing force of the coil spring 667 moves the movable arms 662 and 663 from the second movable position to the first movable position.

  The gears 664 and 665 rotate from the second operating position to the first operating position as the movable arms 662 and 663 are moved from the second movable position to the first movable position.

  As shown in FIG. 22, at the right end of the upper slide base 657, an L-shaped base rib 666 is provided. The base rib 666 is opposed to the rib 664A of the gear 664 positioned at the first operating position with respect to the longitudinal direction of the upper movable base 655 and the upper slide base 657 (see FIG. 25). Here, the longitudinal direction of the upper movable base 655 and the upper slide base 657 is the same as the sliding direction (moving direction) of the upper movable base 655 and the upper slide base 657.

  The gears 664, 665 are provided between the movable slider 658 (see FIG. 25) and the base rib 666 in the longitudinal direction of the upper movable base 655 and the upper slide base 657.

  As shown in FIG. 25, the base rib 666 is a movable slider when the upper slide base 657 (see FIG. 22) moves from the second movement position to the first movement position with respect to the upper movable base 655 (see FIG. 22). Engaging the rib 664A from the opposite direction to 658 and rotate the gears 664, 665 from the second operating position to the first operating position. The base rib 666 of the present embodiment constitutes a second engaging portion of the present invention.

  With the gears 664, 665 rotated to the first operating position (the state shown in FIG. 25), the base rib 666 restricts rotation of the gears 664, 665 by pressing the rib 664A against the movable slider 658. Do. The base rib 666 may not be provided. In this case, rotation of the gears 664 and 665 is restricted only by the biasing force of the coil spring 667.

  As shown in FIG. 23, the upper movable effect member 650 includes a pair of guide rails 668 and 669. Guide rails 668 and 669 are provided on the right side of the spacer 90 (see FIG. 3) so as to be located behind the game board 40 (see FIG. 3) and in front of the liquid crystal display device 50 (see FIG. 3). . The guide rails 668 and 669 are formed in a curved shape along a locus when the upper movable effect member 650 and the upper slide base 657 swing in the vertical direction, and the front and back direction of the pachinko gaming machine 1 (see FIG. 3) Separated.

  A guide piece 670 is provided at the right end of the upper movable base 655, and the guide piece 670 is provided between the guide rails 668 and 669 in the front-rear direction of the pachinko gaming machine 1. The guide piece 670 has triangular reinforcing portions 670a and 670b (see FIG. 22) that are inclined toward the upper movable presentation member 650 from the portions in contact with the guide rails 668 and 669.

  Thereby, as shown in FIG. 21, FIG. 26 and FIG. 27, the upper movable base 655 and the upper slide base 657 drive with the standby position (the position shown in FIG. 21) with the swing shaft 651B (see FIG. 22) as a fulcrum. When moving to the position (the position shown in FIG. 27), it swings up and down along the guide rails 668 and 669 (see FIG. 23). The guide rails 668 and 669 of the present embodiment constitute the guide member of the present invention, and the guide piece 670 constitutes the guided portion of the present invention.

  As shown in FIG. 22, the guide rail 669 positioned on the rear side with respect to the guide rail 668 positioned on the front side extends downward, and the lower end of the guide rail 669 is provided with a stopper 669A. The guide piece 670 abuts against the stopper 669A when the upper movable base 655 and the upper slide base 657 are positioned at the drive position, and the upper movable base 655 and the upper slide base 657 are restricted from moving below the drive position. Ru.

  In the front-rear direction of the pachinko gaming machine 1, a guide rail 668 located on the front side is installed behind the upper slide base 657. Thus, when the upper slide base 657 moves relative to the upper movable base 655 so as to protrude from the first movement position to the second movement position, the upper slide base 657 can be prevented from contacting the guide rail 668, The slide base 657 can be moved smoothly and reliably to the first movement position and the second movement position.

  As shown in FIG. 23, a fixed wedge member 672 and a movable wedge member 673 are provided at the front of the upper slide base 657. The fixed wedge member 672 is fixed to the front surface of the left end of the upper slide base 657, and the movable wedge member 673 is provided between the fixed wedge member 672 and the upper slide base 657 in the front-rear direction of the pachinko gaming machine 1 ing.

  Fitting protrusions 673A to 673C are provided on the rear surface of the movable wedge member 673, and the fitting protrusions 673A to 673C project rearward from the movable wedge member 673. A pair of vertically extending slits 657E and 657F are formed at the left end of the upper slide base 657, and the fitting projections 673A to 673C slide on the slits 657E and 657F via the slide bushes 656F, 656G and 656H. It is freely fitted.

  Thereby, the movable wedge member 673 moves in the vertical direction with respect to the upper slide base 657 and the fixed wedge member 672 as the fitting protrusions 673A to 673C slide along the slits 657E and 657F. The upper slide base 657 and the fixed wedge member 672 of the present embodiment constitute a first movable member of the present invention, and the movable wedge member 673 constitutes a second movable member of the present invention. The upper slide base 657, the fixed wedge member 672 and the movable wedge member 673 constitute the movable means of the present invention.

  The upper slide base 657 and the movable wedge member 673 are elastically connected by a coil spring 674, and the coil spring 674 biases the movable wedge member 673 upward with respect to the upper slide base 657. The coil spring 674 of the present embodiment constitutes the biasing member of the present invention.

  An abutment wall member 675 is provided above the movable wedge member 673, and the abutment wall member 675 is provided on the spacer 90.

  When the upper movable base 655 and the upper slide base 657 move from the drive position to the upper standby position, the upper movable base 655 and the upper slide base 657 are closer to the abutment wall member 675 compared to the drive position.

  On the other hand, when the upper movable base 655 and the upper slide base 657 move from the standby position to the lower drive position, the upper movable base 655 and the upper slide base 657 are separated from the abutment wall member 675 compared to the standby position.

  The movable wedge member 673 contacts the abutment wall member 675 when the upper movable base 655 and the upper slide base 657 move closer to the abutment wall member 675 from the drive position toward the standby position, thereby causing the coil spring 674 to move. Against the biasing force of the upper movable base 655 and the fixed wedge member 672 to move to the first position (the position shown in FIG. 21).

  In addition, the movable wedge member 673 is biased by the coil spring 674 when the upper movable base 655 and the upper slide base 657 move from the standby position toward the drive position and away from the wall member 675. It is moved relative to the upper movable base 655 and the fixed wedge member 672 to move to the second position (the position shown in FIG. 27).

  The upper fixed base 651 and the upper slide base 657 are elastically connected by a coil spring 671, and the coil spring 671 is biased to move the upper slide base 657 upward with respect to the upper fixed base 651. There is. Thereby, the upper movable base 655 and the upper slide base 657 are biased to the standby position. The coil spring 671 assists the driving force of the motor 652 when moving the upper movable base 655 and the upper slide base 657 from the drive position to the standby position (moving upward).

  Next, the operation of the upper movable effect member 650 will be described.

  As shown in FIG. 21, when the motor 652 is driven in one direction with the upper movable effect member 650 positioned at the standby position, power is transmitted from the gear 653 (see FIG. 22) to the gear 654 (see FIG. 22). It is transmitted. As shown in FIG. 23, when the gear 654 rotates, the fitting protrusion 654A (see FIG. 22) slides along the slit 655B of the upper movable base 655 via the slide bush 656B, whereby the upper movable base 655 is moved. The upper slide base 657 swings downward with the swing shaft 651B (see FIG. 22) as a fulcrum.

  At this time, the fitting projection 655D of the upper movable base 655 slides along the slit 651A via the slide bush 656A, whereby the upper movable base 655 and the upper slide base 657 move upward from the standby position toward the drive position. Move down from the

  As shown in FIG. 26, when the upper movable base 655 and the upper slide base 657 move from the standby position to the drive position from the upper side to the lower side, the guide pieces 670 are guided by the guide rails 668 and 669.

  As shown in FIG. 27, when the upper movable base 655 and the upper slide base 657 move from the standby position toward the drive position to move away from the abutment wall member 675, the movable wedge member 673 forms a coil spring 674 (see FIG. 23). ) Is moved relative to the upper movable base 655 and the fixed wedge member 672.

  Specifically, as shown in FIG. 26, while the upper movable base 655 and the upper slide base 657 swing from the standby position to the drive position, the upper end of the movable wedge member 673 contacts the abutting wall member 675. Maintain the condition. As a result, an effect is produced such that the movable wedge member 673 pops out to the upper movable base 655 and the upper slide base 657 which swing downward.

  Thereafter, as shown in FIG. 27, the upper movable base 655 and the upper slide base 657 further swing downward toward the drive position, and when the drive position is reached, the movable wedge member 673 is urged by the coil spring 674. The movable state of the upper movable base 655 and the fixed wedge member 672 is maintained.

  At this time, since the upper end of the movable wedge member 673 does not contact the abutment wall member 675, the movable wedge member 673 jumps out to the upper movable base 655 and the fixed wedge member 672 at maximum, and the wedge appears in the handle of the blade. A presentation is performed.

  As shown in FIG. 27, with the upper movable base 655 and the upper slide base 657 moved to the drive position, the fitting projection 655D (see FIG. 23) of the upper slide base 657 is a sliding bush 656A (see FIG. 23). The lower end of the slit 651A (see FIG. 23) contacts with the lower end of the guide rail 669 (see FIG. 23) and the guide piece 670 abuts against the stopper 669A (see FIG. 23). Thus, the upper movable base 655 and the upper slide base 657 are restricted from moving below the drive position.

  In the drive position, when the motor 661 (see FIG. 23) is driven in one direction, the gear 660 (see FIG. 22) rotates to drive the rack 659 (see FIG. 22), whereby the upper slide base integral with the rack 659 The 657 moves from the first movement position (for example, the positions shown in FIGS. 26 and 27) toward the second movement position (for example, the position shown in FIG. 28). When the upper slide base 657 moves from the first movement position toward the second movement position, the upper fixed base 651 and the upper slide base 657 generally extend in the longitudinal direction. Furthermore, when the upper slide base 657 moves from the first movement position toward the second movement position, the end of the upper slide base 657 protrudes beyond the guide rails 668, 669.

  As shown in FIG. 23, when the upper slide base 657 moves from the first movement position to the second movement position, the fitting projections 657 B, 657 C of the upper slide base 657 are along the slits 655 E, 655 F of the upper movable base 655. Moving.

  At this time, the movable slider 658 moving integrally with the fitting projection 657 moves toward the rib 664A (see FIG. 24) of the gear 664, and presses the rib 664A from the movable slider 658 side. Thus, the gear 664 rotates from the first operating position.

  When the gear 664 rotates from the first operation position, the gear 665 meshing with the gear 664 rotates with the gear 664, and the gears 664 and 665 bring the movable arm 662 and the movable arm 663 closest to each other via the gear portions 662A and 663B. It moves to the 2nd movable position (position shown in FIG. 28) most distant from the first movable position (position shown in FIG. 24). That is, as shown in FIG. 28, the movable arms 662, 663 are in the open state from the closed state.

  In this way, the upper movable effect member 650 moves from the standby position to the drive position as shown in FIGS. A state in which the upper movable base 655 and the upper slide base 657 are pivoted downward most from the standby position and the movable arms 662 and 663 are open may be used as the driving position of the upper movable effect member 650.

  On the other hand, as shown in FIG. 28, when the motor 661 (see FIG. 23) is driven in the other direction with the upper movable effect member 650 positioned at the drive position, the gear 660 is rotated to drive the rack 659. The upper slide base 657 integrated with the rack 659 moves from the second movement position to the upper fixed base 651 toward the first movement position (for example, the position shown in FIGS. 26 and 27). When the upper slide base 657 moves from the second movement position (for example, the position shown in FIG. 28) toward the first movement position with respect to the upper fixed base 651, the upper fixed base 651 and the upper slide base 657 , Generally shrink in the longitudinal direction.

  When the upper slide base 657 moves from the second movement position to the first movement position, the fitting projections 657B and 657C of the upper slide base 657 are along the slits 655E and 655F of the upper movable base 655 as shown in FIG. Moving.

  At this time, as shown in FIG. 25, the base rib 666 provided at the right end of the upper slide base 657 (see FIG. 23) moves toward the rib 664A of the gear 664 and the movable slider 658 moves away from the rib 664A. Moving.

  When the movable slider 658 moves away from the rib 664A, the biasing force of the coil spring 667 moves the movable arms 662, 663 from the second movable position away from each other to the first movable position closer to each other. That is, the first movable arms 662 and 663 move from the open state to the closed state.

  The gears 664 and 665 rotate from the second operating position to the first operating position as the movable arms 662 and 663 are moved from the second movable position to the first movable position.

  As shown in FIG. 27, when the upper slide base 657 moves from the second movement position to the first movement position, the base rib 666 presses the rib 664A of the gear 664 as shown in FIG. Moves from the second operation position to the first movement position.

  As shown in FIG. 25, when the upper slide base 657 moves to the first movement position, the base rib 666 presses the rib 664A toward the movable slider 658 in a state where the gears 664 and 665 are rotated to the first operation position. It regulates that the gears 664 and 665 rotate.

  Next, as shown in FIG. 27, with the upper slide base 657 positioned at the first movement position, when the motor 652 is driven in the other direction, the gear 653 (see FIG. 23) to the gear 654 (see FIG. 23) Power is transmitted to the

  As shown in FIG. 22, when the gear 654 rotates, the fitting projection 654A slides along the slit 655B (see FIG. 23) of the upper movable base 655 via the sliding bush 656B (see FIG. 23). The upper movable base 655 and the upper slide base 657 swing upward with the swing shaft 651B as a fulcrum.

  At this time, the fitting projection 655D (see FIG. 23) of the upper movable base 655 slides along the slit 651A via the sliding bush 656A, whereby the upper movable base 655 and the upper slide base 657 are stabilized. It is rocked.

  As shown in FIG. 27, when the upper movable base 655 and the upper slide base 657 move upward from the drive position toward the standby position from the lower position, the guide pieces 670 are guided by the guide rails 668 and 669.

  As shown in FIG. 26, the movable wedge member 673 is moved on the way from the standby position to the drive position so that the upper movable base 655 and the upper slide base 657 approach the abutment wall member 675 from the drive position toward the standby position. The upper end of the lower wall contacts the wall member 675.

  At this time, as shown in FIG. 21, when the upper movable base 655 and the upper slide base 657 move upward toward the standby position, the upper end of the movable wedge member 673 contacts the abutment wall member 675 to move the movable wedge member 673. Is restricted from moving upward.

  As a result, the movable wedge member 673 moves relative to the upper movable base 655 and the fixed wedge member 672 against the biasing force of the coil spring 674 (see FIG. 23). As a result, an effect that the movable wedge member 673 is accommodated in the upper movable base 655 and the fixed wedge member 672 is performed.

  As shown in FIG. 21, when the upper movable base 655 and the upper slide base 657 move to the standby position, the drive of the motor 652 is stopped. Thus, the upper movable effect member 650 moves from the drive position to the standby position. FIG. 29 shows a state in which the upper movable effect member 650 has moved to the drive position with respect to the game board 40.

  Thus, as shown in FIG. 22, the pachinko gaming machine 1 of the present embodiment is attached to the spacer 90 (see FIG. 3) to which the gaming board 40 (see FIG. 3) is attached and the back of the gaming board 40 A liquid crystal display device 50 (see FIG. 3) for performing predetermined effect display, and an upper movable effect member 650 movable between a standby position and a drive position centering on a swing shaft 651B attached to the spacer 90; Guide rails 668 and 669 provided on the spacer 90 so as to be located in front of the liquid crystal display device 50; It has a guide piece 670 which is guided to the guide rails 668, 669 when moving.

  Thereby, the trajectory of the upper movable effect member 650 can be stabilized. Therefore, the effect by the upper movable effect member 650 can be accurately performed. In addition, for example, when the upper movable effect member 650 is moved between the standby position and the drive position, it is possible to prevent the swing of the game board 40 in the back and forth direction. The upper movable effect member 650, the game board 40 and the liquid crystal display device 50 can be protected by preventing the liquid crystal display device 50 from contacting the liquid crystal display device 50.

  In addition to this, the space between the upper movable effect member 650 and the game board 40, the upper movable effect member 650, and the liquid crystal display device 50 can be prevented by preventing the upper movable effect member 650 from swinging back and forth. The space between can be made smaller. Therefore, the dimension in the front-rear direction of the pachinko gaming machine 1 can be shortened, and space saving of the pachinko gaming machine 1 can be achieved.

  In addition, since the guide piece 670 has triangular reinforcing portions 670a and 670b (see FIG. 22) that incline from the portion in contact with the guide rails 668 and 669 toward the upper movable effect member 650, the rigidity of the guide piece 670 can be increased. It can be improved. Therefore, the upper movable presentation member 650 can be moved smoothly and stably along the guide rails 668 and 669.

  In the pachinko gaming machine 1 of the present embodiment, the upper movable presentation member 650 has the upper movable base 655 and the upper slide base 657 movable along the longitudinal direction of the upper movable base 655, and the upper slide When the base 657 moves from the first movement position to the second movement position, the end of the upper slide base 657 can project beyond the guide rails 668, 669.

  Thus, the movement of the upper slide base 657 can be prevented from being restricted by the guide rails 668 and 669, and effects by the upper movable effect member 650 can be more effectively performed.

  Further, in the pachinko gaming machine 1 of the present embodiment, as shown in FIG. 22, the upper movable presentation member 650 is between the standby position where the upper movable presentation member 650 approaches the abutment wall member 675 and the driving position where the upper movable presentation member 650 An upper slide base 657 and a fixed wedge member 672 movable around a swing shaft 651 B, a movable wedge member 673 movable relative to the upper slide base 657 and the fixed wedge member 672, an upper slide base 657 and a movable wedge member 673 And a coil spring 674 (see FIG. 23) which elastically connects the

  Furthermore, the movable wedge member 673 resists the biasing force of the coil spring 674 by coming into contact with the hit wall member 675 when the upper slide base 657 and the fixed wedge member 672 move closer to the hit wall member 675. To move to the first position (the position shown in FIG. 21) relative to the upper slide base 657 and the fixed wedge member 672, so that the upper slide base 657 and the fixed wedge member 672 move away from the abutment wall member 675 Then, the coil spring 674 urges the upper slide base 657 and the fixed wedge member 672 to move to the second position (the position shown in FIG. 27).

  Thereby, the rendering effect can be improved while operating the upper movable presentation member 650 smoothly with a simple configuration. In particular, the upper movable presentation member 650 is composed of the upper slide base 657 and the fixed wedge member 672, the movable wedge member 673 and the coil spring 674, and the upper slide base 657 and the fixed wedge member Since the movable wedge member 673 can be moved relative to the upper slide base 657 and the fixed wedge member 672 with the movement of 672, the structure of the upper movable effect member 650 can be simplified more effectively.

  Further, as shown in FIG. 22, the upper movable presentation member 650 of the present embodiment is movable relative to the upper movable base 655 and the upper movable base 655 between the first movement position and the second movement position. The upper slide base 657 and the upper movable base 655 are provided on the movable arms 662, 663 and the upper slide base 657 between the first movable position and the second movable position, and the second operation is performed from the first operation position The movable arm 662, 663 is moved from the first movable position to the second movable position by operating in the position, and the movable arm 662, 663 is moved from the second movable position by moving from the second operating position to the first operating position. It has gears 664 and 665 which are moved to the first movable position.

  Furthermore, the upper movable presentation member 650 is provided on the upper slide base 657, and engaged with the rib 664A of the gear 664 when the upper slide base 657 moves from the first movement position to the second movement position with respect to the upper movable base 655. In addition, the movable slider 658 (see FIG. 24) for moving the gears 664 and 665 from the first operating position to the second operating position, and the upper slide base 657, the upper slide base 657 is relative to the upper movable base 655 When moving from the second movement position to the first movement position, the gear 664A is engaged with the rib 664A of the gear 664 from the opposite direction to the movable slider 658 to move the gears 664, 665 from the second operation position to the first operation position. And a base rib 666 (see FIG. 25).

  As a result, the movable arms 662 and 663 can be operated smoothly by a simple configuration. As a result, the rendering effect can be improved while ensuring that the upper movable presentation member 650 performs a smooth operation.

  Further, in the upper movable presentation member 650 of the present embodiment, the gears 664 and 665 are provided between the movable slider 658 and the base rib 666 with respect to the sliding direction (moving direction) of the upper slide base 657. 664 has a rib 664 A engageable with the movable slider 658 and the base rib 666.

  As a result, by engaging the movable slider 658 and the base rib 666 with the rib 664A and rotating the gears 664 and 665, the movable arms 662 and 663 can be moved to the first movable position and the second movable position via the gear portions 662A and 663A. It can be moved between Thereby, the upper movable presentation member 650 can be configured more effectively and simply.

  Also, as shown in FIGS. 24 and 25, when the movable arms 662 and 663 are positioned at the first movable position and the second movable position, the movable slider 658 and the base rib 666 are engaged with the rib 664A, whereby the gear is achieved. The rotation of 664 and 665 can be regulated. Thus, the postures of the movable arms 662 and 663 can be stabilized at the first movable position and the second movable position, and the behavior of the movable arms 662 and 663 can be prevented from becoming unstable.

  In the upper movable effect member 650 of the present embodiment, only the movable wedge member 673 is movable relative to the fixed wedge member 672, but the fixed wedge member 672 may also be movable. Specifically, as shown in FIG. 30, the movable wedge member 673 is movably provided on the fixed plate 690, and the fixed plate 690 is fixed to the upper slide base 657 (see FIG. 23).

  A movable wedge member 691 is movably provided on the fixed body 690. The movable wedge member 673 is provided with a rack 673D in which rack teeth 673a are formed, and the movable wedge member 691 is provided with a rack 691A in which rack teeth 691a are formed.

  The rack teeth 673a mesh with the rack teeth 691a via the gear 692. The fixed plate 690 and the movable wedge member 673 are elastically connected by a coil spring 674. The coil spring 674 biases the movable wedge member 673 upward with respect to the fixed body 690, ie, the upper slide base 657. ing.

  According to this structure, as the upper movable base 655 and the upper slide base 657 swing to the drive position and the standby position, the rack 673D of the movable wedge member 673 moves the gear 692 to the movable wedge member 691. Power can be transmitted to the rack 691A, and in conjunction with the movement of the movable wedge member 673, the movable wedge member 691 can be moved relative to the fixed plate 690.

  As a result, the movable wedge members 673 and 691 can move to a position where the movable wedge members 673 and 691 retract into the fixed plate 690 and a position where the movable wedge members 673 and 691 protrude from the fixed plate 690.

  Further, in the present embodiment, the base rib 666 is used as a configuration for restricting the rotation of the gears 664, 665 in the state where the gears 664, 665 are rotated to the first operating position (state shown in FIG. 25). Alternatively, coil springs as shown in FIGS. 31 and 32 may be used. 31 and 32 are schematic views of the upper movable base 655 and the upper slide base 657.

  As shown in FIGS. 31 and 32, a support member 680A for supporting one end of the coil spring 680 is fixed to the right end of the upper movable base 655, and the other end of the coil spring 680 is opposite to the movable slider 658. An abutment piece 680B is provided which can abut against the rib 664A of the gear 664 from the direction.

  In such a configuration, as shown in FIG. 32, the upper slide base 657 moves from the first position (the position shown in FIG. 31) to the second position (the position shown in FIG. 32) with respect to the upper movable base 655. When the movable slider 658 presses the rib 664 A of the gear 664, the coil spring 680 is compressed as the gear 664 rotates.

  On the other hand, as shown in FIG. 31, the upper slide base 657 moves from the second position (the position shown in FIG. 32) to the first position (the position shown in FIG. 31) with respect to the upper movable base 655, and the movable slider 658 moves. When separated from the rib 664A of the gear 664, the contact piece 680B presses the rib 664A from the direction opposite to the movable slider 658 by the extension of the coil spring 680.

  Even in such a configuration, when the movable arms 662 and 663 are positioned at the first movable position and the second movable position, the movable slider 658 and the coil spring 680 are engaged with the rib 664A to obtain a gear. The rotation of 664 and 665 can be regulated. Thus, the postures of the movable arms 662 and 663 can be stabilized at the first movable position and the second movable position, and the behavior of the movable arms 662 and 663 can be prevented from becoming unstable.

  Furthermore, in place of the base rib 666 and the coil spring 680 described above, a link mechanism as shown in FIGS. 33 and 34 may be used. 33 and 34 are schematic views of the upper movable base 655 and the upper slide base 657.

  As shown in FIGS. 33 and 34, the upper movable base 655 is provided with a rack 681 extending in the same direction as the rack 659 extends, and the rack 681 is opposed to the upper movable base 655. It is configured to be movable.

  The upper slide base 657 is provided with a gear 682 which meshes with the rack teeth 681 a of the rack 681. A gear 683 is rotatably provided on the upper movable base 655, and the gear 683 is provided with an L-shaped rib 683A. The rib 683A can press the rib 664A of the gear 664 from the direction opposite to the movable slider 658.

  The gear 683 moves the rack tooth 681a of the rack 681 when the upper slide base 657 moves to the first position (the position shown in FIG. 33) and the second position (the position shown in FIG. 34) with respect to the upper movable base 655. Between the meshable state and the meshable state.

  When the upper slide base 657 moves relative to the upper movable base 655 from the first position (the position shown in FIG. 33) to the second position (the position shown in FIG. 34), the upper movable presentation member 650 configured in this way The rotation of the gear 682 moves the rack 681 to the left.

  As shown in FIG. 34, when the rack 681 moves to the left, the meshing between the gear 683 and the rack teeth 681a is released (the meshing state is disabled). In addition, the movable slider 658 presses the rib 664A of the gear 664, whereby the gear 664 is rotated. At this time, although the rib 664A presses the rib 683A, a force opposing the pressing force of the rib 664A does not act on the rib 683A, so the gear 683A rotates to allow the gear 664 to rotate.

  On the other hand, as shown in FIG. 33, the upper slide base 657 moves from the second position (the position shown in FIG. 34) to the first position (the position shown in FIG. 33) with respect to the upper movable base 655, and the movable slider 658 moves. When leaving the rib 664 A of the gear 664, the rotation of the gear 682 moves the rack 681 to the right.

  When the rack 681 moves to the right, the gear 683 meshes with the rack teeth 681a and rotates, and the rib 683A presses the rib 664A from the opposite direction to the movable slider 658. Thus, the gear 664 rotates.

  Even in such a configuration, when the movable arms 662 and 663 are positioned at the first movable position and the second movable position, the movable slider 658 and the rib 683A are engaged with the rib 664A, whereby the gear 664 is obtained. , 665 rotation can be regulated. Thus, the postures of the movable arms 662 and 663 can be stabilized at the first movable position and the second movable position, and the behavior of the movable arms 662 and 663 can be prevented from becoming unstable. The gear 682 is driven along with the movement of the upper slide base 657, but may be driven by a motor (not shown).

[Configuration and Operation of Right Movable Effect Member 750 and Left Movable Effect Member 770]
As shown in FIGS. 4 and 43, the pachinko gaming machine 1 of the present embodiment is provided with a right side movable effect member 750 and a left side movable effect member 770. The right side movable effect member 750 and the left side movable effect member 770 are provided on the right side and the left side of the display area 51 at the rear of the game board 40. Note that FIG. 4 shows a state in which the right side movable effect member 750 and the left side movable effect member 770 are positioned behind the central base plate 413 (a state in which they are positioned at a standby position described later). Therefore, as shown in FIG. 4, the right movable effect member 750 and the left movable effect member 770 are configured such that the entire player is not visually recognized by the player at the standby position. The right side movable effect member 750 and the left side movable effect member 770 of the present embodiment constitute the displacement means of the present invention.

  First, the right side movable effect member 750 will be described.

  As shown in FIG. 35, the right side movable member 750 is provided with a right wing member 751, and the right wing member 751 is decorated to simulate a wing. An inner lens 751A is provided on the front surface of the right wing member 751 and an electric decoration substrate 751B (see FIG. 37) is incorporated so as to be positioned behind the inner lens 751A. An LED (not shown) is provided on the electric decoration substrate 751B (see FIG. 37), and the electric decoration substrate 751B (see FIG. 37) performs lighting control of the LED and emits light through the inner lens 751A.

  As shown in FIG. 36, the right wing guide member 752 is provided at the rear of the right wing member 751, and the right wing guide member 752 is a pair of V-shaped guide grooves 752A, which are vertically separated. 752B is formed.

  A pair of fitting projections 751C and 751D which are vertically separated from each other are formed at the rear of the right wing member 751. The fitting projections 751C and 751D are formed in the guide grooves 752A and 752B through the slide bushes 753A and 753B. It is slidably fitted.

  As shown in FIG. 37, at the rear of the right wing guide member 752, a pair of protrusions 752C and 752D which are vertically separated are formed, and the lower ends of movable arms 754 and 755 rotate on the protrusions 752C and 752D, respectively. It is freely supported.

  Longitudinal slits 754A, 755A are formed in the movable arms 754, 755, and sliding bushes 753A, 753B are slidably fitted in the slits 754A, 755A.

  As a result, the movable arms 754 and 755 swing up and down with the protrusions 752 C and 752 D as fulcrums. When the movable arms 754 and 755 swing up and down with the protrusions 752 C and 752 D as a fulcrum, the sliding bushes 753 A and 753 B move along the guide grooves 752 A and 752 B, whereby the right wing member 751 guides the guide grooves 752 A and 752 B. Move in the vertical and horizontal directions (including the oblique direction) to draw a letter along the.

  Gear portions 754B, 755B are formed on the movable arms 754, 755, and the gear portions 754B, 755B mesh with rack teeth 756A, 756B (see FIG. 36) formed in the rack 756.

  As shown in FIG. 36, a right wing fixing base 757 is provided at the rear of the right wing guide member 752, and a pair of protrusions 757A and 757B which are vertically separated are formed on the front of the right wing fixing base 757. ing.

  In the rack 756, a pair of vertically elongated slits 756C and 756D are formed separately in the vertical direction. The protrusions 757A and 757B are slidably fitted in the slits 756C and 756D. Thus, the rack 756 is vertically movable with respect to the right wing fixed base 757.

  A slit 756E is formed at the top of the rack 756, and the slit 756E extends in the left-right direction.

  A motor 758 is attached to the front surface of the right wing fixed base 757, and a gear 759 is attached to a rotating shaft (not shown) of the motor 758. The gear 759 is rotatably supported on the rear surface of the right wing fixed base 757. The gear 759 meshes with a gear 760 rotatably supported at the rear of the right wing fixed base 757. The gears 759, 760 are covered by a gear cover 763.

  A fitting protrusion 760A is formed on the gear 760, and the fitting protrusion 760A is slidably fitted in the slit 756E. A semicircular slit (not shown) is formed in the right wing fixing base 757. When the gear 760 rotates, the fitting protrusion 760A is guided along the semicircular slit. When the fitting protrusion 760A is guided along the semicircular slit, the fitting protrusion 760A pushes the rack 756 downward while moving along the slit 756E.

  The right wing fixed base 757 and the rack 756 are connected by a coil spring 762, and the coil spring 762 biases the rack 756 upward.

  A guide protrusion 761 is formed on the right side of the right wing member 751, and the guide protrusion 761 protrudes more forward than the front surface of the right wing member 751. When the right side movable effect member 750 moves to the standby position (the position shown in FIG. 35) and the drive position (the position shown in FIG. 38), the guide projection 761 has difficulty in visually recognizing the back of the game board 40 (see FIG. 4) It is in contact with the rear face of the game board 40 in the area of the game board 40. As a result, the guide projection 761 is difficult to view from the player. The guide protrusion 761 of the present embodiment constitutes the contact portion of the present invention.

  In the right side movable effect member 750 of the present embodiment, when the motor 758 rotates, the gear 759 causes the gear 760 to rotate. When the gear 760 rotates, the fitting protrusion 760A is guided along the semicircular slit, and the fitting protrusion 760A moves along the slit 756E of the rack 756.

  As a result, the rack 756 moves up and down. When the rack 756 moves up and down, the gear portions 754B and 755B of the movable arms 754 and 755, which mesh with the rack teeth 756A and 756B of the rack 756, rotate. Therefore, as shown in FIG. 37, the movable arms 754 and 755 swing up and down with the protrusions 752C and 752D as fulcrums.

  Therefore, the sliding bushes 753A and 753B move along the guide grooves 752A and 752B, and the fitting projections 751C and 751D of the right wing member 751 move in the vertical and horizontal directions along the guide grooves 752A and 752B. As a result, the right wing member 751 is in the standby position (the position shown in FIG. 35) waiting at the rear of the game board 40 (see FIG. 4) and the drive position (the position shown in FIG. 38) Move to and).

  Further, when the right wing member 751 moves from the driving position (the position shown in FIG. 38) to the standby position (the position shown in FIG. 35) obliquely upward right, the rack 756 is pulled upward by the coil spring 762. Thereby, the right wing member 751 which is a heavy load can be pulled up by the coil spring 762 in the direction opposite to the self weight direction, and the drive of the motor 758 (see FIG. 36) can be assisted by the coil spring 762.

  In addition, when the right wing member 751 moves to the standby position and the drive position, the guide projection 761 is located on the rear surface of the game board 40 in the area of the game board 40 where it is difficult to see behind the game board 40 (see FIG. 4). Abut. Thereby, the right wing member 751 can be moved to the standby position and the drive position without the right wing member 751 swinging in the front-rear direction of the pachinko gaming machine 1.

  Next, the left movable effect member 770 will be described.

  As shown in FIG. 39, the left side movable effect member 770 is provided with a left wing member 771 and the left wing member 771 is decorated to simulate a wing. An inner lens 771A is provided on the front surface of the left wing member 771 and an electric decoration substrate 771B (see FIG. 41) is incorporated so as to be positioned behind the inner lens 771A. An LED (not shown) is provided on the electric decoration substrate 771B (see FIG. 41), and the electric decoration substrate 771B (see FIG. 41) performs lighting control of the LED and emits light through the inner lens 771A.

  As shown in FIG. 40, a left wing guide member 772 is provided at the rear of the left wing member 771. The left wing guide member 772 has a pair of V-shaped guide grooves 772A separated in the vertical direction, 772 B is formed.

  As shown in FIG. 41, a pair of fitting projections 771C and 771D which are separated in the vertical direction are formed at the rear of the left wing member 771. The fitting projections 771C and 771D are sliding bushes 773A and 773B (see FIG. 40) and slidably fitted in the guide grooves 772A, 772B.

  A pair of protrusions 772C and 772D which are vertically separated from each other is formed at the rear of the left wing guide member 772. The upper ends of movable arms 774 and 775 are rotatably supported by the protrusions 772C and 772D.

  Longitudinal slits 774A, 775A are formed in the movable arms 774, 775, and sliding bushes 773A, 773B are slidably fitted in the slits 774A, 775A.

  As a result, the movable arms 774 and 775 swing up and down with the protrusions 772C and 772D as fulcrums. When the movable arms 774 and 775 swing up and down around the protrusions 772C and 772D, the sliding bushes 773A and 773B move along the guide grooves 772A and 772B, whereby the left wing member 771 moves in the guide grooves 772A and 772B. Move in the vertical and horizontal directions (including the oblique direction) to draw a letter along the.

  Gear portions 774B and 775B are formed on the movable arms 774 and 775, and the gear portions 774B and 775B mesh with rack teeth 776A and 776B formed on the rack 776.

  As shown in FIG. 40, a left wing fixing base 777 is provided at the rear of the left wing guide member 772 and a pair of protrusions 777A and 777B which are vertically separated are formed on the front face of the left wing fixing base 777. ing.

  In the rack 776, a pair of vertically elongated slits 776C and 776D are formed separately in the vertical direction. Protrusions 777A, 777B are slidably fitted in the slits 776C, 776D. As a result, the rack 776 is vertically movable with respect to the left wing fixed base 777.

  A slit 776E is formed at the top of the rack 776, and the slit 776E extends in the left-right direction.

  As shown in FIG. 41, a motor 778 is attached to the rear of the left wing fixed base 777, and a gear 779 is attached to a rotating shaft (not shown) of the motor 778. As shown in FIG. 40, the gear 779 is rotatably supported on the front surface of the left wing fixed base 777. The gear 779 is in mesh with a gear 780 rotatably supported on the front surface of the left wing fixing base 777. The gears 779 and 780 are covered by a gear cover 783.

  As shown in FIG. 40, a fitting projection 780A is formed on the gear 780, and the fitting projection 780A is slidably fitted in the slit 776E. When the gear 780 rotates, the fitting projection 780A pushes the rack 776 upward while moving along the slit 776E.

  The left wing fixed base 777 and the rack 776 are connected by a coil spring 782, and the coil spring 782 biases the rack 776 upward.

  A guide protrusion 781 is formed on the left side of the left wing member 771, and the guide protrusion 781 protrudes more forward than the front surface of the left wing member 771. When the left side movable effect member 770 moves to the standby position (the position shown in FIG. 39) and the drive position (the position shown in FIG. 42), the guide projection 781 has difficulty in visually recognizing the back of the game board 40 (see FIG. 4) It is in contact with the rear face of the game board 40 in the area of the game board 40. As a result, the guide projection 781 is difficult to view from the player. The guide projection 781 of the present embodiment constitutes the contact portion of the present invention.

  In the left side movable effect member 770 of the present embodiment, the gear 779 rotates the gear 780 when the motor 778 (see FIG. 41) rotates. When the gear 780 rotates, the fitting projection 780A moves along the slit 776E of the rack 776.

  As a result, the rack 776 moves up and down. When the rack 776 moves up and down, the gear portions 774B and 775B of the movable arms 774 and 775, which mesh with the rack teeth 776A and 776B of the rack 776, rotate. Therefore, as shown in FIG. 41, the movable arms 774 and 775 swing up and down with the fitting projections 772C and 772D as a fulcrum.

  Therefore, as shown in FIG. 40, the sliding bushes 773A, 773B move along the guide grooves 772A, 772B, and the fitting projections 771C, 771D (see FIG. 41) of the left wing member 771 are guide grooves 772A, 772B. It moves vertically and horizontally along (see FIG. 41). As a result, the left wing member 771 is in the standby position (the position shown in FIG. 39) waiting at the rear of the game board 40 (see FIG. 4) and the drive position (the position shown in FIG. 42) Move to and).

  Also, when the left wing member 771 moves from the standby position (the position shown in FIG. 39) to the drive position obliquely upward right (the position shown in FIG. 42), the rack 776 is pulled upward by the coil spring 782. Thereby, the left wing member 771 which is a heavy load can be pulled up by the coil spring 782 in the direction opposite to the self weight direction, and the drive of the motor 778 (see FIG. 41) can be assisted by the coil spring 782.

  In addition, when the left wing member 771 moves to the standby position and the drive position, the guide projection 781 is an area of the game board 40 where it is difficult to visually recognize the rear of the game board 40 (see FIG. 4) Abut. Thus, the left wing member 771 can be moved to the standby position and the drive position without swinging the left wing member 771 in the front-rear direction of the pachinko gaming machine 1.

  FIG. 43 is a view showing a state in which the right side movable effect member 750 and the left side movable effect member 770 are moved from the standby position to the drive position when the game board 40 is viewed from the front. The right side movable effect member 750 and the left side movable effect member 770 move so as to approach each other when moving from the standby position to the drive position.

  Furthermore, when the right side movable effect member 750 and the left side movable effect member 770 move from the standby position to the drive position, the right side movable effect member 750 moves leftward and then moves downward, the left side movable effect member 770 Is moved to move upward after moving to the right. Therefore, when the right side movable effect member 750 and the left side movable effect member 770 move from the standby position to the drive position, the right side movable effect member 750 and the left side movable effect member 770 move as if they were rotating (liquid crystal display In front of the device 50, the right movable effect member 750 and the left movable effect member 770 are visually recognized as one effect member, and the motion as if the one effect member is rotating counterclockwise) It is possible to enhance the stage effect.

  As described above, the right side movable effect member 750 and the left side movable effect member 770 of the present embodiment have the guide protrusions 761 and 781 that abut on the rear surface of the game board 40 (see FIG. 4), and the guide protrusions 761 and 781 When the right side movable effect member 750 and the left side movable effect member 770 move to the standby position and the drive position, the right side of the game board 40 is in contact with the rear surface of the game board 40 in the area of the game board 40 The movable effect member 750 and the left movable effect member 770 are provided.

  As a result, when the right side movable effect member 750 and the left side movable effect member 770 move to the standby position and the drive position, the guide projections 761 and 781 abut on the rear surface of the game board 40 (see FIG. 4). 761 and 781 can be used as guides for moving the right movable effect member 750 and the left movable effect member 770, and the right movable effect member 750 and the left movable effect member 770 can be operated stably. As a result, it is possible to improve the rendering effect while guaranteeing the smooth operation of the right side movable effect member 750 and the left side movable effect member 770.

  Further, by bringing the guide projections 761 and 781 into contact with the rear surface of the game board 40 (see FIG. 4), the decoration formed on the front surface of the right movable effect member 750 and the left movable effect member 770 contacts the game board 40 Can be prevented. Therefore, it is possible to protect the front face of the right side movable effect member 750 and the left side movable effect member 770 on which the decoration imitating a wing is provided from the game board 40.

  Furthermore, in the area where it is difficult to visually recognize the rear of the game board 40 (see FIG. 4), the guide projections 761 and 781 of the right movable effect member 750 and the left movable effect member 770 are in contact with the rear surface of the game board 40. The right movable effect member 750 and the guide protrusions 761 and 781 of the left movable effect member 770 are not easily viewed by the player. Therefore, the decorativeness of the game board 40 can be maintained.

  As shown in FIG. 20, a small movable effect member 790 (shown by an imaginary line in FIG. 4) is provided on the front side of the right guide portion 413e. The small movable effect member 790 reciprocates between the upper left and the lower right by being driven by an electromagnetic solenoid (not shown). The small movable effect member 790 is not limited to the electromagnetic solenoid, and may be driven by various actuators including, for example, a motor, a gear, and the like.

[Modification of distribution device]
Hereafter, the modification of the distribution apparatus 421 is demonstrated. 44 to 48 show a first modification of the distribution device 421. FIG. 49 and 50 show a second modification of the distribution device 421. FIG.

  In the distribution apparatus 800 according to the first and second modifications described below, the configuration other than the distribution drum 801 is the same as that of the distribution apparatus 421 shown in FIG. Therefore, in FIGS. 44 to 50, the configuration of the distribution drum 801 will be specifically described, and the description of the configuration other than the distribution drum 801 will be omitted. The first modification and the second modification of the distribution device 421 are different in the configuration of the distribution drum 801.

[Distributing drum of the first modification]
As shown in FIG. 44, the distributing drum 801 according to the first modification includes a cylindrical (hour-shaped) drum main body 802 having a central hole 801 e into which the distributing shaft 502 (see FIG. 5) can be inserted. Four grooves 802A to 802D which are formed on the drum main body 802, extend along the central axis direction of the drum main body 802, and are divided in the circumferential direction of the drum main body 802, and one end of the drum main body 802 A protruding portion 803 radially protrudes from a portion (left end), and a protruding portion 804 protruding radially from the other end (right end) of the drum main body 802.

  The four groove portions 802A to 802D are formed in the drum main body 802 between wall surfaces extending at 90 degrees with respect to the central axis, and the blade portions 805 are formed between the adjacent groove portions 802A to 802D.

  The blade portion 805 extends radially outward from the drum main body 802, and extends in a cross shape when viewed frontward in the central axial direction of the drum main body 802. The blade portion 805 constitutes a partition wall which divides the groove portions 802A to 802D in the circumferential direction of the drum main body 802.

  The projecting portion 803 is formed in a conical shape inclined in the axial direction of the drum body 802 (see FIG. 47). Further, as shown in FIG. 45, the projection 803 is formed with a notch 803A communicating with one groove 802D of the four grooves 802A to 802D.

  The projecting portion 804 is formed in a conical shape inclined in the axial direction of the drum body 802 (see FIG. 48). As shown in FIG. 44, the protrusion 804 is formed with a notch 804A communicating with the three grooves 802A to 802C among the four grooves 802A to 802D. A recess 806 is formed on the side surface of the protrusion 804, and a design lens 507 (see FIG. 5) is attached to the recess 806.

  As shown in FIG. 45, one groove portion 802D of the four groove portions 802A to 802D is closed on the right side by the protruding portion 804, the left side is opened, and the other three sets of groove portions 802A to 802C are , The left side is closed by the projection 803, and the right side is opened. The open portions of the projecting portions 803 and 804 are portions where the notches 803A and 804A are formed, respectively.

  As shown in FIG. 46, a first cam lock 504 is attached to one end of the distribution drum 801 in the axial direction. The first cam lock 504 has the same configuration as the first cam lock 504 shown in FIG. Here, the distribution drum 801 constitutes the rotating member of the present invention, and the groove parts 802A to 802D constitute the receiving part of the present invention.

  As shown in FIG. 46, mounting surfaces 802a are provided in the grooves 802A to 802D, respectively. The mounting surface portion 802a is formed of one surface of the blade portion 805 in the circumferential direction of the distribution drum 801, and gaming balls received in the respective groove portions 802A to 802D are temporarily mounted on the mounting surface portion 802a. Be placed. Note that "the game balls are temporarily placed" means that the game balls received by the groove portions 802A to 802D rotate on the distribution surface 801 by their own weight and fall on the mounting surface portion 802a. It refers to the state in which the ball stays (is in contact).

  The center axis of rotation of the distribution drum 801 extends in the same direction as the left and right direction of the pachinko gaming machine 1, and the placement surface portion 802a is a downflow path plate 423 so that the placement surface portion 802a can be seen from the upper side during rotation. Protruding forward from the reference).

  In other words, the surface of the blade portion 805 opposite to the mounting surface portion 802a is hidden behind the flow-down path plate 423 (see FIG. 4) and can not be seen from above. Therefore, the gaming balls flowing down the flow path board 423 (see FIG. 4) in the gaming area 41 (see FIG. 4) are always mounted on the placement surface 802 a in the grooves 802A to 802D, and the sorting drum 801 is Rotate only in the direction.

  As shown in FIG. 44, the projecting portion 803 which constitutes a part of the three groove portions 802A to 802C is provided on one side in the axial direction of the distributing drum 801 with respect to the mounting surface portion 802a, and It has a wall surface portion 803B that determines the distribution direction. That is, the wall surface portion 803B is opposed to the notch 804A in the axial direction of the distribution drum 801.

  As shown in FIG. 47, the wall surface portion 803B is orthogonal to the first inclined surface 803e extending obliquely from the mounting surface portion 802a outward in the radial direction of the drum main body 802 and the mounting surface portion 802a from the first inclined surface 803e. And a second inclined surface 803 f extending radially outward of the drum main body 802.

  The inclination angle θ1 (for example, 120 °) of the first inclined surface 803e with respect to the mounting surface portion 802a is larger than the inclination angle θ2 (for example, 90 °) of the second inclined surface 803f with respect to the mounting surface portion 802a. The second inclined surface 803 f is configured of a vertical surface.

  The second inclined surface 803f extends above the center point 807a of the gaming ball 807 placed on the placement surface portion 802a from the first inclined surface 803e. In other words, the outer end 803u of the second inclined surface 803f in the radial direction of the drum body 802 is located above the center point 807a of the gaming ball 807 placed on the placement surface 802a.

  As shown in FIG. 45, the projecting portion 804 which constitutes a part of one groove portion 802D is provided on the other of the placement surface portion 802a in the axial direction of the sorting drum 801, and It has a wall surface portion 804B to be determined. That is, the wall surface portion 804B faces the notch 803A in the axial direction of the distribution drum 801.

  As shown in FIG. 48, the wall surface portion 804B is orthogonal to the first inclined surface 804e extending obliquely from the mounting surface portion 802a outward in the radial direction of the drum main body 802 and the mounting surface portion 802a from the first inclined surface 804e. And a second inclined surface 804 f extending radially outward of the drum main body 802.

  The inclination angle θ1 (for example, 120 °) of the first inclined surface 804e with respect to the mounting surface portion 802a is formed larger than the inclination angle θ2 (for example, 90 °) of the second inclined surface 804f with respect to the mounting surface portion 802a. The second inclined surface 804 f is configured of a vertical surface.

  The second inclined surface 804f extends above the center point 807a of the gaming ball 807 mounted on the mounting surface portion 802a from the first inclined surface 804e. In other words, the outer end 804 u of the second inclined surface 804 f in the radial direction of the drum body 802 is located above the center point 807 a of the gaming ball 807 placed on the placement surface 802 a.

  In the sorting apparatus 800, for example, as shown in FIG. 47, when the groove portion 802C faces upward, the groove portion 802C is in a mode capable of receiving the game ball. When the groove portion 802C flows down from above the gaming ball in a state where the gaming ball can be received, the groove portion 802C receives the gaming ball, and the gaming ball is placed on the placement surface portion 802a. Thereby, the groove portion 802C is directed downward while the distribution drum 801 is rotated by the weight of the game ball.

  Under the present circumstances, a game ball moves to the right by the slope of the 1st slope 803e, and is distributed to the right along the 1st slope 803e. Thereby, the game balls distributed by the distribution drum 801 are guided to the second path 423c (see FIG. 4) side.

  In the distributing drum 801, the three grooves 802A to 802C out of the four grooves 802A to 802D have the notches 804A on the right side, so the gaming ball has the second path 423c with a probability of 3/4 (FIG. 4) It is distributed to the reference side.

  On the other hand, for example, as shown in FIG. 48, when the groove portion 802D faces upward, the groove portion 802D is in a mode in which the gaming ball can be received. When the groove 802D flows down from above the gaming ball in a state where the gaming ball can be received, the groove 802D receives the gaming ball, and the gaming ball is placed on the placement surface 802a. At this time, the groove portion 802D is directed downward while the distribution drum 801 is rotated by the weight of the game ball.

  Under the present circumstances, a game ball moves to the left by the slope of the 1st slope 804e, and is distributed to the left along the 1st slope 804e. Thereby, the game balls distributed by the distribution drum 801 are guided to the first path 423b (see FIG. 4) side.

  Since only one groove portion 802D of the four groove portions 802A to 802D has the notch 803A on the left side of the distribution drum 801, the gaming ball has the first path 423b (see FIG. 4) with a probability of 1⁄4 (see FIG. 4) It is distributed to the) side.

  As described above, the sorting apparatus 800 according to the first modification includes the sorting drum 801 in which a plurality of grooves 802A to 802D for receiving gaming balls flowing down the gaming area 41 (see FIG. 4) are formed in the circumferential direction. , And the game balls received (mounted) in the groove portions 802A to 802D are distributed.

  As shown in FIGS. 47 and 48, the grooves 802A to 802D extend outward in the radial direction of the sorting drum 801, and the sorting surface 802a on which gaming balls are placed and the sorting surface 802a are sorted A first inclined surface provided on both sides in the axial direction of the drum 801 and having wall surface portions 803B and 804B for determining the distribution direction of gaming balls, and the wall surface portions 803B and 804B are connected to the mounting surface portion 802a 803e, 804e, and second inclined surfaces 803f, 804f connected to the first inclined surfaces 803e, 804e are formed, and the inclination angle θ1 of the first inclined surfaces 803e, 804e with respect to the mounting surface portion 802a is The inclination angle θ2 of the second inclined surfaces 803f and 804f with respect to the surface portion 802a is set larger.

  Thereby, the inclination angles of the second inclined surfaces 803f, 804f can be made steeper than the inclination angles of the first inclined surfaces 803e, 804e. Thereby, for example, when the flow-down speed of the game ball is fast, etc., the game ball received in the groove portions 802A to 802D runs up along the wall surface portions 803B and 804B, and the game ball rolls in an unintended direction. It can prevent.

  Therefore, it is possible to prevent the game balls from being caught between the distribution drum 801 and the flow-down path plate 423 (see FIG. 4), and to prevent the occurrence of the rotation failure of the distribution drum 801. As a result, the game balls can be distributed reliably, and the reliability of the pachinko gaming machine 1 can be improved.

  Further, according to the sorting apparatus 800 of the first modified example, the center point 807a of the game ball 807 placed on the placement surface portion 802a from the first sloped surfaces 803e and 804e from the second sloped surfaces 803f and 804f. It is extended to the upper side more than.

  Thus, the center of gravity of the gaming ball 807 placed on the placement surface 802a can be made lower than the upper ends of the second inclined surfaces 803f and 804f, and the gaming sphere 807 placed on the placement surface 802a is a wall surface. It can be more effectively prevented from running up along the sections 803B and 804B. In addition, when the distributing drum 801 is rotated by its own weight of the gaming ball, the gaming ball is surely guided in the direction along the inclined surfaces of the first inclined surfaces 803e and 804e of the grooves 802A to 802D facing downward. Can be discharged.

  In the distribution drum 801 according to the present embodiment, the slopes connecting the outer ends 803u and 804u of the second inclined surfaces 803f and 804f and the protrusions 803 and 804 are outside (mounted on the mounting surface 802a). The outer ends 803u and 804u project from the projecting portions 803 and 804 toward the inner side (the gaming ball 807 placed on the mounting surface portion 802a) because they are inclined in the direction away from the gaming ball 807). It has a shape like that. As a result, when the game ball hits the outer ends 803u and 804u, the game ball is induced in the distribution direction.

  On the other hand, the first inclined surface is formed by inclining the slope connecting the outer ends 803u and 804u and the protrusions 803 and 804 inward (to the gaming ball 807 placed on the placement surface 802a). The concave portions may be formed by 803e and 804e and the second inclined surfaces 803f and 804f. In this case, the second inclined surfaces 803f and 804f can guide the game balls in the distribution direction. Even in this case, the inclination angle θ1 of the first inclined surface with respect to the mounting surface portion 802a is larger than the inclination angle θ2 of the second inclined surface with respect to the mounting surface portion 802a.

[Distributing drum of the second modification]
As shown in FIG. 49, the distribution drum 801 of the second modification differs from that of the present embodiment in the configuration of the first cam lock 504 (see FIG. 7), and the configuration of the blade portion is the first modification. It is different from the sorting drum.

  That is, as shown in FIG. 7, in the first cam lock 504 of the present embodiment, the convex portion of the gear portion 504e is formed at four places (four places for the concave part) as well. As shown in FIG. 49, the gear portion 810A in the dividing drum 801 has eight convex portions 810a and concave portions 801b. In this case, the gear portion of the second cam lock 811 also has eight convex portions 811 a and concave portions 811 b meshing with the gear portion 810A.

  According to such a configuration, the inclination angle of the slope continuous with the convex portion 810a and the concave portion 810b can be made larger than the inclination angle of the slope continuous with the convex portion and the concave portion of the gear portion 504e in the present embodiment. That is, in the distribution drum 801 of the second modification, the inclination angle of the slope connecting the lowermost portion of the concave portion 810b and the vertex of the convex portion 810a is the lowermost portion of the concave portion of the gear portion 504e and the convex portion in the present embodiment. It can be larger than the inclination angle of the slope connecting with the top of the part.

  Therefore, the unevenness in the gear portion 810A of the second modification can be made steeper than the unevenness in the gear portion 504e in the present embodiment. Thereby, the convex portion is formed at four rotation angles of the distributing drum 810 until the convex portion 810a moves from the concave portion 811b of the second cam lock 811 to the convex portion 811a when the distributing drum 801 rotates. The rotation angle of the distribution drum 801 can be made smaller.

  Therefore, when the distribution drum 801 rotates, the convex portion 810a of the gear portion 810A is in the middle of the slope of the second cam lock 811 by the pressing force of the second cam lock 811 biased by the spring member 506 (see FIG. 5). In this state, the distribution drum 801 can be reliably prevented from being locked in the rotational direction.

  Further, as shown in FIG. 50, the blade portion 812 of the distribution drum 801 of the second modification is more circumferential than the blade portion 805 (see FIG. 44) of the distribution drum 801 of the first modification. It has a thin configuration.

  Specifically, as the tip end side of the blade portion 812 is directed radially outward, the blade portion 812 gradually becomes thinner, and the tip portion has the thinnest shape. Therefore, the circumferential width of the top surface 812a of the blade portion 812 is smaller than the circumferential width of the top surface of the blade portion 805 (see FIG. 44) in the first modification. Therefore, the top surface 812a of the wing 812 has a smaller area in contact with the game ball as compared with the wing 805 (see FIG. 44) in the first modification.

  According to such a configuration, when the gaming balls flowing down are received by the groove portions 802A to 802D, the game balls are prevented from being placed on the top surface 812a of the wing portion 812 and distribution is performed. It is possible to prevent the game ball from being caught between the drum 801 and the flow path board 423 (see FIG. 4). For this reason, it is possible to prevent the occurrence of the rotation failure of the distribution drum 801 and distribute the gaming balls more reliably, and the reliability of the pachinko gaming machine 1 can be more effectively improved.

[Electric configuration of gaming machine]
A block diagram showing a control circuit of the pachinko gaming machine 1 in the present embodiment is shown in FIG. As shown in FIG. 51, the pachinko gaming machine 1 mainly includes a main control circuit 100 that controls a game and a sub control circuit 200 that controls an effect according to the progress of the game.

  The main control circuit 100 includes a main CPU 101, a main ROM 102 (read only memory), and a main RAM 103 (read / write memory).

  A main ROM 102, a main RAM 103, etc. are connected to the main CPU 101, and the main CPU 101 has a function of executing various processes according to a program stored in the main ROM 102.

  The main ROM 102 stores programs for controlling the operation of the pachinko gaming machine 1 by the main CPU 101, for example, programs for causing the main CPU 101 to execute the processing shown in FIGS. 52 to 61, various tables, etc. There is.

  The main RAM 103 has a function of storing values of various flags and variables as a temporary storage area of the main CPU 101. Although the main RAM 103 is used as a temporary storage area of the main CPU 101 in the present embodiment, the present invention is not limited to this, and any storage medium that can read and write may be used.

  The main control circuit 100 generates a clock pulse of a predetermined frequency, a reset clock pulse generating circuit 104, an initial reset circuit 105 generating a reset signal at power on, and a command to a sub control circuit 200 described later. And a serial communication IC 106 for supplying The reset clock pulse generation circuit 104, the initial reset circuit 105, and the serial communication IC 106 are connected to the main CPU 101.

  The reset clock pulse generation circuit 104 generates a clock pulse every predetermined period (for example, 2 milliseconds) in order to execute a system timer interrupt process described later.

  The initial reset circuit 105 includes a capacitor and a watchdog timer, and transmits a reset signal to the main CPU 101 when the voltage applied to the capacitor reaches a predetermined value. Further, the initial reset circuit 105 discharges to release the voltage applied to the capacitor by receiving a predetermined control signal from the main CPU 101.

  The serial communication IC 106 is connected to the main CPU 101, the sub control circuit 200, and the payout / firing control circuit 300, and includes a sub control board buffer and a payout / firing control circuit buffer.

  Further, various devices are connected to the main control circuit 100. For example, as various devices responsive to a signal from the main control circuit 100, a special symbol display device 431 for performing variable display of a special symbol in a special symbol game, a round number display device 432 for displaying the number of rounds in a round game, a special symbol A first special symbol hold display device 433a and a second special symbol hold display device 433b for displaying the number of pending variable display of special symbols in the game, and a normal symbol display device for variable display of an ordinary symbol as an identification symbol in an ordinary symbol game 434, Normal symbol holding display device 435 for displaying the number of pending variable display of normal symbols in normal symbol game, ordinary electric role solenoid 111 for making flat plate member 415a projected or retracted, and shutter member 422a Let the large falling opening 423e (large winning opening 418) open Winning opening solenoid 112 such that the closed state is connected. In addition, an external terminal board used to transmit data to a calling device (not shown) having a function of calling a hall clerk and a function of displaying the number of hits and a hall computer that manages pachinko gaming machines in the entire hall is connected.

  In addition, various sensors are connected to the main control circuit 100. For example, in the main control circuit 100, the game ball is provided in the count sensor 113 for supplying a predetermined detection signal to the main control circuit 100 when the gaming ball is won in the big winning opening 418, and the general winning opening 419a, 419b, 419c. When the game ball wins in the general winning ball sensor 114a and the general winning opening 419d for supplying a predetermined detection signal to the main control circuit 100 when winning, a general winning for supplying a predetermined detection signal to the main control circuit 100 When the game ball enters the ball sensor 114b, the ball passage detector 416, the ball passage detection sensor 115 for supplying a predetermined detection signal to the main control circuit 100, when the game ball wins the first starting opening 414a When the gaming ball wins in the first starting opening winning ball sensor 116a and the second starting opening 414b that supply a predetermined detection signal to the main control circuit 100, the predetermined detection signal A predetermined detection signal is supplied to the main control circuit 100 when the game ball enters the second starting opening winning ball sensor 116b, the first special out port 420b, and the second special out port 420c supplied to the control circuit 100. A first out ball detection sensor 117a, a second out ball detection sensor 117b, a backup clear switch 118 for clearing backup data at the time of power interruption or the like according to the operation of the game arcade manager are connected. In the present embodiment, the term "winning" means that the game ball passes through the area provided with each of the above sensors.

  Further, a payout / firing control circuit 300 is connected to the main control circuit 100. To the payout / firing control circuit 300, a payout device 71 for paying out gaming balls, a launching device 20 for firing gaming balls, and a card unit 400 are connected. The card unit 400 can be transmitted / received to / from the lending operation unit 401 which outputs a signal requesting the card unit 400 to lend a gaming ball by the operation of the player.

  The payout / firing control circuit 300 receives a prize ball control command supplied from the main control circuit 100 and a rental ball control signal supplied from the card unit 400, and transmits a predetermined signal to the payout device 71. The payout device 71 pays out the game ball. Further, the payout / firing control circuit 300 supplies power to the firing solenoid according to the turning angle when the firing handle 21 is held by the player and turned clockwise. Control the firing of the ball.

  Furthermore, a sub control circuit 200 is connected to the main control circuit 100. The sub control circuit 200 performs display control in the liquid crystal display device 50, control on sound generated from the speaker 14, control of a lamp including a decoration lamp, and the like according to various commands supplied from the main control circuit 100. .

  In the present embodiment, the main control circuit 100 supplies a command to the sub control circuit 200, and the sub control circuit 200 can not supply a signal to the main control circuit 100. Not limited to this, the sub control circuit 200 may be configured to be able to transmit a signal to the main control circuit 100.

  The sub control circuit 200 controls the sub CPU 201, the program ROM 202, the work RAM 203, the RTC 204, the lower movable effect member 610, the upper movable effect member 650, the right movable effect member 750 and the left movable effect member 770. A display control circuit 210 for performing display control in the liquid crystal display device 50; an audio control circuit 220 for controlling audio generated from the speaker 14; a lamp control circuit 230 for controlling the lamp 15 including a decoration lamp; The first operation means control circuit 240a receives an operation signal based on the player's operation from 16; the second operation means control circuit 240b receives an operation signal based on the player's operation from the touch sensor 425; the light source 426b of the illumination array 426 LED control circuit 25 for controlling light emission It is constructed from. The sub control circuit 200 executes effects according to the progress of the game in response to the command from the main control circuit 100.

  The sub CPU 201 has a function of executing various processes in accordance with the program stored in the program ROM 202. In particular, the sub CPU 201 controls the sub control circuit 200 in accordance with various commands supplied from the main control circuit 100.

  The program ROM 202 stores programs for controlling the game effects of the pachinko gaming machine 1 by the sub CPU 201 and various tables.

  In the present embodiment, the main ROM 102 and the program ROM 202 are used as storage means for storing programs, tables and the like, but the present invention is not limited thereto, and a computer readable storage medium provided with control means If it is, it may be another aspect, for example, may be recorded on storage media, such as a hard disk drive, CD-ROM and DVD-ROM, and a ROM cartridge. Further, these programs may not be stored in advance, but may be downloaded after power on and stored in the work RAM 203 or the like. Furthermore, each of the programs may be recorded on separate storage media.

  The work RAM 203 stores various flags and variable values as a temporary storage area of the sub CPU 201. In the present embodiment, the work RAM 203 is used as a temporary storage area of the sub CPU 201. However, the present invention is not limited to this, and any storage medium that can read and write may be used. The RTC 204 clocks the current time.

  The display control circuit 210 is a circuit that performs display control of the liquid crystal display device 50, and includes an image data processor (hereinafter referred to as VDP), an image data ROM storing data for generating various image data, It comprises a frame buffer for buffering image data, a D / A converter for converting image data as an image signal, and the like.

  The display control circuit 210 is a device capable of performing various processes for displaying an image on the liquid crystal display device 50 in accordance with data supplied from the sub CPU 201. The display control circuit 210 displays on the liquid crystal display device 50 various image data such as identification symbol image data indicating an identification symbol, background image data, image data for effect, etc. in accordance with an image display instruction supplied from the sub CPU 201. Temporarily store the image data to be used in the frame buffer.

  Then, the display control circuit 210 supplies the image data stored in the frame buffer to the D / A converter at a predetermined timing. The D / A converter converts image data as an image signal and supplies the image signal to the liquid crystal display device 50 at a predetermined timing, whereby an image is displayed on the liquid crystal display device 50. That is, the display control circuit 210 performs control to cause the liquid crystal display device 50 to display an image related to a game.

  Further, the audio control circuit 220 is configured of a sound source IC for controlling audio, an audio data ROM for storing various audio data, an amplifier for amplifying an audio signal (hereinafter referred to as AMP), and the like.

  The sound source IC controls the sound generated from the speaker 14. The sound source IC selects one audio data from a plurality of audio data stored in the audio data ROM in response to an audio generation instruction supplied from the sub CPU 201. The sound source IC also reads out the selected audio data from the audio data ROM, converts the audio data into a predetermined audio signal, and supplies the audio signal to the AMP. The AMP amplifies the audio signal and generates audio from the speaker 14.

  The lamp control circuit 230 includes a drive circuit for supplying a lamp control signal, a decoration data ROM in which a plurality of kinds of lamp decoration patterns are stored, and the like.

  The first operation means control circuit 240 a transmits the operation signal received from the effect button 16 to the sub CPU 201. The sub CPU 201 supplies data for performing rendering according to the operation signal to the display control circuit 210 and the like.

  The second operation unit control circuit 240 b transmits the operation signal received from the touch sensor 425 to the sub CPU 201. The sub CPU 201 supplies data for performing rendering according to the operation signal to the display control circuit 210 and the like.

  The movable effect device control circuit 205 includes a motor 612 for driving the lower movable effect member 610, a motor 652 for driving the upper movable effect member 650, a motor 661, a motor 758 for driving the right movable effect member 750, a left movable effect member A movable effect device 205A including a motor 778 for driving the 770 and an electromagnetic solenoid (not shown) for driving the small movable effect member 790 is connected.

  The movable effect control circuit 205 drives the movable effect device 205A in the big hit game state, the normal game state, etc., thereby the lower movable effect member 610, the upper movable effect member 650, the right movable effect member 750 and the left movable effect member An effect of moving 770 between the standby position and the drive position, and an effect of reciprocating the small movable effect member 790 in the vertical direction are performed.

  The LED control circuit 250 is provided on the LED provided on the lower movable effect member 610, the LED provided on the upper movable effect member, the LED provided on the right movable effect member 750 and the left movable effect member 770, and the effect button 16 Drive circuit for supplying current to the LED group 18 consisting of the LEDs and the light source 426b of the illumination array 426, data in which a light emission pattern for performing display of plural types of illumination display and LED group 18 is stored It comprises ROM and the like.

  Next, processing executed by the main control circuit 100 and the sub control circuit 200 according to the present embodiment will be described. First, processing executed by the main CPU 101 of the main control circuit 100 will be described. When the power is turned on, the main CPU 101 reads a program from the main ROM 102 and executes main control main processing. Further, even when the main CPU 101 is executing the main control main process, the main CPU 101 may interrupt the main control main process and execute the system timer interrupt process. The main CPU 101 generates a clock pulse every predetermined period (for example, 2 milliseconds), and executes system timer interrupt processing in response to this.

[System timer interrupt processing]
The system timer interrupt process of the main CPU 101 will be described with reference to FIGS. 52, 53 and 54. As shown in FIG. 52, in step S10, processing for saving each register is performed. In this process, the main CPU 101 performs a process of saving a register. If this process ends, the process moves to step S11.

  In step S11, random number update processing is performed. In this process, the main CPU 101 performs a process of updating the random number. For example, the main CPU 101 updates random numbers such as a jackpot determination random number counter, a jackpot symbol random number counter, a normal symbol determination random number counter, a presentation condition determination random number counter, and a prefetch notice determination random number counter. The big hit judgment random number counter and the big hit symbol random number counter lose their fairness if the update timing of the counter value is indeterminate, so they are updated at a fixed timing every 2 msec to secure this. To do. If this process ends, the process moves to step S12.

  In step S12, a switch input detection process is performed. In this processing, the main CPU 101 performs processing to determine whether or not there is an input to the switch. For example, the main CPU 101 may be a count sensor 113 (see FIG. 51) provided in the big winning opening 418 (see FIG. 4) or a general winning ball sensor provided in the general winning openings 419a, 419b, 419c (see FIG. 4). 114a (see FIG. 51), a general winning ball sensor 114b (see FIG. 51) provided in the general winning opening 419d (see FIG. 4), and a ball passage detection provided in the ball passage detector 416 (see FIG. 4) The first starting opening winning ball sensor 116a and the second starting opening winning ball sensor 116b (see FIG. 51) provided at the sensor 115 (see FIG. 51), the first starting opening 414a and the second starting opening 414b (see FIG. 4). And detection signals from the first out-of-ball detection sensor 117a and the second out-of-ball detection sensor 117b provided in the first special out port 420b and the second special out port 420c (see FIG. 4). By receiving, it determines whether each switch detects the game ball. When the main CPU 101 determines that it has been detected, it updates the special winning opening prize ball counter, the general winning opening prize ball counter, the starting opening prize ball counter, etc. according to the detection. Details of the switch input process will be described later. If this process ends, the process moves to step S13.

  In step S13, a timer update process is performed. In this process, the main CPU 101 measures the open time of the waiting time timer for synchronizing the main control circuit 100 and the sub control circuit 200, and the open time of the big winning opening 418 (see FIG. 4) opened when a big hit occurs. A process for updating various timers, such as a special winning opening opening time timer, is performed. When this process ends, the process proceeds to step S14.

  In step S14, command output processing is performed. In this process, the main CPU 101 supplies various commands to the sub control circuit 200. As these various commands, for example, a demonstration display command derived and displayed on the liquid crystal display device 50, a derived symbol designating command described later, a variation pattern designating command described later, a big hit type command described later, a big hit start command described later, It includes a small hit start command to be performed, a start opening winning command to be described later, an out ball command, and the like. In this process, the main CPU 101 supplies, to the sub control circuit 200, data indicating the value of the probability variation state variation frequency counter described later and data indicating the value of the time short status variation frequency counter described later, in addition to various commands. . In addition, the main CPU 101 is a normal winning combination solenoid 112 (see FIG. 51) for driving the shutter member 422a of the large drop opening 423e (large winning opening 418), and an ordinary electric combination to open and close the flat plate member 415a of the ordinary electric combination 415 The solenoid power supply for driving the object solenoid 111 (see FIG. 51) is supplied. In addition, the variation pattern of the identification symbol (derived symbol) for effect displayed in the display area 51 (see FIG. 4) of the liquid crystal display device 50 is determined in the start opening winning detection process (see FIG. 54) described later. In this case, the main CPU 101 generates a variation pattern designation command indicating the determination result and supplies the variation pattern designation command to the sub control circuit 200. Further, when it is determined that the advance notice is to be executed in the start-up winning game detection process (see FIG. 54) described later, the main CPU 101 generates an advance notice / predictive decision command indicating the determination result to the sub control circuit 200. Supply. If this process ends, the process moves to step S15.

  In step S15, game information output processing is performed. In this processing, the main CPU 101 controls the sub control circuit 200, the payout / fire control circuit, for game information which is information related to a game processed by the main control circuit 100, the sub control circuit 200, the payout / fire control circuit 300, etc. 300, output to an external device (e.g. hall computer or calling device). If this process ends, the process moves to step S16.

  In step S16, processing is performed to restore each register. In this processing, the main CPU 101 performs processing to restore each register to the address before interrupt processing. When this process ends, the present subroutine ends.

[Switch input detection processing]
The subroutine (switch input detection processing) executed in step S12 of FIG. 52 will be described with reference to FIG. In step S20, a starting opening winning combination detection process is performed. In this process, the main CPU 101 controls the first starting opening winning ball sensor 116a and the second starting opening winning ball sensor 116b (see FIG. 51) provided in the first starting opening 414a and the second starting opening 414b (see FIG. 4). When the detection signal from the is received, the jackpot judgment random number value and the jackpot symbol random number value are acquired, 4 pieces are set as the upper limit, the number of reserved pieces for the special symbol is added, and the payout information is made to the predetermined area of the main RAM 103 set. Details of the starting opening winning combination detection process will be described later. If this process ends, the process moves to step S21.

  In step S21, general winning opening passage detection processing is performed. In this process, the main CPU 101 controls the general winning ball sensor 114a (see FIG. 51) provided on the general winning openings 419a, 419b and 419c (see FIG. 4) and the general winning openings 419 d (see FIG. 4). When the detection signal from the winning ball sensor 114b (see FIG. 51) is received, the payout information corresponding to the winning of the general winning openings 419a, 419b, 419c, 419d is set in a predetermined area of the main RAM 103. If this process ends, the process moves to step S22.

  In step S22, a special winning opening passage detection process is performed. In this process, when the main CPU 101 receives a detection signal from the count sensor 113 (see FIG. 51) provided in the special winning opening 418 (see FIG. 4), the payout corresponding to the winning of the special winning opening 418 is made. Information is set in a predetermined area of the main RAM 103. If this process ends, the process moves to step S23. The payout information corresponding to the winning of the first start opening 414a, the second start opening 414b, the general winning openings 419a, 419b, 419c, 419d, and the special winning opening 418 set in the predetermined area of the main RAM 103 is a prize ball control command. It is supplied from the main control circuit 100 to the payout / emission control circuit 300. The payout / firing control circuit 300 causes the payout device 71 to pay out the gaming balls based on the supplied prize ball control command. As described above, the payout device 71 functions as a game value giving unit capable of giving a predetermined game value based on the game medium having passed through either the third passage area or the fourth passage area.

  In step S23, a sphere passage detector passage detection process is performed. In this process, when the main CPU 101 receives a detection signal from the ball passage detection sensor 115 (see FIG. 51) provided in the ball passage detector 416 (see FIG. 4), the lottery result for the normal symbol (randomness A numerical value) is acquired, and four are set as the upper limit, and “1” is added to the normal symbol holding memory number counter (holding number) stored in the main RAM 103. If this process ends, the process moves to step S24.

  In step S24, a first out port passage detection process is performed. In this process, when the main CPU 101 receives a detection signal from the first out-of-sphere detection sensor 117a (see FIG. 51) provided in the first special out port 420b (see FIG. 4), the main CPU 101 executes the first out-sphere command. When the detection signal from the second out-of-sphere detection sensor 117b (see FIG. 51) stored in the main RAM 103 and provided in the second special out port 420c (see FIG. 4) is received, the second out-ball command is stored in the main RAM 103. Perform processing to store in

[Starting mouth winning detection process]
The sub-routine (starting opening winning detection process) executed in step S20 of FIG. 53 will be described with reference to FIG. In step S30, processing is performed to determine whether or not it has been detected by the first starting opening winning ball sensor. In this process, the main CPU 101 determines whether a detection signal has been received from the first starting opening winning ball sensor 116a. If the detection signal is received from the first starting opening winning ball sensor 116a, the process proceeds to step S31. If the detection signal is not received from the first starting opening winning ball sensor 116a, the processing proceeds to step S39. Transfer the process.

  In step S31, a payout information setting process is performed. In this process, the main CPU 101 sets payout information corresponding to the winning of the first start opening 414a (see FIG. 4) in a predetermined area of the main RAM 103. If this process ends, the process moves to step S32.

  In step S32, it is determined whether or not the number of first starting hole winnings held is smaller than "4". In this process, the main CPU 101 determines whether or not the number of holdings based on the winning of the first starting opening 414a (see FIG. 4) is smaller than "4". If the number of holdings is smaller than "4", the step The process proceeds to step S33, and if the number of held items is "4" or more, the process proceeds to step S39.

  In step S33, a process is performed to add "1" to the number of pending positions of the first starting hole winning. In this process, the main CPU 101 performs a process of adding “1” to the value of the number of holdings based on the winning of the first starting opening 414 a (see FIG. 4) stored in the main RAM 103. If this process ends, the process moves to step S34.

  In step S34, random number acquisition / storage processing is performed. In this process, the main CPU 101 extracts a big hit determination random number value for the special symbol game from the big hit determination random number counter (so-called special symbol lottery), and further extracts a big hit symbol random number value from the big hit symbol random number counter. Then, the main CPU 101 stores the extracted big hit determination random number value and the big hit symbol random number value in the main RAM 103, the first special symbol start storage area storing the random value based on the winning of the first start opening 414a (see FIG. 4). Perform processing to store in In the present embodiment, the first special symbol start storage area is the first special symbol start storage area (0) to the first special symbol start storage area (4), and the first special symbol start storage area (0) Judgment results based on the random numbers for collision judgment stored in) are derived and displayed by a special symbol, and various random number values obtained by winning in the first starting opening 414a (see FIG. 4) during fluctuation of the special symbol are First special symbol start storage area (1) to first special symbol start storage area (4) are sequentially stored. If this process ends, the process moves to step S35.

  In step S35, special symbol determination processing is performed. In this process, the main CPU 101 refers to the big hit random number determination table (see FIG. 73) and the big hit symbol random number determination table (see FIG. 74) based on the big hit determination random number value and the big hit symbol random number value extracted in step S34. The special symbol to be stopped and displayed on the special symbol display device 431 is determined, and data indicating the special symbol is stored in a predetermined area of the main RAM 103. In the present embodiment, the special symbol indicates a big hit symbol indicating that a big hit has been won, a small hit symbol indicating that a small hit has been won, and that neither a big hit nor a small hit has been won. Missing design, and is included.

[Big hit random number judgment table]
Here, the big hit random number determination table will be described with reference to FIG. In the present embodiment, the big hit random number determination table is the big hit random number determination table (see FIG. 73A) that is referred to when the random number value based on the winning of the first starting opening 414a (see FIG. 4) is extracted. A big hit random number judgment table (second starting opening) to be referred to when random number values based on the winning of the second starting opening 414b (see FIG. 4) shown in FIG. 73 (b) are extracted. And are stored in the main ROM 102. In the jackpot random number determination table, determination value data is associated with a jackpot determination random value for which a predetermined width is set, for each probability change flag indicating whether the gaming state is a definite change state or a non-determination change state. Here, the random number value for jackpot determination is 65,536 (0 to 65535), and it is determined whether the jackpot is the result of the lottery triggered by the winning of the first starting port 414a or the second starting port 414b. It is a random value representing a numerical value, specifically, a lottery result of a special symbol. The definite change flag is a flag that is stored in the main RAM 103 and represents whether or not the definite change state is selected as the gaming state after the end of the big hit gaming state, and is not a definite change state when the value is "0". Indicates a non-deterministic state, and indicates that the state is a probable state if the value is "1". As described above, the main control circuit 100 manages a flag as to whether or not the state is a positive change state, and the jackpot probability changes depending on whether the positive change state or not. Also, the selectivity shown in FIG. 73 represents the probability that the corresponding determination value data will be selected.

  Specifically, the big hit random number determination table (first start port) shown in FIG. 73 (a) is a big hit determination random number value “777-943” (width 167 in the case of the probability change flag “0” (non-probability change state). The big hit determination value data is associated with), the small hit determination value data is associated with the big hit determination random number value "1-300" (width 300), and the loss determination value data is associated with random number values other than these. ing. Also, in the big hit random number determination table (first start port), in the case of the probability change flag "1" (positive change state), the big hit determination value data is associated with the big hit determination random number value "777-1277" (width 500), The small hit determination value data is associated with the jackpot determination random number value “1-300” (width 300), and the loss determination value data is associated with random number values other than these. As described above, in the present embodiment, the probability of becoming a big hit (hereinafter also referred to as a big hit probability) is 1/392 when winning in the first starting opening 414 a in a non-deterministic state, and the probability of becoming a small hit ( Hereinafter, it is also called a small hit probability) is 1/218. On the other hand, when winning in the first starting opening 414a in a definite variation state, the big hit probability is 1/131 and the small hit probability is 1/218.

  Further, the big hit random number determination table (second starting port) shown in FIG. 73 (b) shows a big hit for the big hit determination random number value “777-943” (width 167) in the case of the positive change flag “0” (non positive change state). Judgment value data are associated, and loss judgment value data is associated with random number values other than this. In the big hit random number determination table (second starting port), the big hit determination value data is associated with the big hit determination random number value “777-1277” (width 500) in the case of the probability variation flag “1” (positive variation state), Loss determination value data is associated with random number values other than this. As described above, in this embodiment, the probability of becoming a big hit (hereinafter, also referred to as a big hit probability) is 1/392 when winning in the second starting port 414b in a non-deterministic state, and a small hit will be won. There is no. On the other hand, when winning in the first starting opening 414a in a definite change state, the jackpot probability is 1/131 and there is no chance of winning in a small hit.

[Big hit symbol random number judgment table]
Next, the jackpot symbol random number determination table will be described with reference to FIG. In the present embodiment, the jackpot symbol random number determination table is a jackpot symbol random number determination that is referred to when the random number value based on the winning of the first starting opening 414a (see FIG. 4) shown in FIG. The jackpot symbol random number determination table (the second table shown in FIG. 74 (b) and the random number value based on the winning on the second start window 414b (see FIG. 4) shown in FIG. The start port) is stored in the main ROM 102. In the jackpot symbol random number determination table, a symbol designation command is associated with a jackpot symbol random number value for which a predetermined width is set. Here, the jackpot symbol random number value represents a random number value that determines the jackpot symbol when the result of the lottery is a jackpot. Further, the symbol designation command represents a jackpot symbol designation command corresponding to the jackpot symbol random number value.

  Specifically, in the jackpot symbol random number determination table (first starting port) shown in FIG. 74 (a), the symbol designation command "z0" is associated with the jackpot symbol random number value "0 to 19", and the jackpot symbol random number value The symbol designation command "z1" is associated with "20 to 39", the symbol designation command "z2" is associated with big hit symbol random number value "40 to 59", and the symbol designation is specified for big hit symbol random number "60 to 79" The command “z3” is associated, and the jackpot symbol random number “80 to 99” is associated with the symbol designation command “z4”. As described above, in the present embodiment, when winning in the first start opening 414a and winning a big hit, the symbol designation commands "z0" to "z4" are equally selected with a probability of 20/100.

  In the jackpot symbol random number determination table (second starting port) shown in FIG. 74 (b), the symbol selection command "z0" is associated with the jackpot symbol random number value "0 to 19", and the jackpot symbol random number value "20" The symbol designation command "z4" is associated with 99 ". As described above, in this embodiment, when the second starting opening 414b is won and the big hit is won, the symbol designation command "z0" is selected at 20/100 and the symbol designation command "z4" is at 80/100. It is selected. That is, when winning in the second start opening 414b and winning a big hit, the probability that the symbol designation command "z4" is selected is higher than when winning in a first start opening 414a and winning a big hit.

  Referring back to FIG. 54, in step S35, specifically, the main CPU 101 determines the big hit random number determination table (first start port) shown in FIG. 73 (a) and the big hit symbol random number determination table shown in FIG. 74 (a) 1) With reference to the start opening, the symbol designation command associated with the special symbol to be stopped and displayed on the special symbol display device 431 is determined based on the jackpot determination random number value extracted in step S34. Specifically, when the extracted big hit determination random number value is associated with the big hit determination value data in the big hit random number determination table (first starting port), the main CPU 101 extracts the big hit extracted in step S34. Based on the symbol random number value, the jackpot symbol random number determination table (first start opening) is referred to, and one of the symbol designation commands "z0" to "z4" is selected. Further, when the extracted main hit determination random number value is associated with the small hit determination value data in the big hit random number determination table (first start port), the main CPU 101 selects the symbol designation command “z11” (see FIG. Select 75). Further, when the extracted main hit determination random number value is associated with the loss determination value data in the big hit random number determination table (first start port), the main CPU 101 selects the symbol designation command “z5” (FIG. 75) (FIG. See). If this process ends, the process moves to step S36.

  In step S36, a jackpot determination process is performed. In this process, the main CPU 101 refers to the big hit random number determination table (first start port) shown in FIG. 73A, and the big hit determination random number value extracted in step S34 is associated with the big hit determination value data. Determine if it is. If this process ends, the process moves to step S37.

  In step S37, fluctuation pattern determination processing is performed. In this process, the main CPU 101 extracts a variation pattern random number value, and determines a special symbol variation pattern based on the variation pattern random number value, the special symbol determined in step S35, and the result of the jackpot determination process of step S36. The variation pattern is determined with reference to a variation pattern determination table (see FIG. 75) to be stored, and stored in a predetermined area of the main RAM 103. The main CPU 101 determines the variation display mode of the special symbol in the special symbol display device 431 based on the data indicating such variation pattern.

[Variation pattern determination table]
Here, the fluctuation pattern determination table will be described with reference to FIG. The variation pattern determination table is stored in the main ROM 102, and the symbol designation command ("z0", "z1", "z2", "z3", "z4", "z4", "z5", "z11" ) And winning categories ("lost", "small hit", "big hit") are associated. Further, in the variation pattern determination table, data indicating the variation time of the special symbol is associated with each variation pattern.

  In addition, fluctuation time is the information which may be used as execution time of the production in fluctuation of 1 including the case where it is used as an end condition of fluctuation display in fluctuation of 1, and is 1 vis-a-vis fluctuation pattern of 1 When one fluctuation time is associated, when a plurality of fluctuation times are associated with one fluctuation pattern, when a fluctuation time is associated with a plurality of fluctuation patterns, And, in the case where a plurality of fluctuation patterns are associated with a plurality of fluctuation times, the correspondence of various information is taken into consideration. On the other hand, 1 fluctuation pattern corresponds to 1 fluctuation. In the case where there are two or more variation patterns corresponding to one variation, the relationship between the variation, the variation pattern, and the variation time is configured by the combination of each memory pattern. Rukoto is considered.

  Referring back to FIG. 54, in step S37, the main CPU 101 supplies data indicating the determined fluctuation pattern to the special symbol display device 431. The special symbol display device 431 variably displays the special symbol in the variation time defined in the variation pattern determination table (see FIG. 75) based on the data indicating the variation pattern, and in the mode associated with the symbol designation command Stop display. Further, data indicating a variation pattern is supplied from the main CPU 101 of the main control circuit 100 to the sub CPU 201 of the sub control circuit 200 as a variation pattern designation command based on the first start hole winning. The sub CPU 201 of the sub control circuit 200 executes the effect display according to the received fluctuation pattern designation command. If this process ends, the process moves to step S38.

  In step S38, pre-reading advance notice determination processing is performed. In this process, the main CPU 101 determines whether or not to execute the advance notice by referring to the random number value for advance notice determination and the advance notice determination table for determining whether to execute the advance notice.

  Here, the pre-reading notice determination table will be described. The pre-read advance notice determination table is stored in the main ROM 102, and associates each variation pattern determined according to the number of holdings with a determination value for determining whether or not pre-read advance notice is to be performed. The determination values are more associated as the variation time is a longer variation pattern. That is, as the fluctuation time is a fluctuation pattern having a long fluctuation time, it becomes easier to determine that the prefetch notice is to be executed. When the main CPU 101 determines that the prefetch notice is to be executed, the main CPU 101 transmits, to the sub CPU 201 of the sub control circuit 200, a prefetch notice determination command including information indicating that the prefetch notice is to be executed. The sub CPU 201 of the sub control circuit 200 executes an effect of changing the display mode of the holding symbol corresponding to the received preview notice determination command as the preview notice. In addition to the effect of changing the display mode of the reserved symbol, the advance notice is not limited as long as it is accompanied by a change such as a change in the effect stage or a change in the effect mode. If this process ends, the process moves to step S39.

  In step S39, a command setting process is executed to increase the number of held first starting hole wins. In this process, the main CPU 101 uses the main command to increase the number of pending items for driving the first special symbol suspension display device 433a (see FIG. 4) according to the process of adding "1" to the value of the number of pending items in step S33. A process of storing in the RAM 103 is performed. The main CPU 101 supplies this holdup number increase command to the first special symbol hold display device 433a. The first special symbol hold display device 433a lights the display lamp based on the supplied hold number increase command. If this process ends, the process moves to step S40.

  In step S40, a process is performed to determine whether or not the second starting opening winning ball sensor has detected it. In this process, the main CPU 101 determines whether a detection signal has been received from the second starting opening winning ball sensor 116b. If the detection signal is received from the second starting opening winning ball sensor 116b, the process proceeds to step S41. If the detection signal is not received from the second starting opening winning ball sensor 116b, this subroutine is executed. finish.

  In step S41, a payout information setting process is performed. In this process, the main CPU 101 sets payout information corresponding to the winning of the second start port 414b (see FIG. 4) in a predetermined area of the main RAM 103. If this process ends, the process moves to step S42.

  In step S42, processing is performed to determine whether the number of pending positions for the second starting opening winning is smaller than "4". In this process, the main CPU 101 determines whether or not the hold number based on the winning of the second start port 414b (see FIG. 4) is smaller than "4". If the hold number is smaller than "4", the step The process proceeds to S43, and when the number of held items is "4" or more, this subroutine is ended.

  In step S43, processing is performed to add "1" to the number of pending positions for the second starting opening winning. In this process, the main CPU 101 performs a process of adding “1” to the value of the number of holdings based on the winning of the second start port 414 b (see FIG. 4) stored in the main RAM 103. If this process ends, the process moves to step S44.

  In step S44, random number acquisition / storage processing is performed. In this process, the main CPU 101 extracts a big hit determination random number value for the special symbol game from the big hit determination random number counter (so-called special symbol lottery), extracts a big hit symbol random number value from the big hit symbol random number counter, and further reads ahead The random number value for advance notice determination is extracted from the notice determination random number counter. Then, main CPU 101 stores the extracted random number value for big hit determination, big hit symbol random number value and random number value for advance notice determination, in the main RAM 103, the random number value based on the winning of the second starting opening 414b (see FIG. 4). Perform processing to store in the second special symbol start storage area. In the present embodiment, the second special symbol start storage area is the second special symbol start storage area (0) to the second special symbol start storage area (4), and the second special symbol start storage area (0) Judgment results based on the random numbers for collision judgment stored in) are derived and displayed by a special symbol, and various random number values acquired by winning in the second starting opening 414b (see FIG. 4) during the fluctuation of the special symbol are The second special symbol start storage area (1) to the second special symbol start storage area (4) are sequentially stored. If this process ends, the process moves to step S45.

  In step S45, special symbol determination processing is performed. In this process, the main CPU 101 refers to the big hit random number determination table (see FIG. 73) and the big hit symbol random number determination table (see FIG. 74) based on the big hit determination random number value and the big hit symbol random number value extracted in step S44. The special symbol to be stopped and displayed on the special symbol display device 431 is determined, and data indicating the special symbol is stored in a predetermined area of the main RAM 103.

  Specifically, the main CPU 101 refers to the big hit random number determination table (second starting port) shown in FIG. 73 (b) and the big hit symbol random number determination table (second starting port) shown in FIG. 74 (b), step S44. The symbol designation command associated with the special symbol to be stopped and displayed on the special symbol display device 431 is determined based on the jackpot determination random number value extracted in the above. Specifically, when the extracted big hit determination random number value is associated with the big hit determination value data in the big hit random number determination table (second starting port), the main CPU 101 extracts the big hit extracted in step S44. Based on the symbol random number value, the jackpot symbol random number determination table (second starting opening) is referred to, and either of the symbol designation command "z0" or "z4" is selected. Further, the main CPU 101 selects the symbol designation command "z5" when the extracted big hit determination random number value is associated with the loss determination value data in the big hit random number determination table (second starting port). . If this process ends, the process moves to step S46.

  In step S46, a jackpot determination process is performed. In this process, the main CPU 101 refers to the big hit random number determination table (second starting port) shown in FIG. 73 (b), and the big hit determination random number value extracted in step S44 is associated with the big hit determination value data. Determine if it is. If this process ends, the process moves to step S47.

  In step S47, fluctuation pattern determination processing is performed. In this process, the main CPU 101 extracts a variation pattern random number value, and determines a special symbol variation pattern based on the variation pattern random number value, the special symbol determined in step S45, and the result of the jackpot determination process in step S46. The variation pattern is determined with reference to a variation pattern determination table (see FIG. 75) to be stored, and stored in a predetermined area of the main RAM 103. The main CPU 101 determines the variation display mode of the special symbol in the special symbol display device 431 based on the data indicating such variation pattern.

  Further, the main CPU 101 supplies data indicating the determined fluctuation pattern to the special symbol display device 431. The special symbol display device 431 variably displays the special symbol in the variation time defined in the variation pattern determination table (see FIG. 75) based on the data indicating the variation pattern, and in the mode associated with the symbol designation command Stop display. Further, data indicating a fluctuation pattern is supplied from the main CPU 101 of the main control circuit 100 to the sub CPU 201 of the sub control circuit 200 as a fluctuation pattern designation command based on the second start opening winning. The sub CPU 201 of the sub control circuit 200 executes the effect display according to the received fluctuation pattern designation command. If this process ends, the process moves to step S48.

  In step S48, pre-reading advance notice determination processing is performed. In this process, as in step S38, the main CPU 101 compares the random number value for preview advance notice determination with the determination value of the prefetch advance notice determination table for determining whether or not to execute prefetch advance notice. Decide whether to run or not. When the main CPU 101 determines that the prefetch notice is to be executed, the main CPU 101 transmits, to the sub CPU 201 of the sub control circuit 200, a prefetch notice determination command including information indicating that the prefetch notice is to be executed. The sub CPU 201 of the sub control circuit 200 executes an effect of changing the display mode of the holding symbol corresponding to the received preview notice determination command as the preview notice. If this process ends, the process moves to step S49.

  In step S49, a command setting process is executed to increase the number of held second starting hole wins. In this process, the main CPU 101 uses a main command to increase the number of pending holdings for driving the second special symbol holding display device 433b (see FIG. 4) according to the process of adding "1" to the value of the pending numbers in step S43. A process of storing in the RAM 103 is performed. The main CPU 101 supplies this holdup number increase command to the second special symbol hold display device 433b. The second special symbol hold display device 433b lights the display lamp based on the supplied hold number increase command. When this process ends, the present subroutine ends.

  As described above, the main CPU 101 determines the special symbol and the variation pattern for each winning on the first starting opening 414a or the second starting opening 414b (see FIG. 4). In addition, when the number of held pieces is "0" and the special symbol is not variably displayed, the main CPU 101 displays the first special symbol put on hold as a one-time hold even when winning in the first starting opening 414a or the second starting opening 414b. The device 433a or the second special symbol hold display device 433b is turned on and immediately thereafter turned off to start variable display of the special symbol. The main CPU 101 does not turn on the first special symbol hold display device 433a or the second special symbol hold display device 433b once as a hold, and then determines that the hold number is not "0" as an internal process. The symbols may be displayed variably.

[Main control main processing]
Next, with reference to FIGS. 55, 56, 57, 58, 59, 60 and 61, the main control main processing executed by the main CPU 101 will be described. As shown in FIG. 55, initialization is performed in step S50. In this process, the main CPU 101 reads an activation program from the main ROM 102 in response to the power-on, and initializes a flag or the like stored in the main RAM 103 or restores the state before the power-off. If this process ends, the process moves to step S51.

  In step S51, an initial value random number update process is performed. In this process, the main CPU 101 performs a process of updating the initial value random number counter. If this process ends, the process moves to step S52.

  In step S52, special symbol control processing is performed. As will be described later in detail, in this process, the main CPU 101 determines the big hit random number determination table (first starting port) shown in FIG. 73 (a) or FIG. 73 based on the big hit determination random number value extracted in step S34 or step S43. Referring to the big hit random number determination table (second starting port) shown in (b), it is determined whether or not a special symbol lottery (big hit or small hit) is won, and processing of storing the result of the determination in the main RAM 103 is performed . If this process ends, the process moves to step S53. The main CPU 101 executing the process of step S52 performs the second determination whether to displace the second displacement member to the third position on condition that the game medium has passed through the second passage area. Act as a means.

  In step S53, normal symbol control processing is performed. Although this will be described in detail later, in this process, the main CPU 101 extracts a random number value according to the detection signal from the ball passage detection sensor 115, and refers to the normal symbol winning table stored in the main ROM 102. It is determined whether or not the player has won, and a process of storing the result of the determination in the main RAM 103 is performed. When the normal symbol lottery is won, the flat plate member 415a of the ordinary electric character 415 is drawn in, and the game ball easily enters the second starting opening 414b (see FIG. 4). If this process ends, the process moves to step S54. The main CPU 101 executing the process of step S53 performs the first determination whether or not to displace the first displacement member to the first position on condition that the game medium passes through the first passage area. Act as a means.

  In step S54, symbol display device control processing is performed. In this process, the main CPU 101 controls the special symbol display device 431 and the ordinary symbol display device 434 according to the result of the special symbol control process stored in the main RAM 103 in step S52 and step S53 and the result of the ordinary symbol control process. And the control signal for driving the main RAM 103 are stored. The main CPU 101 transmits this control signal to the special symbol display device 431 or the normal symbol display device 434. The special symbol display device 431 variably displays and stops the special symbol based on the received control signal. The normal symbol display device 434 variably displays and stops the normal symbol based on the received control signal. If this process ends, the process moves to step S55.

  In step S55, a game information data generation process is performed. In this process, the main CPU 101 generates game information data to be transmitted to the sub control circuit 200, the payout / fire control circuit 300, the hall computer, etc., and stores the game information data in the main RAM 103. If this process ends, the process moves to step S56.

  In step S56, storage and gaming state data generation processing is performed. In this processing, the main CPU 101 generates storage / gaming state data to be transmitted to the sub control circuit 200 according to the big hit flag, the probability change flag, and the time saving flag, and performs processing for storing the data in the main RAM 103. If this process ends, the process moves to step S51. The sub CPU 201 of the sub control circuit 200 recognizes the current gaming state (for example, the big hit gaming state, the probability changing state, the time saving state) by receiving the storage and gaming state data.

[Special symbol control process]
A subroutine (special symbol control process) executed in step S52 of FIG. 55 will be described with reference to FIG. In FIG. 56, numerical values drawn laterally from step S60 to step S69 indicate control state flags corresponding to those steps, and are stored in a storage area functioning as a control state flag in the main RAM 103. The main CPU 101 executes one step corresponding to the numerical value of the control state flag stored in the main RAM 103 to advance the special symbol game.

  In step S60, a process of loading a control state flag is performed. In this process, the main CPU 101 reads the control state flag stored in the main RAM 103. If this process ends, the process moves to step S61.

  Note that, in steps S61 to S69 described later, the main CPU 101 determines whether or not to execute various processing in each step based on the value of the control state flag, as described later. The control state flag indicates the game state of the special symbol game, and enables one of the processes in steps S61 to S69 to be performed. In addition to that, the main CPU 101 executes the processing in each step at a predetermined timing determined according to the waiting time timer or the like set for each step. Note that before this predetermined timing is reached, the process ends without executing the process in each step, and another subroutine is executed.

  In step S61, a special symbol storage check process is performed. Although the details of this process will be described later, in this process, when the control status flag is a value (00) indicating a special symbol storage check, the main CPU 101 checks the number of reserved special symbols, and the like. If this process ends, the process moves to step S62.

  In step S62, special symbol variation time management processing is performed. In this process, the main CPU 101 determines that the control status flag is the value (01) indicating the special symbol variation time management, and the value (02) indicating the special symbol display time management is the control status flag when the variation time has elapsed. Set and set waiting time (for example, 1 second) in the waiting time timer. That is, after the waiting time after confirmation has elapsed, the process of step S63 is set to be executed. When this process ends, the process moves to step S63.

  In step S63, a special symbol display time management process is performed. The details of this process will be described later, but in this process, the main CPU 101 determines that the control status flag is the special symbol display time management value (02), and when the wait time after confirmation has passed, the hit (big hit or It is determined whether or not the small hit). When it is a hit, the main CPU 101 sets a value (03) indicating big hit start interval management in the control state flag, and sets a time corresponding to the big hit start interval in the waiting time timer. That is, after the time corresponding to the big hit start interval has elapsed, the process of step S64 is set to be executed. On the other hand, when the hit is not a hit, the main CPU 101 sets a value (08) indicating the end of the special symbol game. That is, setting is made to execute the process of step S69. If this process ends, the process moves to step S64 or step S69.

  In step S64, a big hit start interval management process is performed. In this process, the main CPU 101 determines that the control status flag indicates the big hit start interval management (03) and indicates that the big winning opening is open when the time corresponding to the big hit start interval has passed (04). Is set in the control status flag. That is, setting is made to execute the process of step S65. Further, the main CPU 101 performs processing for setting a round number command and a round start command in the main RAM 103. Here, the round count command and the round start command set in the process of this step are supplied from the main CPU 101 of the main control circuit 100 to the sub CPU 201 of the sub control circuit 200 so that the sub control circuit 200 performs the round count and Recognize the start of the round. If this process ends, the process moves to step S65.

  In step S65, the special winning opening open process is performed. In this process, the main CPU 101 sets the opening upper limit time (for example, about 30 seconds) of the special winning opening 418 (see FIG. 4) to the special winning opening opening time timer, and the special winning opening 418 read from the main ROM 102. Data for releasing the key is stored in the main RAM 103. Then, the main CPU 101 reads the data for opening the big winning opening 418 (see FIG. 4) stored in the main RAM 103 in the process of step S14 of FIG. 52, and the solenoid power supply for opening the big winning opening 418. Is supplied to the special winning opening solenoid 112 (see FIG. 51) that drives the shutter member 422a of the shutter device 422. Then, after the open upper limit time has elapsed, the main CPU 101 sets a value (05) indicating the special winning opening residual ball monitoring in the control state flag. That is, setting is made to execute the process of step S66. Further, the main CPU 101 performs processing for setting a round end command in the main RAM 103. Here, the round end command set in the process of this step is supplied from the main CPU 101 of the main control circuit 100 to the sub CPU 201 of the sub control circuit 200, whereby the sub control circuit 200 recognizes the end of the round. If this process ends, the process moves to step S66. The main CPU 101 that executes the process of step S65 functions as a second displacement member control unit that displaces the second displacement member to the third position a predetermined number of times based on the second determination unit making a positive determination. Do.

  In step S66, a special winning opening residual ball monitoring process is performed. In this process, the main CPU 101 determines that the control status flag is a value (05) indicating residual ball monitoring in the large winning opening, and the large winning opening winning counter is "7 or more" when the residual ball monitoring time in the special winning opening has elapsed. It is determined whether any of the condition that the special winning opening open frequency counter is a predetermined number or more (the final round) is satisfied. When one of the conditions is satisfied, the main CPU 101 sets a value (07) indicating a big hit game end interval in the control state flag. On the other hand, when the main CPU 101 does not satisfy any of the conditions, the main CPU 101 sets a value (06) indicating the waiting time management before the special winning opening reopening to the control state flag. If this process ends, the process moves to step S67 or step S68.

  In step S67, a waiting time management process before the special winning opening reopening is performed. In this process, the main CPU 101 sets the large winning opening opening number counter when the control status flag is a value (06) indicating the waiting time management before big winning opening reopening and the time corresponding to the interval between rounds has passed. Update memory to increase "1". The main CPU 101 sets a value (04) indicating that the special winning opening is open in the control state flag. That is, setting is made to execute the process of step S65. If this process ends, the process moves to step S65.

  In step S68, a big hit end interval process is performed. Although the details of this process will be described later, in this process, the main CPU 101 determines that the control status flag is a value (07) indicating the big hit end interval, and the special symbol game is executed when the time corresponding to the big hit end interval has elapsed. A value (08) indicating end is set in the control state flag. That is, setting is made to execute the process of step S69. If this process ends, the process moves to step S69.

  In step S69, special symbol game end processing is performed. In this process, the main CPU 101 sets a value (00) indicating a special symbol storage check, when the control status flag is a value (08) indicating the end of the special symbol game. That is, setting is made to execute the process of step S61. When this process ends, the present subroutine ends.

  Thus, the main CPU 101 executes the special symbol game by setting the control state flag. Specifically, when the main CPU 101 is not in the big hit or small hit gaming state, and the result of the hit determination is a loss, the control status flags are (00), (01), (02), (08) and so on. By setting in order, the processing of step S61, step S62, step S63 and step S69 shown in FIG. 56 is executed at a predetermined timing. Further, when the main CPU 101 is not in the big hit or small hit gaming state, and the result of the hit determination is the big hit or small hit, the control status flag is (00), (01), (02), (03) and so on. By setting in order, the processing of step S61, step S62, step S63 and step S64 shown in FIG. 56 is executed at a predetermined timing, and control to a big hit or small hit gaming state is executed. Furthermore, when control to the big hit or small hit gaming state is executed, the main CPU 101 sets the control state flag in order of (04), (05), (06) as shown in FIG. 56. The processes of step S65, step S66 and step S67 are executed at a predetermined timing to execute a big hit or small hit game. In addition, when the termination condition of the big hit or the small hit game is satisfied, the processing of steps S68 and S69 shown in FIG. 56 is executed at a predetermined timing by setting (07) and (08) in order. End the big hit or small hit game.

[Special symbol memory check process]
A subroutine (special symbol storage check process) executed in step S61 of FIG. 56 will be described with reference to FIG. In step S70, it is determined whether the control state flag is a value (00) indicating a special symbol storage check. In this process, when the main CPU 101 determines that the control state flag is the value (00) indicating the special symbol storage check, the process proceeds to step S71. On the other hand, when the main CPU 101 determines that the control state flag is not the value (00) indicating the special symbol storage check, the main CPU 101 ends the present subroutine.

  In step S71, it is determined whether or not the number of held second starting hole wins is "0". In this process, the main CPU 101 determines the presence / absence of data of the second special symbol start storage area (0) to the second special symbol start storage area (4) of the main RAM 103. In main CPU 101, the start memory corresponding to the second special symbol is "0", that is, no data is stored in the second special symbol start storage area (0) to the second special symbol start storage area (4) If it is determined that, the process proceeds to step S77. On the other hand, in main CPU 101, the start memory corresponding to the second special symbol is not "0", that is, data is stored in the second special symbol start storage area (0) to the second special symbol start storage area (4) If it is determined that there is, the process proceeds to step S72.

  In step S72, a process of subtracting "1" from the second start storage number is performed. In this processing, the main CPU 101 performs processing to clear data of the second special symbol start storage area (0) of the main RAM 103. When this process ends, the process moves to step S73.

  In step S73, special symbol storage area transfer processing based on the second start opening winning is performed. In this process, the main CPU 101 causes the data of the second special symbol start storage area (1) to the second special symbol start storage area (4) of the main RAM 103 to be the second special symbol start storage area (0) to the second 2) Perform processing to shift (store) in the special symbol start storage area (3). If this process ends, the process moves to step S74.

  In step S74, processing is performed to set the value (01) indicating the special symbol fluctuation time management to the control state flag. In this process, the main CPU 101 performs a process of setting a value (01) indicating a special symbol fluctuation time management in the control state flag. If this process ends, the process moves to step S75. Further, the main CPU 101 generates a derived symbol designating command for determining a derived symbol (identifying symbol for effect) corresponding to the special symbol to be displayed on the special symbol display device 431 by the sub CPU 201 described later, and the main RAM 103 It stores in the predetermined area of Main CPU 101 outputs the derived symbol designation command to sub control circuit 200 in step S14 shown in FIG. The sub CPU 201 of the sub control circuit 200 starts variable display of derived symbols based on the received derived symbol designation command.

  In step S75, a waiting time set process is performed. In this process, the main CPU 101 performs a process of setting the variation time corresponding to the variation pattern of the special symbol determined in step S37 or step S46 shown in FIG. 54 in the waiting time timer. When this process ends, the process moves to step S76.

  In step S76, processing is performed to clear the storage area used for the current variation. In this process, the main CPU 101 performs a process of clearing the storage area of the main RAM 103 used for the variable display of this time. When this process ends, the present subroutine ends.

  In step S77, a process is performed to determine whether the number of held first starting hole wins is "0". In this process, the main CPU 101 determines the presence / absence of data of the first special symbol start storage area (0) to the first special symbol start storage area (4) of the main RAM 103. The main CPU 101 determines that the start memory corresponding to the first special symbol is 0, that is, no data is stored in the first special symbol start storage area (0) to the second special symbol start storage area (4). If yes, the process moves to step S80. On the other hand, in main CPU 101, the start memory corresponding to the first special symbol is not 0, that is, data is stored in first special symbol start storage area (0) to first special symbol start storage area (4). If it is determined, the process proceeds to step S78. The main CPU 101 performs the process of step S77 after the process of step S71. That is, the main CPU 101 preferentially digests the second starting opening winning.

  In step S78, a process of subtracting "1" from the first start storage number is performed. In this process, the main CPU 101 performs a process of clearing data of the first special symbol start storage area (0) of the main RAM 103. If this process ends, the process moves to step S79.

  In step S79, special symbol storage area transfer processing based on the first start-up winning is performed. In this process, the main CPU 101 executes data of the first special symbol start storage area (1) to the first special symbol start storage area (4) of the main RAM 103, the first special symbol start storage area (0) to the first 1) Perform processing to shift (store) in the special symbol start storage area (3). If this process ends, the process moves to step S74.

  In step S80, a demonstration display process is performed. In this process, the main CPU 101 performs a process of setting a demonstration display permission value in the main RAM 103. In addition, main CPU 101, the start memory of the special symbol game (the first special symbol start storage area or the second special symbol start storage area where the random number value for hitting determination is stored) becomes 0 for a predetermined time (for example, If it is maintained for 30 seconds, set a value to allow execution of the demo display as the demo display permission value. Then, when the demonstration display permission value is a predetermined value, the main CPU 101 sets a demonstration display command and supplies it to the sub control circuit 200. The sub control circuit 200 performs a demonstration display on the liquid crystal display device 50 based on the demonstration display command. When this process ends, the present subroutine ends.

[Special symbol display time management process]
A subroutine (special symbol display time management process) executed in step S63 of FIG. 56 will be described with reference to FIGS. 58 and 59. As shown in FIG. 58, in step S90, processing is performed to determine whether the control state flag is a value (02) indicating special symbol display time management. In this process, the main CPU 101 performs a process of determining whether the control state flag is a value (02) indicating a special symbol display time management process. If the main CPU 101 determines that the control status flag is the value (02) indicating the special symbol display time management processing, the process proceeds to step S91, and the control status flag is the value indicating the special symbol display time management processing ( If it is determined that the condition is not 02), the present subroutine ends.

  In step S91, it is determined whether the waiting time is "0". In this process, the main CPU 101 determines whether the value of the waiting time timer corresponding to the special symbol display management process is “0”. If the main CPU 101 determines that the value of the waiting time timer is “0”, the process proceeds to step S92, and if it is determined that the value of the waiting time timer is not “0”, the present subroutine ends.

  In step S92, it is determined whether or not a big hit has occurred. In this process, the main CPU 101 determines the probability variation flag stored in the main RAM 103 and the big hit random number determination table (first start port) shown in FIG. 73 (a) or the big hit random number determination table shown in FIG. 73 (b) The jackpot determination random number value stored in the first special symbol start storage area (0) or the second special symbol start storage area (0) of the main RAM 103 is correlated with the jackpot determination value data with reference to the start opening). It is determined whether or not it is the value (big hit or not). If the main CPU 101 determines that it is a big hit, it shifts the process to step S98 shown in FIG. 59, and if it determines that it is not a big hit, it shifts the process to step S93. Note that, in this process, the main CPU 101 also performs a process of determining whether a small hit or not. Specifically, the main CPU 101 refers to the probability variation flag stored in the main RAM 103 and the big hit random number determination table (first start port) shown in FIG. 73 (a), and the first special symbol start storage area of the main RAM 103 ( 0) It is determined whether the jackpot determination random number value stored in (0) is a value associated with the small hit determination value data (small hit). If the main CPU 101 determines that it is a small hit, it opens the big winning opening 418 for a certain period of time, and if it determines that it is not a small hit, it transfers the process to step S93. The main CPU 101 determines that it is a small hit, and when the large winning opening 418 is opened for a certain period and then closed (when the large winning opening opening time as a small hit has elapsed), the small hitting gaming state is over. The game state is controlled so as not to be a more advantageous game state than the game state at the time of the small hit winning. Note that the large winning opening opening time as a small hit is a total opening time which is the sum of the opening times when the opening and closing of the large winning opening 418 is repeated intermittently.

  In step S93, the control state flag is set to a value (08) indicating the end of the special symbol game. In this process, the main CPU 101 performs a process of setting a value (08) indicating the end of the special symbol game in the control state flag. If this process ends, the process moves to step S94.

  In step S94, processing is performed to determine whether the time saving state change number counter is "0". In this process, the main CPU 101 determines whether or not the value of the time short state fluctuation number counter in the main RAM 103 is “0”. Here, the time saving state change frequency counter indicates the number of times the special symbol is changed and stopped in the time saving state. If the main CPU 101 determines that the value of the time saving state change counter is "0", the present subroutine is ended, and if it is determined that the value of the time saving state change counter is not "0", the step is performed. Transfer the process to S95.

  In step S95, a process of subtracting "1" from the time saving state change number counter is performed. In this process, the main CPU 101 performs a process of subtracting “1” from the time short state fluctuation number counter of the main RAM 103. When this process ends, the process moves to step S96.

  In step S96, processing is performed to determine whether the time saving state change number counter is "0". In this process, the main CPU 101 determines whether or not the value of the time short state fluctuation number counter in the main RAM 103 is “0”. If the main CPU 101 determines that the value of the time saving state change number counter is “0”, the process proceeds to step S97, and if the value of the time saving state change number counter is not “0”, the main CPU 101 This subroutine ends.

  In step S97, the time saving flag is set to "0". In this processing, the main CPU 101 performs processing to set “0” to the time saving flag stored in the main RAM 103. Here, the time saving flag is a flag that is stored in the main RAM 103 and represents whether or not the time saving state is selected as the gaming state after the big hit end, and when the value is "0", the time saving state is not It indicates (non-time-shortened state), and when the value is “1”, it indicates that the time-shortened state is present. In the process of step S56 shown in FIG. 55, the main CPU 101 generates gaming state data to be transmitted to the sub control circuit 200 in accordance with the value of the time saving flag. When this process ends, the present subroutine ends.

  As shown in FIG. 59, in step S98, a big hit mode determination process is performed. In this process, the main CPU 101 determines the big hit mode based on the symbol designation command determined in step S35 or step S44 shown in FIG. Specifically, the main CPU 101 determines the big hit mode in which the number of rounds is "10" when the symbol designation command is "z0", "z1", "z2" and "z3", and the symbol designation command is "" In the case of z4 ", the big hit aspect whose number of rounds is" 16 "is determined. Further, when the symbol designation command is “z11”, the main CPU 101 determines the small hit mode. If this process ends, the process moves to step S99.

  In step S99, a big hit flag setting process is performed. In this process, when the main CPU 101 determines that a big hit is made in the process of step S 92 shown in FIG. 58, the big CPU 1 sets a big hit flag in the main RAM 103. If this process ends, the process moves to step S100.

  In step S100, a special winning opening open frequency counter clear process, a short time status change frequency counter clear process, a short time flag clear process, and a probability change flag clear process are performed. In this process, the main CPU 101 clears the special winning opening open frequency counter and the time saving state fluctuation frequency counter stored in the main RAM 103. Further, the main CPU 101 stores the value of the time saving flag in the main RAM 103 as the winning time flag, and then sets the time saving flag to “0”. Further, the main CPU 101 stores the value of the probability variation flag in the main RAM 103 as the probability variation flag at the time of winning, and then sets the probability variation flag to “0”. When this process ends, the process moves to step S101.

  In step S101, processing is performed to set a value (03) indicating big hit start interval management in the control state flag. In this process, the main CPU 101 performs a process of setting a value (03) indicating big hit start interval management in the control state flag. When this process ends, the process moves to step S102.

  In step S102, processing is performed to set a waiting time (5000 ms) as the big hit start interval time. In this process, when the main CPU 101 determines that a big hit is made in the process of step S92 shown in FIG. 58, the main CPU 101 performs a process of setting the value (5000 ms) of the waiting time timer as the big hit start interval time in the main RAM 103. . When this process ends, the process moves to step S103.

  In step S103, a big hit start command setting process is performed. In this process, when the main CPU 101 determines that the game is a big hit in the process of step S 92 shown in FIG. 58, the main CPU 101 performs a process of setting a big hit start command in the main RAM 103. When this process ends, the process moves to step S104. Here, the big hit start command set in the process of this step and the small hit start command set in the process of step S99 are determined from the main CPU 101 of the main control circuit 100 by the sub control circuit 200. By being supplied to the sub CPU 201, the sub control circuit 200 recognizes the big hit or the small hit start.

  In step S104, a special winning opening open frequency data setting process is performed. In this process, the main CPU 101 sets the big winning opening open frequency data according to the big hit mode or the small hit mode determined in the big hit mode determination process of step S98. Specifically, when the main CPU 101 determines the big hit mode in which the number of rounds is “10” in the big hit mode determination process, “10” is set as the upper limit value in the large winning opening opening number counter of the main RAM 103 Do. When the main CPU 101 determines the big hit mode in which the number of rounds is “16” in the big hit mode determination process, the main CPU 101 sets “16” as the upper limit value in the big winning opening open frequency counter of the main RAM 103. When the main CPU 101 determines the small hit mode in the big hit mode determination process, the main CPU 101 sets “1” as the upper limit value to the large winning opening open frequency counter of the main RAM 103. The count value of the opening number counter is synonymous with the number of rounds. When this process ends, the process moves to step S105.

  In step S105, a round number display LED pattern flag setting process is performed. In this process, the main CPU 101 sets a round number display LED pattern flag for performing display control of the round number display device 432 in the main RAM 103. When this process ends, the present subroutine ends.

[Big hit end interval processing]
A subroutine (big hit end interval process) executed in step S68 of FIG. 56 will be described with reference to FIG. In step S110, it is determined whether the control state flag is a value (07) indicating a big hit end interval. In this process, the main CPU 101 performs a process of determining whether the control state flag of the main RAM 103 is a value (07) indicating the big hit end interval process. If the main CPU 101 determines that the control state flag is the value (07) indicating the big hit end interval process, the process proceeds to step S111, and the control state flag is not the value (07) indicating the big hit end interval process If it is determined, the present subroutine ends.

  In step S111, it is determined whether the waiting time is "0". In this process, the main CPU 101 determines whether the value of the waiting time timer corresponding to the big hit end interval process is “0”. If the main CPU 101 determines that the value of the waiting time timer is "0", the process proceeds to step S112. If the value of the waiting time timer is not determined to be "0", the present subroutine ends. Do.

  In step S112, a special winning opening open number display LED pattern flag clear process is performed. In this process, the main CPU 101 performs a process of clearing the special winning opening open count display LED pattern flag stored in the main RAM 103. When this process ends, the process moves to step S113.

  In step S113, round number distribution flag clear processing is performed. In this process, the main CPU 101 performs a process of clearing the round number distribution flag stored in the main RAM 103. If this process ends, the process moves to step S114.

  In step S114, the control state flag is set to a value (08) indicating the end of the special symbol game. In this process, the main CPU 101 performs a process of setting a value (08) indicating the end of the special symbol game in the control state flag. If this process ends, the process moves to step S115.

  In step S115, a big hit flag clear process is performed. In this process, the main CPU 101 performs a process of clearing the big hit flag stored in the main RAM 103 when the big hit flag is set in the process of step S99 shown in FIG. When this process ends, the process moves to step S116.

  In step S116, a process of setting a positive change flag is performed. In this process, main CPU 101 determines the symbol designating command determined in step S35 or step S44 shown in FIG. 54 and the winning time flag and the winning time change flag stored in main RAM 103 in step S100 shown in FIG. With reference to the jackpot type determination table shown in FIG. 76, processing of setting the positive change flag in the main RAM 103 is performed. If this process ends, the process moves to step S117.

[Big hit type decision table]
Here, the big hit type determination table will be described with reference to FIG. The big hit type determination table is stored in the main ROM 102, and the winning type is a big hit symbol designation command (“z0”, “z1”, “z2”, “z3”, “z4”) in a plurality of variation patterns. The short time flag, the short number of times, the definite variation flag, the number of definite variations and the number of rounds are associated.

  The symbol designation command in the jackpot type determination table is a value corresponding to the symbol designation command in the jackpot symbol random number determination table (see FIG. 74). In addition, the number of time savings in the big hit type determination table indicates the upper limit value of the number of times of variation of the special symbol in the time short status started after the end of the big hit gaming state. In the present embodiment, the time saving state is ended when the jackpot is won or when there is a fluctuation of the special symbol corresponding to the number of times shown in the big hit type determination table. That is, it shifts from the time saving state to the non-time saving state. Further, the number of definite variations in the big hit type determination table indicates the upper limit value of the number of variations of the special symbol in the probable variation state which is started after the end of the large hit gaming state. In the present embodiment, the definite change state is ended when the jackpot is won or when there is fluctuation of the special symbol for the number of definite changes shown in the big hit type determination table. That is, the transition from the positive change state to the non positive change state is made.

  Further, in the big hit type determination table, four tables corresponding to the values of the winning time short flag and the winning time probability change flag are stored in the main ROM 102. Specifically, in the jackpot type determination table shown in FIG. 76A, when the value of the winning time short flag is “0” and the value of the winning time probability change flag is “0”, that is, the non-short time state and The main CPU 101 is referred to when a big hit occurs in a non-deterministic change state. Also, in the big hit type determination table shown in FIG. 76 (b), when the value of the winning time short flag is "1" and the value of the winning time probability change flag is "0", that is, the time saving state and the non-probability changing state When a big hit sometimes occurs, the main CPU 101 is referred to. Further, in the big hit type determination table shown in FIG. 76C, when the value of the winning time short flag is “0” and the value of the winning time probability change flag is “1”, that is, the non-short time state and the odd state When a big hit sometimes occurs, the main CPU 101 is referred to. Further, in the big hit type determination table shown in FIG. 76 (d), when the value of the winning time short flag is "1" and the value of the winning time probability change flag is "1", that is, in the time saving state and the probability changing state. When a big hit is made, the main CPU 101 is referred to.

  Further, the big hit types in the present embodiment include one big hit, one big hit, two big hits, three big hits, four big hits, and five big hits. The jackpot 1 is a jackpot in which the gaming state after the jackpot gaming state ends becomes a non-short time state and a non-probability state. The jackpot 2 is a jackpot in which the gaming state after the jackpot gaming state ends becomes a non-time-shortened state and a definite change state (a so-called latency change). The jackpot 3 is a jackpot in which the gaming state after the jackpot gaming state ends becomes a time saving state and a probability changing state less than 200 times. The big hit 4 is a big hit in which the gaming state after the big hit gaming state ends becomes a short time state and a definite change state of 200 times in a short time. The jackpot 5 is a jackpot in which the gaming state after the jackpot gaming state ends becomes a time-saving state and a false non-changing state.

  In the jackpot type determination table shown in FIG. 76 (a), which is referred to when a jackpot occurs in the non-short time state and the non-probability state, a jackpot 1 is associated with the symbol designation command "z0", and the jackpot "z1" is hit 2 is mapped, "z2" and "z3" are mapped to the big hit 3, and "z4" is mapped to the big hit 4. In the jackpot type determination table shown in FIG. 76 (b), which is referred to when a jackpot occurs in the time saving state and the non-determination state, a jackpot 1 is associated with the symbol designation command "z0" and "z1" A big hit 2 is associated, a big hit 3 is assigned to "z2" and "z3", and a big hit 4 is assigned to "z4". In the jackpot type determination table shown in FIG. 76 (c) which is referred to when a jackpot occurs in the non-short time state and the definite change state, a jackpot 1 is associated with the symbol designation command "z0", "z1"- A big hit 3 is associated with "z3" and a big hit 4 is associated with "z4". Also, in the jackpot type determination table shown in FIG. 76 (d) which is referred to when a jackpot occurs in the time saving state and the definite change state, the jackpot designation 5 is associated with the symbol designation command "z0", and the jackpot "z1" is hit 3 is mapped, and the big hit 4 is mapped to "z2" to "z4".

  Referring back to FIG. 60, specifically, in step S116, the main CPU 101 performs a big hit according to the winning time flag and the winning time change flag in the big hit type determination table shown in FIGS. 76 (a) to 76 (d). With reference to the type determination table, the value of the probability change flag associated with the symbol designation command is read out and stored in the main RAM 103. Further, the main CPU 101 refers to the big hit type determination table corresponding to the winning time short flag and the winning time probability change flag among the big hit type determination tables shown in FIGS. 76 (a) to (d), and associates with the symbol designation command. A big hit type command indicating the big hit types (1 big hit, 2 big hits, 3 big hits, 4 big hits or 5 big hits) is generated and stored in the main RAM 103.

  In step S117, a time saving flag setting process is performed. In this process, main CPU 101 determines the symbol designating command determined in step S35 or step S44 shown in FIG. 54 and the winning time flag and the winning time change flag stored in main RAM 103 in step S100 shown in FIG. With reference to the jackpot type determination table shown in FIG. 76, processing for setting the time saving flag in the main RAM 103 is performed. If this process ends, the process moves to step S118. Specifically, the main CPU 101 refers to the big hit type determination table corresponding to the winning time flag and the winning time probability change flag among the big hit type determination tables shown in FIGS. 76 (a) to 76 (d), and designates the symbol designation command. The processing of reading out the value of the time saving flag associated with V.sub.1 is stored in the main RAM 103.

  In step S118, processing is performed to determine whether the probability change flag is "1". In this processing, the main CPU 101 performs processing to determine whether the value of the probability change flag in the main RAM 103 is “1”. If the main CPU 101 determines that the value of the probable change flag is "1", the process proceeds to step S119, and if the value of the probable change flag is determined not to be "1", the process proceeds to step S120. .

  In step S119, a process is performed to set the number of probability variations in the probability variation state variation number counter. In this process, main CPU 101 determines the symbol designating command determined in step S35 or step S44 shown in FIG. 54 and the winning time flag and the winning time change flag stored in main RAM 103 in step S100 shown in FIG. With reference to the jackpot type determination table shown in FIG. 76, processing is performed to set the number of probability variations in the probability variation state variation number counter of the main RAM 103. When this process ends, the process moves to step S120. Specifically, the main CPU 101 refers to the big hit type determination table corresponding to the winning time flag and the winning time probability change flag among the big hit type determination tables shown in FIGS. 76 (a) to 76 (d), and designates the symbol designation command. A process of reading out the value of the number of times of probability variation associated with and storing in the main RAM 103 is performed.

  In step S120, it is determined whether the time saving flag is "1". In this processing, the main CPU 101 performs processing to determine whether the value of the time saving flag in the main RAM 103 is “1”. If the main CPU 101 determines that the value of the time saving flag is “1”, the process proceeds to step S121. If the value of the time saving flag is not “1”, the main CPU 101 ends the present subroutine.

  In step S121, processing is performed to set the number of time saving times in the time saving state fluctuation number counter. In this process, main CPU 101 determines the symbol designating command determined in step S35 or step S44 shown in FIG. 54 and the winning time flag and the winning time change flag stored in main RAM 103 in step S100 shown in FIG. With reference to the jackpot type determination table shown in FIG. 76, processing is performed to set the number of time reductions in the time reduction state change number counter of the main RAM 103. When this process ends, the present subroutine ends. Specifically, the main CPU 101 refers to the big hit type determination table corresponding to the winning time flag and the winning time probability change flag among the big hit type determination tables shown in FIGS. 76 (a) to 76 (d), and designates the symbol designation command. A process of reading out the value of the number of times of time reduction associated with is stored in the main RAM 103.

[Normal symbol control process]
A subroutine (normal symbol control processing) executed in step S53 of FIG. 55 will be described with reference to FIG. In FIG. 61, numerical values drawn on the side of step S130 to step S135 indicate normal symbol control state flags corresponding to those steps, and are stored in a storage area functioning as a normal symbol control state flag in the main RAM 103 ing. The main CPU 101 executes one step corresponding to the numerical value of the normal symbol control state flag stored in the main RAM 103, and the normal symbol game proceeds.

  In step S130, processing for loading a normal symbol control state flag is performed. In this process, the main CPU 101 reads the normal symbol control state flag stored in the main RAM 103. When this process ends, the process moves to step S131.

  In addition, in steps S131 to S135 described later, the main CPU 101 determines whether or not to execute various processing in each step based on the value of the normal symbol control state flag, as described later. The normal symbol control state flag indicates the game state of the normal symbol game, and enables execution of any of the processes in steps S131 to S135. In addition to that, the main CPU 101 executes the processing in each step at a predetermined timing determined according to the waiting time timer or the like set for each step. Note that before this predetermined timing is reached, the process ends without executing the process in each step, and another subroutine is executed.

  In step S131, normal symbol storage check processing is performed. In this process, when the main CPU 101 determines that the normal symbol control state flag is the value (00) indicating the normal symbol storage check, the value of the normal symbol storage number counter (number of suspension) stored in the main RAM 103 is " It is determined whether it is 0 or not. When the value of the normal symbol storage number counter is “0”, the main CPU 101 sets a value (04) indicating the normal symbol game end processing in the normal symbol control state flag. On the other hand, when the value of the normal symbol holding memory number counter is not "0", the main CPU 101 sets the value (01) indicating the normal symbol variation time monitoring process to the normal symbol control state flag, and the predetermined symbol of the normal symbol is selected. The fluctuation time is set to the waiting time timer. If this process ends, the process moves to step S135 or step S132.

  In step S132, normal symbol fluctuation time monitoring processing is performed. In this process, the main CPU 101 determines that the normal symbol control state flag is a value (01) indicating normal symbol fluctuation time monitoring, and the value (02) indicating a normal symbol display time monitoring is normal symbol when the fluctuation time has elapsed. The control state flag is set, and the wait time after decision is set in the wait time timer. That is, after the waiting time after confirmation has elapsed, the process of step S133 is set to be performed. If this process ends, the process moves to step S133.

  In step S133, normal symbol display time monitoring processing is performed. In this process, the main CPU 101 extracts a random number value when the normal symbol control state flag is a value (02) indicating normal symbol display time monitoring, and the wait time after confirmation has elapsed, and is stored in the main ROM 102 It is determined whether or not the normal symbol lottery is won by referring to the normal symbol winning table. Here, in the time saving state and the non-time saving state (normal gaming state), different normal symbol winning tables are referred to. That is, in the time saving state, the probability of winning the normal symbol lottery is high (for example, 255/256) The normal symbol winning table is referred to, and in the non-time reducing state (normal gaming state), the probability of winning the normal symbol lottery is The low (for example, 0/256) normal symbol winning table is referred to. When the main CPU 101 wins the normal symbol lottery, the main CPU 101 sets the value (03) indicating the release of the ordinary electric character to the normal symbol control state flag, and when the normal symbol lottery is not won, the normal symbol game end processing Is set to a normal symbol control state flag. When this process ends, the process moves to step S134 or step S135.

  In step S134, a normal motorized product opening process is performed. In this process, when the normal symbol control state flag is the value (03) indicating the normal electric character opening, the main CPU 101 sets the ordinary electric character opening flag and takes a time to pull in the flat plate member 415a. Set the character release time to the waiting time timer. That is, after the ordinary character article release time has elapsed, the process of step S135 is set to be performed. The main CPU 101 normally solenoid combination solenoid 111 which brings the flat plate member 415a of the ordinary traction combination 415 of the second starting opening 414b (see FIG. 4) into a retracted state when the ordinary traction combination open flag is set. Supply solenoid power (see FIG. 51). Further, when the main CPU 101 pulls in the flat plate member 415a of the ordinary motor-operated part 415, there is a waiting time timer in which there is a predetermined number of winnings on the second starting port 414b or the common-compartment opening time is set. In the case of “0”, the solenoid power supply is supplied to the normal motor-operated product solenoid 111, and the flat plate member 415a of the normal motor-controlled product 415 is made to project.

  In step S135, normal symbol game end processing is performed. In this process, when the normal symbol control state flag is the value (04) indicating normal symbol game end processing, the main CPU 101 subtracts 1 from the value of the normal symbol hold storage number counter stored in the main RAM 103, A value (00) indicating normal symbol memory check processing is set in the normal symbol control state flag. When this process ends, the present subroutine ends.

  Next, processing executed by the sub CPU 201 of the sub control circuit 200 will be described. In response to power on, the sub CPU 201 reads a program from the program ROM 202 and executes a sub control circuit main process. In addition, even when the sub CPU 201 is executing the sub control circuit main processing, the sub CPU 201 may interrupt the sub control circuit main processing and execute the sub control circuit interrupt processing. The sub CPU 201 generates a clock pulse every predetermined period (for example, 2 milliseconds), and executes the sub control circuit interrupt processing accordingly.

[Sub control circuit interrupt processing]
The sub control circuit interrupt processing executed by the sub CPU 201 will be described with reference to FIG. In step S210, a random number update process is performed. In this process, the sub CPU 201 saves each register and performs a process of updating the random numbers stored in the work RAM 203. Specifically, the sub CPU 201 performs random number update processing so as to increase the count value of the counter for effect pattern determination stored in the work RAM 203 by "1". If this process ends, the process moves to step S211.

  In step S211, command reception processing is performed. In this process, the sub CPU 201 performs a process of receiving a command transmitted from the main control circuit 100 to the sub control circuit 200 and storing the command in the work RAM 203. In this process, the sub CPU 201 performs processing of receiving data transmitted from the main control circuit 100 to the sub control circuit 200 as well as the command and storing the data in the work RAM 203. If this process ends, the process moves to step S212.

  In step S212, a timer update process is performed. In this process, the sub CPU 201 performs a process of updating various timers stored in the work RAM 203. Specifically, processing for updating a timer used in rendering processing and the like is performed. If this process ends, the process moves to step S213.

  In step S213, command output processing is performed. In this process, the sub CPU 201 performs a process of outputting various commands to the display control circuit 210, the audio control circuit 220, the lamp control circuit 230, the first operation means control circuit 240a, and the second operation means control circuit 240b. In this process, in addition to various commands, the sub CPU 201 controls the display control circuit 210, the audio control circuit 220, the lamp control circuit 230, the first operation means control circuit 240a, the second operation means control circuit 240b, and the LED control. A process of outputting various data to the circuit 250 is performed. When this processing is completed, processing is performed to restore each register to the address before the interrupt processing, and this subroutine is completed.

[Sub control circuit main processing]
Next, with reference to FIGS. 63, 64, 65, 66, 67, 68, 69, 70, 71 and 72, the sub control circuit main processing executed by the sub CPU 201 will be described. As shown in FIG. 63, in step S220, initialization processing is performed. In this process, the sub CPU 201 reads an activation program from the program ROM 202 in response to power on, initializes a flag and the like stored in the work RAM 203, and performs a process of setting. If this process ends, the process proceeds to step S221.

  In step S221, random number update processing is performed. In this process, the sub CPU 201 performs a process of updating the initial value of the random number stored in the work RAM 203. If this process ends, the process moves to step S222.

  In step S222, command analysis processing is performed. As will be described in detail later, in this processing, the sub CPU 201 performs processing of analyzing a command received from the main control circuit 100 in step S211 shown in FIG. 62 and stored in the work RAM 203. This process will be described later. If this process ends, the process moves to step S223.

  In step S223, rendering processing is performed. Although the details will be described later, in this process, the sub CPU 201 performs pre-reading advance notice effects and effects settings using the illumination array 426. If this process ends, the process moves to step S224.

  In step S224, display control processing is performed. In this process, the sub CPU 201 stores data for displaying the effect image on the liquid crystal display device 50 in the work RAM 203. The data for displaying this effect image includes, for example, a pre-read advance notice determination command to be described later, data of a reserved symbol to be described later, and the like. Then, the sub CPU 201 transmits the stored data to the display control circuit 210 in the process of step S213 shown in FIG. The display control circuit 210 uses the image data ROM (not shown) to generate various image data such as derived symbol data, background image data, and effect image data based on the data for displaying the effect image from the sub CPU 201. It is read out, superimposed, and displayed on the display area 51 of the liquid crystal display device 50. If this process ends, the process moves to step S225.

  Here, in the present embodiment, the pre-read advance notice effect is an identification corresponding to the reserved symbol by setting the reserved symbol for effect displayed on the liquid crystal display device 50 to a display mode different from the normal display mode. In the derivation display of symbols, it is an effect (so-called holding ball advance notice) for informing the player of the reliability to be a big hit.

  The effect pattern of the preview advance notice effect is set by the advance notice effect determination process described later by the sub CPU 201. The preview advance notice effect is not limited to the mode of displaying in the display area 51 of the liquid crystal display device 50, and may be performed by a character, a segment, or a second display device (liquid crystal display device or the like).

  In step S225, voice control processing is performed. In this process, the sub CPU 201 stores data for generating sound from the speaker 14 in the work RAM 203. The sub CPU 201 transmits the stored data to the voice control circuit 220 in the process of step S213 shown in FIG. The voice control circuit 220 generates a sound from the speaker 14 based on data for generating the sound. If this process ends, the process moves to step S226.

  In step S226, lamp control processing is performed. In this process, the sub CPU 201 stores data for controlling the lamp 15 including the decoration lamp and the like in the work RAM 203. The sub CPU 201 transmits the stored data to the lamp control circuit 230 in the process of step S213 shown in FIG. The lamp control circuit 230 lights, blinks, or extinguishes the lamp 15 based on data for controlling the lamp 15. When this process ends, the present subroutine ends.

Command analysis processing
The subroutine (command analysis processing) executed in step S222 of FIG. 63 will be described with reference to FIGS. In step S230, it is determined whether there is a received command. In this process, the sub CPU 201 determines whether or not the command received from the main control circuit 100 is stored in the work RAM 203. If it is determined that the command is stored, the process proceeds to step S231. If it is determined that the command is not stored, this subroutine is ended.

  In step S231, processing is performed to analyze the command received in the sub control circuit interrupt processing. In this process, the sub CPU 201 performs a process of analyzing a command or data received from the main control circuit 100 at step S211 shown in FIG. 62 and stored in the work RAM 203. When this process ends, the process moves to step S232. Such commands and data, demo display command, derived symbol specification command, prefetch warning notice determination command, first and second out ball command, data of fluctuation pattern indicated by fluctuation pattern specification command, big hit type command, definite variation state fluctuation Data indicating the value of the count counter, data indicating the value of the time reduction status change counter, big hit start command, small hit start command, data indicating the value of the probability change flag, data indicating the value of the time short flag, starting opening winning command etc. included.

  Further, the sub CPU 201 performs processing of storing data of the fluctuation pattern indicated by the analyzed fluctuation pattern designation command and data indicated by the prefetch advance notice determination command in the fluctuation pattern storage area. In the present embodiment, the variation pattern storage area is from the variation pattern storage area (0) to the variation pattern storage area (4). The data of the fluctuation pattern indicated by the analyzed fluctuation pattern designation command and the data indicated by the prefetch advance notice determination command are sequentially stored in the fluctuation pattern storage area (0) to the fluctuation pattern storage area (4). The sub CPU 201 performs effect pattern determination processing described later based on the data of the change pattern stored in the change pattern storage area (0), and performs pre-read notification effect setting processing described later based on the data indicated by the pre-read notification effect command. . As described above, in the present embodiment, the variation pattern designation command and the prefetch advance notice determination command for which the variation display of the special symbol is suspended are also variation pattern storage area (0) to variation pattern storage area (4) of the work RAM 203 Is stored in The sub CPU 201 reads out the fluctuation pattern designation command and the pre-read notice determination command stored in the fluctuation pattern storage area (0) to the fluctuation pattern storage area (4) to perform so-called “prereading effect”, in particular 'Will be possible. Further, the variation pattern storage area (0) to the variation pattern storage area (4) are the first variation pattern storage area (0) to the first variation opening where the variation pattern specification command based on the first start-up winning and the predictive advance notice determination command are stored. 1) Variation pattern storage area (4), and second variation pattern storage area (0) to second variation pattern storage area (4) in which a variation pattern specification command based on the second starting opening winning combination and a predictive advance notice determination command are stored ,including.

  In step S232, processing is performed to determine whether or not a fluctuation pattern designation command has been received. In this process, as a result of the analysis in step S231, the sub CPU 201 determines whether or not the command received from the main control circuit 100 includes a variation pattern designation command, and determines that the variation pattern designation command is included. If it is determined that the change pattern designation command is not included, the process proceeds to step S234.

  In step S233, rendering pattern determination processing is performed. In this process, the sub CPU 201 refers to the effect table shown in FIG. 77 based on the variation pattern designation command analyzed in step S 231 shown in FIG. 64 and the random value extracted for determining the effect pattern, and performs the effect pattern Are determined and stored in the work RAM 203.

[Effect table]
Here, the effect table will be described with reference to FIG. In the present embodiment, the effect table changes the derived symbol fluctuation time, the random number value for the effect pattern determination in which the predetermined width is set to the fluctuation pattern indicated in the fluctuation pattern designation command, the selection rate, the effect pattern, the contents of the effect The winning type and the symbol designation command are associated with each other and stored in the program ROM 202. In the effect table, the fluctuation pattern corresponds to the fluctuation pattern of the fluctuation pattern determination table (see FIG. 75). Also, the fluctuation time corresponds to the fluctuation time of the fluctuation pattern determination table (see FIG. 75). In addition, the effect pattern indicates the type of effect pattern assigned to each effect content. The winning type corresponds to the determination value data of the big hit random number determination table (see FIG. 73). Also, the symbol designation command corresponds to the symbol designation command of the jackpot symbol random number determination table (see FIG. 74).

  Referring back to FIG. 64, in step S233, for example, when the variation pattern designation command is "HN20" and the random number value extracted for effect pattern determination is "10", the sub CPU 201 performs effect table (see FIG. 77). ), The effect pattern “EN 39” is determined, and processing for storing in the work RAM 203 is performed. The sub CPU 201 transmits the effect pattern "EN 39" to the display control circuit 210. The display control circuit 210 displays “special effect A” which is the effect content of the effect pattern “EN 39” on the display area 51 (see FIG. 4) of the liquid crystal display device 50. When this process ends, the present subroutine ends.

  In step S234, processing is performed to determine whether or not a derived symbol specification command has been received. In this process, as a result of the analysis in step S231, the sub CPU 201 determines whether or not the command received from the main control circuit 100 includes a derived symbol designation command, and determines that the derived symbol designation command is included. If it is determined that the process proceeds to step S235, and if it is determined that the derived symbol designating command is not included, the process proceeds to step S236.

  In step S235, processing for determining a derived symbol is performed. In this process, the sub CPU 201 determines a derived symbol according to a derived symbol designation command received from the main control circuit 100, and displays the derived symbol on the display area 51 (see FIG. 4) of the liquid crystal display device 50. Are stored in the work RAM 203. Specifically, the sub CPU 201 determines a derived symbol indicating a big hit if the derived symbol specifying command is associated to a big hit, and determines a derived symbol indicating a small hit if it is matched to a small hit. If it is associated with a loss, the derived symbol indicating the loss is determined. When this process ends, the present subroutine ends.

  Here, in the present embodiment, the derived symbol is variably displayed on the display area 51 (see FIG. 4) of the liquid crystal display device 50 in a mode in which, for example, three numbers from "0" to "9" are arranged. Or stop display. And, as for the derived design which shows big hit, as for stop indicatory feature, for example, all three numbers are the same number, this number is odd. Also, in the derived symbol indicating a small hit, the stop display mode is such that, for example, all three numbers are the same number, and this number is an even number. In addition, in the derived symbol indicating a loss, for example, the stop display mode does not have the same three numbers.

  In addition, in step S235, the sub CPU 201 sets a derived symbol variation start command for starting variable display of the determined derived symbol. Then, in the process of step S213 shown in FIG. 62, the sub CPU 201 transmits the derived symbol variation start command and the data of the variation pattern of the variation pattern storage area (0) to the display control circuit 210. The display control circuit 210 starts the fluctuation display of the derived symbol in the display area 51 (see FIG. 4) of the liquid crystal display device 50 based on the derived symbol fluctuation start command, and displays the stop after the fluctuation time elapses based on the data of the fluctuation pattern. Do. At this time, the sub CPU 201 acquires from the RTC 204 the derived symbol fluctuation start time at which the variable symbol display of the derived symbol has started, and stores it in the work RAM 203. The sub CPU 201 shifts the data of the fluctuation pattern storage area (1) to the fluctuation pattern storage area (4) to the fluctuation pattern storage area (0) to the fluctuation pattern storage area (3) after the stop display of the derived symbol Process to memorize).

  In step S236, a process is performed to determine whether or not the pre-reading advance notice determination command has been received. In this process, the sub CPU 201 determines, as a result of the analysis in step S 231, whether or not the command received from the main control circuit 100 includes the pre-read advance notice determination command, and determines that the pre-read advance notice determination command is included. If it is determined that the process proceeds to step S237, and if it is determined that the pre-reading advance notice determination command is not included, the process proceeds to step S240.

  In step S237, pre-reading advance notice effect setting processing is performed. In this process, the sub CPU 201, which will be described in detail later, is a liquid crystal display device corresponding to the storage area in which the prefetching advance notice determination command is stored in the variation pattern storage area (1) to the variation pattern storage area (4). A process is performed to make settings for changing the display mode of the holding symbol displayed at 50. When this process ends, the present subroutine ends.

  In step S240, it is determined whether the first out-sphere command or the second out-sphere command has been received. In this process, as a result of the analysis in step S231, the sub CPU 201 determines whether the command received from the main control circuit 100 includes the first out sphere command or the second out sphere command, and the first out If it is determined that the sphere command or the second out sphere command is included, the process proceeds to step S241, and if it is determined that the first out sphere command or the second out sphere command is not included, the step The process moves to S242.

  In step S241, point counting processing is performed. As will be described in detail later, in this process, the sub CPU 201 uses a partial storage area of the work RAM 203 as a counter, and stores it in the counter each time it receives a first out sphere command or a second out sphere command. A predetermined point value is added to the existing point value. When this process ends, the present subroutine ends.

  In step S 242, processing corresponding to the received other command is performed. In this processing, the sub CPU 201 performs processing corresponding to commands other than the fluctuation pattern designation command, the derived symbol designation command, the prefetch notice determination command, and the out sphere command. When this process ends, the present subroutine ends.

[Pre-reading notice production setting processing]
The subroutine (pre-reading advance notice effect setting processing) executed in step S 237 of FIG. 64 will be described with reference to FIG.

  In step S250, processing is performed to set the display pattern of the reserved symbol. In this process, the sub CPU 201 performs a process of setting the display color of the holding symbol corresponding to the fluctuation pattern determined by the process of the main CPU 101. In the present embodiment, the display color of the retention symbol displayed on the liquid crystal display device 50 is white, blue, yellow, or green, and in the process of step S250, the sub CPU 201 gives advance notice by the process of the main CPU 101. The display color of the holding symbol corresponding to the fluctuation pattern not determined is set to white, and the holding symbol corresponding to the fluctuation pattern determined to give advance notice by the processing of the main CPU 101 is set to either blue or yellow. The sub CPU 201 refers to a basic display color determination table (not shown) as to whether the display color of the reserved symbol is to be blue or yellow, acquires a random value by random number lottery, and displays this random value and display A process of determining the display color is performed by comparing with the color setting determination value. In addition, green is a display color of the holding symbol which changes by operation of the touch sensor 425 mentioned later.

  Here, the basic display color determination table will be described. The basic display color determination table is a random number value used as a display color setting determination value for determining the display color of the holding symbol in the effect pattern determined by the sub CPU 201 based on the variation pattern designation command transmitted from the main CPU 101 And the display color of the holding symbol corresponding to the display color setting determination value are associated with each other, and are stored in the program ROM 202.

  The display color of the retention design corresponding to the judgment value for display color setting is 2 colors of blue and yellow, and the range of the random value used as the judgment value for display color setting is distributed so as to select either blue or yellow. It is done. Concretely, when the big hit reliability of the production contents corresponding to the production pattern is low, blue is easy to be selected, and as the big hit reliability of the production contents is high yellow is easy to be selected, the judgment value for display color setting A range of random numbers is set. Therefore, when the random number value acquired by the sub CPU 201 by random number lottery is the display color setting determination value corresponding to blue, the display color of the holding symbol is set to blue and the display color setting determination value corresponding to yellow. In the case, the display color of the holding symbol is set to yellow. When this process ends, the process of step S251 is shifted.

  In step S251, processing is performed to set data of the display color of the reserved symbol. In this process, the sub CPU 201 performs a process of setting the display color data of the holding symbol set in the process of step S250 in a predetermined area for transmission of the work RAM 203. Data of the display color of the holding symbol set in the work RAM 203 is transmitted to the display control circuit 210 by the process of step S213 shown in FIG. The display control circuit 210 causes the display area 51 (see FIG. 4) of the liquid crystal display device 50 (see FIG. 4) to display the holding symbol of the display color set in the process of step S251 based on the received display color data of the holding symbol. When this process ends, the process of step S252 is shifted.

  In step S252, it is determined whether or not the held symbol whose display color is set in step S250 is the held symbol corresponding to the second starting opening winning combination. In this process, the sub CPU 201 determines whether or not it is a reserved symbol by the second start opening winning according to whether the prefetch advance notice determination command is stored in the first variation pattern storage area or in the second variation pattern storage area. Do. That is, when the pre-reading advance notice determination command is stored in the second variation pattern storage area, the sub CPU 201 determines that it is a holding symbol due to the second starting opening winning. Sub-CPU 201 moves the process to step S 253 when it is determined that it is a holding symbol by the second starting opening winning, and ends this subroutine when it is not determined that it is the holding symbol by the second starting opening winning .

  In step S253, a holding symbol change setting process is performed. In this process, the sub CPU 201 determines the process of determining whether to change the holding symbol whose display mode has been changed in step S250 to green on the condition that the touch sensor 425 is operated, although the details will be described later. Do. When this process ends, the present subroutine ends.

[Pending symbol change setting process]
A subroutine (pending symbol change setting process) executed in step S253 of FIG. 66 will be described with reference to FIG.

  In step S260, it is determined whether or not the effect pattern corresponding to the held symbol is a big hit. In this process, the sub CPU 201 determines whether or not the effect pattern corresponding to the held symbol is a big hit, and if it is determined to be a big hit, the process proceeds to step S261, and if not determined to be a big hit, the step Transfer the process to S262.

  In step S261, processing is performed to determine the change of the holding symbol corresponding to the effect pattern that is a big hit. In this process, the sub CPU 201 compares the random number value acquired by random number lottery with the determination value set in the big hit for holding symbol change determination table, and determines to change the holding symbol when it is determined that they match. If this process ends, the process moves to step S263.

  In step S262, a process of determining a change in the held symbol corresponding to the fluctuation pattern other than the big hit is performed. In this process, the sub CPU 201 compares the random number value acquired by random number lottery with the determination value set in the non-big-hit reserved symbol change determination table, and determines to change the reserved symbol when it is determined as a match. If this process ends, the process moves to step S263.

  Here, the large hit reserved design change determination table is a table in which the effect pattern to be a big hit and the random number range to be the determination value are associated, and it is determined that the sub CPU 201 matches the random value and the determination value in step S261. The random number range is set so that the probability of doing is 50%. The reserved symbol change determination table for non-big hit is a table in which the effect pattern associated with the variation pattern for lost or small hit is associated with the random number range for the determination value, and the sub CPU 201 is a random value in step S261. And the determination value are set to be 1%.

  In step S263, a process of setting a holding symbol changeable flag is performed. In this process, the sub CPU 201 performs a process of setting “1” as the holding symbol changeable flag in a predetermined area of the second variation pattern storage area corresponding to the holding symbol determined to change the display mode. When this process ends, the present subroutine ends.

[Point counting process]
A subroutine (point counting process) executed in step S241 of FIG. 65 will be described with reference to FIG. In step S270, processing is performed to determine the current gaming state. In this process, the sub CPU 201 performs the big hit gaming state based on the data transmitted from the main control circuit 100 to the sub control circuit 200 in the storage and gaming state data generation process of step S56 (see FIG. 55). If it is determined that the jackpot gaming state, the process proceeds to step S271. If it is not determined that the jackpot gaming state, the process proceeds to step S272.

  In step S271, processing is performed to add the first count value to the point counter. In this process, the sub CPU 201 performs a process of adding the first count value to the count value stored in a predetermined area of the work RAM 203 used as a point counter. In the present embodiment, "20" is set as the first count value when the first out sphere command is received, and "30" is set as the first count value when the second out sphere command is received. ing. If this process ends, the process moves to step S273.

  In step S272, processing is performed to add the second count value to the point counter. In this process, the sub CPU 201 performs a process of adding the second count value to the count value stored in a predetermined area of the work RAM 203 used as a point counter. In the present embodiment, “1” is set as the second count value when the first out sphere command is received, and “100” is set as the second count value when the second out sphere command is received. ing. That is, since it is extremely difficult for the game ball to pass through the second special out port 420c rather than the first special out port 420b, many points are added when passing through the second special out port 420c. Count value is set. When this process ends, the present subroutine ends.

  In step S273, processing is performed to determine whether the final round has ended. In this process, the sub CPU 201 ends the final round on the basis of the round number command transmitted from the main control circuit 100 in step S64 and the round end command transmitted from the main control circuit 100 in step S65. If it is determined that the shutter member 422a has protruded, the process proceeds to step S274. If it is not determined that the final round has ended, this subroutine ends.

  In step S274, processing for stopping point addition is performed. In this process, the sub CPU 201 performs a process of temporarily stopping the point counter so that points are not added. If this process ends, the process moves to step S275.

  In step S275, processing is performed to determine whether or not the big hit gaming state has ended. In this process, the sub CPU 201 determines whether or not the big hit gaming state has ended based on the data transmitted from the main control circuit 100 to the sub control circuit 200 in the storage and gaming state data generation process of step S56 (see FIG. 55). If it is determined that the jackpot gaming state has ended, the process proceeds to step S276. If it is not determined that the jackpot gaming state has ended, the present subroutine ends.

  In step S276, a process of restarting point addition is performed. In this process, the sub CPU 201 performs a process of canceling the pause state of the point counter and returning it to a state in which points are added. When this process ends, the present subroutine ends.

  That is, in the big hit gaming state, whenever the game ball passes the first special out port 420b, the count value of the point counter is increased by "20", and in the other than the big hit gaming state, the first special out port 420b is played Each time the ball passes, the count value of the point counter is incremented by one. Here, in the interval from the end of the last round to the end of the jackpot gaming state in the jackpot gaming state, points are not added even if the gaming ball passes the first special out port 420b. In this way, it is possible to prevent the count value of the point counter from rising at once due to many game balls passing the first special out port 420b in the interval from the end of the last round to the end of the big hit gaming state. it can.

[Demonstration processing]
The subroutine (effect processing) executed in step S223 of FIG. 63 will be described with reference to FIG. In step S280, touch sensor activation processing is performed. As will be described in detail later, in this process, the sub CPU 201 determines whether to activate the operation of the touch sensor 425 based on the count value of the point counter, and in the period determined to be activated, the sub CPU 201 Control to receive an operation signal from the touch sensor 425 is performed. If this process ends, the process moves to step S281. The sub CPU 201 that executes the process of step S280 functions as an effect determination unit that determines whether or not a predetermined effect can be performed based on the number of game media that has passed through the first special out port 420b. .

  In step S281, touch sensor effect processing is performed. Although the details will be described later, in this process, the sub CPU 201 performs control to execute an effect of changing the display color of the holding symbol by the operation of the touch sensor 425 by the player. If this process ends, the process moves to step S282.

  In step S282, illumination effect processing is performed. Although the details will be described later, in this process, the sub CPU 201 performs control to notify the operation timing of the touch sensor 425 using the illumination array 426. If this process ends, the process moves to step S283. The sub CPU 201 that executes the process of steps S281 and S282 functions as an effect execution unit that enables a predetermined effect to be executed based on the fact that the effect determination unit makes a positive determination.

  In step S283, other rendering processing is performed. In this process, the sub CPU 201 stores, in the work RAM 203, data for controlling various effects displayed during the effect during the fluctuation of the derived symbol, the effects performed before the start of the fluctuation, and the like. The sub CPU 201 outputs such data to the display control circuit 210, the audio control circuit 220, the lamp control circuit 230, the first operation means control circuit 240a and the second operation means control circuit 240b in step S213 of FIG. . When this process ends, the present subroutine ends.

[Touch sensor activation process]
A subroutine (touch sensor activation processing) executed in step S280 in FIG. 69 will be described with reference to FIG. As shown in FIG. 70, in step S290, processing is performed to determine whether the point value in the point counter has exceeded a preset set value. In this process, the sub CPU 201 compares the point value stored in the storage area used as a point counter in the work RAM 203 with the setting value stored in advance in the predetermined storage area of the work RAM 203, and the point value is It is determined whether or not the set value (for example, 240) is exceeded. If it is determined that the point value exceeds the set value, the process proceeds to step S291, and if it is not determined that the point value exceeds the set value. The process moves to step S298.

  In step S291, processing for enabling the touch sensor 425 is performed. In this process, the sub CPU 201 sets a touch sensor activation flag in the work RAM 203, and performs a process for enabling reception of an operation signal transmitted from the touch sensor 425. If this process ends, the process moves to step S292.

  In step S292, processing for activating a timer is performed. In this process, the sub CPU 201 uses a predetermined area of the work RAM 203 as a timer for measuring a predetermined time (for example, one minute), and performs a process of starting the countdown of the timer. If this process ends, the process moves to step S293.

  In step S293, processing is performed to determine whether the touch sensor 425 has been operated. In this process, the sub CPU 201 determines whether or not the operation signal from the touch sensor 425 has been received, and if it is determined that it has been received, the process proceeds to step S 295, and if it is not determined that it has been received, The process moves to step S294.

  In step S294, it is determined whether the timer value has become "0". In this process, the sub CPU 201 determines whether the timer value stored in the predetermined area of the work RAM 203 used as the timer has become "0", and has determined that the timer value has become "0". If so, the process proceeds to step S295. If it is not determined that the timer value has become "0", this subroutine ends.

  In step S295, processing is performed to invalidate the touch sensor 425. In this process, the sub CPU 201 clears the touch sensor activation flag stored in the work RAM 203 and performs a process of not receiving the operation signal transmitted from the touch sensor 425. If this process ends, the process moves to step S296.

  In step S296, processing for resetting the timer is performed. In this process, the sub CPU 201 performs a process of storing an initial value (for example, one minute) in a predetermined area of the work RAM 203 used as a timer. If this process ends, the process moves to step S297.

  In step S297, processing is performed to update the point value of the point counter to a value obtained by subtracting the set value. In this process, the sub CPU 201 updates the process of updating the point value stored in the storage area used as the point counter in the work RAM 203 to the value obtained by subtracting the setting value ("240" in the present embodiment). Do. That is, point values exceeding the set value are carried over. When this process ends, the present subroutine ends.

  In step S 298, processing for disabling the touch sensor 425 is performed. In this process, the sub CPU 201 clears the touch sensor activation flag stored in the work RAM 203 and performs a process of not receiving the operation signal transmitted from the touch sensor 425. When this process ends, the present subroutine ends.

  In this manner, the touch sensor 425 operates until the touch sensor 425 is operated or the timer elapses for a predetermined time (for example, one minute) after the point value counted by the point counter exceeds the preset setting value. The operation becomes valid in the period of and the operations in other periods become invalid.

  In the present embodiment, "240" is set as the set value, "20" as the first count value, "1" as the second count value, and one minute as the timer value. It can be set as appropriate. For example, by setting “50” as the set value, “5” as the second count value, “1” as the second count value, and 3 minutes as the timer value, the touch sensor 425 is easily activated in the time saving state. You may set it so that the activated state becomes long. Further, in the present embodiment, the operation is invalidated when the touch sensor 425 is operated. However, the present invention is not limited thereto. For example, the touch sensor 425 can be operated many times until the timer value is counted for one minute. It may be set. Further, in the present embodiment, the point value exceeding the set value is carried over in step S 297. However, the present invention is not limited to this, and for example, it may be reset (set to “0”).

[Touch sensor effect processing]
A subroutine (touch sensor effect processing) executed in step S281 in FIG. 69 will be described with reference to FIG. As shown in FIG. 71, in step S301, it is determined whether the touch sensor activation flag is set. In this process, the sub CPU 201 determines whether the touch sensor activation flag is set in the work RAM 203, and when it is determined that the touch sensor activation flag is set, the process proceeds to step S302, and the touch is performed. If it is not determined that the sensor activation flag has been set, this subroutine is ended.

  In step S302, processing is performed to determine whether the touch sensor 425 has been operated. In this process, the sub CPU 201 determines whether or not the operation signal from the touch sensor 425 has been received, and if it is determined that it has been received, the process proceeds to step S303, and if it is not determined that it has been received, This subroutine ends.

  In step S303, processing is performed to change the held symbol corresponding to the fluctuation pattern storage area in which the held symbol changeable flag is set. In this process, the sub CPU 201 sets “1” in the storage area of the work RAM 203 used as the held symbol changeable flag in the second variation pattern storage area (1) to the second variation pattern storage area (4). It is determined whether or not it has been set, and a process of changing the held symbol corresponding to the second variation pattern storage area in which "1" is set is performed. Note that the display color of the holding symbol that is changed based on the operation of the touch sensor 425 is set in advance in a predetermined storage area of the work RAM 203. In the present embodiment, the display color of the holding symbol is changed to "green". When this process ends, the present subroutine ends.

  It should be noted that the pending symbol changeable flag stored in the work RAM 203 is cleared when the variation of the identification symbol for effect based on the data of the storage area where the pending symbol changeable flag is stored, stop display is executed Ru.

[Illumination effect processing]
The subroutine (illumination effect processing) executed in step S282 in FIG. 69 will be described with reference to FIG. As shown in FIG. 72, in step S310, it is determined whether the touch sensor activation flag is set. In this process, the sub CPU 201 determines whether the touch sensor activation flag is set in the work RAM 203, and when it is determined that the touch sensor activation flag is set, the process proceeds to step S311, and the touch is performed. If it is not determined that the sensor activation flag is set, the process proceeds to step S313.

  In step S311, it is determined whether or not a big hit game is being played. In this process, the sub CPU 201 determines whether or not a big hit is in progress based on the data transmitted from the main control circuit 100 to the sub control circuit 200 in the storage and gaming state data generation process of step S56 (see FIG. 55). If it is determined that a big hit game is being performed, the present subroutine is ended. If it is not determined that a big hit game is being performed, the process proceeds to step S312.

  In step S312, a process of lighting the light source 426b of the illumination array 426 is performed. In this process, the sub CPU 201 causes the light source 426b of the illumination array 426 to emit light, and visualizes the latent image of the light guide plate 426a. When this process ends, the present subroutine ends.

  In step S313, the light source 426b of the illumination array 426 is turned off. In this process, the sub CPU 201 performs a process of turning off the light source 426b of the illumination array 426 so as not to visualize the latent image of the light guide plate 426a. When this process ends, the present subroutine ends.

  Thus, the rendering by the illumination array 426 is performed in a period in which the operation of the touch sensor 425 is valid. However, when the operation of the touch sensor 425 is in a period during which the jackpot is in progress, the effect by the illumination array 426 is not executed. As such, the fact that the effect by the illumination array 426 is being executed means that the player is notified that the operation of the touch sensor 425 is effective. Note that, when the timer counts 10 seconds before, it may be notified that the operation of the touch sensor 425 will be invalidated soon by changing the light emission color of the light source 426b or displaying it in a blinking manner.

  Further, in the process shown in FIG. 72, even if the operation of the touch sensor 425 is in the effective period, even if it is in the big hit game, the effect by the illumination array 426 is not executed by the process of step S311. The process of can be omitted. That is, in step S310, the sub CPU 201 determines whether or not the touch sensor activation flag is set in the work RAM 203. If it is determined that the touch sensor activation flag is set, the process proceeds to step S312. It is also good. Thereby, for example, when the operation of the touch sensor 425 becomes effective during the big hit game, the touch sensor 425 is operated even during the big hit game to check whether the display color of the holding symbol changes. It becomes possible. For example, if there is a retained design due to the second starting opening winning, as in the case where the big hit is continuous in the high probability time short state (so-called consecutive chan), check whether the display color of the retained design changes or not Becomes possible.

  By the way, the effect by the illumination array 426 is executed in the big hit gaming state and the time saving state in which the game ball is hit to the right because the game ball passes through the first special out port 420b. Specifically, the effect by the illumination array 426 is executed when the gaming ball passes the first special out port 420b and points are added, and in the present embodiment, the points exceed, for example, "240". Be done.

  Here, in the present embodiment, since the addition point in the big hit gaming state is set to "20", temporarily, the game ball passing the first special out port 420b in the interval between rounds 1 and 2 temporarily In the case of 16 rounds, it is highly likely that rendering by the illumination array 426 will be performed.

  Further, in the present embodiment, since the addition point in the time saving state is set to "1", the effect by the illumination array 426 is executed when the 240 game balls pass the first special out port 420b. It will be Here, normally, in the pachinko gaming machine 1, since the gaming balls are fired to an extent that does not exceed 100 per minute, consider entering the second starting opening 414b or the third special out opening 420d. However, the rendering by the illumination array 426 is executed at a rate of once every several minutes.

  Furthermore, when a round game of 16 rounds is executed in the big hit game state, there is a high possibility that the effect by the illumination array 426 is started at the time of starting the short time game, and a round game of 10 rounds is executed. There is a low possibility that illumination array 426 will start rendering at the time of starting a short game, but there is a high possibility that rendering by illumination array 426 is started within a relatively early time after starting a short game . The player can operate the touch sensor 425 at any timing while the illumination array 426 emits light. When the touch sensor 425 is operated, or when 1 minute has elapsed since the illumination array 426 emits light, the illumination array 426 does not emit light, but after approximately 3 minutes, the effect by the illumination array 426 is executed again. Ru.

[Advance notice notice production]
Next, prefetch advance notice effects will be described with reference to FIG. FIG. 78 is a diagram for explaining the transition of the display screen in the display area 51 (see FIG. 4) of the liquid crystal display device 50, and the derived symbol 53, the round display 54, the remaining fluctuation number display 55, and the first holding ball number Only the display 56 and the second number-of-held-balls display 57 are shown. In addition, the 1st holding ball number display 56 shows the holding ball based on the prize-winning to the 1st starting opening 414a, and a maximum of 4 holding | maintenance symbols are displayed. The second holding ball number display 57 indicates a holding ball based on the winning on the second starting opening 414b, and a maximum of four holding symbols are displayed.

  FIG. 78 (a) shows the display mode of the final round in the jackpot gaming state. In the present embodiment, character information "Round 16" is displayed as the round display 54. In the present embodiment, it is assumed that the point value of the point counter exceeds the set value (for example, 240) at the time of the final round. At this time, the illumination array 426 does not emit light. After the big hit gaming state ends, the game of the time saving state is started.

  FIG. 78 (b) shows a display mode immediately after the start of the game in the time saving state. In the present embodiment, “200 more times” is displayed as the remaining fluctuation number display 55. In addition, this fluctuation | variation number display 55 is decremented "1" every time the derivation | leading-out pattern 53 repeats a fluctuation | variation and stop. Also, since the point value of the point counter has already exceeded the set value, the illumination array 426 lights up and character information "Touch !!" is displayed. Then, when the player performs a right strike, the gaming ball passes the ball passage detector 416, and the second starting opening 414b is frequently opened, as shown in FIG. 78 (c) in the time saving state. In many cases, four holding symbols are displayed as the second holding ball number display 57.

  Here, the processing of steps S38 and S48 shown in FIG. 54 changes the display of the holding symbol corresponding to the holding ball determined to give the advance notice. In the example shown in FIG. 78 (c), the color of the holding symbol changes from white to blue. The player visually refers to whether or not to operate the touch sensor 425 by visually recognizing this display. In the example shown in FIG. 78 (c), it is assumed that the player sees off the operation of the touch sensor 425 because a big hit can not be expected much in blue.

  Then, it is assumed that the player continues to hit the right and a green holding symbol is displayed as shown in FIG. 78 (d). At this time, it is assumed that the player operates the touch sensor 425 as shown in FIG. 78 (e) because the player can expect the big hit relatively. At this time, if the yellow retention symbol turns green, it can be confirmed that the jackpot is more reliable. In addition, as shown to FIG. 78 (e), if it is a yellow retention symbol, it can be known beforehand that possibility of a loss is high.

  If the stop display mode of the identification symbol during variation shown in FIG. 78 (e) is lost, the player operates the touch sensor 425, so in the next variation of the identification symbol, as shown in FIG. 78 (f), The illumination array 426 is turned off and the character information "Touch !!" is not displayed.

  In the player, the player continues to hit the right and the fluctuation count is consumed to increase the count value of the point counter, and when several minutes have passed and the set value is exceeded, the illumination array 426 is again output. It lights up and character information "Touch !!" is displayed.

  When the remaining number of times of change decreases, the player may operate the touch sensor 425 if the holding symbol changes because it may be of any color. Then, as shown in FIG. 78 (g), when the holding symbol turns blue and the touch sensor 425 is operated and viewed, the white holding symbol turns green as shown in FIG. 78 (h). I suppose. In this case, the player sees the fluctuation of the identification symbol corresponding to the green holding symbol while being aware in advance that there is a possibility of losing. Here, in the time saving state, if it is the effect contents with the highest hit in the big hit, the fluctuation of the derived symbol 53 corresponding to the suspension symbol is almost finished without taking a few seconds, so first, the effect time becomes long I hope. Temporarily, when production time becomes long, the player sees the fluctuation and production of the derivation pattern 53 while further expanding the sense of expectation for the big hit.

  As mentioned above, although embodiment of this invention was described, it only illustrated the specific example and does not limit this invention in particular. That is, in the gaming machine of the present invention, the game medium is mainly divided into a game board having a game area on which game media can roll, and the first area and the second area which are different from each other in the game area. A firing means capable of firing game media to the game area while adjusting the launch intensity of the game media, and a first pass forming a first passage area through which the game media launched to the first area can pass A region forming member, a second passage region through which game media having passed through the first passage region can pass, united with the first passage region forming member, and passage of game media to the second passage region A first displacement member which can be displaced to any of a first position for facilitating the movement of the game medium and a second position for making it difficult to pass the game medium to the second passage area, and a game medium which does not pass through the second passage area It is possible to accept A distribution device for distributing game media to one of the first and second paths for guiding the game media in different directions through the received game media, and the game media distributed to the first route pass The third passing area where possible, the fourth passing area where gaming media distributed to the second path can pass, and the gaming medium allocated to the second path can roll, and the fourth A second displacement member displaceable to any one of a third position facilitating the passage of gaming media to the passage area and a fourth position allowing passage of gaming media to the fourth passage region difficult; When the second displacement member is at the fourth position, the game medium passing through the upper portion of the second displacement member is the second one when the second displacement member is displaced from the fourth position to the third position. Easy to move to the 4 pass area side The above-mentioned fourth on the condition that the game medium has passed through the winning a prize mechanism, the first out port for passing game media not passing through the fourth passing area, and sending it out of the gaming area, and the game medium passing through the first passing area. The first displacement member is moved to the first position based on a first determination unit that determines whether or not to displace the displacement member to the first position, and that the first determination unit makes a positive determination. A second determination unit that determines whether to displace the second displacement member to the third position on the condition that the game medium has passed through the first displacement member control means for displacing the second passage area and the second passage area. Means, and second displacement member control means for displacing the second displacement member to the third position a predetermined number of times based on that the second determination means makes a positive determination, the third passing area, and the fourth The game media has passed through any of the passing areas Based on the game value giving means capable of giving a predetermined game value, the effect executing means for making the predetermined effect executable under the condition that the game medium passes through the first out port, and the second The game medium rolling on the area includes a second out port for passing the game medium which does not pass through the area serving as a trigger for giving a predetermined game value by the game value giving means, and sending it out of the game area. The launch means, the first passage area forming member, the second passage area, the first displacement member, the distributing device, the third passage area, the fourth passage area, the second displacement member, and the winning combination Specific examples of the easy mechanism, the first out port, the first determination means, the first displacement member control means, the second determination means, the second displacement member control means, the game value giving means, the effect execution means, the second out port, etc. The configuration can be changed in design as appropriate

  For example, in the embodiment described above, although the color of the retention symbol is determined by the processing of the sub control circuit 200, the color of the retention symbol is determined by the main control circuit 100, and the fact is displayed by the sub control circuit A command may be sent to 200.

  Further, in the embodiment described above, although the holding symbol of the second starting opening winning is configured to be able to be changed by the operation of the touch sensor 425 by the player, the holding symbol of the first starting opening winning is Needless to say, it may be configured to be able to be changed by the operation of the touch sensor 425 by a person. In this case, for example, a passage sensor is provided which detects a game ball passing through a passage opening 413c (see FIG. 4) formed on the left side of the central base plate 413 (see FIG. 4). A predetermined value may be added to the point value of the point counter each time it is performed. Furthermore, when the holding symbol of the first starting hole winning is configured to be able to be changed by the operation of the touch sensor 425 by the player, the process of step S311 in the process shown in FIG. If it exceeds, it is desirable to make the touch sensor 425 operable even during the big hit game. Thereby, for example, when the number of holding balls is four, if the transition from the normal game to the big hit game is made, operate the touch sensor 425 during the big hit game and change the held symbol corresponding to the first starting hole winning? It becomes possible to confirm whether or not. Temporarily, when the retention symbol which turned green appears in the retention symbol which corresponds to the 1st starting opening winning a prize due to the operation of touch sensor 425, for example, it is made to digest the retention symbol immediately at any time in time saving game The player carries out the leading display of the identification symbol in the green holding symbol, or the leading display of the identification symbol in the green holding symbol at the time when the time reduction count is 200 times and digests the 190 times. It becomes possible to make decisions and to give the player a new interest.

  Further, in the above-described embodiment, the winning facilitating mechanism 424 is formed by the semi-cylindrical rib 424a, but other than that, for example, the surface of the shutter member 422a is corrugated or a minute projection is provided, etc. The game ball may be decelerated. In the present embodiment, even if the game ball is not decelerated using the easy-to-win mechanism 424, it is a mechanism that allows many of the right-handed game balls to easily win the big winning hole 418. Is applicable. For example, in the interval between rounds, a detour path for detouring the game ball to the back side of the game board is provided, and the game ball is returned from the detour path to the board of the game board at the timing when the shutter member opens. Good. Furthermore, two shutter members are arranged side by side along the rolling path of the game ball on one big winning opening, a passage is provided between the two shutter members, and the upstream shutter member protrudes at the end of the round The game ball passing through the passage digests the interval between rounds while passing through the passage, and when the interval between rounds ends and the two shutter members retract, the game ball passing through the passage from the downstream shutter member side wins a prize It may be something to win a mouth.

  In addition, by preparing LEDs of plural colors as the light source 426b of the illumination array 426 and changing the display color of the latent image 426c, the player may be motivated to operate the touch sensor 425.

  Further, in the above-described embodiment, the probability of hitting the normal symbol game in the normal gaming state is 0%, so that the identification symbol of the normal symbol game does not change even if the player is hit in the normal gaming state. If the identification symbol of the normal symbol game does not change, the second electric starting hole 414b will not win because the ordinary electric character 415 does not operate. That is, even if you hit the right in the normal gaming state, it will not be the special gaming state. In addition, when hitting the right in the normal gaming state, the winning balls by winning in the general winning opening 419d is three balls, and one sorting device 421 distributes one ball to four balls in the left direction and wins in the general winning opening 419d. However, since the other three balls are out balls, even if all the game balls directed to the left win the general winning hole 419d, the return rate will be 75% and eventually the number of balls will be reduced. Therefore, it is disadvantageous for the player to hit the right in the normal gaming state, so the player aims to increase the number of balls by transitioning to the big hit game, and aims to win the first start hole 414a to the left. You will get a hit.

  Further, according to the above-described embodiment, the gaming ball having passed the first path 423b does not enter any of the general winning opening 419d and the third special out opening 420d, and neither. Although it is divided into cases, it is not limited thereto. For example, the third special out port 420d may be deleted, and the general winning port 419d may be arranged such that the game ball having passed the first path 423b wins almost 100% of the general winning port 419d. In this case, since there are three prize balls when entering the general winning opening 419d for firing four game balls, the player's balls held by the jackpot game by hitting the right in the jackpot gaming state Although the increase number is close to the increase number when all the game balls fired in the game area 41 win a prize winning hole 418 in the big hit gaming state, it does not exceed.

  Further, according to the above-described embodiment, the illumination array 426 is used for the touch suggestion of the touch sensor 425 for changing the retention symbol, but the present invention is not limited thereto, and a button during variation of the identification symbol for effect You may use for the production in connection with operation. For example, the effect pattern of the illumination array 426 including the touch indication of the touch sensor 425 in the effect pattern of changing the effect by operation of the effect button 16 (see FIG. 1) to increase the jackpot expectation, and the touch sensor 425 The effect may be changed by the operation to increase the jackpot expectation. In addition, the display area 51 of the liquid crystal display device 50 is provided with a location for displaying the holding symbol corresponding to the identification symbol currently being changed, and the touch suggestion is executed during a specific variation effect, and the touch sensor 425 is touched. The color of the holding symbol may be changed according to the degree of expectation of the effect. The use method of the touch sensor 425 may be similar to that of the effect button 16.

  Further, in the present embodiment, according to FIG. 10, one LED lamp is disposed on the side of the light guide plate 426a as the light source 426b of the illumination array 426. However, the present invention is not limited thereto. It may be arranged side by side with Thereby, for example, by turning on the plurality of LED lamps in order, it is possible to perform effect display in which light flows. Furthermore, simultaneous lighting is performed when there is a low possibility that the holding symbol changes, and when the holding symbol changes to a high holding probability with a high probability of changing the holding symbol or when the jackpot expectation changes to a high holding probability, etc. The effect by the illumination array 426 may be selectable.

  In the above-described embodiment, according to the flowcharts of FIGS. 66 and 67, the display color of the holding symbol corresponding to the fluctuation pattern determined to be the advance notice by the sub CPU 201 by the processing of the main CPU 101 is white. After determining which one of blue and yellow is to be set, a holding symbol to be green is determined, and a holding symbol changeable flag is associated with the holding symbol. Then, when the touch sensor 425 is operated, the holding symbol associated with the holding symbol changeable flag is changed to green. However, the process of changing the holding symbol by the operation of the touch sensor 425 is not limited to the process described above.

  For example, first, after determining whether the display color of the retention symbol is white, blue, yellow, or green, the display color of the retention symbol to be actually displayed on the display area 51 of the liquid crystal display device 50 is determined. . At this time, it is determined that the display color lower than the originally determined display color determined first is actually displayed, and the liquid crystal display device 50 is caused to display the reserved symbol of the lower display color. Then, when the touch sensor 425 is operated, the lower display color may be changed to the originally determined display color. This example will be described in detail as a modification of the present embodiment with reference to FIGS. 80 and 81.

[Modification 2]
The modification of the present embodiment is to make the sub CPU 201 execute the processing shown in the flowchart of FIG. 81 instead of the flowchart of FIG. 71 instead of the flowchart of FIG. is there. The other processes are the same as in the above-described embodiment, and thus the description thereof is omitted.

  In FIG. 80, in step S254, processing is performed to determine the display color of the reserved symbol. In this process, the sub CPU 201 sets the display color of the holding symbol corresponding to the fluctuation pattern which is not determined to give advance notice by the process of the main CPU 101 to white, and the change pattern determined to give advance notice by the main CPU 101 processing. The holding symbol corresponding to is set to any of blue, yellow and green. The sub CPU 201 refers to a basic display color determination table (not shown) as to which of blue, yellow and green the display color of the holding symbol is to be displayed, acquires a random number value by random number lottery, and this random number value A process of determining a display color is performed by comparing the display color setting determination value. In addition, green is a display color of the holding symbol which changes by operation of the touch sensor 425 mentioned later.

  Here, the basic display color determination table used in the modification will be described. As in the above-described embodiment, the table for determining the basic display color includes, in the effect pattern, a range of random values serving as the display color setting determination value for determining the display color of the holding symbol and the determination for the display color setting. The display color of the holding symbol corresponding to the value is associated with one another, and is stored in the program ROM 202.

  Here, the display color of the retention design corresponding to the determination value for display color setting is three colors of blue, yellow and green, and the range of the random value to be the determination value for display color setting is either blue, yellow or green. It is distributed to select one. Specifically, when the big hit reliability of the effect content corresponding to the effect pattern is low, blue is easy to be selected, next yellow is easy to be selected, and green is hard to be selected. A range of random number values to be determination values is set. Furthermore, the larger the hit content reliability is, the smaller the range of random numbers corresponding to blue, the larger the range of random values corresponding to yellow or green, and the highest hit reliability is in the case of the play content, A range of random number values serving as display color setting determination values is set such that green is most easily selected, yellow is next most easily selected, and blue is most hardly selected. Therefore, in the modification of the present embodiment, the jackpot expectation degree is higher in the order of white, blue, yellow and green.

  Then, if the random number value acquired by the sub CPU 201 by random number lottery is the display color setting determination value corresponding to blue, the display color of the holding symbol is set to blue and the display color setting determination value corresponding to yellow In the case of, the display color of the holding symbol is set to yellow, and in the case of the judgment value for display color setting corresponding to green, the display color of the holding symbol is set to green. The display color of the reserved symbol set in this manner is stored in a predetermined area of the work RAM 203 as the display color of the original reserved symbol. When this process ends, the process of step S255 is shifted.

  In step S255, processing is performed to determine whether the held symbol whose display color has been set in step S254 is the held symbol corresponding to the second starting opening winning combination. This process is the same process as the process of step S 252 shown in FIG. 66, and the sub CPU 201 stores the pre-read advance notice determination command in the first variation pattern storage area or in the second variation pattern storage area Whether or not it is a holding symbol by the second starting opening winning combination is determined depending on whether it is. If it is determined that the sub CPU 201 is the holding symbol by the second starting opening winning, the process proceeds to step S256, and if not determined to be the holding symbol by the second starting opening winning, the process proceeds to step S257 .

  In step S256, processing is performed to set the display color of the reserved symbol to be actually displayed. In this process, the sub CPU 201 performs a process of setting the display color of the holding symbol to be actually displayed in the display area 51 of the liquid crystal display device 50. Specifically, the sub CPU 201 sets the display color of the holding symbol set in step S254 (does not change the display color) or the display color lower than the display color as the display color of the holding symbol to be actually displayed. In the modified example of the present embodiment, since the display color is the upper display color in the order of white, blue, yellow and green, the green is the display color of the top and the lower color of green is white, blue and yellow. . Similarly, the lower yellow color is white and blue, the lower blue color is white, and white is the lowest display color.

  The sub CPU 201 actually displays the display color of the holding symbol to be actually displayed as the display color of the holding symbol set in step S254 (does not change the display color) or a display color lower than the display color. With reference to a color determination table (not shown), random numbers are obtained by random number lottery, and a process of determining a display color is performed by comparing this random number value with an actual display color setting determination value. When this process ends, the process moves to step S257.

  Here, the actual display color determination table will be described. In the actual display color determination table, the reserved symbol to be actually displayed on the display area 51 of the liquid crystal display device 50 according to the original display color of the reserved symbol set in step S254, that is, green, yellow, blue. A range of random number values which are determination values for actual display color setting used to determine a display color is set. The actual display color determination table is composed of a table for determining the actual display color determined in the case of the effect pattern which is a big hit, and a table for determining the actual display color other than the large hit which is referred in the case of the effect pattern other than the big hit. . According to the big hit actual display color determination table, for example, if the original display color of the holding symbol set in step S254 is green, it corresponds to the range of random values corresponding to green (do not change the display color) yellow A range of random number values, a range of random number values corresponding to blue, and a range of random number values corresponding to white are set. If the display color of the holding symbol set in step S254 is yellow, the range of random number values corresponding to yellow (do not change the display color), the range of random number values corresponding to blue, and the range of random number values corresponding to white It is set. If the display color of the holding symbol set in step S254 is blue, a range of random number values corresponding to blue (without changing the display color) and a range of random number values corresponding to white are set. If the display color of the holding symbol set in step S254 is white, the white color is set to the display color of the holding symbol to be actually displayed. In the table for determining the actual display color other than the big hit, the big hit is actually displayed in that the range of the random value corresponding to the blue corresponding to the original display color of the holding symbol in the big hit actual display color determination table is not set. It is different from the color determination table.

  That is, in the modification of the present embodiment, there is a setting in the big hit actual display color determination table, which is not set in the actual display color determination table except for the big hit, and the actual display color is actually green. Settings in which blue is selected as the display color of are included only in the table for determining the actual display color of the big hit. For this reason, when the reserved symbol is initially blue and the reserved symbol changes to green by the operation of the touch sensor 425, a big hit is determined.

  The process shown in the flowchart of FIG. 81 includes the process of step S304 in place of the process of step S303 in the flowchart of FIG. In step S304, processing is performed to set data of the original display color of the holding symbol. In this process, the sub CPU 201 performs a process of setting the data of the display color of the holding symbol set in the process of step S 254 and stored in the work RAM 203 in the predetermined area for transmission of the work RAM 203. The data of the display color of the original reserved symbol set in the work RAM 203 is transmitted to the display control circuit 210 by the process of step S213 shown in FIG. The display control circuit 210 displays the reserved symbol of the original display color set in the process of step S254 in the display area 51 (see FIG. 4) of the liquid crystal display device 50 based on the received data of the displayed symbol display color. Let When this process ends, the present subroutine ends.

  As described above, according to the modification of the present embodiment, the display color of the reserved symbol is displayed on the display area 51 of the liquid crystal display device 50 first in a display color lower than the original display color, and the touch sensor 425 is displayed. Is manipulated to change the lower display color to the original display color. For this reason, it is possible for the player to amplify the sense of expectation for the big hit because it appears that the held symbol has changed from the lower display color to the upper display color by the operation of the touch sensor 425. Specifically, the display color of the holding pattern before and after the operation of the touch sensor 425 is white to white, white to blue, white to yellow, white to green, blue to yellow, blue to green, yellow to green, etc. Change to

  Moreover, in the modification of the present embodiment, the setting in which blue is selected as the actual display color when the original display color is green is included only in the table for determining the actual display color of the big hit, in other words, When the first display color of the retention symbol is blue and the retention symbol changes to green by the operation of the touch sensor 425, a big hit is determined. In this way, it is possible to set a specific color change to be determined only in the case of a big hit. Furthermore, it may be lost if the initial display color of the retention symbol is white or yellow, and the retention symbol changes to green by the operation of the touch sensor 425.

  In the embodiment and modification described above, main CPU 101 determines whether or not to give advance notice (hold ball advance notice), and sub CPU 201 determines the display color of the hold symbol, and further the touch sensor Although the holding symbol to be changed by the operation of 425 and its display color are determined, it is not limited thereto. For example, the main CPU 101 determines whether or not to give advance notice (holding ball advance notice), and determines whether or not to change it by the operation of the touch sensor 425, transmits the result to the sub CPU 201, and the sub CPU 201 The display color of the holding symbol for giving advance notice and the display color when the touch sensor 425 is operated may be determined as appropriate. Further, the main CPU 101 determines whether or not to give advance notice (preserving ball advance notice), and further determines the display color of the holding symbol corresponding to the holding ball determined to give pre-reading notice, and the touch sensor 425 It is determined whether or not the change is made by the operation of and the result is transmitted to the sub CPU 201. Then, the sub CPU 201 may determine the display color of the holding symbol to be changed by the operation of the touch sensor 425.

Second Embodiment
Hereinafter, a second embodiment of the present invention will be described. In the second embodiment of the present invention, differences from the above-described first embodiment of the present invention will be described, and descriptions of the same points as the first embodiment of the present invention will be made. I omit it.

  In the embodiment of the present invention, the special symbol display device 431 constitutes symbol display means for displaying a special symbol. The main CPU 101 starts the variation of the special symbol displayed on the special symbol display device 431 when the predetermined variation display start condition is met, and when the predetermined variation display end condition is met, The symbol variation means is configured to stop the variation of the special symbol displayed on the special symbol display device 431.

  Further, the main CPU 101 constitutes a gaming state transition means for transitioning the gaming state between the normal gaming state and the special gaming state. The sub CPU 201 configures effect determination means capable of determining an effect, and effect execution means for executing an effect.

  Further, the program ROM 202 constitutes effect data storage means for storing effect data to be referred to when executing a predetermined effect and effect data to be referred to when not executing the predetermined effect. Here, the predetermined effect includes effects to be described later such as a 1P effect and a touch point MAX effect.

Command analysis processing
The command analysis processing in the present embodiment will be described with reference to FIGS. 82 and 83. FIG. First, in step S400 in FIG. 82, the sub CPU 201 determines whether or not there is a received command. If it is determined that there is no received command (NO), the sub CPU 201 ends the command analysis process.

  If it is determined that there is a received command (YES), the sub CPU 201 executes the process of step S401. In step S401, the sub CPU 201 analyzes the command received in the sub control circuit interrupt process, and executes the process of step S402.

  In step S402, the sub CPU 201 determines whether or not a fluctuation pattern designation command has been received. If it is determined that the fluctuation pattern designation command has been received (YES), the sub CPU 201 executes the process of step S403. If it is determined that the fluctuation pattern designation command has not been received (NO), the sub CPU 201 executes the process of step S405.

  In step S403, the sub CPU 201 performs effect pattern determination processing. In the effect pattern determination process, the sub CPU 201 refers to the effect table shown in FIG. 77 based on the variation pattern designation command analyzed in step S401 and the random number value extracted for effect pattern determination, and executes the effect pattern. It decides and memorizes in work RAM203.

  After executing the process of step S403, the sub CPU 201 executes the process of step S404. In step S404, the sub CPU 201 executes a point provision effect setting process described with reference to FIGS. 84 and 85, and ends the command analysis process.

  At step S405, sub CPU 201 determines whether or not a derived symbol designation command has been received. If it is determined that the derived symbol designation command has been received (YES), the sub CPU 201 executes the process of step S406. If it is determined that the derived symbol designation command has not been received (NO), the sub CPU 201 executes the process of step S407.

  In step S406, the sub CPU 201 performs processing to determine a derived symbol. In this process, the sub CPU 201 determines a derived symbol according to a derived symbol designation command received from the main control circuit 100, and displays the derived symbol on the display area 51 (see FIG. 4) of the liquid crystal display device 50. Are stored in the work RAM 203.

  In step S <b> 407, the sub CPU 201 determines whether or not the pre-reading advance notice determination command has been received. If it is determined that the pre-reading advance notice determination command has been received (YES), the sub CPU 201 executes the process of step S408. If it is determined that the pre-reading advance notice determination command has not been received (NO), the sub CPU 201 executes the processing of step S411 (FIG. 83).

  In step S408, the sub CPU 201 executes point provision effect setting processing described with reference to FIGS. 84 and 85. After executing the process of step S408, the sub CPU 201 executes the process of step S409.

  In step S409, the sub CPU 201 executes pre-reading advance notice effect setting processing described with reference to FIG. After executing the process of step S409, the sub CPU 201 executes the process of step S410.

  In step S410, the sub CPU 201 executes the pre-read continuous effect setting process described with reference to FIG. After executing the process of step S410, the sub CPU 201 ends the command analysis process.

  In step S411 shown in FIG. 83, the sub CPU 201 determines whether a second out sphere command (hereinafter simply referred to as "out sphere command") has been received. If it is determined that the out sphere command has been received (YES), the sub CPU 201 executes the processing of step S412. If it is determined that the out sphere command has not been received (NO), the sub CPU 201 executes the processing of step S413.

  In step S412, the sub CPU 201 executes out-of-entry ball presentation processing described with reference to FIG. After executing the processing of step S412, the sub CPU 201 ends the command analysis processing.

  In step S413, the sub CPU 201 determines whether a demo display command has been received. If it is determined that the demo display command has been received (YES), the sub CPU 201 executes the process of step S414. If it is determined that the demo display command has not been received (NO), the sub CPU 201 executes the process of step S415.

  In step S414, the sub CPU 201 executes an in-provision latency notification notification effect setting process described with reference to FIG. After executing the process of step S414, the sub CPU 201 ends the command analysis process.

  In step S415, the sub CPU 201 performs processing corresponding to the received other command. In this processing, the sub CPU 201 performs processing corresponding to commands other than the fluctuation pattern designation command, the derived symbol designation command, the prefetch notice determination command, the out sphere command, and the demonstration display command. After executing the process of step S415, the sub CPU 201 ends the command analysis process.

[Point giving effect setting process]
Hereinafter, the point provision effect setting process executed in the command analysis process shown in FIG. 82 and FIG. 83 will be described with reference to FIG. 84 and FIG.

  First, in step S420 in FIG. 84, the sub CPU 201 determines whether or not a variation pattern designation command has been received. If it is determined that the fluctuation pattern designation command has been received (YES), the sub CPU 201 executes the processing of step S421. If it is determined that the fluctuation pattern designation command has not been received (NO), the sub CPU 201 executes the processing of step S428 (FIG. 85).

  In step S421, the sub CPU 201 determines whether the touch point MAX effect flag is one. Here, the touch point MAX effect flag is an effect that uses the current touch point as a set value (for example, 5 points in the embodiment, a value determined as the upper limit, a value sufficient to execute the effect, etc.) Indicates whether or not to execute a point MAX effect (for example, an effect of adding 4 points when the current touch point is 1 point, and an effect of setting 5 points of MAX points) However, the present invention is not limited to this, and control may be performed to indicate whether the touch point is a set value.

  In the first embodiment of the present invention, point values (sometimes simply referred to as “points”) are added in the point counting process described with reference to FIG. In the present embodiment, for example, as described later in the processing of S431 and S434, a point value is added as a touch point in accordance with the selected effect. Note that expressions such as value, number, and point are values that can include zero.

  Further, an upper limit is provided for the point value in the present embodiment, and the upper limit is “5”. Further, the set value in the present embodiment will be described as “5”. That is, the point value in the present embodiment has an upper limit set value.

  The set value or upper limit may be described as a MAX point, but if points can be accumulated beyond the set value (more than 5 points), a value of 5 or more is set as the set value or upper limit. In this case, if the point value has reached 5, the effect of changing the effect mode according to the operation of the player (for example, as shown in FIG. 101 (c) to 101 (e)). Since effects may be executed to change the item to an item after touch, the MAX points may indicate 5 points, and the specified value may have a relationship of 5 points or more. Since the expression that "is MAX" may be expressed as the point value satisfies the execution condition of the effect, or may be expressed as the point value reaches the set value, the point value is accumulated. Also point value if not the maximum value that can be sometimes expressed as becomes MAX.

  If it is determined in step S421 that the touch point MAX effect flag is 1 (YES), the sub CPU 201 executes the process of step S422. If it is determined that the touch point MAX effect flag is not 1 (NO), the sub CPU 201 executes the process of step S425.

  In step S422, the sub CPU 201 determines whether the fluctuation is 5.0 seconds (the fluctuation pattern is HN00 (see FIG. 75)) and whether there is a stage change. Here, stage change means that the effect stage which is a display mode displayed on the liquid crystal display device 50 such as the identification symbol or the background of the identification symbol is changed. The effect stage in the present embodiment includes "normal stage", "choy heat stage" and "superheat stage".

  Here, if the change is 5.0 seconds and the stage change is performed, it takes time to change the effect displayed on the liquid crystal display device 50 at the time of the stage change to a display adapted to each stage effect. (For example, if the time required for the stage change is 3.0 seconds, and the shortest effect time among the effects for adding the touch points is 4.0 seconds, the time required for the effect is 7.0 seconds, and 5.0 The effect of adding a touch point can not be performed because it does not fit in the fluctuation of seconds.) If it is determined that the fluctuation time is insufficient to perform an effect of adding a touch point, in S427, 5. It is possible to control to select other effects that can be performed during 0 second fluctuation. The identification symbol can be expressed as a special symbol, a normal symbol, or a decorative symbol (derived symbol), and the effect of each embodiment can be executed even when any symbol is used.

  For example, the sub CPU 201 determines whether or not to execute the advance notice, whether or not the selection result (or lottery, determination) of the special symbol includes the selection result as the big hit, or the special symbol of which the variable display is suspended. Stage change is executed by lottery with a selection rate according to the selection result or the effect pattern corresponding to the fluctuation (for example, fluctuation pattern) of the selection result.

  In addition, when executing the stage change, the sub CPU 201 may execute it before the start of the fluctuation of the identification symbol or after the start of the fluctuation of the identification symbol, or when performing the stage change during the fluctuation, or before the start of the big hit. When making a change, when making a stage change after the big hit, making a stage change according to the game state, etc., it is possible to make a stage change at various timings.

  If it is determined in step S422 that the fluctuation is 5.0 seconds and there is a stage change (YES), the sub CPU 201 executes the processing of step S427. If it is determined that the change is not a change for 5.0 seconds or there is no stage change (NO), the sub CPU 201 executes the process of step S423.

  In step S423, the sub CPU 201 selects a variation effect (touch point MAX effect) in which the touch point is MAX (for example, a setting value, an upper limit value). After executing the process of step S423, the sub CPU 201 executes the process of step S424.

  In the present embodiment, when the touch point MAX effect which is the pre-reading effect and the “pre-reading advance notice effect when the touch point becomes MAX” are collectively referred to as the touch point MAX effect, “the touch point is MAX. There are cases where it is collectively referred to as “the change effect production” and the touch point MAX effect is referred to, but the effect where the touch point becomes MAX can exist in any effect, and the touch point being the prefetch effect is MAX The effect that becomes the first effect, and the effect that the touch point that is the change effect is MAX may be the second effect, or it can be executed as the effect that the touch point MAX effect of 1 is the look-ahead effect or the change effect It is also good.

  Furthermore, when the touch point can be stored beyond the set value (for example, exceeding 5 points), if the player operates the operation means (for example, the effect button 16, the touch sensor 425, etc.), the touch is performed. 101 (b), which is an effect indicating that the effect of changing (switching, changing, etc.) the previous item into the item after touch is executable, changes to FIG. 101 (c), or FIG. 101 (c) It is also possible to control to add touch points so that the conditions for displaying effects such as) are satisfied at least once.

  In step S424, the sub CPU 201 sets the touch point MAX effect flag to 0. After executing the process of step S424, the sub CPU 201 executes the process of step S427.

  In step S425, the sub CPU 201 determines whether the touch point is MAX. If it is determined that the touch point is MAX (YES), the sub CPU 201 executes the process of step S427. If it is determined that the touch point is not MAX (NO), the sub CPU 201 executes the process of step S426.

  In step S426, the sub CPU 201 selects, based on the variation pattern and the various effects, whether or not to execute a 1P effect in which 1 is added to the touch point. Here, if it is determined that the 1P effect is to be executed, the sub CPU 201 adds 1 to the touch point to select the 1P effect that can be executed as the variation effect. After executing the process of step S426, the sub CPU 201 executes the process of step S427.

  In step S427, the sub CPU 201 selects another variation effect. Here, if the touch point is MAX during the period when the treasure box holding symbol is displayed, the sub CPU 201 adds a touch icon to the treasure box holding symbol.

  Further, the sub CPU 201 selects, for example, effect image data corresponding to the effect pattern, as another change effect except the effect relating to the application of the touch point. After executing the process of step S427, the sub CPU 201 ends the point provision effect setting process.

  In step S428 shown in FIG. 85, the sub CPU 201 determines whether or not the pre-reading advance notice determination command has been received. If it is determined that the pre-reading advance notice determination command has been received (YES), the sub CPU 201 executes the process of step S429. If it is determined that the pre-reading advance notice determination command has not been received (NO), the sub CPU 201 ends the point provision effect setting process.

  In step S429, the sub CPU 201 determines whether 1 is set in the touch point MAX effect flag. If it is determined that the touch point MAX effect flag is set to 1 (YES), the sub CPU 201 executes the process of step S430. If it is determined that the touch point MAX effect flag is not set to 1 (NO), the sub CPU 201 executes the process of step S433.

  In step S430, the sub CPU 201 determines whether the fluctuation is 5.0 seconds and whether there is a stage change. If it is determined that the fluctuation is 5.0 seconds and there is a stage change (YES), the sub CPU 201 executes the processing of step S435. If it is determined that the change is not a change for 5.0 seconds or there is no stage change (NO), the sub CPU 201 executes the process of step S431.

  In step S431, the sub CPU 201 selects a preview advance notice effect (touch point MAX effect) at which the touch point becomes MAX. After executing the process of step S431, the sub CPU 201 executes the process of step S432.

  In step S432, the sub CPU 201 sets the touch point MAX effect flag to 0. After executing the process of step S432, the sub CPU 201 executes the process of step S435.

  In step S433, the sub CPU 201 determines whether the touch point is MAX. If it is determined that the touch point is MAX (YES), the sub CPU 201 executes the process of step S435. If it is determined that the touch point is not MAX (NO), the sub CPU 201 executes the process of step S434.

  In step S434, the sub CPU 201 selects whether or not to execute the 1P effect in which 1 is added to the touch point, based on the variation pattern in which the advance notice generation is performed and the various effects. Here, if it is determined that the 1P effect is to be executed, the sub CPU 201 adds 1 to the touch point to select the 1P effect that can be executed as the prefetch effect. After executing the process of step S434, the sub CPU 201 executes the process of step S435.

  In step S435, the sub CPU 201 adds a touch icon to the treasure box retention symbol if the touch point is MAX during the period when the treasure box retention symbol is displayed. In addition, the sub CPU 201 selects other pre-reading effects except for effects relating to the application of touch points. After executing the process of step S435, the sub CPU 201 ends the point provision effect setting process.

  As described above, the touch point application in the point application effect setting process is performed as a fluctuation effect at the time of fluctuation (at the time of fluctuation start, during fluctuation, at the end of fluctuation, etc.) and the first start opening 414a or the second start opening. There is a case where it is performed as a pre-reading advance notice effect from the selection result at the time of winning for 414 b (hereinafter, simply referred to as “starting opening winning”).

  Although it has been described that the sub CPU 201 selects whether or not to execute the 1P effect in which 1 is added to the touch point in steps S426 and S434 of the point addition effect setting process described above, the touch point does not exceed MAX In a range (for example, a range that does not exceed the set value or the upper limit value), it may be selected whether to execute an effect in which two or more are added to the touch point.

[Pre-reading notice production setting processing]
The prefetch advance notice effect setting process executed in the command analysis process shown in FIGS. 82 and 83 will be described below with reference to FIG.

  If it is determined from the prefetch notice command or the like that the sub CPU 201 is to execute the prefetch notice effect, first, in step S440, the sub CPU 201 selects the display color of the holding symbol. After executing the process of step S440, the sub CPU 201 executes the process of step S441.

  In step S441, the sub CPU 201 sets data representing the display color of the holding symbol in the work RAM 203. After executing the process of step S441, the sub CPU 201 executes the process of step S442.

  In step S 442, the sub CPU 201 is a big hit (big hit 3, 4 (see FIG. 76), hereinafter referred to as “probable change,” shifting to a positive change state as a result of selection (or lottery, determination) of a special symbol for which variable display is suspended 94 or 95 is set in the work RAM 203, and a variation presentation pattern is selected on the basis of the variation presentation selection table set in the work RAM 203. . After executing the process of step S442, the sub CPU 201 executes the process of step S443.

  In step S443, the sub CPU 201 refers to the item selection table after touch shown in FIG. 96, and performs liquid crystal operation by the effective operation of the touch sensor 425 constituting the operation detection unit from the effect pattern and the fluctuation effect pattern set in step S442. The after-touch item displayed on the display device 50 (for example, if it is a reserved symbol and if the after-touch item TA2 in FIG. 96 is selected, the sword retention display shown in FIG. 101 (e) is displayed) select. After executing the process of step S443, the sub CPU 201 executes the process of step S444.

  As an effective operation, the operation of the effect button 16 may be detected, and if the touch sensor 425 is a first operation means and the effect button 16 is a second operation means, a specific operation may be performed. While the effect is being executed (for example, when the special effect described in the effect table of FIG. 77 is being executed), an effective operation of the first operation means can be detected, and the second operation means is effective. The operation may be undetectable. Further, the item after touch does not have to be limited to the holding symbol, and is not limited to this as long as it is an effect to be executed when touched (when the operation means is operated).

  In step S444, the sub CPU 201 sets an after-touch item pattern representing the after-touch item selected in step S443 in the work RAM 203. After executing the process of step S444, the sub CPU 201 executes the process of step S445.

  In step S445, the sub CPU 201 refers to the before-touch item selection table shown in FIG. 97, and determines whether or not the big hit is included in the selection (or lottery, determination) result of the special symbol for which the variable display is suspended. From the corresponding effect pattern (or the variation pattern of the special symbol, the selection result, etc.) and the item pattern after touch set in step S444, the display is displayed on the liquid crystal display device 50 until an effective operation is detected by the touch sensor 425 Select a pre-touch item pattern (e.g., hold symbol). After executing the process of step S445, the sub CPU 201 executes the process of step S446.

  As a pre-touch item, for example, when TB1 in FIG. 97 is selected, a black treasure box symbol is selected as the treasure box symbol in FIG. 101 (b) and the treasure box symbol is displayed or displayed. When the touch point reaches the specified value or upper limit (when it reaches MAX), as shown in FIG. 101 (c), the touch icon on the treasure box symbol (when the effective operation of the operation means is detected, the item before touch changes to the item after touch) Change (change, switch, etc.) to a black treasure box holding symbol with a touch icon with an effect indicating that it is possible.

  In addition, it is not necessary to limit to a reserve symbol at all as a pre-touch item, and if it is an effect to be displayed before or at the same time as an effect to be executed when touched (when the operation means is operated) It is not limited.

  However, when an operation of the operation means is performed by temporarily displaying the item after touch and then displaying the item before touch, before the operation of the operation means is detected and the item after touch is displayed. There is an effect that informs that the displayed item after touch is displayed (including the effect mode in which the item after touch displayed in advance is displayed again when the operation of the operation means is performed). In the case, since the item after touch may be displayed before the item before touch, the item before touch and the item after touch are effects that may be displayed at various timings.

  In addition, as a pre-touch item, it is possible to handle as a pre-touch item whether the reserved symbol with the touch icon or the reserved symbol without the touch icon.

  Furthermore, when the touch icon is attached to the item before touch, the effective operation of the operation means is not detected, and the change related to the item before touch with the touch icon is performed, the start of the change The item after the touch may be displayed at the time, during the change, or at the end of the change, or the item after the touch may be controlled not to be displayed in the change unless a valid operation of the operation means is detected. During the operation, control may be performed so as not to display the item after touch regardless of the detection of the effective operation of the operation means.

  In step S446, the sub CPU 201 sets the pre-touch item pattern selected in step S445 in the work RAM 203. After executing the process of step S446, the sub CPU 201 executes the process of step S447.

  In step S447, the sub CPU 201 determines whether the current touch point is MAX. If it is determined that the current touch point is not MAX (NO), the sub CPU 201 executes the process of step S448. If it is determined that the current touch point is MAX (YES), the sub CPU 201 ends the preview advance notice effect setting process.

  In step S448, the sub CPU 201 determines whether the number of reservations is more than one. If it is determined that the pending number is not more than 1 (NO), the sub CPU 201 ends the pre-reading advance notice effect setting process. If it is determined that the pending number is greater than 1 (YES), the sub CPU 201 executes the process of step S449.

  In the present embodiment, the effect is such that the point is set to MAX (for example, 5 points in the embodiment, a value determined as the upper limit, a value sufficient to execute an effect, etc.) when the number of held pieces is more than 1. Control is performed, but the present invention is not limited to this. It is also possible to control to execute when the number of pending is one or more or zero.

  In step S449, the sub CPU 201 selects by lottery whether the touch point is to be MAX by the next change of the special symbol. After executing the process of step S449, the sub CPU 201 executes the process of step S450.

  In step S450, the sub CPU 201 determines whether or not the touch point is selected to be MAX by the next change of the special symbol. If it is determined that the touch point is selected to be MAX by the next change of the special symbol (YES), the sub CPU 201 executes the process of step S451. If it is determined that the touch point is not selected as MAX by the next change of the special symbol (NO), the sub CPU 201 ends the pre-reading advance notice effect setting process.

  In step S451, the sub CPU 201 sets 1 to the touch point MAX effect flag. After executing the process of step S451, the sub CPU 201 ends the pre-reading advance notice effect setting process.

  If 1 is set in the touch point MAX effect flag, for example, the determination in S421 of FIG. 84 or S429 in FIG. 85 may be YES and the change effect or prefetch advance notice effect in which the touch point is MAX may be executed. .

[Pre-read continuous effect setting process]
Hereinafter, the prefetch continuous effect setting process executed in the command analysis process shown in FIGS. 82 and 83 will be described with reference to FIG.

  If it is determined from the prefetch notice command or the like that the sub CPU 201 is to execute the prefetch continuous effect, in the prefetch continuous effect setting process, for example, as shown in FIGS. And the serial number etc.) (for example, “2 · 4 · 8”, “3 · 5 · 7”, etc.) is displayed on the liquid crystal display device 50 with an effect and the data of the pre-reading continuous effect is displayed on the work as a work It sets to RAM203.

  By executing the pre-read continuous effect setting process continuously at the end of the change, the pre-read continuous effect setting process can increase the expectation for the player's jackpot at the next change when the pre-read continuous effect is performed.

  In addition, as shown in FIG. 102, the effect contents (scenario) of the preview continuous performance are determined and the preview continuous performance is executed for each fluctuation, and the preview continuous performance is continuously executed at the end of the fluctuation, or It is also assumed that the effect contents of the look-ahead continuous effect are executed in a change of one.

  In such a case, an effect mode (for example, the symbol is temporarily stopped with an effect at each temporary stop) such that the effect contents (scenario) of the previewed continuous effect is executed at each temporary stop of the symbol Since a mode etc. are assumed, expression of stop of a symbol, and a display of a combination of symbols can be said to be an expression that can include stop and temporary stop of symbols.

  First, in step S460, the sub CPU 201 refers to the prefetch continuous effect table shown in FIG. 98 and FIG. 104, and selects a scenario of the prefetch continuous effect according to the effect pattern and the currently stored reserved number. After executing the process of step S460, the sub CPU 201 executes the process of step S461.

  In addition, it controlled to choose the scenario of the pre-reading continuation production according to the production pattern and the presently remembered number, but it is not something which is limited to this, it is the fluctuation pattern of special symbol, whether it is big hit or not, big hit It may be controlled to select the effect according to whether to shift to a definite change after the end, the gaming state when the fluctuation related to the big hit is executed, the current gaming state, the gaming state after the big hit end, etc. .

  In step S461, the sub CPU 201 determines whether or not 1 is set in the pre-read continuous effect flag indicating whether or not the pre-read continuous effect is set. If it is determined that the pre-read continuous effect flag is set to 1 (YES), the sub CPU 201 executes the process of step S462. If it is determined that 1 is not set in the pre-read continuous effect flag (NO), the sub CPU 201 executes the process of step S467.

  Further, the pre-reading continuous effect setting process is executed when the sub-CPU 201 determines that the pre-reading continuous effect is to be executed from the type of command received by the sub CPU 201 or the drawing of the effect, and if the pre-reading continuous effect is set in S467 described later Since 1 is set to the prefetch continuation flag in S468, it can be determined that the scenario of the prefetch continuation effect has already been set when 1 is set to the prefetch continuation effect flag. Since the pre-read continuous effect is an effect having the possibility of being executed over a plurality of changes, it is possible to select the effect contents for a plurality of changes by selecting one scenario.

  In step S 462, the sub CPU 201 compares the scenario of the pre-read continuous effect set in advance with the scenario of the pre-read continuous effect selected this time, and extracts effects having overlapping execution timings. After executing the process of step S462, the sub CPU 201 executes the process of step S463.

  Here, the effect of overlapping execution timing will be described later in detail, but as shown in FIG. 103, for example, as the pre-reading continuous effect for the fourth hold, the effect contents of “blue”, “blue”, and “none” After being selected, the fluctuation for the first hold starts, and during the first hold fluctuation, the starting opening (the first starting opening 414a or the second starting opening 414b) has a prize, and the number of holdings is 4 again. If the “red”, “red”, and “虻” production contents are selected as the pre-reading continuous effect for the new 4th hold, the first change of the 1st hold will end The "blue, blue" and "none" scenarios are executed by one change, and the "blue," "blue" and "none" scenarios are executed substantially. "No" and "blue" will be set as the new 1st hold effect contentHowever, since "red", "red", and "rainbow" are newly determined as the pre-reading continuous effects for the new fourth hold, whether "blue" is set as the first hold effect contents It is necessary to select "red" and "red". Such a situation can be expressed as a state in which effects having overlapping execution timings exist, and the execution timings overlap in a similar manner even in the case where there are already set scenarios and newly set scenarios. It can be determined that a rendition exists.

  In step S463, the sub CPU 201 specifies an effect of "none" from the scenario of the pre-reading continuous effect set in advance. After executing the process of step S463, the sub CPU 201 executes the process of step S464.

  In step S464, the sub CPU 201 sets an effect mode of the newly selected prefetched continuous effect to the effect of "none" specified in step S463. After executing the process of step S464, the sub CPU 201 executes the process of step S465.

  In the example of FIG. 103 described above, “red” is set for the first to third hold in a state where “blue” is set for the first hold effect contents as the pre-reading continuous effect set already. When the effect contents of “red” and “rainbow” are newly selected, the effect contents to be finally executed are “blue”, “red” and “eyebrows”. It can be said that such setting of the effect mode is an example of processing for setting the effect mode of the preview continuous effect newly selected for the effect of “none”.

  In step S465, the sub CPU 201 sets 0 in the prefetch continuous effect flag. After executing the process of step S465, the sub CPU 201 ends the pre-reading continuous effect setting process.

  In step S467, the sub CPU 201 sets a scenario of the selected pre-reading continuous effect. After executing the process of step S467, the sub CPU 201 executes the process of step S468.

  In step S468, the sub CPU 201 sets 1 to the prefetch continuous effect flag. After executing the process of step S468, the sub CPU 201 ends the pre-reading continuous effect setting process.

  In the present embodiment, when the selected prefetch continuous effect is set, the prefetch continuous effect flag is set to 1. However, the present invention is not limited to this, and there is no previously-set prefetch continuous effect. When the pre-read continuous effect is set, control may be performed so that 1 is not set in the continuous effect flag.

[Out-of-the-round ball presentation processing]
Hereinafter, the out-of-entry ball presentation process executed in the command analysis process shown in FIGS. 82 and 83 will be described with reference to FIG. In the out slot entry effect processing process, a second out sphere detection sensor 117b (see FIG. 51) that constitutes a discharge medium detection unit that detects gaming media passing through the second special out port 420c (see FIG. 4) as a predetermined exit. When a game medium is detected by reference), it is executed when the out sphere command transmitted from the main CPU 101 is received.

  In this embodiment, when the gaming state changes (such as when the gaming state changes from the normal gaming state to the probability changing gaming state or when the probability changing gaming state changes to the regular gaming state), etc. It is possible to notify which area (for example, the area on the left side, the area on the right side, etc.) of the game area to fire the game ball.

  When such notification is performed, the player can grasp the game area where the game ball should be fired, and thereafter, shoot the game ball to one game area unless otherwise indicated. There are many cases where it is a game that is premised on not playing the game ball in the other game area.

  However, even if such a game is being played, the game ball rolls to the other game area even if it is intended to fire the game ball to one game area, depending on the operating condition of the operation means of the player. There is a case to do it.

  That is, in the present embodiment, the player basically shoots the game ball to the left side of the game area when in the normal gaming state (for example, in the normal state), but the firing means (for example, the operation) Depending on the operation condition of the means), there is a possibility that the gaming ball rolls to the right of the game area, and in such a case, when the second out ball detection sensor 117b detects the gaming ball, the main CPU 101 An out sphere command will be sent from.

  In the present embodiment, there are two out ball detection sensors (a first out ball detection sensor 117a, a second out ball detection sensor 117b, etc.), but in the sub CPU 201, the game ball is used in any out ball detection sensor. It is possible to know if it has been detected.

  First, in step S470, the sub CPU 201 determines whether or not the normal gaming state, that is, the normal gaming state. If it is determined that the processing is normal (YES), the sub CPU 201 executes the processing of step S471. If it is determined that it is not normal (NO), the sub CPU 201 executes the processing of step S473.

  Here, “normally” indicates a state including a non-time-short state and a non-probability state, or a non-time-short state and a probability-change state, but is not limited thereto, and may include a time-short state and a non-probability state It may be

  In addition, the time saving state may indicate the state of high probability of the normal symbol, and the probability variation state may indicate the state of high probability of the special symbol, and the non-time-short state may be the low probability state of the normal symbol, the low probability of the special symbol It may indicate the condition of

  In step S471, if the current gaming state is the latent probability change, the sub CPU 201 refers to the latent probability change notification table shown in FIG. 99, and selects an effect related to the latent probability change notification. After executing the process of step S471, the sub CPU 201 executes the process of step S472.

  In step S472, the sub CPU 201 sets the work RAM 203 to execute the effect selected from the latent probability change notification table. After executing the processing of step S472, the sub CPU 201 ends the out-of-entry ball presentation processing.

  In step S 473, the sub CPU 201 determines whether or not the jackpot is in progress, that is, the special game state. If it is determined that the jackpot is in progress (YES), the sub CPU 201 executes the process of step S474. If it is determined that the jackpot is not in progress (NO), the sub CPU 201 ends the out-of-entry ball presentation process.

  In step S474, it is determined whether or not a big hit is included in the selection (or lottery, determination) result of the special symbol for which the variable display is being held, that is, whether or not there is a big hit in the holding. If it is determined that there is a big hit in the suspension (YES), the sub CPU 201 executes the process of step S475. If it is determined that there is no big hit in the suspension (NO), the sub CPU 201 executes the process of step S476.

  In step S 475, the sub CPU 201 refers to the hold series notification effect selection table shown in FIG. 100, and selects an effect in the case where there is a big hit in the hold. After executing the processing of step S475, the sub CPU 201 ends the out-of-entry ball presentation processing.

  In step S 476, the sub CPU 201 refers to the hold series notification effect selection table shown in FIG. 100, and selects an effect in the case where there is no big hit in the hold. After executing the processing of step S476, the sub CPU 201 ends the out-of-entry ball presentation processing.

  Note that steps S474 to S476 in the above-described out slot entering game effect processing may be executed only for the type of special gaming state (for example, probability variation big hit), and the number of round games is limited to the special gaming state of a specified number or more. It may be executed, or may be executed only for a specific round game in the special game state.

  In addition, steps S 474 to S 476 in the above-mentioned out-lo ball entry effect processing may be executed according to the type of special gaming state (for example, probability variation big hit), and when the number of round games is a special gaming state of a specified number or more It may be executed, may be executed at a specific round game in the special game state, or may be a combination of each condition. Furthermore, even if the jackpot gaming state continues (for example, if the reserve to be digested next to the jackpot already executed is a jackpot, etc.), the player is controlled to perform an effect when entering the outro Good.

[Demonstration-in-probability notification notification production setting process]
Hereinafter, the demonstration-in-provision latent notification notification effect setting process executed in the command analysis process shown in FIGS. 82 and 83 will be described with reference to FIG.

  First, in step S480, the sub CPU 201 determines whether the current gaming state is the latent probability change. If it is determined that the current gaming state is the latent probability change (YES), the sub CPU 201 executes the processing of step S481. If it is determined that the current gaming state is not the latent probability change (NO), the sub CPU 201 ends the in-provision latent notification notification effect setting process.

  In step S481, the sub CPU 201 selects an effect that suggests that the gaming state is a latent probability change. After executing the processing of step S <b> 481, the sub CPU 201 ends the in-provision latent notification notification effect setting processing.

  If it is determined in step S480 that the current gaming state is not the latent probability change, the sub CPU 201 may select an effect that suggests the possibility that the gaming state is the latent probability change.

  That is, the sub CPU 201 may select an effect that suggests the possibility that the gaming state is the latent probability change, regardless of whether the current gaming state is the latent probability change. In this case, the sub CPU 201 may execute an effect in which the selection rate is different depending on whether the gaming state is the latent probability change.

[Touch sensor effect processing]
The touch sensor effect process according to the present embodiment will be described with reference to FIG. The touch sensor effect process in this embodiment is the touch sensor activation process described with reference to FIG. 70 and the touch sensor effect process described with reference to FIG. 71 in the first embodiment of the present invention. Instead of.

  First, in step S 490, the sub CPU 201 determines whether the touch point is MAX, that is, whether the point value is equal to or greater than the set value. If it is determined that the point value is equal to or greater than the set value (YES), the sub CPU 201 executes the process of step S491. If it is determined that the point value is not the set value or more (NO), the sub CPU 201 ends the touch sensor effect process.

  In step S491, the sub CPU 201 determines whether or not it is a period in which the treasure box holding symbol is displayed on the liquid crystal display device 50. If it is determined that it is a period during which the treasure box holding symbol is displayed (YES), the sub CPU 201 executes the process of step S492. If it is determined that it is not a period during which the treasure box holding symbol is displayed (NO), the sub CPU 201 ends the touch sensor effect process.

  In step S 492, the sub CPU 201 sets 1 in a touch sensor activation flag indicating whether the detection result of the touch sensor 425 is valid. After executing the process of step S492, the sub CPU 201 executes the process of step S493.

  In step S 493, the sub CPU 201 determines whether the operation detection flag indicating whether a valid operation has been detected by the touch sensor 425 is 1 or not. If it is determined that the operation detection flag is 1 (YES), the sub CPU 201 executes the process of step S494. If it is determined that the operation detection flag is not 1 (NO), the sub CPU 201 ends the touch sensor effect process.

  In step S494, the sub CPU 201 sets 0 in the touch sensor activation flag. After executing the process of step S494, the sub CPU 201 executes the process of step S495.

  In step S495, the sub CPU 201 sets the display of the effect after the touch when the effective operation is detected by the touch sensor 425. For example, the sub CPU 201 changes the holding symbol displayed on the liquid crystal display device 50 to the holding symbol after the touch. After executing the process of step S495, the sub CPU 201 executes the process of step S496.

  In step S 496, the sub CPU 201 subtracts the setting value from the point value. In the present embodiment, since the set value and the upper limit value are set equal, sub CPU 201 may simply set the point value to zero. After executing the process of step S 496, the sub CPU 201 ends the touch sensor effect process.

[Touch sensor state control processing]
The touch sensor state control process executed as one of the interrupt processes periodically executed by the sub CPU 201 will be described below with reference to FIG.

  First, in step S500, the sub CPU 201 determines whether or not the operation is detected by the touch sensor 425. If it is determined that the operation is detected by the touch sensor 425 (YES), the sub CPU 201 executes the process of step S501. If it is determined that the operation is not detected by the touch sensor 425 (NO), the sub CPU 201 executes the process of step S503.

  In step S501, the sub CPU 201 determines whether 1 is set in the touch sensor activation flag. If it is determined that the touch sensor activation flag is set to 1 (YES), the sub CPU 201 executes the process of step S502. If it is determined that the touch sensor activation flag is not set to 1 (NO), the sub CPU 201 executes the process of step S503.

  In step S502, the sub CPU 201 sets 1 to the operation detection flag. After executing the process of step S502, the sub CPU 201 ends the touch sensor state control process.

  In step S503, the sub CPU 201 sets 0 to the operation detection flag. After executing the process of step S503, the sub CPU 201 ends the touch sensor state control process.

  As described above, the sub CPU 201 constantly monitors the detection state of the touch sensor 425, and in the state where the operation of the touch sensor 425 is detected before the detection result of the touch sensor 425 becomes effective, the detection result of the touch sensor 425 It is assumed that a valid operation is detected by the touch sensor 425 even when the button is activated.

  For example, in the touch sensor effect process described with reference to FIG. 90, even when the operation is continuously detected by the touch sensor 425, the sub CPU 201 has the point value equal to or higher than the set value (S490). If it is a period during which the holding symbol is displayed (S491), the display of the effect after the touch when the effective operation is detected by the touch sensor 425 is set (S495).

[Big wins during the production control process]
In the following, the jackpot effect control process will be described with reference to FIGS. 92 and 93. For example, during the special game state, the jackpot inside effect control process is executed as one of the interrupt processes periodically executed by the sub CPU 201.

  First, in step S510 of FIG. 92, the sub CPU 201 determines whether or not a command indicating that the gaming ball has won a prize in the big winning opening 418 (hereinafter, also simply referred to as an "attacker") has been received. That is, the sub CPU 201 determines whether or not the attacker has won a prize.

  If it is determined that the attacker has won (YES), the sub CPU 201 executes the process of step S511. If it is determined that the attacker has not won (NO), the sub CPU 201 executes the process of step S512.

  In step S 511, the sub CPU 201 sets, in the work RAM 203, data of an effect (hereinafter, also simply referred to as “acquisition number display effect”) for adding the number of winning balls when the attacker has won a prize to the acquisition number.

  In addition, the number of acquisitions may be the number of acquisitions in the special gaming state, or may be the accumulated number of acquisitions in the special gaming state which is continued without being in a non-short time state. After executing the process of step S511, the sub CPU 201 executes the process of step S512.

  In step S512, the sub CPU 201 determines whether or not the number of special gaming states (hereinafter, also simply referred to as "big hit consecutive number") continued without being in a non-short state is equal to or more than a predetermined number (for example, 5 times). to decide.

  In step S512, the sub CPU 201 may determine whether or not the number of consecutive big hits is a predetermined number (for example, five), and the number of consecutive large hits is a multiple of a predetermined value (for example, five or ten). , 15 times etc.).

  If it is determined in step S512 that the number of consecutive big hits is equal to or greater than the predetermined number (YES), the sub CPU 201 executes the process of step S520. If it is determined that the number of consecutive big hits is not the predetermined number or more (NO), the sub CPU 201 executes the process of step S513.

  In step S513, the sub CPU 201 determines whether or not a command indicating that the gaming ball has won in the general winning opening 419d (hereinafter, also simply referred to as "other hole") has been received. That is, the sub CPU 201 determines whether or not there is a winning in the other hole.

  If it is determined that there is a prize in another hole (YES), the sub CPU 201 executes the processing of step S514. If it is determined that there is no winning in another hole (NO), the sub CPU 201 executes the processing of step S516.

  In step S514, the sub CPU 201 sets, in the work RAM 203, data of an effect (hereinafter simply referred to as "effect of other hole winning") when there is a winning in the other hole. For example, the sub CPU 201 works as data of an effect that causes the liquid crystal display device 50 to display an image in which a fairy brings a number indicating the number of prize balls when another hole is won as an effect of other hole winning. It sets to RAM203. After executing the process of step S514, the sub CPU 201 executes the process of step S515. In addition, as an effect of other hole winning, it may be an effect of any aspect as long as it is an effect that can notify that there is a winning in other holes, not only the above-mentioned effect.

  In step S515, the sub CPU 201 sets, in the work RAM 203, data of an acquisition number display effect in which the number of winning balls when there is a prize in another hole is added to the acquisition number. Note that the sub CPU 201 may not include the number of winning balls when the other hole has a prize in the number of winnings. In this case, the process of step S515 is omitted from the jackpot effect control process. After executing the process of step S515, the sub CPU 201 executes the process of step S516.

  In step S 516, the sub CPU 201 determines whether or not there is an overflow in which the number of gaming balls that have won in the attached game in each round game in the special gaming state is larger than a preset number.

  If it is determined that there is an overflow (YES), the sub CPU 201 executes the processing of step S517. If it is determined that there is no overflow (NO), the sub CPU 201 executes the process of step S518.

  In step S517, the sub CPU 201 sets an effect corresponding to the overflow (hereinafter, also simply referred to as "overflow effect"). After executing the process of step S517, the sub CPU 201 executes the process of step S518.

  In step S518, the sub CPU 201 determines whether an acquisition number flag indicating whether a condition for displaying the acquisition number is satisfied is one. If it is determined that the acquisition number flag is 1 (YES), the sub CPU 201 executes the processing of step S519. If it is determined that the acquisition number flag is not 1 (NO), the sub CPU 201 executes the processing of step S524 (FIG. 93).

  In step S519, the sub CPU 201 sets a display related to the number of acquisitions. After executing the process of step S519, the sub CPU 201 executes the process of step S524.

  In step S520, the sub CPU 201 determines whether the number of acquisitions exceeds a predetermined number (for example, 2600). If it is determined that the number of acquisitions exceeds the predetermined number (YES), the sub CPU 201 executes the processing of step S521. If it is determined that the acquired number does not exceed the predetermined number (NO), the sub CPU 201 executes the process of step S522.

  In step S521, the sub CPU 201 sets 1 to the acquisition number display flag. After executing the process of step S521, the sub CPU 201 executes the process of step S522.

  At step S522, the sub CPU 201 determines whether or not the big hit has ended. If it is determined that the jackpot has ended (YES), the sub CPU 201 executes the process of step S523. If it is determined that the big hit has not ended (NO), the sub CPU 201 executes the process of step S518.

  In step S523, the sub CPU 201 sets 0 to the acquisition number display flag. After executing the process of step S523, the sub CPU 201 executes the process of step S518.

  In step S 524 of FIG. 93, the sub CPU 201 determines whether or not to obtain an acquisition number display effect. Specifically, when the data of the acquisition number display effect is set in the work RAM 203, the sub CPU 201 determines that the acquisition number display effect is to be performed, and the data of the acquisition number display effect is set in the work RAM 203. If not, it is determined that the acquisition number display effect is not performed.

  If it is determined that the acquisition number display effect is to be performed (YES), the sub CPU 201 executes the processing of step S525, and if it is determined that the acquisition number display effect is not to be performed (NO), the sub CPU 201 performs the step The process of S526 is performed.

  In step S525, the sub CPU 201 sets the display priority of the layer displaying the image of the number-of-acquisitions display effect to 3. Here, the display priority indicates the position of a layer on the liquid crystal display device 50 on which an image relating to an effect is displayed. The display priority in the present embodiment decreases as the value increases.

  A layer with a high display priority is displayed in front, and a layer with a low display priority is displayed behind the layer with a high display priority. That is, although an image of a layer with a high display priority is not hidden by an image of a layer with a low display priority, an image of a layer with a low display priority is hidden by an image of a layer with a high display priority There is. After executing the process of step S525, the sub CPU 201 executes the process of step S526.

  In step S526, the sub CPU 201 determines whether or not the other hole winning effect is to be performed. Specifically, when the data of the effect of the other hole winning is set in the work RAM 203, the sub CPU 201 determines that the winning number display effect is to be performed, and the data of the effect of the other hole winning is set in the work RAM 203 If not, it is determined that the acquisition number display effect is not performed.

  If it is determined that the other hole winning effect is to be performed (YES), the sub CPU 201 executes the processing of step S527, and if it is determined that the other hole winning effect is not to be performed (NO), the sub CPU 201 , And execute the process of step S528.

  In step S 527, the sub CPU 201 sets the display priority of the layer displaying the effect of the other hole winning to 2. After executing the process of step S527, the sub CPU 201 executes the process of step S528.

  In step S528, the sub CPU 201 determines whether or not to perform the overflow effect. Specifically, the sub CPU 201 determines that the overflow representation is to be performed when the data of the overflow representation is set in the work RAM 203, and the overflow is determined when the data of the overflow representation is not set in the work RAM 203. I decide not to make a presentation.

  If it is determined that the overflow effect is to be performed (YES), the sub CPU 201 executes the processing of step S529, and if it is determined that the overflow effect is not to be performed (NO), the sub CPU 201 performs the big hit middle effect control process Finish.

  In step S527, the sub CPU 201 sets the display priority of the layer displaying the image of the overflow effect to 1. After executing the process of step S <b> 528, the sub CPU 201 ends the jackpot in-progress effect control process.

  As shown in FIG. 110, as for the image of the acquisition number display effect, as shown in (a), the image showing the state where the acquisition number is relatively small, and as shown in (b), the acquisition number is relatively A plurality of images are prepared according to the number of acquisitions, such as an image representing a large number of states. In the image of the acquisition number display effect shown in FIG. 110, as the acquisition number increases, the image representing the displayed character or the like increases.

  As an image of the effect of the other hole winning, a plurality of images are prepared as an example is shown in FIG. The image of the effect of the other hole winning shown in FIG. 111 includes an image showing the number of winning balls based on the other hole winning, and is displayed each time the other hole winning is detected.

  When an acquisition number display effect and an effect of other hole winning are executed, the sub CPU 201 is, as shown in FIG. 112, an image of the acquisition number display effect displayed in a layer having a relatively low display priority. On the other hand, it superimposes so that the image of the effect of the other hole winning combination displayed on the layer having a relatively high display priority is disposed on the front. Further, the sub CPU 201 superimposes an image representing the number of rounds and an image representing the number of winning balls based on the winning on the attacker.

  A plurality of images are prepared for the image of the overflow effect. As an example is shown in FIG. 113, the image of the overflow effect is displayed over substantially the entire display area in order to make it easy for the player to visually recognize that the overflow has occurred. Since the image of the overflow effect has the highest priority, the sub CPU 201 superimposes the image of the overflow effect on the front of the image of the other layer.

  As described above, the expressions “execution of effect” and “perform effect” are expressions that include the display of the effect and literally include the presence or absence of the execution of the effect.

[Change production selection table]
Hereinafter, the variation presentation selection table referred to by the sub CPU 201 in the pre-reading continuous presentation setting process shown in FIG. 86 will be described with reference to FIGS.

  The variation effect selection tables shown in FIGS. 94 and 95 are referred to in order to select the next notification effect as one of the effects selected by the sub CPU 201. FIG. 94 shows a table to be referred to when the selection (or lottery, determination) result of the special symbol for which the variable display is suspended does not include the probability variation big hit. FIG. 95 shows a table which is referred to when the selection (or lottery, determination) result of the special symbol for which the variable display is suspended includes the probability variation big hit.

  In the variation effect selection table shown in FIGS. 94 and 95, the effect pattern, the selection rate, and the variation effect pattern are associated with each other. Although the effect pattern is represented by EN00 to EN44 as shown in FIG. 77, in FIGS. 94 and 95, in order to make the invention easy to understand, it is shown by a combination of effect contents and winning types. There is. Moreover, in FIG. 94 and FIG. 95, the contents of the next notice effect are associated with the fluctuation effect pattern.

  For example, in FIG. 94, when the effect pattern is a special effect (special effect A to H) and the winning type is a loss type, the change effect pattern JY1 is selected at a selection rate of 50/100 and the change effect pattern JY2 is , And selection rate of 50/100, and the variation effect patterns JY3 to JY5 are not selected.

  Similarly, in FIG. 95, when the effect pattern is a special effect (special effect A to H) and the winning type is a probability change big hit, the change effect pattern JY1 is selected at a selection rate of 10/100, and the change effect pattern is selected. JY2 is selected at a selectivity of 40/100, variation effect pattern JY3 is selected at a selectivity of 20/100, variation effect pattern JY4 is selected at a selectivity of 20/100, variation effect pattern JY5 is , Selected at 10/100 selectivity.

  When the variation presentation pattern JY1 is selected, the next announcement presentation is not performed. When the variation presentation pattern JY2 is selected, the next announcement presentation is executed in the default mode. When the variation presentation pattern JY3 is selected, the next announcement presentation is performed in a mode in which a hit more than a small hit is notified. When the fluctuation effect pattern JY4 is selected, the next advance notice effect is usually executed in a mode of notifying a hit that is larger than the big hit. When the variation presentation pattern JY5 is selected, the next announcement presentation is performed in a manner to notify the probability variation big hit.

  In addition, since it is determined from the effect near the end of change basically when it is performed in the order of the effect selected by other effects such as a look-ahead system, the change effect pattern, and the effect pattern for the change of 1 After the presentation pattern is determined, the variation presentation pattern is determined. Therefore, in the variation presentation selection table, the selection ratio of the variation presentation pattern is associated in accordance with the presentation pattern.

  The execution period of the variation presentation pattern may include the execution period of other presentation such as a look-ahead system. In addition, the fluctuation presentation pattern may be simultaneously executed as long as it is before the time when the presentation selected by the presentation pattern is executed.

[After touch item selection table]
Hereinafter, the after-touch item selection table referred to by the sub CPU 201 in the pre-reading continuous effect setting process shown in FIG. 86 will be described with reference to FIG.

  The post-touch item selection table is referred to by the sub CPU 201 when a valid operation of the touch sensor 425 is detected. In the after-touch item selection table shown in FIG. 96, the effect pattern, the change effect pattern, the selection rate, and the after-touch item pattern (the reserved symbol displayed on the liquid crystal display device 50 after the touch) are associated. In FIG. 96, in order to make the invention easy to understand, the contents are associated with the item pattern after touch.

  For example, in FIG. 96, when the effect pattern is EN42 and the variation effect pattern is JY2, the after-touch item pattern TA1 is selected at a selection rate of 10/100, and the after-touch item pattern TA2 is 20/100. After selection, the item pattern TA3 after touch is selected at a selection rate of 10/100, after item pattern TA4 after touch is selected at a selection ratio of 40/100, and after item pattern TA5 after touch is 20 / It is selected at a selectivity of 100.

  If the item pattern TA1 after touch is selected, the default "Hold on white" is displayed. When the item pattern TA2 after touch is selected, “sword hold” of the color determined in the pre-reading continuous effect setting process is displayed. When the item pattern TA3 after touch is selected, a "sword hold" with a rainbow pattern, which is a hit notification of a jackpot or more, is displayed.

  When the item pattern TA4 after touch is selected, a default white "next notice pending" is displayed. When the item pattern TA5 after touch is selected, a "next advance notice hold" of a rainbow pattern notifying of the probability variation big hit is displayed.

[Pre-touch item selection table]
Hereinafter, the pre-touch item selection table to be referred to by the sub CPU 201 in the pre-reading continuous effect setting process shown in FIG. 86 will be described with reference to FIG.

  The pre-touch item selection table is referred to by the sub CPU 201 when selecting an item pattern that can be changed to a post-touch item when a valid operation of the touch sensor 425 is detected.

  In the pre-touch item selection table shown in FIG. 97, the effect pattern, the post-touch item pattern, the selection rate, and the pre-touch item pattern (displayed on the liquid crystal display device 50 before the effective operation of the touch sensor 425 is detected) Symbol) are associated with each other.

  Although the effect pattern is represented by EN00 to EN44 as shown in FIG. 77, in FIG. 97, in order to make the invention easy to understand, it is collectively shown by the winning types. Moreover, the content is matched with the item pattern before a touch.

  For example, in FIG. 97, when the effect pattern corresponds to a big hit and the item pattern after touch is TA3, the item pattern before touch TB1 is selected at a selection rate of 10/100, and the item pattern before touch TB2 is 10, The item pattern TB3 is selected at a selection rate of / 100, the item pattern TB3 before touch is selected at a selection rate of 40/100, and the item pattern TB4 before touch is selected at a selection rate of 60/100.

  When the pre-touch item pattern TB1 is selected, “black treasure chest hold” is displayed. When the pre-touch item pattern TB2 is selected, “tree treasure chest hold” is displayed. When the pre-touch item pattern TB3 is selected, “silver treasure chest hold” is displayed. When the pre-touch item pattern TB4 is selected, "Hold on treasure chest" is displayed.

[Pre-read continuous effect table]
The prefetch continuous effect table referred to by the sub CPU 201 in the prefetch continuous effect setting process shown in FIG. 87 will be described below with reference to FIG.

  In the pre-read continuous effect table shown in FIG. 98, the effect pattern, the number of held items, the selection rate, and the effect content (scenario) are associated. The effect pattern is represented by EN00 to EN44 as shown in FIG. 77. However, in FIG. 98, in order to make the invention easy to understand, it is collectively shown by the winning classification (loss / hit). The contents of the effect include information indicating each effect for the hold 1 to the hold 3.

  For example, in FIG. 98, when the number of holdings is 3, there is a starting opening winning corresponding to the fourth holding symbol, and 50/50 if the variation display of the special symbol display device 431 for this starting opening winning becomes a hit. "Blue", "Blue" and "None" are selected at 100 selectivity, "Blue", "Red" and "Red" are selected at 25/100 selectivity, "25/100" "Red", "Red" and "rainbow" are selected.

  In the previously read-out effect table shown in FIG. 98, when the variable display of special symbol display device 431 is lost, effects including "rainbow" are not selected, so effects including "rainbow" are It will be the effect of informing the hit.

[The latent probability change notification table]
Hereinafter, the latency probability change notification table referred to by the sub CPU 201 in the out-of-entry ball presentation processing shown in FIG. 88 will be described with reference to FIG. In the prefetch latency probability change notification table shown in FIG. 99, the gaming state, the selection rate, and the effect content are associated. The game state is identified by whether or not it is latent certainty ("latent certainty" in the figure).

  For example, in FIG. 99, if the gaming state is a latent probability change, an effect of white lighting one character (not shown) on the board is selected at a selection rate of 25/100, and a selection rate of 25/100 is selected. The effect of white lighting two letters of the board is selected, and the effect of lighting three letters of the board blue is selected at a selection rate of 25/100, and the letter of the board is four characters at a selection rate of 25/100. An effect that lights up in red is selected.

  In the pre-reading latency definite change notification table shown in FIG. 99, if the game state is not a definite condition change, an effect to turn on four characters on the board is not selected, so the four characters on the board are turned on red. The effect to be given is an effect to notify that the gaming state is latent probability change.

[Pending system notification production selection table]
Hereinafter, the on-hold notification generation effect selection table referred to by the sub CPU 201 in the out-of-the-entry ball effect processing shown in FIG. 88 will be described with reference to FIG. In the prefetch latency definite change notification table shown in FIG. 100, the presence or absence of the jackpot in the hold (the selection (or lottery, determination) result of the special symbol for which the variable display is held), the selection rate, and the special game transition suggestion effect The effect content is associated.

  For example, in FIG. 100, if there is a big hit in the hold, the first special game transition suggestion effect is selected, where the shutter (not shown) incorporated in the effect button 16 moves with a selection rate of 50/100, 50 The shutter built in the production button 16 is fully opened for a time longer than the execution time of the first special game transition suggestion effect at a selection rate of / 100, and the LED group 18 provided on the back side of the shutter is rainbow-like The second special game shift suggestion effect to emit light is selected.

  In the pre-reading latency certainty change notification table shown in FIG. 100, if there is no big hit in the hold state, the second special game transition suggestion effect is not selected. For this reason, the second special game shift suggestion effect is an effect that notifies that there is a big hit in the hold.

[Specific example of preview advance notice effect setting process]
In the following, a specific example of the pre-read advance notice effect setting process described with reference to FIG. 86 will be described with reference to FIG.

  As shown in the display state (a), when the default hold symbol (white blink hold) is displayed, and there is a starting opening winning, the touch point (point value) must be MAX (set value). For example, in step S445 of FIG. 86, the treasure box holding symbol selected based on the before-touch item selection table shown in FIG. 97 is displayed as shown in the display state (b).

  As shown in the display state (a), in the state where the default holding symbol (white blinking hold) is displayed, if there is a winning opening winning, if the touch point is MAX, in step S445 in FIG. 86. The treasure box holding symbol selected based on the pre-touch item selection table shown in FIG. 97 is displayed with the touch icon as shown in the display state (c).

  As shown in the display state (b), when the touch box becomes MAX while the treasure box hold symbol without the touch icon is displayed, the treasure box hold symbol (pre-touch item) is the treasure box hold with the touch icon. It is changed to the design.

  In the state shown in the display state (c), when a valid operation of the touch sensor 425 is detected in the step S493 in FIG. 90, as shown in the display state (d) in the step S495 in FIG. After the area where is displayed is hidden by the concealed image, as shown in the display state (e), the display of the effect that the area where the reserved symbol is displayed appears is set.

  When the area in which the holding symbol is displayed appears, the treasure box holding symbol with the touch icon is changed to another holding symbol (post-touch item) based on the after-touch item selection table shown in FIG. 96. .

  For example, in FIG. 96, if the effect pattern is EN06, the change effect pattern is JY1, and the item pattern after touch is TA2, the treasure box with a touch icon with a touch icon appears when the area where the hold symbol is displayed appears , Has been changed to "sword hold" such as blue.

  In the present embodiment, a plurality of holding symbols do not become treasure box holding symbols. That is, in the state where the treasure box holding symbol is displayed, when there is a starting opening winning combination, the holding symbol for the starting opening winning combination is defaulted.

  In addition, when there is a starting opening prize during the fluctuation that will be hit, the holding symbol for the starting opening winning may be a treasure box holding symbol, but this treasure box holding symbol stops the fluctuation becoming a hitting It is changed to the default holding symbol when it shifts to the special game state.

  In the state where the area where the reserved symbol is displayed is hidden by the concealed image, prepare a layer in which the concealed image is drawn in front of the layer where the reserved symbol is drawn, and the layer where the concealed image is drawn It may be realized by changing from the non-display state to the display state, and the concealed image may be drawn in the area where the reserved symbol is displayed.

  In other words, when "Hiding" a holding symbol or "Hiding" a holding symbol, it is expressed as "Hiding" in terms of processing even if an image is displayed instead of the holding symbol as it looks. In some cases, when the image is "hidden", the image may be displayed in place of the reserved symbol.

[Specific example of pre-reading continuous effect setting processing]
Hereinafter, a specific example of the pre-read continuous effect setting process described with reference to FIG. 87 will be described with reference to FIG. 102 and FIG.

  First, with reference to FIG. 102, a simple specific example of the pre-read continuous effect setting process will be described. In this specific example, the decorative symbols are "1" to "9", the colors of the symbols "1" and "9" are "green", "2", "4", "6" and " The color of the pattern of 8 "is" blue ", and the color of the symbols of" 3 "," 5 "and" 7 "is" red ".

  When, in step S460 in FIG. 87, for example, “blue”, “blue”, and “none” are selected from the pre-read continuous effect table shown in FIG. 98 as the pre-read continuous effect for the fourth hold In addition, as shown in (F11), at the end of the change with respect to hold 1, “2 · 4 · 8” in which the color of each symbol is blue is stopped and displayed, and the liquid crystal display 50 or the LED group 18 is used. The blue effect is executed.

  Subsequently, as shown in (F12), at the end of the change with respect to the hold 2, "4 · 6 · 8" in which the color of each symbol is blue is stopped and displayed, and the liquid crystal display 50 or the LED group 18 etc. The blue effect is executed.

  Subsequently, as shown in (F13), at the end of the change with respect to the hold 3, “4 · 5 · 8” in which the colors of the respective symbols are not uniform is stopped and displayed, and by the liquid crystal display device 50 or the LED group 18 etc. The effect is not executed.

  Next, with reference to FIG. 103, a specific example in the case where the scenario of the pre-reading continuous effect setting process is duplicated will be described. When, in step S460 in FIG. 87, for example, “blue”, “blue”, and “none” are selected from the pre-read continuous effect table shown in FIG. 98 as the pre-read continuous effect for the fourth hold In addition, as shown in (F21), at the end of the change to hold 1, “2 · 4 · 8” in which the color of each symbol is blue is stopped and displayed, and the liquid crystal display 50 or the LED group 18 is used. The blue effect is executed.

  Here, it is assumed that there is a starting hole winning during the fluctuation shown in (F21), and the number of held pieces is four. As pre-reading continuous rendition according to this starting opening winning a prize, as shown in (P1) from the pre-reading continuous rendition table shown in FIG. 98 in step S460 of FIG. 87, “red”, “red” and “rainbow” Suppose that the contents of presentation are selected. At this time, as shown in (P2), the effect that has already been set remains for one fluctuation. In addition, "none" of the contents of the effect is not the effect set.

  For this reason, in step S464 in FIG. 87, the effect content for the hold 2 and subsequent is set as a new effect content excluding the effect (the effect for the hold 1) for the first variation from the effect content shown in (P1) As a result, as shown in (P3), the effect contents of "blue", "red", and "rainbow" are set.

  As a result, as shown in (F22), at the end of the change to hold 1 in (P3), “4 · 6 · 8” in which the color of each symbol is blue is stopped and displayed, and the liquid crystal display device 50 or LED A blue effect is performed, such as by group 18.

  Subsequently, as shown in (F22), at the end of the change with respect to hold 2 in (P3), “3 · 5 · 7” in which the color of each symbol is red is stopped and displayed, and the liquid crystal display device 50 or LED A red effect is performed, such as by group 18.

  Subsequently, as shown in (F23), at the end of the change with respect to hold 3 in (P3), “3 · 7 · 7” in which the color of each symbol is red is stopped and displayed, and the liquid crystal display device 50 or LED A rainbow effect is performed by group 18 or the like.

  In addition, although the specific example of the prefetch continuation production setting process mentioned above demonstrated the example which performs presentation based on the effect content of the prefetch continuation presentation table at the time of completion | finish of a fluctuation | variation, the prediction continuation production table at the time of a fluctuation start or during fluctuation. An effect based on the effect content of may be executed.

[Modification of pre-reading continuous effect setting process]
Although the pre-read continuous effect setting process in the present embodiment is described as setting the effects for the hold 1 to hold 3 described above, the fluctuation during execution (hereinafter also referred to as “hold 0”) And hold 4 may be set.

  In this case, the pre-read continuous effect table shown in FIG. 98 is changed as shown in FIG. In the pre-read continuous effect table shown in FIG. 104, the effect pattern, the number of held items, the selection rate, and the effect content (scenario) are associated. The effect pattern is represented by EN00 to EN44 as shown in FIG. 77. However, in FIG. 98, in order to make the invention easy to understand, it is collectively shown by the winning classification (loss / hit). The contents of the effect include information representing each effect for the hold 0 to hold 4.

  For example, in FIG. 104, when the number of holdings is 3, there is a starting opening winning corresponding to the fourth holding symbol, and 50/50 if the variation display of the special symbol display device 431 for this starting opening winning becomes a hit. "None", "Blue", "Blue", "None", "None" are selected at 100 selectivity, and "Blue", "Blue", "Blue", "Red" at 25/100 selectivity , "Red" is selected, and "red", "red", "red", "rainbow", and "rainbow" are selected at a selection rate of 25/100.

  In the pre-read continuous effect table shown in FIG. 104, when the variable display of the special symbol display device 431 corresponding to the holding symbol is lost, effects including “rainbow” are not selected. The effect including the rainbow is the effect of informing the hit.

  With reference to FIG. 105, a simple specific example of a modification of the pre-reading continuous effect setting process will be described. In the pre-read continuous effect table shown in FIG. 104, for example, as the pre-read continuous effect for the fourth hold, the effect contents of “none”, “blue”, “blue”, “none”, and “none” are selected In this case, as shown in (F31), at the end of the variation corresponding to the first "None", "2 · 3 · 2" in which the colors of the respective symbols are not aligned is stopped and displayed, and the liquid crystal display device 50 The effect by the LED group 18 or the like is not executed.

  Subsequently, as shown in (F32), at the end of the fluctuation with respect to the hold 1, “2 · 4 · 8” in which the color of each symbol is blue is stopped and displayed, and by the liquid crystal display device 50 or the LED group 18 etc. The blue effect is executed.

  Subsequently, as shown in (F33), at the end of the change with respect to the hold 2, "4 · 6 · 8" in which the color of each symbol is blue is stopped and displayed, and by the liquid crystal display device 50 or the LED group 18 etc. The blue effect is executed.

  Subsequently, as shown in (F34), at the end of the change with respect to the hold 3, “4 · 5 · 8” in which the colors of the respective symbols are not uniform is stopped and displayed, and by the liquid crystal display device 50 or the LED group 18 etc. The effect is not executed.

  Subsequently, as shown in (F35), at the end of the change with respect to the hold 4, “3 · 5 · 8” in which the colors of the respective symbols are not uniform is stopped and displayed, and the liquid crystal display 50 or the LED group 18 is used. The effect is not executed.

  Next, with reference to FIG. 106 and FIG. 107, a specific example in the case where the scenario of the pre-reading continuous effect setting process is duplicated will be described. As shown in FIG. 106, in the pre-read continuous effect table shown in FIG. 104, for example, as a pre-read continuous effect for the fourth hold corresponding to the changing start opening winning, "none", "blue", "blue" When the effect contents of “None” and “None” are selected, as shown in (F41), the colors of the respective symbols are not aligned at the end of the change with respect to the hold 0 (during variation). While “3 · 2” is stopped and displayed, the effect by the liquid crystal display device 50 or the LED group 18 is not executed.

  Subsequently, as shown in (F42), at the end of the fluctuation with respect to the hold 1, “2 · 4 · 8” in which the color of each symbol is blue is stopped and displayed, and by the liquid crystal display device 50 or the LED group 18 etc. The blue effect is executed.

  Subsequently, it is assumed that there is a starting hole winning during the fluctuation shown in (F43), and the number of held pieces becomes 3. It is assumed that the contents of effects of “red”, “red”, “rainbow”, “rainbow”, and “none” are selected as pre-read continuous effects corresponding to the start-up winning as shown in (P11). At this time, as shown in (P12), the effect that has already been set remains for one fluctuation.

  For this reason, as the new effect content excluding the effect (the effect for pending 0) of the first one fluctuation from the effect content shown in (P12), the effect content for pending 1 and subsequent is set, and as a result, (P13) As shown in, the contents of effects of "blue", "red", "rainbow", "rainbow" and "none" are set.

  As a result, as shown in (F43), at the end of fluctuation with respect to reservation 0 (during fluctuation) in (P13), “4 · 6 · 8” in which the color of each symbol is blue is stopped and displayed, and the liquid crystal display A blue effect is performed by the device 50, the LED group 18, and the like.

  Subsequently, as shown in (F44), at the end of the change with respect to hold 1 in (P13), “3 · 5 · 7” in which the color of each symbol is red is stopped and displayed, and the liquid crystal display device 50 or LED A red effect is performed, such as by group 18.

  Subsequently, as shown in (F45), at the end of the change with respect to hold 2 in (P13), “3 · 7 · 7” in which the color of each symbol is red is stopped and displayed, and the liquid crystal display device 50 or LED A rainbow effect is performed by group 18 or the like.

  Subsequently, as shown in (F46), at the end of the change with respect to hold 3 in (P13), “7 · 7 · 7” in which the color of each symbol is red is stopped and displayed, and the liquid crystal display device 50 or LED A rainbow effect is performed by group 18 or the like.

Cancel pre-reading
When the gaming state is the time saving state, as described below, the sub CPU 201 may cancel the pre-reading continuous effect. Specifically, when the gaming state is the short time state, the sub CPU 201 produces effects to the change in progress (hold 0) and all the changes in the special symbol held (hold 1 to hold 3). If it does not occur, the setting of the pre-reading continuous effect may be prohibited or the setting of the pre-reading continuous effect may be canceled.

  For example, as shown in FIG. 108, when the effects are continuous from hold 0 to hold 3, the sub CPU 201 permits setting of the pre-reading continuous effect or maintains the set pre-reading continuous effect.

  Further, as shown in FIG. 109, when there is no effect on hold 2 or later, the sub CPU 201 prohibits setting of the pre-reading continuous effect at the start of fluctuation corresponding to the hold 2 or pre-read continuous effect set. Cancel.

  Further, as shown in FIG. 109, when there is no effect on hold 2 or later, the sub CPU 201 can set the prefetch effect as the non-prefetching of the setting of the pre-reading continuous effect at the start of fluctuation corresponding to the hold 2 Control is also possible.

  By configuring in this manner, in the present embodiment, when the gaming state is the short time state, the pre-reading continuous effect is executed only when the effect is continuous, so the player's expectation for the pre-reading continuous effect Be able to get higher. That is, according to the present embodiment, the player's confidence with respect to the preread sequential effect can be increased by not executing the preread continuous effect that is unlikely to include the variation of the hit.

  In the pre-read continuous effect described above, in the present embodiment, it is assumed that one step (blue → green) change (reliability change) is normally performed, but in the case of a big hit, there are two steps ( Control may be performed to select a rendering scenario that changes blue to red. However, if effects are combined (when (blue → green → none → none) is selected, (eg when blue → green → red → red) is selected), there are two steps, even in the case of a loss An effect may be performed.

  In addition, when the stage of the production is lowered (when (blue → green → red → red) is selected, (eg when blue → blue → blue → blue) is selected), the reliability of the production is lowered. Control may be performed so as not to change (a place where the effect to be finally performed is (blue → green → blue → blue) is changed to (blue → green → red → red)). In addition, when it becomes a production | presentation aspect to which the reliability of a production | presentation falls, you may control to cancel | release the production | presentation determined behind.

  As described above, the pachinko gaming machine 1 according to the present embodiment assumes that the touch point MAX effect is executed as the effect transition condition, and the treasure box holding symbol is the treasure box holding symbol with the touch icon. When it is determined that the touch point MAX effect is to be executed, the touch point MAX effect is executed by using the next change of the symbol displayed on the special symbol display device 431 as a trigger point. After executing the MAX effect, secure the state that can execute the treasure box holding symbol transition effect. Therefore, the gaming machine according to the present invention can smoothly execute the effect without adjusting the effect.

  In addition, the pachinko gaming machine 1 of the present embodiment executes the effect that the treasure box holding symbol with the touch icon is displayed when it is determined to execute the effect that the treasure box holding symbol is displayed in the state where the touch point is MAX. When the touch point is MAX while the treasure box hold symbol is displayed, the touch point MAX effect and the treasure box hold symbol with the touch icon are displayed to execute the treasure box hold symbol transition effect. And can be performed smoothly.

  Further, the pachinko gaming machine 1 according to the present embodiment executes the treasure box holding symbol transition effect with the effect of the touch point MAX effect as the effect transition condition, and when it is determined that the touch point MAX effect is executed, symbol display If it is determined that the touch point MAX effect can not be performed by the variation pattern of the symbol displayed on the means and the pattern of the effect, the next variation of the symbol displayed on the special symbol display device 431 is to be started By executing the touch point MAX effect as a trigger, after the touch point MAX effect is performed, the state of executing the treasure box holding symbol transition effect is secured. Therefore, the gaming machine according to the present invention can smoothly execute the effect without adjusting the effect.

  In addition, the pachinko gaming machine 1 of the present embodiment is touched before the touch item which is executed when the operation of the touch sensor 425 is detected within a predetermined effective period after the treasure box holding symbol transition effect is executed. The operation for touch sensor 425 is performed earlier than the effective period, since the item transition effect to be the rear item is executed with the operation of touch sensor 425 also being detected as the effective period. Also, perform the item transition effect. Therefore, the gaming machine according to the present invention can prevent the player's interest in the effects from being reduced by reliably performing the item transition effect.

  In particular, since the pachinko gaming machine 1 according to the present embodiment detects the operation of the touch sensor 425, the item transition effect can be prevented from being stopped by the detection of the touch sensor 425 not intended by the player.

  In addition, the pachinko gaming machine 1 of the present embodiment may be suspended for transitioning to the special gaming state on hold, upon detection of a gaming medium passing through the second special out port 420c in the special gaming state. Perform special game transition suggestion effect that suggests.

  Therefore, the gaming machine according to the present invention does not give the player the impression of being forced to play a game by the progress of the game by the player in the special game state also serving as the effect, so the player's interest in the game Can be prevented from falling.

  In addition, since the pachinko gaming machine 1 of the present embodiment suggests the probability that there is a suspension of transitioning to the special gaming state during suspension, it can improve the player's interest in the game.

  Further, in the pachinko gaming machine 1 of the present embodiment, when the staging mode of the preview continuous staging is determined, if the staging mode other than "none" is not decided for the same hold, the staging mode determined. In order to set for the corresponding fluctuation, it is possible to execute effective rendering utilizing the determined rendering mode and the determined rendering mode, and it is possible to improve the player's interest in the rendering.

  In addition, the pachinko gaming machine 1 of the present embodiment gives priority to a plurality of types of effects to be executed in the special gaming state and executes them, thereby facilitating the player with the contents represented by the effects. Therefore, it is possible to prevent a decrease in the player's interest in the game.

  Further, the pachinko gaming machine 1 of the present embodiment does not execute a specific effect depending on the state of the special game state, or does not execute part of the special game state, or the effect in the special game state. Since the patterns are diversified, it is possible to prevent the player's interest in the game from being reduced.

  In addition, the pachinko gaming machine 1 of the present embodiment has effect data to be referred to when executing 1P effect or touch point MAX effect with respect to a variation pattern of 1 of a symbol displayed on the special symbol display device 431. The 1P effect or the touch point MAX effect is stored in the program ROM 202.

  Therefore, in the pachinko gaming machine 1 of the present embodiment, if the variation pattern of the symbol displayed on the special symbol display device 431 is determined, 1P based on the effect data stored in the program ROM 202 corresponding to the variation pattern of the symbol. Since the effect or the touch point MAX effect can be executed, the 1P effect and the touch point MAX effect can be smoothly executed.

Third Embodiment
The third embodiment of the present invention will be described below. In the third embodiment of the present invention, differences from the above-described second embodiment of the present invention will be described, and descriptions of the same points as the second embodiment of the present invention will be made. I omit it.

  The third embodiment of the present invention is a non-game including a state where a demonstration effect is being performed, for example, a state where a demonstration screen is displayed on the liquid crystal display device 50 (hereinafter, also simply referred to as “during demonstration”). When the operation of the touch sensor 425 is detected in the state, an effect is performed.

  The non-playing state refers to a state in which the player has stopped playing the game. Instead of determining whether or not the game is in the non-playing state based on whether or not the sub CPU 201 is in a demo, based on the detection values of the various sensors described above or the command received from the main control circuit 100, etc. It can be determined that the player has stopped playing the game.

  For example, the sub CPU 201 may determine that it is in the non-playing state when the state in which the special symbol does not change in a state other than the special gaming state continues for a predetermined time or more, and in the state other than the special gaming state When the state in which the symbol does not change continues for a predetermined time or more, it may be determined to be in the non-playing state.

[Touch sensor effect processing]
The touch sensor effect process according to the present embodiment will be described with reference to FIG. Although the detection range of touch sensor 425 (the effective distance of touch sensor 425 and the effective range) is always constant, the detection range may be varied according to the effect.

  First, in step S600, the sub CPU 201 determines whether the touch point is MAX, that is, whether the point value is equal to or greater than the set value. If it is determined that the point value is equal to or greater than the set value (YES), the sub CPU 201 executes the process of step S601. If it is determined that the point value is not the set value or more (NO), the sub CPU 201 ends the touch sensor effect process.

  In step S601, the sub CPU 201 determines whether or not it is a period in which the holding symbol is displayed on the liquid crystal display device 50. If it is determined that it is a period in which the held symbol is displayed (YES), the sub CPU 201 executes the process of step S603. If it is determined that it is not a period in which the holding symbol is displayed (NO), the sub CPU 201 executes the process of step S602.

  In step S602, the sub CPU 201 determines whether a demo is in progress. If it is determined that a demo is being performed (YES), the sub CPU 201 executes the processing of step S603. If it is determined that the demonstration is not in progress (NO), the touch sensor effect process is ended.

  In step S603, the sub CPU 201 sets 1 to the touch sensor activation flag. After executing the process of step S603, the sub CPU 201 executes the process of step S604.

  In step S604, the sub CPU 201 determines whether the operation detection flag is one. If it is determined that the operation detection flag is 1 (YES), the sub CPU 201 executes the process of step S605. If it is determined that the operation detection flag is not 1 (NO), the sub CPU 201 ends the touch sensor effect process.

  In step S605, the sub CPU 201 sets 0 in the touch sensor activation flag. After executing the process of step S605, the sub CPU 201 executes the process of step S606.

  In step S606, the sub CPU 201 determines whether a demonstration is in progress. If it is determined that a demo is being performed (YES), the sub CPU 201 executes the process of step S608. If it is determined that the demo is not underway (NO), the sub CPU 201 executes the process of step S607.

  In step S 607, the sub CPU 201 refers to the touch concealment concealed image selection table shown in FIG. 115, and indicates whether or not the variation corresponding to the suspension symbol with the treasure box suspension symbol displayed is a big hit, and stage information indicating the effect stage And a hidden image (see FIG. 101) based on the item after touch. After executing the process of step S607, the sub CPU 201 executes the process of step S608.

  In step S 607, the sub CPU 201 sets the display of the effect after the touch in which the valid operation has been detected by the touch sensor 425. For example, if the sub CPU 201 is not under demonstration, it changes the holding symbol before touching displayed on the liquid crystal display device 50 to the holding symbol after touching, and if during demonstration and the gaming state is the latent probability variation, FIG. 116 With reference to the latent notification notification effect selection table shown in, the effect which suggests that the gaming state is the latent probability change is set.

  In step S607, the sub CPU 201 sets the effect to indicate that the gaming state is the latent probability change during the demonstration, and the selection rate is different depending on whether the gaming state is the latent probability change or not. An effect may be set. After executing the process of step S608, the sub CPU 201 executes the process of step S609.

  In step S609, the sub CPU 201 subtracts the setting value from the point value. After executing the process of step S609, the sub CPU 201 ends the touch sensor effect process.

[On-hold hiding image selection table]
Hereinafter, the on-touch suspension hiding image selection table referred to by the sub CPU 201 in the touch sensor effect process shown in FIG. 114 will be described with reference to FIG.

  The touch hold concealment image selection table shown in FIG. 115 is referred to in order to select a concealment image (see FIG. 101) selected by the sub CPU 201. In the on-touch suspension hiding image selection table shown in FIG. 115, the effect pattern, the after-touch item pattern, the stage information, the selection rate, and the effect content are associated.

  Although the effect pattern is represented by EN00 to EN44 as shown in FIG. 77, in FIG. 115, in order to make the invention easy to understand, it is collectively shown by the winning classification (other than the big hit / big hit). .

  Further, although the item patterns after touch are TA1 to TA5 (see FIG. 96), only TA4 is illustrated, and other item patterns after touch are omitted. The presentation content includes information representing a hidden image.

  For example, in FIG. 115, when the effect pattern is a big hit, the item pattern after touch is TA4, and the stage is “Choy heat stage”, the selection rate of 20/100 is commonly used in each stage. A possible concealed image is selected, a concealed image dedicated to each stage is selected with a selectivity of 60/100, and an concealed image that reports a big hit or more that can be commonly used in each stage with a selectivity of 10/100 Is selected, and a concealed image notifying of a jackpot or more dedicated to each stage is selected with a selectivity of 10/100.

  Although the hidden image in the present embodiment is described as being selected at each selection rate, it is uniquely selected by the combination of the effect before change (item before touch) and the effect after change (item after touch) It may be done.

[Title notification information selection table]
Hereinafter, a latent notification notification effect selection table referred to by the sub CPU 201 in the touch sensor effect process shown in FIG. 114 will be described with reference to FIG.

  In the latent notification notification effect selection table shown in FIG. 116, point values, selection rates, and effect contents are associated. For example, if the point value is "5" or less, "None" is selected at a selectivity of 30/100, "Hat probability 50%" is selected at a selectivity of 20/100, and a selectivity of 10/100 The “probability of 80%” is selected, and the “probability of 100%” is selected at a selectivity of 40/100. If the point value is “6” or more, “none” is selected at a selectivity of 30/100, and “latency probability 77%” is selected at a selectivity of 70/100.

  In the latency notification effect selection table shown in FIG. 116, when anything other than "none" is selected, there is a notification effect in which it is determined that the gaming state is the latency probability change, but the gaming state is not the latency probability change Also in the case, by making the sub CPU 201 refer to a table different in selection rate similar to the latency notification notification effect selection table shown in FIG. 116 to the sub CPU 201, the sub CPU 201 executes the effect that suggests the possibility that the gaming state is the latent probability change. You may do so.

  As described above, even if the pachinko gaming machine 1 of this embodiment is in the non-playing state where the player has stopped playing the game, it is in a state where the execution condition of the treasure box holding symbol transition effect is established. For example, by performing the operation of the touch sensor 425, an effect that suggests the possibility that the gaming state is latent may be performed, so that the player's interest in the effect can be improved.

  In addition, even if the pachinko gaming machine 1 of the present embodiment is in the non-playing state, if the touch point is MAX, the game state may be latently probable by the operation of the touch sensor 425 being performed. In order to carry out the suggestion that suggests that, it is possible to improve the player's interest in the presentation.

Fourth Embodiment
The fourth embodiment of the present invention will be described below. In the fourth embodiment of the present invention, differences from the above-described second embodiment of the present invention will be described, and descriptions of the same points as the first embodiment of the present invention will be made. I omit it.

  In the second embodiment of the present invention, the upper limit value equal to the set value is defined as the point value, but in the present embodiment, the point value is added beyond the upper limit value (set value). It can be done.

[Point giving effect setting process]
Hereinafter, the point provision effect setting process according to the present embodiment will be described with reference to FIGS. 117 and 118.

  First, in step S620 in FIG. 117, the sub CPU 201 determines whether or not a variation pattern designation command has been received. If it is determined that the fluctuation pattern designation command has been received (YES), the sub CPU 201 executes the processing of step S621. If it is determined that the fluctuation pattern designation command has not been received (NO), the sub CPU 201 executes the processing of step S629 (FIG. 118).

  In step S621, the sub CPU 201 determines whether the touch point MAX effect flag is one. If it is determined in step S621 that the touch point MAX effect flag is 1 (YES), the sub CPU 201 executes the processing of step S622. If it is determined that the touch point MAX effect flag is not 1 (NO), the sub CPU 201 executes the process of step S625.

  In step S 622, the sub CPU 201 determines whether the variation is 5.0 seconds (the variation pattern is HN 00 (see FIG. 75)) and whether there is a stage change. If it is determined that the fluctuation is 5.0 seconds and there is a stage change (YES), the sub CPU 201 executes the processing of step S628. If it is determined that the change is not a change for 5.0 seconds or there is no stage change (NO), the sub CPU 201 executes the process of step S623.

  In step S623, the sub CPU 201 selects a variation effect whose touch point is MAX. After executing the process of step S623, the sub CPU 201 executes the process of step S624.

  In step S624, the sub CPU 201 sets the touch point MAX effect flag to 0. After executing the process of step S624, the sub CPU 201 executes the process of step S626.

  In step S625, the sub CPU 201 selects, based on the variation pattern and various effects, whether or not to execute 1P effect in which 1 is added to the touch point. Here, if it is determined that the 1P effect is to be executed, the sub CPU 201 adds 1 to the touch point to select the 1P effect that can be executed as the variation effect. After executing the process of step S625, the sub CPU 201 executes the process of step S626.

  In step S626, the sub CPU 201 determines whether the touch point exceeds MAX (MAX point). If it is determined that the touch point exceeds the MAX point (YES), the sub CPU 201 executes the process of step S627. If it is determined that the touch point does not exceed the MAX point (NO), the sub CPU 201 executes the process of step S628.

  In step S627, the sub CPU 201 sets 1 to the special effect flag. Here, the special effect flag (for example, the touch point when the current touch point exceeds a set value (for example, 5 points in the embodiment, a value determined as the upper limit, a value sufficient to execute the effect, etc.) To promote the operation of the touch sensor 425 or the effect of informing the extent to which the touch point exceeds the set value, for example, when 1 is added to the touch point in a state where is 5 points Represents whether or not to execute After executing the process of step S627, the sub CPU 201 ends the point provision effect setting process.

  In step S628, the sub CPU 201 selects another variation effect. Here, the sub CPU 201 executes the same process as step S427 in the point provision effect setting process described with reference to FIGS. 84 and 85. After executing the process of step S628, the sub CPU 201 ends the point provision effect setting process.

  In step S629 shown in FIG. 118, the sub CPU 201 determines whether or not the pre-reading advance notice determination command has been received. If it is determined that the pre-reading advance notice determination command has been received (YES), the sub CPU 201 executes the process of step S630. If it is determined that the pre-reading advance notice determination command has not been received (NO), the sub CPU 201 ends the point provision effect setting process.

  In step S630, the sub CPU 201 determines whether 1 is set in the touch point MAX effect flag. If it is determined that the touch point MAX effect flag is set to 1 (YES), the sub CPU 201 executes the process of step S631. If it is determined that the touch point MAX effect flag is not set to 1 (NO), the sub CPU 201 executes the process of step S634.

  In step S631, the sub CPU 201 determines whether the fluctuation is 5.0 seconds and whether there is a stage change. If it is determined that the change is a change for 5.0 seconds and there is a stage change (YES), the sub CPU 201 executes the process of step S637. If it is determined that the change is not a change for 5.0 seconds or there is no stage change (NO), the sub CPU 201 executes the process of step S632.

  In step S632, the sub CPU 201 selects pre-reading advance notice effect in which the touch point becomes MAX. After executing the process of step S632, the sub CPU 201 executes the process of step S633.

  In step S633, the sub CPU 201 sets the touch point MAX effect flag to 0. After executing the process of step S633, the sub CPU 201 executes the process of step S635.

  In step S <b> 634, the sub CPU 201 selects whether to execute the 1P effect in which 1 is added to the touch point based on the fluctuation pattern and various effects. Here, if it is determined that the 1P effect is to be executed, the sub CPU 201 adds 1 to the touch point to select the 1P effect that can be executed as the variation effect. After executing the process of step S634, the sub CPU 201 executes the process of step S635.

  In step S635, the sub CPU 201 determines whether the touch point exceeds the MAX point. If it is determined that the touch point exceeds the MAX point (YES), the sub CPU 201 executes the process of step S636. If it is determined that the touch point does not exceed the MAX point (NO), the sub CPU 201 executes the process of step S637.

  In step S636, the sub CPU 201 sets 1 to the special effect flag. After executing the process of step S636, the sub CPU 201 ends the point provision effect setting process.

  In step S637, the sub CPU 201 selects another variation effect. Here, the sub CPU 201 executes the same process as step S 435 in the point provision effect setting process described with reference to FIGS. 84 and 85. After executing the process of step S637, the sub CPU 201 ends the point provision effect setting process.

  As described above, there are cases in which the touch points are given as a fluctuation effect at the time of fluctuation and as a pre-reading advance notice effect at the time of winning opening winning in a point giving effect setting process. That is, the point provision effect is performed as a pre-read advance effect or as an effect to be executed at the time of change.

  Although it has been described that the sub CPU 201 selects whether or not to execute the 1P effect in which 1 is added to the touch point in steps S625 and S634 of the point addition effect setting process described above, two or more are added to the touch point It may be selected whether or not to perform the effect to be performed.

  In addition, the sub CPU 201 notifies that the touch point has become the MAX point when the touch point has become the MAX point, and that the touch point has exceeded the MAX point when the touch point has exceeded the MAX point May not be notified.

  The sub CPU 201 does not notify that the touch point has become the MAX point when the touch point has become the MAX point, and the touch point exceeds the MAX point when the touch point exceeds the MAX point. May be notified.

[Touch sensor effect processing]
The touch sensor effect process according to the present embodiment will be described with reference to FIG. First, in step S640, the sub CPU 201 determines whether the point value is equal to or greater than the set value. If it is determined that the point value is equal to or greater than the set value (YES), the sub CPU 201 executes the process of step S641. If it is determined that the point value is not the set value or more (NO), the sub CPU 201 ends the touch sensor effect process.

  In step S 641, the sub CPU 201 determines whether or not it is a period during which the liquid crystal display device 50 displays the holding symbol. If it is determined that it is a period in which the held symbol is displayed (YES), the sub CPU 201 executes the process of step S642. If it is determined that it is not a period in which the holding symbol is displayed (NO), the sub CPU 201 ends the touch sensor effect process.

  In step S642, the sub CPU 201 sets 1 to the touch sensor activation flag. After executing the process of step S642, the sub CPU 201 executes the process of step S643.

  In step S643, the sub CPU 201 determines whether the operation detection flag is one. If it is determined that the operation detection flag is 1 (YES), the sub CPU 201 executes the process of step S644. If it is determined that the operation detection flag is not 1 (NO), the sub CPU 201 ends the touch sensor effect process.

  In step S644, the sub CPU 201 determines whether the special effect flag is one. If it is determined that the special effect flag is 1 (YES), the sub CPU 201 executes the process of step S645. If it is determined that the special effect flag is not 1 (NO), the sub CPU 201 executes the process of step S646.

  In step S645, the sub CPU 201 refers to the after-touch item selection table shown in FIG. 120 and the on-touch hold concealment image selection table shown in FIG. 121, and effects of selecting the display of the effects already selected in the stock state. Change to the display of and set.

  Here, the stock state refers to a state in which the point value exceeds the MAX point (for example, in the case where the specified value is 5 points, the state in which the point value is 6 points). After executing the process of step S645, the sub CPU 201 executes the process of step S647.

  In step S646, the sub CPU 201 sets the display of the effect after the touch that has already been selected. After executing the process of step S646, the sub CPU 201 executes the process of step S647.

  In step S647, the sub CPU 201 sets 0 in the touch sensor activation flag. After executing the process of step S647, the sub CPU 201 executes the process of step S648.

  In step S648, the sub CPU 201 subtracts a set value (for example, 5 points in the embodiment, a value determined as an upper limit, a value sufficient to execute an effect, etc.) from the point value. After executing the process of step S648, the sub CPU 201 ends the touch sensor effect process.

  Note that, in steps S645 and S646 of the touch sensor effect process described above, the sub CPU 201 may execute an informing effect that suggests the possibility of a latent change in latency. In this case, the sub CPU 201 executes the notification effects performed in steps S645 and S646 in mutually different modes.

  By configuring in this manner, the pachinko gaming machine 1 of the present embodiment allows the player to select the content of the notification effect that suggests the possibility that the gaming state is the latent probability change. Can improve the player's interest in

[After touch item selection table]
Hereinafter, the after-touch item selection table referred to by the sub CPU 201 in the touch sensor effect process shown in FIG. 119 will be described with reference to FIG. The item selection table after touch shown in FIG. 120 is referred to in the stock state. If it is not in the stock state, the after-touch item selection table shown in FIG. 96 is referred to.

  In the after-touch item selection table illustrated in FIG. 120, the effect pattern, the change effect pattern, the selection rate, and the after-touch item pattern are associated. In addition, in FIG. 120, in order to make the invention easy to understand, it is associated with the contents of the item pattern after touch shown in FIG.

  For example, in FIG. 120, when the effect pattern is EN42 and the variation effect pattern is JY2, the after-touch item pattern TA1 is selected at a selection rate of 10/100, and the after-touch item pattern TA2 is 20/100. The selection rate is selected, the post-touch item pattern TA3 is selected at a 10/100 selection rate, the post-touch item pattern TA4 is selected at a 40/100 selection rate, and the post-touch item pattern TA5 is 20/100 It is selected by the selection rate of

  When the item pattern TA1 after touch is selected, the default "Hold on white" is displayed without change. When the item pattern TA2 after touch is selected, a blue, red or gold "fairy" hold is displayed instead of the blue or red "sword" hold.

  When the item pattern TA3 after touch is selected, instead of the rainbow pattern "sword" suspension to be notified of hitting more than a big hit, a "fairy" suspension of rainbow pattern to be notified of hitting more than a big hit is displayed.

  When the item pattern TA4 after touch is selected, a default "white" hold with a timer effect is displayed instead of the default white "next notice" hold. When the item pattern TA5 after touch is selected, a "rainbow pattern" suspension with a timer effect notifying of a probability variation big hit is displayed instead of the "next notice" suspension of a rainbow pattern notifying a probability variation big hit.

  Further, when the item pattern TA4 or TA5 after touch is selected, depending on the effect pattern and the change effect pattern, the “holy sword” suspension with the timer effect is displayed after the touch.

  In the timer effect, for example, the time until the next advance effect is executed is displayed. In other words, the timer effect is an effect that informs the player when the next advance notice will be performed (for example, the fluctuation time or effect time from when the timer effect is displayed until the next notice effect is performed) Effect).

  In "Fairy" hold, a fairy in blue, red or gold appears instead of "sword" hold. Note that the degree of expectation held by the player is blue <red <golden, but may be replaced with blue> red> golden or the like.

  The "sacred sword" hold is displayed as an effect that has a higher degree of expectation than the "sword" hold. The sub CPU 201 may control so that the upper movable effect member 650 (hereinafter simply referred to as "sacred sword feature") is driven at the timing when "sacred sword" suspension is displayed, "sacred sword" suspended The holy sword character may be controlled to be driven at the timing at which the change to the symbol is started.

  In addition, the sub CPU 201 causes the holy sword character to be driven at the timing when the operation means such as the touch sensor 425 is operated before, after or after being displayed, the “sacred sword” suspension is displayed. It may be controlled to Further, the sub CPU 201 may control the holy sword feature to be driven when a specific effect is performed during the change to the “saint sword” suspension.

  As described above, the sub CPU 201 may control the holy sword character to be driven at various timings, but the section and permission for prohibiting the driving of the holy sword character in relation to other effects. It may be controlled to provide a section to

  As a section which forbids the drive of the holy sword character, for example, there is a section before the specific effect is performed during the super reach, a section in which a plurality of other effects are performed, and the like. That is, the sub CPU 201 prohibits the driving of the holy sword character if the content of the effect is lost due to the driving of the holy sword character or if the story of the effect is divided. May be

  In addition, the production driven by the holy sword character may be a production in which the big hit is finalized, or may be a production in which the big hit expectation is high. That is, the presentation driven by the holy sword character may be performed in the case of a loss.

  In the present embodiment, the selection (or lottery, determination) result of the special symbol for which the variable display is suspended is that the sub CPU 201 selects the item pattern after touch at the starting opening winning at the starting opening winning. However, the present invention is not limited to this, and the item pattern after touch may be reselected by lottery again after winning opening winning.

[On-hold hiding image selection table]
Hereinafter, the on-touch suspension hiding image selection table referred to by the sub CPU 201 in the touch sensor effect process shown in FIG. 119 will be described with reference to FIG. The touch-hold concealment image selection table shown in FIG. 121 is referred to in the stock state. If it is not in the stock state, the on-touch hold concealment image selection table shown in FIG. 115 is referred to.

  The touch hold concealment image selection table shown in FIG. 121 is referred to in order to select the concealment image (see FIG. 101) selected by the sub CPU 201. In the touch concealment concealed image selection table shown in FIG. 121, the effect pattern, the item pattern after touch, the stage information, the selection rate, and the effect content are associated.

  Although the effect pattern is represented by EN00 to EN44 as shown in FIG. 77, in FIG. 121, in order to make the invention easy to understand, it is collectively shown by the winning classification (other than the big hit / big hit). .

  Further, although the item patterns after touch are TA1 to TA5 (see FIG. 96), only TA4 is illustrated, and other item patterns after touch are omitted. The presentation content includes information representing a hidden image.

  For example, in FIG. 121, when the effect pattern is a big hit, the item pattern after touch is TA4, and the stage is a "choy heat stage", the selection rate is 20/100 and commonly used in each stage A possible concealed image is selected, a concealed image dedicated to each stage is selected with a selectivity of 20/100, and an concealed image that reports a big hit or more that can be commonly used in each stage with a selectivity of 10/100 Is selected, and a concealed image notifying of a big hit or more for each stage is selected with a selectivity of 10/100, and a stock notified of a big hit or more that can be commonly used in each stage with a selectivity of 20/100. A state-specific concealed image is selected, and a stock state-specific concealed image notifying of a jackpot or more specific to each stage is selected with a selectivity of 20/100.

  Although the hidden image in the present embodiment has been described as being selected at each selection rate, it is uniquely determined by a combination of the effect before change (item before touch) and the effect after change (item after touch). It may be selected.

  As described above, in the pachinko gaming machine 1 of the present embodiment, in order to execute the effect to be performed when the touch point is 5, the 1P effect and the touch point MAX effect are performed, and thereby the touch point is performed. In order to perform the effect performed when the touch sensor 425 is operated or the touch point exceeds 5 every time the becomes 5, the 1P effect is performed after the touch point becomes 5 By allowing the player to select whether to wait and to operate the touch sensor 425, the player can select the effect to be performed, so it is possible to improve the player's interest in the effect accompanied by the operation. .

  In addition, when there are two types of defined values, one defined value may be set to 0 and the other defined value may be set to 5, and one defined value may be set to 0 as a defined value for executing the castellation effect. By setting to, you can also control to be always executed. In addition, it is also possible to set the other specified value to a value smaller than 5. Also, with two types of points to be stored, each specified value is provided, and the first point is the first specified value. It is also possible to control to change to a touchable hold when the second point reaches a second predetermined value. Furthermore, it is also possible to change to a touchable hold when one of the two types of points reaches a specified value.

Fifth Embodiment
The fifth embodiment of the present invention will be described below. In the fifth embodiment of the present invention, differences from the above-described fourth embodiment of the present invention will be described, and descriptions of the same points as the fourth embodiment of the present invention will be made. I omit it.

  In the present embodiment, the sub CPU 201 has a Real Time Clock (RTC) effect function of operating a special effect in a predetermined time zone as a predetermined period.

[RTC production process]
The RTC effect process executed as one of the interrupt processes periodically executed by the sub CPU 201 in a predetermined time zone will be described below with reference to FIG.

  First, in step S660, sub CPU 201 determines whether the current time is the start time of the RTC effect. If it is determined that the current time is the start time of the RTC effect (YES), the sub CPU 201 executes the process of step S661. If it is determined that the current time is not the start time of the RTC effect (NO), the sub CPU 201 executes the process of step S667.

  In step S661, the sub CPU 201 selects the opening (rendering) of the RTC effect. After executing the process of step S661, the sub CPU 201 executes the process of step S662.

  In step S 662, the sub CPU 201 selects a loop effect of the RTC effect. After executing the process of step S662, the sub CPU 201 executes the process of step S663.

  In step S663, the sub CPU 201 selects an ending (effect) of the RTC effect. After executing the process of step S663, the sub CPU 201 executes the process of step S663.

  In step S664, the sub CPU 201 sets 1 in the unrestricted touch state flag indicating whether the unrestricted touch state in which the operation by the touch sensor 425 is enabled even if the point value is not equal to or greater than the set value. After executing the process of step S664, the sub CPU 201 executes the process of step S665.

  In step S665, the sub CPU 201 sets an end time of the RTC effect. After executing the process of step S665, the sub CPU 201 executes the process of step S666.

  In step S 666, the sub CPU 201 sets opening data in the work RAM 203. After executing the process of step S666, the sub CPU 201 ends the RTC effect process.

  In step S667, the sub CPU 201 determines whether the current time is an end time of the RTC effect. If it is determined that the current time is the end time of the RTC effect (YES), the sub CPU 201 executes the process of step S668. If it is determined that the current time is not the end time of the RTC effect (NO), the sub CPU 201 executes the process of step S670.

  In step S668, the sub CPU 201 sets ending data in the work RAM 203. After executing the process of step S668, the sub CPU 201 executes the process of step S669.

  In step S669, the sub CPU 201 sets 0 to the unlimited touch state flag. After executing the process of step S669, the sub CPU 201 ends the RTC effect process.

  In step S670, the sub CPU 201 sets data of loop effect in the work RAM 203. After executing the process of step S670, the sub CPU 201 ends the RTC effect process.

[Touch sensor effect processing]
The touch sensor effect process according to the present embodiment will be described with reference to FIG. First, in step S 680, sub CPU 201 determines whether the unlimited touch state flag is 1 or not.

  If it is determined that the unlimited touch state flag is 1 (YES), the sub CPU 201 executes the process of step S684. If it is determined that the unlimited touch state flag is not 1 (NO), the sub CPU 201 executes the process of step S 681.

  In step S 681, the sub CPU 201 determines whether the point value is equal to or greater than the set value. If it is determined that the point value is equal to or greater than the set value (YES), the sub CPU 201 executes the process of step S682. If it is determined that the point value is not the set value or more (NO), the sub CPU 201 ends the touch sensor effect process.

  In step S 682, sub CPU 201 determines whether or not it is a period in which the hold symbol is displayed on liquid crystal display device 50. If it is determined that it is a period in which the held symbol is displayed (YES), the sub CPU 201 executes the process of step S684. If it is determined that it is not a period in which the held symbol is displayed (NO), the sub CPU 201 executes the process of step S683.

  In step S683, the sub CPU 201 determines whether a demo is in progress. If it is determined that a demo is being performed (YES), the sub CPU 201 executes the process of step S684. If it is determined that the demonstration is not in progress (NO), the sub CPU 201 ends the touch sensor effect process.

  In step S684, the sub CPU 201 sets 1 to the touch sensor activation flag. After executing the process of step S684, the sub CPU 201 executes the process of step S685.

  In step S <b> 685, the sub CPU 201 determines whether the operation detection flag is 1 or not. If it is determined that the operation detection flag is 1 (YES), the sub CPU 201 executes the process of step S686. If it is determined that the operation detection flag is not 1 (NO), the sub CPU 201 ends the touch sensor effect process.

  In step S686, the sub CPU 201 sets 0 in the touch sensor activation flag. After executing the process of step S686, the sub CPU 201 executes the process of step S687.

  In step S687, the sub CPU 201 determines whether a demonstration is in progress. If it is determined that a demo is being performed (YES), the sub CPU 201 executes the processing of step S689. If it is determined that the demo is not underway (NO), the sub CPU 201 executes the process of step S688.

  In step S688, the sub CPU 201 refers to the hold concealed image selection table shown in FIG. 115 and determines whether or not the variation corresponding to the held symbol with the treasure box held symbol displayed is a big hit, stage information, and touch The concealed image (see FIG. 101) is selected based on the back item. After executing the process of step S688, the sub CPU 201 executes the process of step S689.

  In step S689, the sub CPU 201 sets the display of the effect after the touch in which the effective operation has been detected by the touch sensor 425. For example, if the sub CPU 201 is not under demonstration, it changes the holding symbol before touching displayed on the liquid crystal display device 50 to the holding symbol after touching, and if during demonstration and the gaming state is the latent probability variation, FIG. 116 With reference to the latent notification notification effect selection table shown in, the effect which suggests that the gaming state is the latent probability change is set.

  In step S689, the sub CPU 201 sets the effect which suggests that the gaming state is the latent probability change during the demonstration, and the selection rate differs depending on whether the gaming state is the latent probability change or not. An effect may be set. After executing the process of step S689, the sub CPU 201 executes the process of step S690.

  In step S 690, sub CPU 201 determines whether the unlimited touch state flag is 1 or not. If it is determined that the unlimited touch state flag is 1 (YES), the sub CPU 201 ends the touch sensor effect process. If it is determined that the unlimited touch state flag is not 1 (NO), the sub CPU 201 executes the process of step S691.

  In step S691, the sub CPU 201 subtracts the setting value from the point value. After executing the process of step S691, the sub CPU 201 ends the touch sensor effect process.

  As described above, the pachinko gaming machine 1 according to the present embodiment does not execute unless the touch point is MAX, the touch effect is a specific effect in which the item before touch becomes the item after touch, in the execution period of the RTC effect, the touch point Since execution is performed even if it is not MAX, it is possible to prevent a decrease in the interest of the player who is expecting the specific effect that the pre-touch item becomes the post-touch item to be performed.

  As described above, in the state in which the unlimited touch state flag is 1, that is, in the state in which the RTC effect is being executed, the touch sensor activation flag may be set regardless of whether the touch point has reached the specified value. Therefore, if the operation detection flag becomes 1 during the period when the RTC effect is being executed (for example, the player's hand is placed within the effective range of the touch sensor 425 by the player in a state where the pre-touch effect is displayed) Then, the effect is executed after the player touches.

  Further, in the state where the unlimited touch state flag is 1, that is, in the state where the RTC effect is being performed, the point value is not subtracted, so it is possible to set a point increase section where point values can be stored.

  Also, in each embodiment, the effective range of the touch sensor 425 always has a fixed effective range, and more specifically, if an object (for example, a player's hand) exists within a fixed distance from the touch sensor It becomes operation knowledge. The effective range of the touch sensor 425 may change according to the effect, or the effective range may change according to the gaming state.

  Moreover, although the touch sensor 425 and the production button 16 exist as operation means in each example, even if the presentation button 16 is pressed when the touch point reaches the specified value, the item after the touch is not displayed. It may be controlled, or even if any operation means of the touch sensor 425 and the effect button 16 is operated, it may be controlled to display an item after touch.

  In the embodiment of the present invention described above, various control processes are divided into the main control process executed by the main CPU 101 and the sub control process executed by the sub CPU 201, but various processes included in the sub control process are described. The main CPU 101 may execute the process, or the sub CPU 201 may execute various processes included in the main control process.

  In the embodiment of the present invention, although an example in which the gaming machine according to the present invention is applied to the pachinko gaming machine 1 has been described, the present invention is not limited thereto. The gaming machine according to the present invention uses medals as gaming media. The present invention can also be applied to other game machines such as a pachislot machine to be used.

<Summary of the invention>
<Summary 1>
In the gaming machine described in JP-A-2016-39923, when the game balls winning in the special view 1 start area and the special view 2 start area join at the rear surface of the game board, the flow of the game balls Depending on the direction, the game ball discharged from the special view 1 start area and the game ball discharged from the special view 2 start area may come in contact with each other to cause ball clogging. For this reason, if the ball clogging continues, there is a possibility that the game of the player may be disturbed.

  The gaming machine according to the present invention is provided with a plurality of ball passages (601, 602) in which gaming balls winning in a plurality of winning openings (second starting opening 414b, general winning opening 419d) flow, and a plurality of ball passages. A gaming machine (pachinko gaming machine 1) having a junction (604) where the plurality of ball passages merge on the downstream side, and a partition (a partition plate 605) is provided in the ball passage, the partition In the game unit, the traveling direction of the gaming ball flowing down to the merging portion from at least one of the plurality of ball passages is substantially the same as the traveling direction of the gaming ball flowing down to the merging portion from the other ball passage It has a configuration for guiding a ball.

  With this configuration, in the gaming machine according to the present invention, the traveling direction of the gaming ball flowing down from at least one of the plurality of ball passages into the merging portion is substantially the same as the traveling direction of the gaming ball flowing down from the other ball passage into the merging portion Since the game balls are guided in the direction of movement of the game balls, it is possible to prevent the game balls flowing down from the plurality of ball passages from coming into contact at the merging portion. As a result, it is possible to prevent the occurrence of ball clogging, and the game can be continued smoothly.

  Further, in the gaming machine according to the present invention, preferably, the partition portion is formed of a common wall portion forming the plurality of ball passages.

  With this configuration, the gaming machine according to the present invention adds a dedicated member that constitutes the partition to the ball passage by configuring the partition from a common wall that forms a plurality of ball passages. It is unnecessary to simplify the configuration of the ball passage.

<Summary 2>
In the gaming machine described in Japanese Patent Application Laid-Open No. 2013-226196, there is a possibility that the trajectory of the accessory is not stable when the accessory rotates around the base end, and in particular, the accessory has become huge. In this case, the trajectory of the character may not be more stable.

  Thereby, at the time of rotational movement of the goods, the goods may come into contact with the decoration member provided in the game machine, and a load may be applied to the drive unit such as a motor for driving the goods. It may not be executed correctly.

  The gaming machine according to the present invention comprises a support member (crate 60) attached with a game board (40) having a game area (41) in which game media roll, and is attached to the back of the game board, A display device (liquid crystal display device 50) for effect display, and an accessory (upper movable effect) movable between a standby position and a drive position centering on the base end (swinging axis 651B) attached to the support member Member 650) and a guide member (guide rails 668 and 669) provided on the support member so as to be located in front of the display device, and the accessory performs the standby with the base end as a fulcrum It has a guided portion (guide piece 670) guided by the guide member when moving between the position and the drive position.

  With this configuration, in the gaming machine according to the present invention, the item movable on the base end is movable between the standby position and the drive position while the guided portion is guided by the guide member. The orbit can be stabilized. For this reason, it is possible to accurately perform the effect by the character.

  In addition, for example, when the prize is moved between the standby position and the drive position, it is possible to prevent the swing in the back and forth direction of the gaming machine, thereby preventing the prize from contacting the game board or the display device As a result, the property, the game board and the display device can be protected. In addition to this, it is possible to reduce the space between the character and the game board and the space between the character and the display device by preventing the character from swinging back and forth. Therefore, the dimension in the front-rear direction of the gaming machine can be shortened, and space saving of the gaming machine can be achieved.

  Further, in the gaming machine of the present invention, the accessory is a first moving member (upper movable base 655) and a second moving member (upper slide base 657) movable in the longitudinal direction of the first moving member. A second movement member is a first movement position where the area overlapping the first movement member in the front-rear direction of the gaming machine is the largest, and the first movement member The end portion of the second moving member is provided so as to be movable between the second moving position where the overlapping area in the front-rear direction is the smallest, and the second moving member moves to the second moving position. Preferably it can project beyond the member.

  With this configuration, the gaming machine according to the present invention can prevent the movement of the second moving member from being restricted by the guide member, and can perform the effect by the character more effectively.

<Summary 3>
In the gaming machine described in JP 2013-226196 A, in addition to the configuration for rotating the arm base, a configuration for moving the first arm and the second arm is required, and Configuration is complicated. Therefore, the structure for moving the first arm and the second arm may inhibit the rotation of the arm base, and may also lead to a failure.

  In order to achieve the above object, the gaming machine according to the present invention has a base end portion (swinging shaft 651 B) between a standby position close to the fixing member (the abutment wall member 675) and a driving position separating from the fixing member. Game machine (pachinko gaming machine 1) including movable means (upper movable presentation member 650) having a first movable member (upper slide base 657, fixed rod member 672) movable about the center A second movable member (a movable wedge member 673) relatively movable with respect to the first movable member, and an urging member (a coil for elastically coupling the first movable member and the second movable member) A spring 674), and the second movable member contacts the fixed member when the first movable member moves closer to the fixed member, thereby urging the biasing member Against the first movable The first movable member is moved relative to the material and moved to the first position, and when the first movable member moves away from the fixed member, the first movable member is biased by the biasing member. It is configured to move relative to the movable member and move to the second position.

  With this configuration, the gaming machine according to the present invention resists the biasing force of the biasing member by the second movable member coming into contact with the fixed member when the first movable member moves closer to the fixed member. Is moved relative to the first movable member to move to the first position, and the second movable member is biased by the biasing member when the first movable member is moved away from the fixed member. As a result, the relative movement with respect to the first movable member and the movement to the second position can be performed, so the effect of the movable means can be improved while smoothly operating the movable means with a simple configuration.

  In particular, the movable means comprises the first movable member, the second movable member, and the biasing member, and by associating the fixed member with this, the second movable member becomes the first movable member along with the movement of the first movable member. Since the relative movement is possible, the configuration of the movable means can be simplified more effectively.

  In the gaming machine according to the present invention, a support member (spacer 90) on which a game board (40) having a game area on which game media roll is mounted, and the back of the game board, and predetermined effect display And a guide member (guide rails 668 and 669) provided on the support member so as to be located in front of the display device (the liquid crystal display device 50). It is preferable to have a guided portion (guide member 679) guided by the guide member when moving between the standby position and the drive position with the end as a fulcrum.

  With this configuration, in the gaming machine according to the present invention, the movable means movable with the base end as the fulcrum is movable between the standby position and the drive position while the guided portion is guided by the guide member. The orbit can be stabilized. For this reason, the effect by the movable means can be accurately performed.

  Further, for example, when the movable means is moved between the standby position and the drive position, it is possible to prevent the swinging of the gaming machine in the back and forth direction, so that the movable means is prevented from contacting the game board or the display device Thus, the movable means, the game board and the display device can be protected. In addition to this, it is possible to reduce the space between the movable means and the game board and the space between the movable means and the display device by preventing the movable means from swinging back and forth. Therefore, the dimension in the front-rear direction of the gaming machine can be shortened, and space saving of the gaming machine can be achieved.

<Summary 4>
In the gaming machine described in JP 2013-226196 A, in addition to the configuration for rotating the arm base, a configuration for moving the first arm and the second arm is required, and Configuration is complicated. Therefore, the structure for moving the first arm and the second arm may inhibit the rotation of the arm base, and may also lead to a failure.

  A gaming machine according to the present invention is a gaming machine (pachinko gaming machine 1) having a character (upper movable presentation member 650) movable between a standby position and a driving position, wherein the character is a first slide A member (upper movable base 655), a movable body (upper slide base 657) movable relative to the base main body between the first movement position and the second movement position, and the base main body, A movable member (movable arms 662, 663) movable between a movable position and a second movable position, and the base body are provided, and the movable member is provided by operating from a first operation position to a second operation position. An operating member for moving the movable member from the second movable position to the first movable position by moving the first movable position to the second movable position and moving the second operating position to the first operating position Gear 66 665), the movable member is engaged with the actuating member when the movable member moves from the first movement position to the second movement position with respect to the base main body, A first engaging portion (movable slider 658) for moving from the first operating position to the second operating position, and the movable body, the movable body being movable relative to the base main body from the second moving position A second engagement that causes the actuating member to move from the second actuating position to the first actuating position by engaging the actuating member from a direction opposite to the first engagement portion when moving to the first movement position A base rib 666).

  With this configuration, in the gaming machine according to the present invention, when the base body moves to the first movement position and the second movement position with respect to the movable body, the first engagement portion and the second engagement portion act as operating members. Since the movable member can be moved between the first movable position and the second movable position by engaging with the movable member, the movable member can be smoothly operated with a simple configuration. As a result, it is possible to improve the rendering effect while guaranteeing that the character performs smoothly.

  Further, in the gaming machine of the present invention, the actuating member is constituted by gears (664, 665), the movable member has gear portions (662A, 663A) meshing with the gears, and the gears are The gear is provided between the first engaging portion and the second engaging portion in the moving direction of the movable body, and the gear is disposed on the first engaging portion and the second engaging portion. It is preferred to have engageable ribs (664A).

  According to this configuration, the gaming machine according to the present invention causes the movable member to move to the first movable position via the gear portion by rotating the gear by engaging the first engaging portion and the second engaging portion with the rib. It is movable between the second movable position. As a result, the accessory can be configured more effectively and simply.

  In addition, when the movable member is positioned at the first movable position and the second movable position, the rotation of the gear can be restricted by engaging the first engagement portion and the second engagement portion with the rib. Thus, the posture of the movable member can be stabilized at the first movable position and the second movable position, and the behavior of the movable member can be prevented from becoming unstable.

<Summary 5>
In the gaming machine described in Japanese Patent Application Laid-Open No. 2013-226196, when the arm base is stopped at the drive position, the arm base does not have a configuration to restrict the movement of the arm base. Is rocked, and there is a risk that the product will not operate smoothly. In particular, when the item is enlarged, the swing of the arm base is further increased, and thus the above-mentioned problems are more feared.

  The gaming machine according to the present invention includes a fixed body (lower fixed base 611, rotating body 621), and a movable body (lower movable base 615) movable to a standby position and a drive position with respect to the fixed body. A gaming machine (pachinko gaming machine 1) having a character (a lower movable presentation member 610) configured by the driving means (motor 612) for moving the movable body to the standby position and the drive position. The movable body has a first contact portion (protrusion 617B) that abuts the fixed body at least in the drive position, and the fixed body is configured to move the second movable body when the movable body is in the drive position. 1 contact portion has a second contact portion (rib 626) with which the contact portion abuts, and when the movable body is stopped at the drive position, the drive means at least the movable body from the drive position Do not move toward the standby position It has a configuration for imparting a driving force for biasing the movable member.

  With this configuration, in the gaming machine according to the present invention, at least the movable body is on standby from the drive position when the accessory is stopped at the drive position with the first contact portion abutting on the second contact portion. Since the drive means for urging the movable body so as not to move toward the position is provided, the movable body can be prevented from swinging in the moving direction at the drive position, and the movable body can be stably stopped at the drive position. It can be done. As a result, it is possible to improve the rendering effect by the character while guaranteeing the smooth operation of the character.

  In the gaming machine according to the present invention, an arm member is connected to the movable body, and transmits the driving force of the driving means to the movable body to move the movable body to the standby position and the driving position It is preferred to have an arm 618).

  With this configuration, in the gaming machine according to the present invention, when the movable body is positioned at the drive position, the arm member is bent when the load is excessively applied to the movable body from the motor via the arm member. The load applied from the contact portion to the second contact portion can be absorbed. Thereby, it is possible to prevent an excessive load from being applied to the movable body and the motor.

  Furthermore, when the movable body is positioned at the drive position, when a rattle such as a driving gear provided between the movable body and the fixed body is generated, the arm member is bent by the rattling by the rattle. It can be eliminated.

  Further, in the gaming machine of the present invention, the first contact portion is constituted by a projection provided on the movable body, and the second contact portion is when the movable body is in the drive position. The first rib (rib 626) against which the first contact portion abuts, and the second rib (rib 626) against which the first contact portion abuts when the movable body is in the standby position, When the movable body moves to the drive position, the projection abuts against the first rib, and when the movable body moves to the standby position, the projection abuts against the second rib. preferable.

  With this configuration, in the gaming machine according to the present invention, the protrusion abuts the first rib when the movable body moves to the drive position, and the protrusion abuts the second rib when the movable body moves to the standby position Since the contact is made, the movable body can be stably stopped at either the drive position or the standby position.

  In the gaming machine according to the present invention, an elastic member is provided on at least one of the first contact portion and the second contact portion to be in contact with the other of the first contact portion and the second contact portion. Is preferred.

  With this configuration, in the gaming machine according to the present invention, even when an excessive load is applied to the movable body from the drive means when the movable body is at the drive position, the elastic member is bent and the first contact portion The load applied to the second contact portion can be absorbed. Thereby, it is possible to prevent an excessive load from being applied to the movable body and the drive means.

<Summary 6>
In the gaming machine described in Japanese Patent Application Laid-Open No. 2013-226196, when the arm base is stopped at the drive position, the arm base does not have a configuration to restrict the movement of the arm base. Is rocked, and there is a risk that the product will not operate smoothly. In particular, when the item is enlarged, the swing of the arm base is further increased, and thus the above-mentioned problems are more feared.

  A game machine according to the present invention includes a fixed body (lower fixed base 611) and a movable body (lower movable base 615, rotating body 621) movable relative to the fixed body, and the movable body is on standby A gaming machine (pachinko gaming machine 1) having an accessory (lower movable effect member 610) movable to a position and a driving position, and a first locking portion (locking piece 611F) provided on the fixed body And a second locking portion (locking piece 615B) provided on the movable body, and the first locking portion and the second locking portion are locked to each other at the standby position to achieve the role. Locking means (locking piece 611F, locking piece 615B) for restricting the swing of the object, and a guide member (base cover 623) for guiding the wiring connected to the above-mentioned goods, the guide member The movable body is in the standby position, Provided in front of the body, having a structure for regulating said movable body is moved forward.

  With this configuration, the gaming machine according to the present invention has the locking means that regulates the swing of the movable body by locking the first locking portion and the second locking portion to each other at the standby position. The movable body can be prevented from swinging relative to the fixed body at the position, and the movable body can be stably held.

  Furthermore, in the state where the movable body is in the standby position, a guide member is provided in front of the movable body for restricting the movable body from moving forward, so excessive vibration is added to the accessory during transportation of the gaming machine, etc. In such a case, the movable body can be prevented from moving forward with respect to the fixed member.

  Thus, in the state where the movable body is at the standby position, the locking between the first locking portion and the second locking portion is not released. For this reason, it can prevent that a malfunction arises in operation | movement of a thing by releasing the latching with a 1st latching | locking part and a 2nd latching | locking part. Therefore, it is possible to improve the rendering effect while guaranteeing smooth operation of the prizes.

  In addition to this, since the guide member is configured by the guide member that guides the wiring connected to the accessory, it is possible to eliminate the need for a dedicated member that restricts the movable body from moving forward. For this reason, it is possible to prevent an increase in the number of parts and to prevent an increase in the manufacturing cost of the item.

<Summary 7>
In the gaming machine described in JP 2013-226196 A, when the arm base rotates or when the first arm and the second arm move, the arm base and the first arm and the second arm are stabilized. There is no configuration to move. Due to this, there is a possibility that the character does not operate smoothly. In particular, when the item is enlarged, the swing of the arm base is further increased, and thus the above-mentioned problems are more feared.

  The gaming machine according to the present invention comprises a gaming board (40) at least a part of which has translucency or light guiding property, and displacement means provided behind the gaming board and movable to a standby position and a drive position (right side A gaming machine (pachinko gaming machine 1) including a movable effect member 750 and a left movable effect member 770, wherein the displacement means is a contact portion (guide protrusion 761, 781) that abuts against the back surface of the game board And the contact portion contacts the back surface of the game board in a region where it is difficult to visually recognize the rear of the game board when the displacement means moves to the standby position and the drive position. It has the structure provided in the displacement means.

  With this configuration, in the gaming machine according to the present invention, when the displacement means moves to the standby position and the drive position, the abutment portion abuts against the back surface of the game board, so the abutment portion is moved when the displacement means moves. It can be used as a guide, and the displacement means can be operated stably. As a result, it is possible to improve the rendering effect by the displacement means while ensuring that the displacement means performs a smooth operation.

  Further, by bringing the contact portion into contact with the back surface of the game board, it is possible to prevent the decoration or the like formed on the front surface of the displacement means from coming into contact with the game board. For this reason, the front of the displacement means can be protected from the game board.

  Furthermore, since the contact portion of the displacement means is in contact with the back surface of the game board in an area where it is difficult to visually recognize the rear of the game board, the contact portion of the displacement means is not easily viewed from the player . Therefore, the decorativeness of the game board can be maintained.

<Summary 8>
In the gaming machine of JP-A-2016-39923, since the inclined surface having a simple shape is formed on the wall portion of the sorting drum, depending on the speed of the gaming ball accepted by the receiving portion, etc. However, the game ball may roll in an unintended direction, such as running up an inclined surface. As a result, there is a possibility that the sorting drum may bite and cause a rotation failure, and it may be difficult to sort the gaming balls.

  The gaming machine according to the present invention has a rotating member (sorting drum 801) on which a plurality of receiving portions (groove portions 802A to 802D) for receiving gaming balls flowing down the game area (41) are formed, and the receiving portion A gaming machine (pachinko gaming machine 1) including a sorting device (800) for sorting received gaming balls, wherein the receiving portion extends outward in the radial direction of the rotating member, and the gaming balls are placed Mounting surface portion (802a) and wall surface portions (803B and 804B) for determining the distribution direction of gaming balls mounted on the mounting surface portion, and the wall surface portion includes the mounting surface portion A connected first inclined surface (803e, 804e) and a second inclined surface (803f, 804f) connected to the first inclined surface are formed, and the first inclined surface relative to the mounting surface portion The inclination angle (θ1) That has a larger configuration than the inclination angle of the second inclined surface (.theta.2).

  With this configuration, in the gaming machine according to the present invention, the inclination angle of the first inclined surface with respect to the mounting surface portion is formed larger than the inclination angle of the second inclined surface with respect to the mounting surface portion. Further, the inclination angle of the second inclined surface can be made steep. Thus, it is possible to prevent the game ball from rolling in an unintended direction, for example, the game ball received by the receiving portion runs up along the wall portion when the flow-down speed of the game ball is fast.

  For this reason, it is possible to prevent the rotation member from being bitten by the ball and occurrence of the rotation failure, and it is possible to distribute the game balls reliably, and to improve the reliability of the game machine.

  Further, in the gaming machine according to the present invention, the second inclined surface is extended from the first inclined surface to above the central point (807a) of the game ball (807) placed on the mounting surface portion. Is preferred.

  With this configuration, in the gaming machine according to the present invention, the center of gravity of the gaming ball placed on the placement surface can be made lower than the upper end of the second inclined surface, and the gaming ball placed on the placement surface Can be more effectively prevented from running up along the wall surface. In addition, when the rotary member is rotated by the weight of the game ball, the game ball can be reliably discharged in the direction along the first inclined surface of the receiving portion facing downward.

<Summary 9>
In the gaming machine described in JP-A-2015-171438, although it is possible to decelerate the game ball passing above the attacker, it is not possible to decelerate the game ball entered into the attacker.

  For this reason, it is only possible to increase the number of gaming balls passing above the attacker, and it is not possible to cause more gaming balls to enter the attacker. Therefore, in the above-described conventional gaming machine, it is impossible to increase the number of gaming balls to be won in the special winning opening and to provide the player with many benefits.

  A game machine according to the present invention is a variable winning means (shutter member) provided in a game area (41) and capable of transitioning to an open state for opening a pay area (large winning opening 418) and a closed state for closing the pay area. 422a), detecting means (count sensor 113) capable of detecting gaming balls having won in the winning area, and provided outside the winning area, at least when the variable winning means is in the closed state, the variable winning The first reduction means for reducing the rolling speed of the gaming ball rolling on the means (rib 424a), and the detection means among the gaming balls guided from the outside of the winning area to the inside of the winning area A second reduction means (rib 424b) capable of reducing the rolling speed of the game ball not detected in the first game, and the variable winning means is provided between the first reduction means and the second reduction means It has been When serial variable winning device is in an open state or a closed state, it has an internal be decelerating constituting a game ball that roll of the winning region by said second reduction means.

  With this configuration, the gaming machine according to the present invention can decelerate the game ball rolling on the variable winning means by the first deceleration means when the variable winning means is in the closed state, and the variable winning means is opened. Since the game ball rolling inside the pay area can be decelerated by the second deceleration means when in the state or the closed state, more game balls can be played in the pay area before the game ball is detected by the detection means. You can win a prize. Therefore, many game balls can be paid out, and a sufficient profit can be given to the player.

<Summary 10>
In conventional gaming machines as described in Japanese Patent Application Laid-Open No. 2013-106670, since the effects that can be performed differ depending on the pattern of fluctuation such as the fluctuation time of the symbol, when determining the effect or performing the effect If the presentation is not adjusted, it may not be possible to execute the presentation smoothly.

  The gaming machine according to the present invention comprises: symbol variation means (main CPU 101) that changes symbols when a start condition is satisfied, and effect execution means (sub CPU 201) that executes an effect according to an effect pattern, said effect being The execution means is a second effect (for example, the second effect) that can be shifted from the first effect (for example, when the first effect (for example, the effect that the treasure box holding symbol is displayed) and a predetermined effect transition condition (for example, the touch point is MAX) are satisfied. , Treasure box holding symbol transition effect) and effect to be executed when the effect transition condition is not established, and executed according to the pattern variation pattern of the symbol changing means and the effect pattern of the effect Whether or not to be determined is determined, and the third effect (for example, 1P effect) in which the effect transition condition is satisfied when the effect is executed a plurality of times, and the effect transition condition is not satisfied. The fourth effect (for example, touch point MAX effect) in which the effect transition condition is satisfied when the effect is executed when the effect is executed once or not. The fourth effect has a configuration to be executed at the time of the next change of the change for which the fourth effect is performed.

  With this configuration, the gaming machine according to the present invention executes the second effect with the effect transfer condition as the effect transition condition, and if it is determined that the fourth effect is to be executed, the next symbol by the symbol fluctuation means By executing the fourth effect in response to the start of the change of the second effect, it is possible to secure a state in which the second effect can be executed after the fourth effect is executed. Therefore, the gaming machine according to the present invention can smoothly execute the effect without adjusting the effect.

  In the gaming machine according to the present invention, the effect executing means executes the second effect when it is determined to execute the first effect in a state where the effect transition condition is satisfied, the first effect is executed and the first effect is executed. In the state where the effect is being executed, when the effect transition condition is satisfied, the first effect being executed may be shifted to the second effect.

  With this configuration, the gaming machine according to the present invention performs the second effect when the first effect is determined to be executed in a state where the effect transition condition is satisfied, in a state where the first effect is being executed. When the effect transition condition is satisfied, the second effect can be executed to smoothly transition from the first effect in order to shift the first effect being executed to the second effect.

<Summary 11>
In conventional gaming machines as described in Japanese Patent Application Laid-Open No. 2013-106670, since the effects that can be performed differ depending on the pattern of fluctuation such as the fluctuation time of the symbol, when determining the effect or performing the effect If the presentation is not adjusted, it may not be possible to execute the presentation smoothly.

  The gaming machine according to the present invention comprises: symbol variation means (main CPU 101) that changes symbols when a start condition is satisfied, and effect execution means (sub CPU 201) that executes an effect according to an effect pattern, said effect being The execution means is a second effect (for example, the second effect) that can be shifted from the first effect (for example, when the first effect (for example, the effect that the treasure box holding symbol is displayed) and a predetermined effect transition condition (for example, the touch point is MAX) are satisfied. , A treasure box holding symbol transition effect) and an effect to be executed when the predetermined effect transition condition is not satisfied, and a third effect (for example, the effect transition condition is satisfied when executed) Touch point MAX effect), and it is determined that the third effect is to be executed for a predetermined change, the pattern fluctuation pattern in the symbol fluctuation means When it is determined that the third effect can not be executed with the predetermined fluctuation by the run and the effect pattern of the effect, it is possible to decide to execute the three effects at the time of the next fluctuation of the predetermined fluctuation. The configuration is

  With this configuration, the gaming machine according to the present invention is displayed on the symbol display means when it is determined that the second effect is performed with the third effect being performed as the effect transition condition and the third effect is performed. If it is determined that the third effect can not be performed by the fluctuation pattern of the symbol and the pattern of the effect, the third effect is executed triggered by starting the next fluctuation of the symbol displayed on the symbol display means As a result, after executing the third effect, the state of executing the second effect is secured. Therefore, the gaming machine according to the present invention can smoothly execute the effect without adjusting the effect.

<Summary 12>
In the conventional gaming machine as described in JP 2013-106670 A, the operation of the operation means is not reflected in the effect unless the operation of the operation means such as the button is performed within the effective period according to the effect. For the player who has operated the operation means earlier than the effective period, there is a risk of reducing the interest in the effect.

  The gaming machine according to the present invention is a first effect which can establish a predetermined performance execution condition, an effect execution means (sub CPU 201) for executing an effect, an operation detection means (touch sensor 425) capable of detecting a predetermined operation. The second effect is executed (for example, touch point MAX effect), and the second effect (for example, treasure box hold symbol transition effect) which is executed when the predetermined effect execution condition is satisfied by the execution of the first effect. A third effect (for example, a third effect) (for example, triggered by the detection of the predetermined operation by the operation detection unit within a predetermined effective period (for example, a period in which the touch sensor activation flag is 1) started after Item transfer effect), the effect executing means is in a state where the predetermined operation is detected by the operation detecting means when the effect is not within the predetermined effective period, Triggered by having reached a predetermined valid period, an arrangement is capable of executing the third effect.

  With this configuration, in the gaming machine according to the present invention, the third effect executed upon detection of the predetermined operation within the effective period becomes the effective period while the predetermined operation is detected. In order to execute the event as a trigger, the third effect is executed even if the predetermined operation is performed earlier than the effective period. Therefore, the gaming machine according to the present invention can prevent the player's interest in the effects from being reduced by the third effects being surely executed.

  In particular, the gaming machine according to the present invention prevents the third effect from being executed by the detection of the touch sensor not intended by the player when the operation detection means capable of detecting the predetermined operation is configured by the touch sensor. can do.

  In addition, the gaming machine according to the present invention further includes symbol variation means (main CPU 101) that changes symbols when the start condition is satisfied, and the second effect is a predetermined effect transition condition (for example, touch point is MAX) When 4 is established, it is possible to shift from the fourth effect (for example, an effect in which a treasure box holding symbol is displayed), and the first effect is an effect to be executed when the effect transition condition is not satisfied, It is determined whether or not to be executed according to the fluctuation pattern of the symbol in the symbol fluctuation means and the effect pattern of the effect, and the fifth effect (the effect transition condition is satisfied when the effect is executed plural times) For example, 1P effect) and the effect to be executed when the effect transition condition is not satisfied, and the execution availability of the effect is determined by lottery, and the effect is transferred when the effect is executed once. Even if the sixth effect includes the sixth effect (for example, the touch point MAX effect) in which the condition is established, the sixth effect may be executed at the time of the next fluctuation of the fluctuation for which the lottery of the sixth effect is performed. Good.

  With this configuration, the gaming machine according to the present invention executes the second effect based on the effect transition condition as the effect of the sixth effect, and if it is determined to execute the sixth effect, the next symbol by the symbol variation means By executing the sixth effect in response to the start of the change of the second effect, it is ensured that the second effect can be executed after the sixth effect is executed. Therefore, the gaming machine according to the present invention can smoothly execute the effect without adjusting the effect.

<Summary 13>
In the conventional gaming machine as described in Japanese Patent Application Laid-Open No. 2013-106670, it is possible to improve the interest of the player in playing the game by devising the conditions under which the effect can be executed.

  The gaming machine according to the present invention is a symbol variation means (main CPU 101) that changes symbols when a start condition is satisfied, an effect execution means (sub CPU 201) that executes an effect, and an operation detection means capable of detecting a predetermined operation. (Touch sensor 425), a first effect (for example, touch point MAX effect) capable of satisfying a predetermined effect execution condition, and a second effect executed when the predetermined effect execution condition is satisfied by the first effect execution (For example, a treasure box holding symbol transfer effect) and the predetermined operation by the operation detection means within a predetermined effective period (for example, a period in which the touch sensor activation flag is 1) started after the second effect is performed And a third effect (for example, an effect in which an item before touch becomes an item after touch) which is executed when the operation of F is detected. A fourth effect (for example, a gaming state is performed) triggered by the detection of the predetermined operation by the operation detection unit when the condition is satisfied and the start condition is not satisfied. And (d) an arrangement that is capable of performing a rendition that suggests the possibility of being latent).

  With this configuration, in the gaming machine according to the present invention, even if the start condition is not satisfied, if the execution condition of the second effect is satisfied, the fourth operation can be performed by performing a predetermined operation. In order to execute, it is possible to improve the player's interest in the effect.

  Further, according to the predetermined transition condition, the gaming machine according to the present invention plays the game between the normal gaming state and the special gaming state capable of providing the predetermined gaming value to the player as compared with the normal gaming state. The game state transition means (main CPU 101) for shifting the state is further provided, and the fourth effect can be a game state in which the probability that the game state changes to the special game state is relatively high in the normal game state. You may make it suggest sex.

  With this configuration, even if the gaming machine according to the present invention is in the non-gaming state, the gaming state is special by performing a predetermined operation if the execution condition of the first effect is satisfied. In order to execute the fourth effect that suggests the possibility of being in the gaming state where the probability of shifting to the gaming state is relatively high, it is possible to improve the player's interest in the effect.

  In the gaming machine according to the present invention, the effect data to be referred to when executing the first effect and the effect data to be referred to when the first effect is not executed are referred to with respect to one fluctuation pattern by the symbol fluctuation means. And effect data storage means for storing the effect data.

  With this configuration, the gaming machine according to the present invention executes the effect based on the effect data stored in the effect data storage means corresponding to the pattern change pattern if the change pattern of 1 by the symbol change means is determined. Can be performed smoothly.

<Summary 14>
In the conventional gaming machine as described in Japanese Patent Application Laid-Open No. 2013-106670, the player often grasps the execution timing of the effect accompanied by the operation, and the unexpectedness of the effect is lost, and the operation is performed. There is a risk that the player's interest in the accompanying effect may be reduced.

  The gaming machine according to the present invention includes a presentation execution unit (sub CPU 201) for executing a presentation, and an operation detection unit (touch sensor 425) capable of detecting a predetermined operation, and a first presentation execution condition (for example, touch) The predetermined operation is detected by the operation detection unit in a state in which the first effect (for example, 1P effect or the touch point MAX effect) in which the point can establish 5) and the first effect execution condition are satisfied. At least the first effect is executed in a state in which the second effect (for example, the effect to be executed at a touch point of 5) and the first effect execution condition are satisfied. If the second effect execution condition (for example, a state where the touch point exceeds 5) can be satisfied and the second effect execution condition is satisfied, the operation detection unit And it has a configuration in which the third effect predetermined operations are performed in response to that detected (e.g., production which is performed in a state where the touch point exceeds 5), a.

  With this configuration, the gaming machine according to the present invention performs the second operation every time the execution condition of the second effect is satisfied or the third effect is performed, in order to execute the second effect. By allowing the player to select whether to perform a predetermined operation after waiting for the execution of the first effect after the execution condition of the effect is established, the player can select the effect to be executed. As a result, it is possible to improve the player's interest in the effect accompanied by the operation.

  In the gaming machine according to the present invention, the game is performed between the normal gaming state and the special gaming state capable of providing a predetermined gaming value to the player in comparison with the normal gaming state according to the predetermined transition condition. The game state transition means (main CPU 101) for transitioning the state is further provided, and the second effect and the third effect are in a game state (where the probability of shifting to the special game state is relatively high in the normal game state) For example, it may include a notification effect that suggests the possibility of being a latent probability change, and the effect executing means may execute the notification effects of the second effect and the third effect in different modes.

  With this configuration, the gaming machine according to the present invention can cause the player to select the content of the notification effect that suggests the possibility of being in the gaming state with a relatively high probability of transitioning to the special gaming state. It is possible to improve the player's interest in the accompanying presentation.

  Also, the gaming machine according to the present invention executes the first effect on the symbol variation means (main CPU 101) that performs variation of the symbol when the start condition is satisfied, and the variation pattern of the symbol by the symbol variation means. An effect data storage unit (program ROM 202) for storing effect data to be referred to at the time and effect data to be referred to when the first effect is not executed may be further provided.

  With this configuration, the gaming machine according to the present invention executes an effect based on the effect data stored in the effect data storage means corresponding to the pattern change pattern, if the pattern change pattern by the symbol change means is determined. Can be performed smoothly.

<Summary 15>
In a conventional gaming machine as described in JP 2013-106670 A, when high conditions are set to execute a specific effect, a considerable game is required to execute a specific effect. There is a risk that the interest to the game of the player who is expecting the specific effect will be reduced by having to perform the specific effect and the specific effect is not executed.

  The gaming machine according to the present invention comprises a presentation execution unit (sub CPU 201) for executing a presentation, an operation detection unit (touch sensor 425) capable of detecting a predetermined operation, and a clock unit (RTC 204) capable of measuring time. The first operation (for example, touch point MAX effect) that can establish a predetermined effect execution condition (for example, touch point is MAX) and the predetermined effect execution condition is satisfied by the operation detection unit A second effect (for example, an item transition effect) which is executed when a predetermined operation is detected, and a time measured by the clock means is a predetermined time (for example, an execution period of an RTC effect) When it is determined, regardless of whether or not the predetermined effect execution condition is satisfied, the operation detection means detects that the predetermined operation has been detected before. Having the structure and a rendering execution period capable of executing a second effect.

  With this configuration, the gaming machine according to the present invention executes a specific effect that is not executed when a predetermined condition is not satisfied, for a predetermined period, even if the predetermined condition is not satisfied, a specific effect It is possible to prevent the player's interest in playing the game from being lowered.

<Summary 16>
The conventional gaming machine as described in Japanese Patent Application Laid-Open No. 2013-106670 compulsorily plays a game only by performing effects such as urging a predetermined operation or urging passing a game medium to a predetermined area. May give the player the impression of being played, which may reduce the player's interest in the game.

  The gaming machine according to the present invention includes a gaming area in which gaming media can be moved, a symbol variation means (main CPU 101) that changes the symbol when the gaming medium passes the starting area and the starting condition is satisfied, Game state transition means (main CPU 101) capable of transitioning the game state to a special game state capable of giving a game value, and based on the passage when the game ball passes the start area at least during the fluctuation of the symbol Ejection medium detection which detects the game medium which passes the ejection area (the second special out port 420c) for ejecting the game medium from the game area by storing memory means (main RAM 103) which can hold and store the start condition and store it Means (second out ball detection sensor 117b), a profit giving means (main CPU 101) capable of giving a profit to the player when passing of the game medium is detected And an effect execution unit (sub CPU 201) for executing an effect, wherein the profit giving unit does not give a profit to the player when passage of the game medium is detected by the discharged medium detecting unit. The effect executing means can execute a predetermined effect when the game medium is detected by the discharged medium detecting means during the special game state, and the predetermined effect is the special game to the hold The special game transition suggestion effect that suggests the possibility that there is a suspension to shift to the state is included, and the effect execution means can execute the special game transition suggestion effect when the game medium is detected by the discharge medium detection means A gaming machine characterized by being.

  With this configuration, the gaming machine according to the present invention suggests that there may be a suspension of transitioning to the special gaming status upon suspension upon detection of gaming media passing through the predetermined outlet in the special gaming status. Execute special game shift suggestion effect.

  Therefore, the gaming machine according to the present invention does not give the player the impression of being forced to play a game by the progress of the game by the player in the special game state also serving as the effect, so the player's interest in the game Can be prevented from falling.

  In the gaming machine according to the present invention, the special game transition suggestion effect suggests that the first special game transition suggestion effect (for example, The second special game transition suggestion effect (for example, the presentation button that suggests that it is determined that there is a hold to shift to the special gaming state in the hold) and the effect that the shutter built in the effect button 16 moves) The shutter built in 16 is fully open, and the LED group 18 provided on the back side of the shutter emits light in rainbow colors), and the effect executing means The second special game shift suggestion effect may be performed in mutually different modes.

  With this configuration, the gaming machine according to the present invention can improve the attraction of the player to the game because it suggests the probability that there is a suspension of transitioning to the special gaming state on suspension.

<Summary 17>
In the conventional gaming machine as described in Japanese Patent Application Laid-Open No. 2013-31485, when the effect is executed over a plurality of changes as in the pre-reading effect, it is possible to respond to the determined change or the change during execution. It is necessary to select an effective rendition according to each change of a fixed change or an on-going change, considering that the rendition is determined. That is, the conventional gaming machine may not be able to improve the player's interest in the effects unless a combination of effective effects is taken into consideration.

  The gaming machine according to the present invention includes at least a gaming area in which gaming media can be moved, and a symbol variation means (main CPU 101) that performs variation of a symbol when the starting condition is established by passing the gaming medium. When the game ball passes through the starting area, a plurality of holding memory means (main RAM 103) capable of holding and storing the starting condition based on the passing, and variations based on the holding based on the passing, a plurality of times Continuous effect determining means (main CPU 101) capable of determining whether or not to continuously execute relevant continuous effects across fluctuations and whether or not the effect execution content is under execution of the continuous effects, and effect Continuous effect (e.g., pre-read continuous effect) for continuing the continuous effect as the effect execution content of the continuous effect (e.g., pre-read continuous effect) and The non-continuation effect which does not continue the continuation effect is included, the above-mentioned execution execution expedient, the execution contents of the continuous production of each fluctuation which the aforementioned continuation production decision expedient decides with the 1st timing and the timing after the 1st timing The content of the continuous rendition of each variation determined at a certain second timing is compared, and when the execution of the continuous rendition is determined for the same hold, it is determined at the first timing. The continuous effect is executed, and the continuous effect which is determined is executed when the continuous effect is determined for only one of the same suspension.

  With this configuration, the gaming machine according to the present invention is determined to set the determined effect for the corresponding hold if the effect is not determined for the same hold when the effect is determined. An effective rendition utilizing the rendition and the determined rendition can be executed, and the player's interest in the rendition can be improved.

<Abstract 18>
Although the conventional gaming machine as described in JP-A-2016-106752 can provide various information to the player by the effect, if there are too many types of effects performed in the same period, which It becomes difficult for the player to grasp what the effect represents, and conversely, there is a risk that the player's interest in the game may be reduced.

  A gaming machine according to the present invention includes a gaming area in which gaming media can be moved, and a gaming state transition means (main CPU 101) capable of shifting the gaming state to a special gaming state in which a predetermined gaming value can be given to a player. A game execution area (a sub CPU 201) for executing a game, and the game area is different from the first area (big winning opening 418) in which game media can pass in the special game state, and the first area And 2 areas (general winning opening 419d), and the effect executing means is a first effect (effect of winning another hole) to be executed when a game medium passes through the second area in the special game state, It is executed when the number of game media that has passed the first area exceeds at least a predetermined number during one period (each round game) in which the first area can pass in the special game state. Second stage ( And third effect (acquisition number display effect) according to the number of game values given to the player in the special game state, and the second effect is the first effect. The third effect is executed with a higher priority, and the third effect is executed with a lower priority than the first effect.

  With this configuration, the gaming machine according to the present invention can give priority to the effects of the plurality of types executed in the special gaming state, thereby facilitating the player with the contents represented by the effects. Since the user is made to grasp, it is possible to prevent the player's interest in the game from being reduced.

  In the gaming machine according to the present invention, the effect executing means performs the first effect and the first effect when the special gaming state satisfies a special condition (for example, when the number of consecutive big hits is five or more). The second game is performed when the number of game value awards given to the player in the special game state exceeds a predetermined number (for example, when the number of wins exceeds 2600) without executing the second effect. 3 production may be performed.

  With this configuration, the gaming machine according to the present invention does not execute a specific effect depending on the state of the special game state, or does not execute part of the special game state, thereby producing an effect pattern in the special game state. Can be prevented from lowering the interest of the player in the game.

1 Pachinko machine (game machine)
40 game board 41 game area 50 liquid crystal display device (display device)
90 Spacer (supporting member)
101 Main CPU (symbol changing means, gaming state transition means, profit giving means)
103 Main RAM (pending storage means)
113 Count sensor (detection means)
117b 2nd out sphere detection sensor (discharge medium detection means)
201 Sub CPU (effect execution means, effect determination means)
202 Program ROM (effect data storage means)
204 RTC (Timekeeping Means)
414b second starting opening (winning opening)
418 Large winning opening (winning area, first area)
419d General winning opening (winning opening, second area)
420c second special out (discharge area)
422a Shutter member (variable winning means)
424a Rib (1st reduction gear)
424b Rib (second decelerating means)
425 Touch Sensor (Operation Detection Means)
431 Special symbol display device (symbol display means)
601, 602, 603 Sphere passage 604 Merge portion 605 Partition plate (partition portion)
610 Lower movable effect member (feature)
611 Lower fixed base (fixed body)
611F Locking piece (first locking portion, locking means)
612 motor (driving means)
615 Lower movable base (movable body)
615B Locking piece (second locking portion, locking means)
617B Projection (first contact portion)
618 Movable arm (arm member)
621 Rotating body (movable body)
623 Base cover (guide member)
626 Ribs (Second Contact, First Rib, Second Rib)
650 Upper movable effect member (feature)
651B Swing shaft (base end)
655 Upper movable effect member (base body, first moving member)
657 Upper slide base 657 (first movable member, movable body, movable means, second movable member)
658 Movable slider (first engagement part)
662, 663 Movable arm (movable member)
662A, 663A gear portion 664, 665 gear (operating member)
664A Rib 666 Base rib (second engagement part)
668, 669 guide rails (guide members)
670 Guide piece (guided member)
672 Fixed wedge member (first movable member, movable means)
673 Movable wedge member (second movable member, movable means)
674 Coil spring (biasing member)
675 Base wall member (fixed member)
750 Right side movable effect member (displacement means)
761, 781 Guide projection (contact part)
770 Left side movable effect member (displacement means)
800 distribution device 801 distribution drum (rotary member)
Groove part (receiving part) 802A-802D
802a Mounting surface portion 803B, 804B Wall surface portion 803e, 804e 1st inclined surface 803f, 804f 2nd inclined surface 807 game ball 807a center point of game ball θ1 1st inclined surface inclination angle θ2 2nd inclined surface inclination angle

Claims (2)

A game area in which game media can be moved;
Gaming state transition means capable of transitioning the gaming state to a special gaming state capable of giving a predetermined gaming value to the player;
Providing an effect executing means for executing an effect;
The gaming area includes a predetermined area through which gaming media can pass in the special gaming state,
The effect executing means is
A specific display that is executed when the number of gaming media that has passed the predetermined area exceeds at least a predetermined number in at least one period in which the predetermined area can pass in the special gaming state;
It is possible to execute a special display according to the number of grants of the gaming value given to the player in the special gaming state,
When the specific display and the special display are displayed as an image display on the same display device, and the display positions of the specific display and the special display overlap, high priority is given to the front of the image of the effect to be executed with low priority. A game machine that superimposes and displays an image of an effect to be executed. A game area in which game media can be moved;
Gaming state transition means capable of transitioning the gaming state to a special gaming state capable of giving a predetermined gaming value to the player;
An effect executing means for executing an effect;
And a predetermined area through which game media can pass in the special game state.
The effect executing means is
A specific display to be executed when at least the special game state passes through the predetermined area and the first condition is satisfied;
When the second condition is established during the special game state, it is possible to execute a special display according to the game value given to the player,
When the specific display and the special display are displayed as an image display on the same display device, and the display positions of the specific display and the special display overlap, high priority is given to the front of the image of the effect to be executed with low priority. A game machine that superimposes and displays an image of an effect to be executed.

Images