JP7110160B2 - ball game machine - Google Patents

Description

TECHNICAL FIELD The present invention relates to a pinball game machine provided with a shooting handle for controlling the shooting intensity of game balls shot toward a game area.

Generally, in a pinball game machine, a player operates a rotary type shooting handle to control the driving force of a ball shooting device, thereby adjusting the shooting intensity of game balls toward a game area. This adjustment includes left-hand hitting adjustment in which the game ball flows down to the left side of the center case arranged substantially in the center of the game board, and right-hand hitting adjustment in which the game ball flows down to the right side of the center case. Considering that the game is usually played with the left hand and the shooting rate is adjusted so that the game ball enters the game start opening, it is important to adjust the shooting intensity when hitting the left hand, and the shooting intensity is as delicate as possible. Need to be able to adjust.

From this point of view, the variable resistor built into the shooting handle is configured so that the rate of change of the resistance value with respect to the amount of operation of the handle is varied with a predetermined resistance value as a boundary, thereby improving the flight strength of the game ball. It has been proposed to enable fine adjustment (Patent Document 1 below).

JP-A-11-33171

However, there are other factors to consider, such as the position of the board surface parts such as the return prevention piece, the center case, and the bouncer (buffer rubber) in the middle of the flight path of the game ball, especially the position of the top of the center case. be. The apex of the center case is a branch point that divides the flowing direction of the game ball into the left side and the right side. If the apex of this center case is not properly positioned in relation to the firing intensity versus firing handle rotation angle, i.e., to match the characteristics of the individual launcher, the center case will soon become unusable within a narrow range of firing handle rotation angles. It may happen that the game ball reaches the vertex of. For this reason, it is not always easy to build a relationship that enables delicate handle adjustment when hitting left in a pinball game machine.

SUMMARY OF THE INVENTION Accordingly, an object of the present invention is to solve the above problems and to provide a pinball game machine in which the apex of the center case is arranged appropriately in relation to the firing intensity with respect to the rotation angle of the firing handle.

The above objects of the present invention are achieved by the following means.
(1) a firing handle (32);
A variable resistor (firing intensity VR74) whose resistance value changes according to the operation of the firing handle;
A shooting means (shooting mechanism 17) for shooting game balls along the shooting rail;
a guide rail (46) arranged on the game board surface to form a game area;
a center case (47) arranged in the game area of the game board;
A launch guide passage (104) formed by a portion of the guide rail (a portion sandwiched between the first and second rails 46a and 46b) and guiding a game ball launched from the launch rail to the game area;
a return prevention piece (200) provided at the exit of the firing guide passage;
a vertex (201) which is formed integrally with or separately from the center case and serves as a branch point for dividing the flowing direction of the game ball into the left side and the right side of the center case;
a rebounding body (202) that receives the impact of the game ball flying to the right beyond the vertex;
Firing control means (firing control device 90) for controlling the firing intensity of the game ball by the firing means based on the resistance value of the variable resistor when the firing handle is rotated;
with
The variable resistor has a constant B-curve characteristic in a range from at least the rotation angle position θ1 of the handle when the game ball reaches the game area beyond the return prevention piece to the maximum rotation angle position θMAX,
A range A2 is from the rotation angle position θ1 of the shooting handle at which the game ball reaches the game area beyond the return prevention piece to the rotation angle position θ2 of the shooting handle at which the game ball reaches the vertex,
Rotation corresponding to 50% of the handle rotation angle range from the rotation angle position θ1 of the shooting handle at which the game ball reaches the game area over the return prevention piece to the handle rotation angle θ3 at which the game ball reaches the rebounding body. When the range B2 is up to the angular position θC,
Range A2 > Range B2
The vertices are arranged so that the relationship of
A pinball game machine characterized by :

According to the present invention, the placement of the apex of the center case can be made appropriate, and fine adjustment operation of the firing handle can be made possible during left-hand shots.

1 is an overall front view of a pinball game machine according to a first embodiment of the present invention; FIG. 1 is an exploded perspective view of a pinball game machine according to the present invention; FIG. 1 is a front view of a game board of a pinball game machine according to the present invention; FIG. 1 is a perspective view of a game board of a pinball game machine according to the present invention; FIG. 1 is an exploded perspective view of the front part of a game board of a pinball game machine according to the present invention; FIG. It is a diagram showing the configuration of the shooting handle of the pinball game machine according to the present invention, (A) shows a state in which the shooting lever is not operated, and (B) shows a state in which the shooting lever is operated. 1 shows the configuration of a shooting mechanism of a pinball game machine according to the present invention, where (A) shows a state in which game balls are supplied to a launch rail, and (B) shows a state in which game balls are shot with a mallet. is. 1 is a block diagram showing a launch control device for a pinball game machine according to the present invention; FIG. It is the figure which made the flow path of a game ball in the game board of FIG. 3 easy to understand. 1 shows the relationship between the rotation angle of the firing handle and the firing intensity of the firing mechanism of the pinball game machine according to the present invention, and (a), (b), (c), (d), and (e) are the first and second embodiments. , 3, 4, 5. It shows an example of a connection circuit of the firing intensity VR74 of the pinball game machine according to the present invention, (a) is an example of a circuit in which the resistance value changes linearly with respect to the rotation angle, and (b) is logarithmically It is a figure which shows the circuit example with which a resistance value changes. As a specific example of the game board according to the pinball game machine of the present invention, FIG. 13 is a diagram showing a base plate, a launch rail, and a center case that constitute the game board of FIG. 12; FIG.

<Embodiment 1>
A first preferred embodiment of the gaming machine according to the present invention will be described in detail below with reference to the drawings. In addition, in Embodiment 1 described below, a pachinko game machine will be described as an example of a pinball game machine according to the present invention.

<1. Overview of Configuration: Figures 1 and 2>

1 and 2, a gaming machine body 1 includes a wooden outer frame 2 and a front frame 3 arranged in front of the outer frame 2. As shown in FIG. The front frame 3 is pivotally attached to the outer frame 2 via a pair of upper and lower first hinges 4 arranged on the left end side so as to be freely openable and detachable. The outer frame 2 can be locked in the closed state by means of a locking means 5 provided in the outer frame 2. As shown in FIG.

The front frame 3 includes a body frame 6 and a glass door 7 arranged on the front side of the body frame 6. - 特許庁The glass door 7 is pivotally attached to the body frame 6 via a pair of upper and lower second hinges 8 arranged on the left end side so as to be openable and detachable. can be locked with The first hinge 4 and the second hinge 8 are arranged so as to be coaxial.

As shown in FIG. 2, the outer frame 2 is formed in a rectangular shape by a pair of left and right vertical frame members 2a and 2b and a pair of upper and lower horizontal frame members 2c and 2d. A front cover member 9 made of synthetic resin is attached to the front lower portion of the outer frame 2 so as to connect the front lower portions of the left and right vertical frame members 2a and 2b. The front cover member 9 protrudes forward from the left and right vertical frame members 2a and 2b, and the body frame 6 is arranged above it.

The body frame 6 is made of synthetic resin, and is formed in a rectangular shape that can be substantially abutted on the front edge side of the outer frame 2 on the upper side of the front cover member 9. The game board is provided with a rectangular opening on the upper side. A mounting portion 14 and a lower mounting portion 15 provided below the game board mounting portion 14 are integrally provided.

A game board 16 is detachably mounted on the game board mounting portion 14 from the front side, and on the front side of the lower mounting portion 15, as shown in FIG. are placed.

As shown in FIG. 2, the body frame 6 is integrally or separately provided with a surrounding wall 317 projecting rearward from the outer periphery of the game board mounting portion 14 . The surrounding wall 317 surrounds and protects the back side mechanism of the game board 16 mounted on the game board mounting portion 14 from the outer peripheral side.

As shown in FIG. 2 , the glass door 7 includes a resin door base 22 formed in a rectangular shape corresponding to the front side of the body frame 6 . A window hole 24a of a display window (glass window) 24 is formed in the door base 22 so as to correspond to the front side of the game area 23 formed on the game board 16. A plurality of upper speakers 25 are arranged at predetermined locations, and an upper decorative cover 27 is attached to substantially cover each speaker 25 from the front side.

Further, on the front side of the lower part of the door base 22, there is an upper tray 30 which stores the game balls put out from the putting out means 28 arranged on the rear side of the body frame 6 and supplies them to the shooting mechanism 17, and the upper tray 30. A lower tray 31 for storing surplus balls and the like when full, a shooting handle 32 for operating the shooting mechanism 17, etc. are arranged, and a lower decorative cover 33 substantially covers the upper tray 30, the lower tray 31, etc. from the front side. is installed. The lower decorative cover 33 is formed in a bulging shape facing forward, and operation means such as a performance button 34 that can be pressed by the player and a cross operation means 35 are provided on the upper side thereof. The cross-shaped operating means 35 has four operating portions, a rear upper key 35a, a front lower key 35b, a left left key 35c, and a right right key 35d.

A glass unit 36 is detachably attached to the rear side of the door base 22 so as to substantially block the window hole 24a from the rear side, and is arranged along the edges of the first and second hinges 4 and 8. a vertical hinge end side reinforcing sheet metal 37 arranged along the edge of the opening and closing end side; a vertical opening and closing end side reinforcing sheet metal 38 arranged along the edge of the opening and closing end side; The metal plate 39 is detachably fixed by screws or the like. Further, on the door base 22, a glass door upper hinge metal fitting 40 and a glass door lower hinge metal fitting 41 constituting the second hinge 8 are arranged at the upper left portion and the lower left portion, respectively.

A ball feeding unit 42, a lower tray guide unit 43, and the like are attached to the rear side of the lower reinforcing sheet metal 39. As shown in FIG. The ball feeding unit 42 is for feeding game balls in the upper tray 30 to the shooting mechanism 17 one by one, and is arranged corresponding to the front side of the shooting mechanism 17 . The lower tray guide unit 43 guides surplus balls when the upper tray 30 is full and foul balls that have returned without reaching the game area 23 despite being shot by the shooting mechanism 17 to the lower tray 31. It is arranged adjacent to the ball feeding unit 42 on the side of the first and second hinges 4 and 8 thereof.

<2. Game board: Fig. 4, Fig. 5>

As shown in FIG. 4, the game board 16 comprises a substantially rectangular base plate 45 made of non-transparent material such as plywood or made of transparent material such as synthetic resin. A guide rail 46 for guiding the game ball fired from the shooting mechanism 17 (FIG. 2) to the upper side of the game area 23 is mounted in an annular shape, and the game area 23 inside the guide rail 46 (FIG. 3, 4), a center display frame unit (hereinafter referred to as a center case) 47, a start winning unit 48, a large winning unit 49, a normal winning unit 50, and other game parts, as well as a windmill and a large number of game nails (not shown). ) is placed.

In addition, on the plurality of unit parts 47 to 50, in addition to various display means such as a normal symbol display device 51, a normal reserved number display device 52, a first special symbol display device 53, a second special symbol display device 54, etc. A symbol starting port 55, a first special symbol starting port 56, a second special symbol starting port 57, a big winning port 58, a plurality of normal winning ports 59, etc. are provided. 4, a liquid crystal display (LCD) 60 as image display means is mounted on the rear side of the base plate 45 via a rear mounting base 61. As shown in FIG.

As shown in FIG. 4, the rear mounting base 61 includes a rear wall portion 66 formed substantially parallel to the base plate 45 and having a rectangular opening 66a formed substantially in the center thereof, and an outer edge of the rear wall portion 66. A peripheral wall portion 67 extends forward from the base plate 45 to the rear surface of the base plate 45, and a front edge portion of the peripheral wall portion 67 protrudes along the rear surface of the base plate 45 and is fixed to the base plate 45 by a fixing screw or the like. A vertically elongated liquid crystal display device 60 is detachably fixed to the back side of the back wall portion 66 while being housed in a housing case 69 . .

*
(2-1. Base plate 45: FIG. 5)

FIG. 5 is an exploded perspective view of the game board 16. As shown in FIG.
As shown in FIG. 5, the base plate 45 is formed in a substantially rectangular shape when viewed from the front, and has a plurality of base plates 45, for example, three base plates, for mounting a center case 47, a starting winning unit 48, a large winning unit 49, a normal winning unit 50, and the like. Two mounting holes 62 to 64, an out port 65, and the like are formed to penetrate in the front-rear direction. The mounting hole 62 is for mounting the center case 47 and is provided substantially in the center of the game area 23 . The mounting hole 63 is for mounting the starting winning unit 48 (first special symbol starting port 56), and the mounting hole 64 is for mounting the normal winning unit 50 (normal winning port 59). is provided in The out port 65 is arranged at the bottom of the game area 23 .

(2-2. Guide rail 46: Fig. 5)
Referring to FIG. 5, the guide rail 46 is arranged on the front side of the base plate 45 of the game board 16 so as to surround the outer peripheral side of the game area 23. A ball is guided to the upper side of the game area 23 through a shooting guide passage 104 sandwiched between the first and second rails 46a and 46b. A large number of game nails (not shown) are arranged in the game area 23, and a game ball driven into the upper part of the game area 23 through the guide rail 46 flows down the left flow path on the left side of the vertex 201 of the center case 47. 108a or the right flowing path 108b on the right side to flow down on the game board surface.

The guide rail 46 is formed of three first to third rail members 101 to 103 as shown in FIG. The first rail member 101 is made of synthetic resin, and is detachably attached to the front side of the base plate 45 along the left edge and the upper edge. The arc-shaped side surface (inner side surface) serves as a first rail 46a that constitutes part of the guide rail 46 (outer guide surface).

The second rail member 102 is made of metal. , forming a second rail 46 b that constitutes a part of the guide rail 46 . A portion sandwiched between the first rail 46a and the second rail 46b serves as a shooting guide passage 104 that guides the game ball shot by the shooting mechanism 17 to the game area 23. As shown in FIG.

A return prevention piece 200 is provided at the upper end of the second rail member 102, that is, at the exit of the firing guide passage 104. As shown in FIG. The return-preventing piece 200 prevents the game ball once entering the game area 23 from the outlet of the shooting guide passage 104 from returning to the shooting guide passage 104 again, and interferes with the next shooting operation of the game ball. It is a member to avoid this.

The third rail member 103 is made of synthetic resin. The side surface of the game area 23 side is a third rail 46c that constitutes a part of the guide rail 46. As shown in FIG. The first rail member 101 and the third rail member 103 may be divided into a plurality of parts along the rail longitudinal direction.

The first rail member 101 has a left pillar portion 101a, a lateral upper portion 101b integrally continuing from the upper portion of the left pillar portion 101a, and an upper right corner portion 101c integrally continuing from the lateral upper portion 101b. The upper right corner portion 101c of the first rail member 101 is connected to the upper portion of the portion forming the right column portion of the third rail member 103. As shown in FIG. The inner surface (first guide rail 46a) of the left column portion 101a, the lateral upper portion 101b, and the upper right corner portion 101c of the first rail member 101, and the inner surface of the upper portion of the third rail member 103 about two-thirds (second 3 guide rail 46 c ) is a curved surface along one large radius arc as a whole and forms the outer guide rail of the guide rail 46 . A stepped portion that functions as a rebounding body (buffer member) 202 is provided in the upper right portion (upper right corner portion 101c) of the outer guide rail 46a. This bounce body 202 protects the game board member by absorbing the impact when the game ball hit by the mallet 85 of the shooting mechanism 17 collides, and directs the game ball toward the center of the game area 16. By bouncing back, the game ball struck by the mallet 85 works to eliminate the inconvenience of being directly taken into the out port 65 along the third rail 46c.
In the case of this embodiment, the bounce body 202 is made of synthetic resin and integrated with the first rail member 101 . However, the rebounding body 202 can also be provided as a separate member from the first rail member 101 using soft synthetic resin, rubber, or the like.

(2-3. Center case 47: Figures 4 and 5)
As shown in FIG. 4, in the game area 3a, a center case 47 is provided on the front side of the liquid crystal display device 60 so as to surround the display surface in a long way. The center case 47 constitutes a display frame of the liquid crystal display device 60 and is detachably attached from the front side of the base plate 45 along the inner circumference of the attachment hole 62 . As shown in FIGS. 3 to 5, the center case 47 has a front mounting plate 105 arranged outside the mounting hole 62 along the front surface of the base plate 45, through which game balls can pass, and a liquid crystal display. The armor frame portion 106 is arranged in a substantially gate shape extending from the left and right sides to the upper portion on the front side of the device 60 and protrudes forward on the inner peripheral side of the front mounting plate 105, and the left and right lower ends of the armor frame portion 106. and a stage 107 (see FIGS. 3 and 4) arranged between the units.

The center case 47 protects the display surface of the liquid crystal display device 60 from the surrounding game balls, and allows the game ball to be distributed to the left and right according to the launch strength or stroke length of the game ball. Acts as a sorting means. In this embodiment, between the upper surface of the armor frame portion 106 of the center case 47 and the ball guide rail (first rail 46a), a play area through which game balls can pass is formed. The game ball hit on the upper side of the is distributed to the left and right at the vertex 201 of the upper outer peripheral surface of the armor frame portion 106, and either the left flow path 108a on the left side of the center case 47 or the right flow path 108b on the right side. flow down

The center case 47 is provided with a warp entrance (left passage port) 109 through which game balls can flow in at least one of the left flow path 108a side and the right flow path 108b side, for example, the left flow path 108a side. . The game ball that has flowed into the warp entrance 109 enters the armor frame 106, rolls freely in the left-right direction on the stage 107, and then hits the center drop part 110 provided corresponding to the center in the left-right direction of the game area 23. It falls forward from either the (stage concave portion) or the other portion.

In addition, an entry prevention means (slope) 111 is provided on the upper side of the stage 107 to prevent the game ball from entering the rear side due to rebounding or the like. The entry prevention member 111 is entirely transparent, and the rear side can be visually recognized from the front side through the entry prevention member 111 .

(2-4. First Unit 47a and Second Unit 47b)
Referring to FIG. 5, center case 47 covers the outer peripheral side of liquid crystal display device 60 from the front side and forms display window 24 corresponding to liquid crystal display device 60 inside. The center case 47 is provided with a first unit 47a and a second unit 47b which are divided in the circumferential direction so as to surround the display window 24. It is detachably attached to the front side of the game board 16 with screws or the like. Note that the center case 47 is provided with a first unit 47a and a second unit 47b which are divided into two in the circumferential direction. can be divided into

As shown in FIG. 5, the first unit 47a includes a front mounting plate 105 arranged along the front surface of the game board 16 outside the mounting hole 62 and through which game balls can pass. A decorative armor frame portion 106 is provided on the front side of the front mounting plate 105 (over both left and right sides from the vertex 201 side) in a substantially gate shape when viewed from the front and protrudes forward on the inner peripheral side of the front mounting plate 105. A window frame portion 106a is formed in the armor frame portion 106 so as to be bent rearward from the inner periphery thereof to be arranged in the mounting hole 62 and surround the display window 24 from the outer periphery.

The front mounting plate 105 and the armor frame part 106 define the game area 23 on the outer peripheral side of the center case 47 . On the outer peripheral surface of the upper side of the armor frame portion 106, there is formed a vertex 201 that serves as a branch point for distributing the game ball hit into the upper part of the game area 23 through the guide rail 46 to the left flow path 108a or the right flow path 108b. ing. Specifically, the vertex 201 is formed by a convex portion or a step that becomes the highest portion (top portion) when the center case 47 is arranged within the board surface of the game board 16 (base plate 45). In the case of this embodiment, the apex 201 is formed by a stepped wall (a step corresponding to approximately one game ball) in which the outer peripheral surface of the upper side of the armor frame portion 106 is higher on the right side than on the left side.

Various display means such as a normal symbol display device 51, a normal reserved number display device 52, a first special symbol display device 53, a second special symbol display device 54, etc. are arranged at appropriate positions on the front side of the first unit 47a. there is

The second unit 47b has a stage 107 for dropping the game ball from the front side of the game board 16 to the first special symbol starting port 56, and a warp entrance for guiding the game ball flowing down the left flow path 108a side to the stage 107. 109 are provided.

The second unit 47b is arranged between the left and right lower end portions of the window frame portion 106a of the first unit 47a and the like. A plate 105, a stage 107 arranged on the upper side of the front mounting plate 105, and an entry prevention member 111 arranged on the rear side from the upper side of the stage 107, and both the left and right ends are the left and right lower ends of the first unit 47a. It is detachably connected to the part with a screw or the like.

(2-5. Accessories of center case 47: Fig. 5)
The normal symbol start port 55 is for starting the variable display of normal symbols by the normal symbol display device 51, and is composed of a passage gate or the like through which the game ball can pass, and is a passage detection means ( (illustration omitted). This normal symbol starting port 55 is provided on the front side of the front mounting plate 105 in the right part of the center case 47, and the game balls flowing down the right flowing path 108b can pass through.

In the center case 47, on the right sleeve portion of the armor frame portion 106, a normal design display device 51 (normal design display means) in which a plurality of (two in this example) LEDs are arranged, and a plurality of (this example A normal reserved quantity indicator 52 is provided, which is formed by arranging four (4) LEDs.

In the normal symbol display device 51 according to the present embodiment, a normal symbol variation display game is executed by a normal symbol variation display operation represented by two LEDs. For example, as a variable display operation, the normal symbols by the LED alternately turn on and off in a seesaw manner, and by stopping with one side lit up, the propriety of the normal symbol variable display game is made clear. there is And when the stop symbol after the variation of the normal symbol display device 51 becomes a winning mode (assisted winning), a normal profit state occurs. When it becomes this "ordinary profit state", the opening and closing plate 112 is in an open state, the second special symbol start opening 57 is opened or expanded and the game ball is easily introduced (start opening open state), and normal A profit state occurs that is more advantageous to the player than the state.

The normal reserved number indicator 52 operates as follows. When the normal symbol starting port 55 detects the game ball during the normal holding period including during the symbol fluctuation of the normal symbol display device 51 and during the normal profit state, the normal random number information acquired thereby is predetermined. Up to 4 of the upper limit reserved number are reserved and stored, and each time the normal reserved period ends, one is consumed, and the normal pattern is changed on the normal reserved number display 52.例文帳に追加The stored number (normal reserved number) of this normal random number information is displayed by the normal reserved number display 52 and notified to the player.

The first special symbol starting port 56 is for starting the symbol variation (first special symbol variation display (first special symbol variation display game)) by the first special symbol display device 53, and does not have opening/closing means. It is composed of non-openable winning means, and includes game ball detection means (not shown) for detecting a winning game ball. This first special symbol starting port 56 is provided in the starting prize winning unit 48, and is arranged in an upward opening shape on the lower side corresponding to the central drop portion 110 of the stage 107, and is the warp entrance on the left downstream path 108a side. Since there is a winning route from stage 109 to stage 107, a game ball that has flowed down the left flow path 108a can win a prize at a higher probability than a game ball that has flowed down the right flow path 108b. .

The second special symbol starting port 57 is for starting the symbol variation (second special symbol variation display (second special symbol variation display game)) by the second special symbol display device 54, and opening and closing of the opening/closing portion 112. It consists of opening and closing type winning means (so-called electric chew) that can change between an open state in which a game ball can win a prize and a closed state in which a game ball cannot win (or is more difficult to win than in the open state). A game ball detecting means (not shown) for detecting is provided. The winning area of the second special symbol starting port 57 is an open state (easy winning state) that facilitates winning according to the operating state (operating or non-operating) of the opening and closing part 112, and a winning state that is easier to win than the open state. It is converted to a closed state (difficult-to-win state) that makes it difficult or impossible to win. In this embodiment, when the opening/closing part 112 is inoperative, the closed state (non-winning state) is maintained in which the second special symbol starting port 57 cannot be won. The opening/closing part 112 is opened when a normal profit state occurs when a stop symbol (result of the normal symbol variation display game) after the normal symbol fluctuation in the normal symbol display device 51 becomes a winning mode (predetermined mode). performs opening and closing operations in a predetermined opening pattern, and changes from the closed state to the open state for a predetermined period of time.

This second special symbol starting port 57 is arranged on the front mounting plate 105 in the right part of the first unit 47a of the center case 47 and on the downstream side of the normal symbol starting port 55, and flows down the right flowing path 108b. A game ball can win a prize. The opening/closing plate 112 is swingable around a rotation axis in the left-right direction provided on the lower side. The front side of the front mounting plate 105 protrudes (opens) in a downwardly inclined manner to allow game balls to win backwards.

The first special symbol display device 53 is composed of a 7-segment LED display capable of displaying one or more (one in this example) first special symbols, and the first special symbol starting port 56 is The first special symbol is variably displayed for a predetermined time on the condition that the game ball is detected, and the jackpot determination random value included in the first special random number information acquired when the game ball is detected by the first special symbol start port 56 is preliminarily set. If it matches with a predetermined big win determination value, it stops in the first big win mode, and in other cases, it stops in the first losing mode. When the stop symbol after the variation of the first special symbol display device 53 becomes the first jackpot mode, the first special profit state occurs.

The second special symbol display device 54 is composed of a 7-segment LED display capable of variably displaying one or more (one in this example) second special symbols, and the second special symbol starting port 57 is The second special symbol is variably displayed for a predetermined time on the condition that the game ball is detected, and the jackpot determination random value included in the second special random number information acquired when the game ball is detected by the second special symbol start port 57 is preset. If it matches with a predetermined big win determination value, it stops in the second big win mode, and in other cases, it stops in the second losing mode. When the stop symbol after the variation of the second special symbol display device 54 becomes the second jackpot mode, the second special profit state occurs.

A first special symbol display device 53 is arranged in the armor frame portion 106 on the left sleeve portion of the first unit 47a in the center case 47, and a second special symbol display device 53 is arranged in the armor frame portion 106 on the right sleeve portion of the first unit 47a. A special symbol display device 54 is arranged. The first and second special designs are not numeric designs, etc., but consist of a plurality of types of designs consisting of a combination of lines and points that have no special meaning per se, and one or more of those designs is the first design. 1, 2nd jackpot mode, other than that is the 1st, 2nd loss mode.

In addition, during the symbol variation of the first special symbol display device 53, during the symbol variation of the second special symbol display device 54, and during the special holding period including the first and second special profit states, the first and second special symbol start When the means 56 and 57 detect game balls, the first and second special random number information acquired thereby are retained and stored up to a predetermined upper limit retained number, for example, 4 each. Then, when the second special pattern side reserved memory is 1 or more at the end of the special reserved period (when the pattern fluctuation start condition regarding the second special pattern is satisfied), the reserved memory of the second special pattern is digested. Then, the variation of the second special symbol is performed, and when only the reserved memory on the side of the first special symbol is 1 or more (when the symbol variation start condition regarding the first special symbol is satisfied), the first special symbol is suspended. The memory is digested and the variation of the first special symbol is performed.

In this way, in this embodiment, both the first special symbol and the second special symbol are not fluctuating, and when both the first special symbol side and the second special symbol side have pending memory. , the variation of the second special symbol is preferentially performed. The number of stored first and second special random number information (first and second special reserved numbers) is notified to the player by the number of icon images or the like on the liquid crystal display device 60 .

The big winning port 58 is provided in the big winning unit 49 and has an opening/closing plate 113 that can switch between an open state in which a game ball can win and a closed state in which a game ball cannot win. This big winning opening 58 is arranged downstream of the second special symbol start opening 57 at the bottom of the ball flow downstream of the outer circumference of the right sleeve of the center case 47, and is located to the right of the game ball that has flowed down the left downstream path 108a. A game ball that has flowed down the flow path 108b can win a prize with a higher probability. This big winning opening 58 is the first and second special symbols generated when the first and second special symbols of the first and second special symbol display devices 53 and 54 stop in the first and second jackpot modes after the variation. During the profit state, the opening/closing plate 113 is opened forward according to a predetermined opening pattern, and the game balls dropped thereon enter inside.

<3. Launch Handle 32 and Launch Device>
The firing device is composed of firing handle 32 , firing mechanism 17 and control device 90 .

(1) Structure of firing handle 32: FIG.
FIG. 6 shows the configuration of the firing handle (set) 32 . The firing handle 32 includes a firing lever (operating handle) 71 , a firing stop button 72 , a touch sensor 73 , a firing intensity VR (variable resistor) 74 and a firing stop switch 75 .

The firing handle 32 includes a grip portion 70 (FIG. 2) fixed to the lower front surface of the front frame 3, more precisely, the lower front portion of the door base 22, and a firing lever 71 rotatably provided on the grip portion 70. equipped. The grip portion 70 is composed of two members, a rear half body fixed to the front frame 3 and a front half body fixedly coupled thereto. A touch sensor 73, a firing intensity VR 74, a firing stop switch 75, and a return spring 78 are incorporated in the front half body.

The firing lever 71 is interlocked with the firing strength VR74 by connecting (or directly connecting) the gear G1 provided on the rotating shaft 76 to the gear G2 provided on the rotating shaft 87 of the firing strength VR74. FIG. 6A shows a state in which the firing lever 71 is not operated. When the firing lever 71 is rotated clockwise against the force of the return spring 78 as indicated by the arrow in FIG. The rotary shaft 77 is rotated to vary the resistance value of the shooting strength VR74, thereby making it possible to adjust the shooting power of the hit ball.

In addition, the firing stop button 72 is provided so as to be able to advance and retreat in the radial direction with respect to the firing handle 32, and by pressing it, the internal firing stop switch can be turned ON/OFF. The touch sensor 73 is intended to sense that the firing lever 71 of the firing handle 32 is gripped, and is made of a planar or annular member that is plated or the like to have conductivity. Although it is provided on the front surface or the back surface of the grip portion 70 in the above, it can also be provided in an annular shape around the grip portion 70 .

The touch sensor 73 is input to the control device 90 . The control device 90 has a touch determination section that is electrically connected to the plated portion and detects whether or not the player has touched the plated portion based on a change in electrostatic capacitance. The control device 90 is configured so that the shooting mechanism 17 shoots the game ball only while receiving the contact detection signal from the touch sensor 73 . As a result, it is possible to prevent the player from performing an illegal shooting operation without gripping the grip part 70. - 特許庁

(2) Structure of firing mechanism 17: FIG.
As shown in FIG. 2, the lower mounting portion 15 of the body frame 6 is provided with a firing mechanism 17 . FIG. 7 shows the configuration of this launching mechanism 17. As shown in FIG.

In FIG. 7, reference numeral 80 denotes a mounting board attached to the lower mounting portion 15 of the body frame 6, and the shooting mechanism 17 is constructed by providing the following elements on the mounting board 80. As shown in FIG.

In FIG. 7(A), the firing rail 81 is a member that is arranged on the mounting board 80 so as to be diagonally upward to the left. is provided so as to follow the first rail 46a. The protrusion 82 is a member arranged opposite to the launch rail 81 with a gap therebetween. A ball fixing portion 83 is formed. A game ball 84 is supplied from the upper tray 30 to the game ball stationary portion 83 through the ball feeding unit 42, and waits as shown in FIG. 7(A).

A hammer 85 is an inverted L-shaped member, and an elastic member is provided at a tip portion 85a thereof. Firing solenoid 87 is the firing drive source and in this embodiment comprises a rotary solenoid. The base of the mallet 85 is fixed to the rotation output shaft 86 of the firing solenoid 87, and can be reciprocally rotated in the direction of the arrow in FIG. It has become. The stoppers 88 and 89 are members that limit the reciprocating rotational movement of the mallet 85 within a predetermined rotational angle range and determine the non-rotating position and the rotational position of the mallet 85 .

FIG. 7A shows the standby state before the game ball 84 is shot by the mallet 85. FIG. In this standby state, the game ball 84 is supplied to the game ball stationary portion 83 on the launch rail 81 and is stopped, and the tip portion 85a of the mallet 85 is at a position away from the game ball stationary portion 83, which is precisely the return spring. is stopped at a position where it abuts against the stopper 88.

FIG. 7B shows the state after the game ball 84 has been shot by the mallet 85. FIG. When the firing solenoid 87 is energized, the mallet 85 is rotated against a return spring (not shown), and more accurately, the mallet 85 is rotated to a position where it abuts against the stopper 89 . As a result, the tip portion 85a of the mallet 85 enters the game ball stationary portion 83 and hits the game ball 84, so that the game ball 84 is ejected.

*
(3) Launch control device: Fig. 8
FIG. 8 shows the control system of the launcher. Reference numeral 90 denotes a firing control device (fire control board) connected to a main control device (main control board: not shown) composed mainly of a microcomputer, and includes a firing intensity setting circuit 91, a firing timing generation circuit 92, and a firing It includes a drive circuit 93 and a ball feed control circuit 94 . The touch sensor 73, the firing intensity VR 74, and the firing stop switch 75 are connected to the input side of the firing control device 90, and the firing solenoid 87 and the ball feed solenoid 42a are connected to the output side. Although not shown, the control device of the gaming machine 1 according to the present embodiment includes a main control board (main control means) for overall control of overall game operations (game operation control), and a main control board (main control means). A performance control board (performance control means) that receives a performance control command from the board and controls the execution (appearance) of the performance by the performance means (performance control means), and a payout control board (payout control means) that controls the payout of prize balls. and a power board (power control means) that generates and supplies necessary power (including backup power) from an external power source to each board of the gaming machine. Further, the production control board is connected with a liquid crystal display device 60 as an image display device, production LEDs (light production means), speakers 18 and 25, and other production means. Under the control of the effect control board, the liquid crystal display device 60 independently displays a plurality of types of decorative patterns (for example, left pattern, middle pattern, Various effects including the variable display operation (variable display and stop display) of the three decorative patterns on the right are displayed by images.

In the special symbol display devices 53 and 54, the 'special symbol variation display game (first special symbol variation display game, second special symbol variation display game)' by the variation display operation of 'special symbols (special symbols 1 and 2)' ' is supposed to be executed. In the above-mentioned liquid crystal display device 60, the variable display of the decorative design by the image is performed in synchronization with the variable display of the special design by the special design display devices 53 and 54, and various advance notice effects (effect images) are performed. Along with this, the 'decorative pattern variation display game' is executed.

When the above-described special symbol variation display game is started, along with this, the decorative symbol variation display game is started by variably displaying decorative symbols (dramatic game symbols) on the liquid crystal display device 60, and accompanying this, Various productions are developed. When the special pattern variation display game ends, the decorative pattern variation display game also ends, and the special pattern display device reflects the predetermined special pattern indicating the big win lottery result, and the liquid crystal display device 60 reflects the big win lottery result. A decorative pattern is derived and displayed. In other words, the result of the special symbol variation display game is reflected and displayed by the decorative symbol variation display game including the decorative symbol variation display operation.

Therefore, for example, when the result of the special symbol variation display game (the result of the big win lottery) is "big hit", the decorative symbol variation display game develops an effect that reflects the result. Then, in the special symbol display device, when the special symbol is stopped and displayed in a display mode indicating a big hit (for example, the display state of "7" in the 7 segment), the liquid crystal display device 60 displays "left", "middle", and "right". ” in each display area, the decorative pattern reflects the “big hit” (hit pattern: for example, in each of the “left”, “middle” and “right” display areas, the three decorative patterns are “7”, “ 7” and “7” display modes). When the "big hit" is achieved, specifically, the special symbol variation display game ends, and the decorative symbol variation display game ends accordingly, and as a result, the "big win" symbol mode is derived and displayed. After that, the jackpot game is started. In this jackpot game, until the opening time of the big winning hole 58 by the opening/closing plate 113 elapses for a predetermined time (maximum opening time: for example, 29.8 seconds), or until the number of winning balls into the big winning hole 58 reaches the maximum winning number. The winning area is opened or expanded until it reaches (the upper limit of the number of winning balls allowed for the winning opening whose entrance is opened or enlarged by one actuation of the accessory: for example, 10), If any of these conditions are met, the big winning mouth is closed (satisfaction of the round game end condition (closure condition)). round) repeated.

Returning to the description of FIG. 8, the firing intensity VR74 has three terminals: a potential application side terminal a, a ground side terminal b, and a wiper side terminal (variable output terminal) c. These three terminals are connected to the emission intensity setting circuit 91 of the emission control device 90 via connection lines. As shown in FIG. 11(a), in the emission intensity setting circuit 91, a DC potential is applied to the potential application side terminal a via the first resistor R1, and the ground side terminal b is applied via the second resistor R2. grounded. These first resistor R1 and second resistor R2 may be omitted. Then, the potential between the wiper side terminal c and the ground side terminal b is input to the first input terminal of the operational amplifier of the firing intensity setting circuit 91 as an output voltage based on the variable resistance value of the firing intensity VR74. It's becoming A signal from the current detection circuit in the firing drive circuit 93 is input to the second input terminal of this operational amplifier. Therefore, the operational amplifier of the firing intensity setting circuit 91 adjusts its own output signal according to the variable resistance value of the firing intensity VR74 while referring to the signal of the current detection circuit in the firing drive circuit 93. FIG. The output of this operational amplifier determines the magnitude of the drive current for the firing solenoid 87 via the firing drive circuit 93 . Therefore, the firing solenoid 87 is driven by a DC current having a magnitude corresponding to the operation amount (rotational angle θ) of the firing handle 32 (firing lever 71).

The firing control device 90 also has a firing timing generation circuit 92, to which a firing control signal (fire timing signal) 95 from a main control device (not shown) is input. . This firing control signal 95 is a firing timing signal for obtaining a predetermined timing (for example, firing within 99 game balls per minute), and is a firing timing signal formed in a main controller (not shown). This is the signal sent from the timing signal generation circuit.

In addition to the firing control signal 95, signals from the touch sensor 73 and the firing stop switch 75 are also input to the firing timing generating circuit 92. part 70), and on the condition that the firing stop switch 75 is OFF (the firing stop button 72 is not pressed), based on the firing control signal (fire timing signal) 95, the game ball The firing drive circuit 93 is energized and controlled to allow firing.

Further, the shooting control device 90 has a ball feed control circuit 94 which drives and controls the ball feed solenoid 42 a of the ball feed unit 42 .

(4) Configuration of right-handed disadvantage under normal state (non-electrical support state) In the gaming machine 1 of the present embodiment, the first special symbol start port 56 is in the left flow path 108a, and the right flow path 108b includes: There are a normal symbol starting port 55, a second special symbol starting port 57 (so-called electric chew) with an opening/closing plate 112, and a big prize winning port 58 with an opening/closing plate 113. As for the game performance, when the game state is the normal state, the ball is entered into the first special symbol starting port 56, a big hit lottery related to the first special symbol is performed, and the fluctuation display of the first special symbol is performed, A game (first special symbol variation display game) for displaying the result of the jackpot lottery is played. When winning the jackpot lottery related to this first special symbol, a jackpot game is generated.

When the big hit game ends, the big winning opening 58 is closed, and the game state can be shifted to a game state (for example, a probability variable state or a time saving state) with "state with electric sapo (electric sapo state)". In this embodiment, one or a plurality of types of "probability variable jackpot" that triggers the transition to the variable probability state and/or "shorter working hours jackpot" that triggers the transition to the shorter working hours state are provided. In the variable probability state, the jackpot lottery probability fluctuates from a predetermined normal probability (low probability in the normal state: for example, 1/300) to a high probability (for example, 1/30), and the electric support state (privilege game state) is changed. Occur. In addition, in the time saving state, the jackpot lottery probability remains at a predetermined normal probability (low probability), but a state with an electric support occurs. In addition, in the variable probability state and the time saving state, a "special symbol time saving state" occurs in which the average execution time of the special symbol variation display game is shorter than in the normal state. In addition, the probability variation state and the time saving state are the number of executions of the special symbol variation display game (the total number of executions of the first special symbol variation display game and the number of executions of the second special symbol variation display game) without winning the big hit. reaches a predetermined upper limit number of times (for example, 100 times), the process ends and the normal state is entered.

When it comes to the game state with the above "electric sapo state", the opening and closing plate 112 of the second special symbol starting port 57 operates in an opening and closing pattern that is more advantageous than at least the normal state (normal game state). Specifically, when the ball enters the normal symbol starting port 55, an "assisted winning lottery" based on normal random number information is performed, and based on the result of this lottery, the normal symbol on the normal symbol display device 51 is variably displayed to display the normal symbol. A variable display game is started, and after a predetermined variable time elapses, the result is stopped and displayed by a combination of lighting and non-lighting of the LEDs. For example, when the result of the normal symbol variation display game is "assist hit", the display unit of the normal symbol display device 51 is stopped and displayed in a specific lighting state (for example, two LEDs 39 are all lit). In the case of this "assist hit", the opening and closing plate 112 of the second special symbol starting port 57 opens and closes in a predetermined opening and closing pattern, but under the state with the electric sapo, the opening and closing plate 112 is in the normal state with respect to the normal profit state. The opening/closing operation is performed in an opening/closing pattern that is more advantageous than the normal state, and a normal profit state that is more advantageous than the normal state is generated. In addition, under the state with the electric support, the auxiliary winning lottery probability by the auxiliary winning lottery fluctuates from a predetermined normal probability (low probability in normal state: for example, 1/256) to a high probability (for example, 255/256), and , "Normal symbol time saving state" in which the average execution time of the normal symbol variation display game is shorter than the normal state is generated. Therefore, under the state with the electric sapo, the auxiliary hit is likely to occur, the normal profit state occurs frequently, and the operating rate improved state in which the operating rate of the opening and closing plate 112 per unit time is improved compared to the normal state. It will be in the base game state. As a result, under the game state with the ``state with electric sapo'', the ball is easily entered into the second special symbol starting port 56, the big winning lottery relating to the second special symbol is performed, and the variable display of the second special symbol is performed. Then, the second special symbol variation display game is performed. In addition, one or more types of variable probability big hits and/or short-time jackpots may be provided in the jackpot lottery related to the first special pattern, and one or more types of variable probability big wins and/or short-time big wins may be provided in the jackpot lottery related to the second special pattern. may be provided. In the case of the present embodiment, the jackpot lottery related to the second special pattern has a higher probability of selecting the type of jackpot with a relatively higher profit than the jackpot lottery related to the first special pattern, and the lottery is advantageous to the player. It has become. That is, the game development is more advantageous for the player to receive the lottery in the second special symbol variation display game than in the first special symbol variation display game. In particular, in the state with the electric sapo, the probability of winning at the starting port 57 side is dramatically improved and the chance of executing the second special symbol variation display game also increases, so the state with the electric sapo is a high base game state. In addition, the game state is advantageous for the player from the viewpoint of the big winning lottery.

In this embodiment, when the player aims at the launch position on the side of the big winning opening 58 (when aiming so that the game ball passes through the right flow path 108b), the game ball enters the normal symbol start opening 55. Although it is easy to win, the game ball is difficult to be guided to the first special symbol starting port 56 side, or is not guided. In addition, if it is in a normal state (a state in which the player is not in an advantageous state such as a jackpot game or an electric sapo state), even if the ball is entered in the normal symbol start port 55, the auxiliary hit in the normal symbol variation display game will not occur. The lottery is in a low probability state, and most of the game balls are invalid balls (dead balls). Also, it is almost impossible to win the first special symbol starting port 56 in the left flow path 108a by striking to the right. Therefore, right-handed hitting in the normal state (no electric sapo state (non-electrical sapo)) is disadvantageous for the player (left-handed hitting is advantageous for the player). On the other hand, if the electric sapo is present, the game ball is aimed to pass through the right flow path 108b instead of "left hitting" which aims to make the game ball pass through the left flow path 108a. "Right-handed" is considered advantageous. That is, depending on the game state, the progress of the game works to the player's advantage or disadvantage depending on which of the left-flowing path 3b and the right-flowing path 3c the game ball is allowed to flow down.

(5) Flow path For the above reasons, under normal conditions, the "right-handed hitting" in which the game ball flows down to the right side area from the top 201 of the center case 47 is not adopted. It will adopt "left-handed hitting" that flows down. FIG. 9 shows the flow paths (routes) a, b, c, and d that become the left flow path 108a when the left-handed stroke is adopted, and the flow-down path (route) e which becomes the right flow path 108b when the right-handed stroke is adopted. are indicated by arrows in an easy-to-understand manner. Of these routes, the route d indicates the path along which the game ball bounces off the vertex 201 . If the shooting strength of the game ball exceeds the return ball prevention piece 200 and is within the range of rebounding at the vertex 201, the game ball is hit left and the game ball flows down through any of routes a, b, c, and d.

In the left area of the center case 47 of the game area 23, one or more game ball flow-down guide means such as nails, projections, steps, etc. are provided, and a plurality of flow-down paths (routes a, b, c, d) is formed, and it is configured such that it is possible to select which flow path to flow down by adjusting the discharge intensity. In the right area of the center case 47, there is provided a common flow path (route e) that commonly guides the game balls after passing the vertex 201, and a plurality of flow paths (routes f, g) are provided on the downstream side thereof. It is impossible or difficult to select which flow path to flow down by adjusting the firing intensity.

Here, the "game ball flow-down guide means" provided in the left area is an element such as a nail, projection, step, or the like, which affects the flow direction of the game ball, and the nail, projection, or step is used singly or in combination. Therefore, as a configuration in which a flow-down path is formed in the left-hand region, (i) a configuration in which a plurality of flow-down paths are formed by dividing the left-hand region in the lateral direction by one or more "nails", and (ii) A mode in which the left region is divided by one or more "protrusions" to form a plurality of flow-down paths, (iii) A left-side region is divided by one or more "steps" to form a plurality of flow-down paths (iv) A configuration in which the left region is divided by a combination of “nails” and “protrusions” to form multiple flow paths, (v) A configuration in which the left region is divided by combining “protrusions” and “steps” and (vi) a form in which a plurality of flow-down paths are formed by dividing the left side area by combining "steps" and "protrusions". One flow-down path is also formed between the game ball flow-down guide means (for example, step 12) located at the highest level among them and the vertex 201 (see route d in FIG. 9).

Referring to FIGS. 4 and 5, in the case of the present embodiment, the flow path guide projections 10 and 11 are formed on the front mounting plate (mounting plate) 105 on the upper left part of the center case 47 in the advancing direction (horizontal direction) of the game ball. It is set before and after. Further, a barrier 12 with a step is provided on the left side wall of the armor frame portion 106 of the center case 47 . These passage guide projections 10, 11 and a barrier 12 formed by a step act as a game ball flow-down guide means. After all, in the left region, between the return prevention piece 200 and the vertex 201, there are two flow path guide projections 10, 11 and one step as elements (game ball flow guide means) that affect the flow direction of the game ball. Barriers 12 formed by steps are provided back and forth in the traveling direction of the game ball. As a result, the left flow path 108a is divided into four flow paths a, b, c, and d shown in FIGS. A first route a whose entrance is the space between the anti-return piece 200 and the flow path guide projection 10a, and the space between the flow path guide projections 10 and 11, when viewed in the direction in which the game ball advances from left to right. A second route b as an entrance, a third route c as an entrance in the space between the flow path guide projection 11 and the barrier 12, and a route d that rebounds at the vertex 201 and ends up in any of the routes a, b, and c. and

In the case of "left hitting" in which the game ball flows down to the left area from the vertex 201 of the center case 47 in the game area, the shooting intensity is adjusted so as to select one of the routes a, b, c, and d. become. Adjust the firing intensity so that it will be any of the routes a, b, c, d, and which of the four routes a, b, c, d the game ball is directed to is the first special symbol that is the target This is very important for the player because it affects whether or not the game ball can enter the starting hole 56 . Even if one of the four routes a, b, c and d is selected, the game ball does not reach the first special symbol starting port 56 if the momentum of the batted ball is too weak. Even if the momentum of the hit ball is too strong, it will be bounced off by nails and windmills and cannot be successfully entered. This is because the direction and strength in which the game ball flows is not constant even within the same route, and the player is required to finely adjust the strength of the discharge as an operation of the discharge handle.

On the other hand, in the right side area (right flowing path 108b) of the center case 47 of the game area, a common flowing path (route e) is formed to commonly guide the game balls after passing the vertex 201 of the center case 47. , it is impossible or difficult to select the downflow path (routes f, g) of the game ball after passing through this common downflow path e by adjusting the launch intensity. That is, when the game ball is hit to the right in the game area beyond the vertex 201 of the center case 47 and flows down to the right area, as shown in FIGS. Since it only flows down through one common flow path (route e), there is no means for the player side to select a flow path (routes f, g) that branch off from the route e.

In this way, the game area 23 has a plurality of flow-down paths in both the left side area and the right side area of the center case 47 . Of these routes, for the routes a, b, c, and d for the left region (left flow path 108a) of the center case 47, one of these routes can be selected by adjusting the firing intensity by the operation amount of the firing handle. is possible. However, as for the right side area (right flow path 108b) of the center case 47, after passing through the vertex 201, it is divided into a plurality of flow paths (routes f, g) after passing through one common flow path (route e). Therefore, these routes f and g cannot be selected by adjusting the emission intensity. In this respect, the case of selecting the left side area of the center case 47 (left flow path 108a) is significantly different from the case of selecting the right side area of the center case 47 (right flow path 108b).

(6) Handle rotation angle θ and firing intensity F
When the firing device is energized at the handle rotation angle .theta.A (see FIG. 10), current flows through the firing solenoid 87 in the firing device body (firing mechanism 17), and the mallet 85 in the firing device body repetitively moves. start the launching motion. The repetitive hitting action of the mallet 85 is the action of striking the game ball 84 sent onto the launch rail 81 with the mallet 85 reciprocatingly rotating and ejecting the game ball 84 along the launch rail 81. Repeat a predetermined number of times per minute.

The force (shooting intensity) for ejecting the game ball along the shooting rail depends on the intensity of the current flowing through the shooting solenoid 87 in the shooting device main body. The intensity of the current flowing through the firing solenoid 87 changes depending on the resistance value of the firing intensity VR74 (current adjusting element) that is adjusted by operating the handle. That is, the shooting intensity of the game ball struck by the mallet 85 depends on the handle operation amount (handle rotation angle θ) of the shooting device.

In the case of the firing characteristics of FIG. 10, as shown by the straight line graph, the firing intensity F and the steering wheel rotation angle θ are in a proportional relationship. The emission intensity F increases in proportion to this. This is because the firing intensity VR74 (variable resistor) has a B curve in which the resistance value changes linearly with respect to the rotation angle.

When the handle operation amount is less than the handle rotation angle θ=θA to θ1, the firing intensity is still weak and cannot exceed the return ball preventing piece. Therefore, in order to hit the game ball into the game area of the game board, it is necessary to increase the handle operation amount to the handle rotation angle θ1 or more. After that, the player adjusts the firing intensity of the shooting device within the range of the handle rotation angle θ=θ1 to θMAX so as to be suitable for left-handed or right-handed shots.

The steering wheel rotation angle .theta.B is a position where the amount of steering wheel operation is exactly half (50% of the maximum steering wheel rotation angle .theta.MAX). The handle rotation angle .theta.3 is the position at which the shot ball hits the rebounding body 202 (buffer member) at the entrance of the channel on the right side of the game board with a shooting intensity F3.

(5) Firing characteristics of the launcher and placement of the top of the center case 47 As described above, the firing intensity VR74 uses a B-curve variable resistor whose resistance value changes linearly with respect to the rotation angle. there is Therefore, the shooting control device 90 changes the shooting intensity of the game ball according to the rotational operation amount (rotational angle) of the shooting handle 32 (shooting lever 71), that is, the resistance value of the shooting intensity VR74.

FIG. 9 shows that, in the process of assembling a game machine having such a shooting device, the center case 47 is placed at a proper position on the game board 16 with the guide rail 46 provided on the base plate 45 and the apex 201 thereof. It shows a state in which it is installed with consideration given to In order to make it easier to understand the path along which the game ball flies or rolls, the contours of the inner peripheral surfaces of the guide rails 46 (first, second and third rails 46a, 46b, 46c) and the outer peripheral surface of the center case 47 are shown. It is drawn in bold. The mounting position of the center case 47 is determined so that the apex 201 of the armor frame 106 has a positional relationship exceeding 50% of the steering wheel rotation angle .theta.

Specifically, FIG. 10 shows the relationship between the handle rotation angle θ and the firing intensity F (board part), and the horizontal axis represents the handle rotation angle θ (0 to MAX), which is the amount of operation of the firing handle 32. , and the vertical axis represents the launch strength F, which is the force for ejecting the game ball along the launch rail 81 . Here, the firing intensity F is expressed with the position of the board surface component as a guideline. That is, the launch intensity F is determined by the position of the anti-return piece 200 (strength reaching the anti-return piece 200), the position of the vertex 201 of the center case 47 (strength reaching the vertex 201), and the strength of the rebounding body 202. The position (strength reaching the rebounding body 202) is used as a guideline.

A θ-F graph 97 showing the relationship between the steering wheel rotation angle θ and the firing intensity F is a straight line in this example. In other words, the resistance value of the firing intensity VR74 increases linearly with the amount of steering wheel operation (handle rotation angle θ), and the firing intensity F increases linearly as the steering wheel rotation angle θ increases. be.

The θ-F graph 97 in FIG. 10 is a guideline for what position the vertex 201 of the armor frame 106 should be placed in relation to the rotation angle θ and the firing intensity F when the center case 47 is attached. is shown.

Let θ2 be the rotation angle position of the vertex 201 to be arranged now. That is, let θ2 be the rotation angle position at which the shot intensity F2 at which the shot game ball reaches the vertex 201 of the center case 47 is obtained. Where to place the vertex 201 is equivalent to moving the intersection point P1 between the firing intensity F2 and the rotational angle position θ2 for this vertex 201 on the θ-F graph 97 .

Assume now that the firing handle 32 is rotated to the central position θB of the maximum operable range (θ0 to θMAX), that is, to the 50% position of the maximum rotatable range of the firing intensity VR74 (variable resistor). Suppose that the vertex 201 is arranged so that the game ball reaches the vertex 201 with a launch intensity F2, that is, the intersection point P1 on the θ-F graph 97 is set at the intersection point P2. think. A problem when the intersection point P1 is set at the position of the intersection point P2 in this way is that it becomes difficult to adjust the game ball to flow to the left downstream path 108a. That is, the operable range in which the shooting handle 32 can be adjusted so as to flow the game ball to the left flow path 108a is half of the maximum operable range θ0 to θMAX of the shooting handle 32, that is, the maximum rotatable range of the firing intensity VR74. is limited to a range of up to 50% (θ0 to θB), when the player tries to adjust the firing intensity so as to flow the game ball to the left flow path 108a, the degree of change per unit angle becomes rough, It becomes difficult to adjust the force of left-handed hitting by steering wheel operation.

Therefore, in order to solve this problem, in the present embodiment (Embodiment 1 in FIG. 10(a)), the position at which the vertex 201 of the center case 47 is arranged (the position of the intersection point P1 on the θ-F graph 97) is That is, the position of the handle rotation angle θ2 corresponding to the vertex 201 is determined to be at a position exceeding 50% (θ0 to θB) of the maximum operable range θ0 to θMAX of the shooting handle 32.

That is, as shown in FIG. 10 as (a) Embodiment 1,
Range A1 = The range A1 (range of θ0 to θ2) is from the position θ0 at which the rotation angle of the launch handle is zero to the handle rotation angle θ2 at which the game ball reaches the vertex 201,
Range B1 = Range B1 (range of θ0 to θB) from the position θ0 at which the rotation angle of the launch handle is zero to the handle rotation angle θB corresponding to 50% of the maximum operable range θ0 to θMAX in which the launch handle can be rotated.
Then, the following formula (1) Range A1 (θ0 to θ2) > Range B1 (θ0 to θB) (1)
The top portion 201 of the center case is arranged so that the relationship of

Here, one "range A1" (range of θ0 to θ2) corresponds to the steering wheel rotation angle (steering wheel operation amount) up to the steering wheel rotation angle θ2 corresponding to the vertex 201. It is a virtual movement range when the position of the angle θ2 (the intersection point P1 on the θ-F graph 97) is moved. It does not matter whether it ends at the angle θA. Here, for convenience of explanation, it is assumed that the θ-F graph 97 rises linearly from the rotation angle θ0. “Range B1” (the range of θ0 to θB), which is the comparison target of the other “range A1”, is the handle rotation amount up to the handle rotation angle θB corresponding to 50% of the maximum operable range θ0 to θMAX of the firing handle 32. (handle operation amount), which is determined only by the handle rotation angle as a measure, but is indicated as P2 on the θ-F graph 97 in preparation for the case where the firing intensity F should also be taken into account.

Next, as to how far the upper limit of "range A1", that is, the position of P1 (rotation angle position θ2 reaching the vertex 201 of the center case) can be shifted to the right on the θ-F graph 97, the position of P1 is The rotation angle position θ3 (P3 on the θ-F graph 97) at which the game ball directly hits the bounce body 202 (buffer member) is stopped in the angle range before. It is preferable to widen the range A1 (θ0 to θ2), but if the position of P1 is moved too far to the right on the θ-F graph 97, for example, the position of P1 on the θ-F graph 97 will be shifted to P3. If the game ball is moved to the right side close to , the game ball that has passed the vertex 201 immediately hits the rebounding body 202 (buffer member) when hit to the right. As a result, there is a risk that a game ball that has passed over the vertex 201 and entered the right side will rebound to the left side, or that the momentum of the game ball flowing down the right flow path 108b will be extremely weakened. Therefore, it is preferable that the maximum angular position at which the position of P1 can be shifted to the right is up to the middle of P2 and P3 on the θ-F graph 97 . For example, if the interval length from the rotational angular position .theta.B to the rotational angular position .theta.3 is X, the maximum angular position of P1 is preferably stopped within about 1/2 to 2/3 of the interval length X. In the case of FIG. 10, the position of P1 (rotation angle position θ2) on the θ-F graph 97 at which the vertex 201 of the center case is arranged is set at the position of ⅓ of the interval length X between θB-θ3. As to how far the lower limit of "range A1", that is, the position of P1 (rotation angle position θ2 reaching the vertex 201 of the center case) can be shifted to the left on the θ-F graph 97, the above range A1>range It is determined by the relational expression of B1.

As described above, if the vertex 201 of the center case is arranged so that the relationship of "Range A1 (the range of θ0 to θ2)>Range B1 (the range of θ0 to θB)" of the above equation (1) is satisfied, the "maximum operation Compared to the case where the vertex 201 is arranged so that the game ball reaches the vertex 201 at the 50% position of the possible range, the launch intensity F is such that the game ball flows down the left downflow path 108a. The adjustment range of the rotation angle (rotational angle range) when adjusting is widened, and the adjustment of the firing intensity F at the time of left-handed hitting is facilitated. Therefore, it is difficult to determine which of the routes a, b, and c the flow path should be, and how much force (handle operation amount) should be applied after setting the flow path to one of the routes a, b, and c. Easier to adjust.

<Embodiment 2>
Next, Embodiment 2 will be described. In the first embodiment, the range A1 and the range B1 are considered based on the position θ0 at which the steering wheel rotation angle is zero. In this second embodiment, "Range A2" and "Range B2" are considered based on the handle rotation angle θ1 (P4 on the θ-F graph 97) reaching the game area beyond the anti-return piece 200, and range A2> The relationship of the range B2 is used as a condition for arranging the vertex 201 of the center case.

In FIG. 10, the handle rotation angle θ1 on the horizontal axis indicates the rotation angle position (P4 on the θ-F graph 97) corresponding to the shooting intensity F1 at which the shot ball crosses the return ball prevention piece 200 and reaches the game area. . In Embodiment 2 of FIG. 10(b), "Range A2" and "Range B2" are considered based on the steering wheel rotation angle θ1 (P4 on the θ-F graph 97) corresponding to the return ball prevention piece 200. It is. In addition, regarding "Range B2", which is a comparison target of "Range A2", from the rotation angle position θ1 (P4 on the θ-F graph 97) of the shooting handle when the game ball reaches the game area beyond the return prevention piece 200, Focus is placed on the rotation angle position θC corresponding to 50% of the handle rotation angle range (θ1 to θ3) up to the handle rotation angle θ3 (P3 on the θ-F graph 97) at which the game ball reaches the bounce body 202. .

That is, Embodiment 2 of FIG. 10(b) is
"Range A2" = Range A2 (range A2 ( range of θ1 to θ2),
“Range B2”=Handle rotation angle θ3 at which the game ball reaches the rebounding body 202 (P3 ) up to the rotation angle position θC corresponding to 50% of the handle rotation angle range (θ1 to θ3) is defined as range B2 (the range of θ1 to θC),
Formula (2) below Range A2 (θ1 to θ2) > Range B2 (θ1 to θC) (2)
The vertex 201 of the center case is arranged so that the relationship of

The upper and lower limits of range A2 are the same as those already described for range A1 in the first embodiment.

If the vertex 201 of the center case is arranged so that the relationship of "Range A2>Range B2" in the above equation (2) is satisfied, the maximum operable range will be 50% as in the case of the above equation (1). Compared to the case where the apex 201 is arranged so that the game ball reaches the apex 201 at the position, the adjustment range of the rotation angle when flowing the game ball to the left flow path 108a is expanded, so the launch strength F at the time of left hitting can be easily adjusted.

<Embodiment 3>
Next, Embodiment 3 will be described. In Embodiment 3 of FIG. 10(C), the range A3 is the same as the range A1 of Embodiment 1 of FIG.

That is, in the first embodiment shown in FIG. 10(a), the range B1 is from the steering wheel rotation angle zero (θ0) to 50% of the maximum operable range (handle rotation angle θB), and this range B1 is used as a comparison target for the range A1. , the condition for arranging the vertex 201 of the center case (Range A1>Range B1). On the other hand, in the third embodiment shown in FIG. 10C, the same range as the range A1 in the first embodiment is adopted as the "range A3", and the steering wheel rotation angle θMAX (θ− The steering wheel rotation angle range up to P5) on the F graph 97 is defined as "range B3", and this range B3 is used as a comparison target for range A3 (= range A1), and the condition for arranging the vertex 201 of the center case (range A3 > range B3) is considered.

In FIG. 10, the steering wheel rotation angle .theta.MAX on the horizontal axis indicates the maximum rotation angle position (P5 on the .theta.-F graph 97) which is the operation limit beyond which the steering wheel cannot be rotated. In the third embodiment, the operation range (the range of θ2 to θMAX) from the steering wheel rotation angle θ2 corresponding to the vertex 201 of the center case to the maximum rotation angle position θMAX is defined as “range B3”.

That is, Embodiment 3 of FIG. 10(C) is
Range A3 = Range A1 = A range A3 (range of θ0 to θ2) is defined from the position θ0 at which the rotation angle of the shooting handle is zero to the rotation angle position θ2 of the shooting handle at which the game ball reaches the vertex 201 of the center case,
Range B3 = Range B3 (range of θ2 to θMAX) is defined as the range from the rotational angle position θ2 of the firing handle at which the game ball reaches the vertex 201 of the center case to the maximum rotational angular position θMAX at which the firing handle can be rotated.
Formula (3) below Range A3 (θ0 to θ2) > Range B3 (θ2 to θMAX) (3)
The vertex of the center case is determined so that the relationship of

The upper and lower limits of range A3 are the same as those already described for range A1.

When the apex 201 of the center case is arranged so as to satisfy the relationship of "Range A3>Range B3" in the above equation (3), the game ball is directed to the left flow path 108a as in the first and second embodiments. At the time of left-handed hitting, the rotation angle adjustment range of the handle is widened, so that it is possible to obtain the effect of facilitating adjustment of the firing intensity F of left-handed hitting.

<Embodiment 4>
Next, Embodiment 4 of FIG. 10(d) will be described. In the fourth embodiment, the same range as the range A2 of the second embodiment shown in FIG. 10B is adopted as the "range A4", and the following "range B4" is newly considered as a comparison target.

That is, in Embodiment 2 of FIG. 10(b), the handle rotation angle θ1 at which the game ball reaches the game area beyond the return prevention piece 200 is used as a reference, and the handle rotation angle at which the game ball reaches the rebounding body 202 from this θ1. Up to 50% of the handle rotation angle range (θ1 to θ3) up to θ3, up to the handle rotation angle θC (from P4 to P22 on the θ-F graph 97) is defined as “range B2”, and this range B2 is set from θ1 to the game ball. A condition (range A2>range B2) for arranging the vertex 201 of the center case was considered as a comparison target of the "range A2" up to the steering wheel rotation angle θ2 at which the vertex 201 is reached.

On the other hand, in Embodiment 4 of FIG. 10(d), the range A2 of Embodiment 2 is the same as "Range A4". The steering wheel rotation angle range up to the steering wheel rotation angle θ3 (P5 on the θ-F graph 97) reaching the return body 202 is defined as “range B4”, and this range B4 is used as a comparison target for range A4 (= range A2), and the center case , the condition (range A4>range B4) for arranging the vertex 201 of is considered.

That is, Embodiment 4 of FIG. 10 (d) is
"Range A4" = Range A4 (range A4 ( range of θ1 to θ2),
"Range B4" = Range B4 (range of θ2 to θ3) from the rotation angle position θ2 of the shooting handle at which the game ball reaches the vertex 201 of the center case to the rotation angle position θ3 of the shooting handle at which the game ball reaches the rebounding body 202 ), then
Formula (4) below Range A4 (θ1 to θ2) > Range B4 (θ2 to θ3) (4)
The vertex 201 of the center case is arranged so that the relationship of

The upper and lower limits of range A4 (point P1) are the same as those already described for range A1 in the first embodiment.

If the vertex 201 of the center case is arranged so as to satisfy the relationship of "range A4 (θ1 to θ2)>range B4 (θ2 to θ3)" in the above equation (4), the above (1) to (3) As in the case of the formula, compared with the case where the vertex 201 is arranged so that the game ball reaches the vertex 201 at the position of 50% of the maximum operable range, the adjustment of the rotation angle when the game ball flows down to the left flow path 108a Since the range is expanded, it is possible to obtain the effect of facilitating the adjustment of the firing intensity F when hitting to the left.

<Embodiment 5>
Next, Embodiment 5 of FIG. 10(e) will be described.
When the firing handle 32 is operated, the firing solenoid 87 and the ball feed solenoid 42a are not energized immediately, but are energized after being slightly turned to the right. In FIG. 10, the range of the handle rotation angle θ0 to less than θA in the initial stage is a section in which the firing solenoid 87 of the firing mechanism 17 is not yet energized, that is, a "play zone". It is fired after passing (θ0 to less than θA).

Of the game balls shot from the shooting rail 81 by the hammer 85 of the shooting mechanism 17, the game balls that did not reach the game board surface, that is, the game balls that could not fly out before the return prevention pieces 200 are called foul balls. After staying in the launch guide passage 104 (guide rail), it is returned to the upper plate 30 through the foul ball gutter on the back surface of the upper plate. When the shooting handle 32 is operated to the handle rotation angle .theta.1, the game ball reaches the shooting intensity F1 that exceeds the return prevention piece 200 and reaches the game area, and the foul ball disappears.

When the handle operation amount reaches the "handle rotation angle θA", the firing solenoid 87 of the firing device is energized from that point. In the case of this example, the position of the handle rotation angle θA at which the firing device is energized is set within the range of 15 to 25% of the total operating range in FIG.

Embodiment 5 of FIG. 10 (e) is
Range C = Range C is from the position θ0 at which the rotation angle of the firing handle is zero to the handle rotation angle position θA at which the firing operation is started when the firing solenoid 87 of the firing mechanism 17, which is the firing means, is energized.
Range D = When the range D is from the handle rotation angle position θA at which energization starts to the handle rotation angle position θ1 at which the game ball reaches the game area after exceeding the return prevention piece 200,
Formula (5) below Range C (θ0 to θA) > Range D (θA to θ1) (5)
The excitation of the firing solenoid 87 in the firing control device 90 is controlled so that the relationship is as follows.

In other words, the section length Y from the handle rotation angle zero (θ0) to the handle rotation angle θ1 where the game ball exceeds the return prevention piece 200 is divided into two, and the right half (Y/2) is the section length Y. A steering wheel rotation angle θA at which energization is started is placed at an arbitrary position within the section.
in short,
θ1=Handle rotation angle at which the game ball reaches the game area beyond the return prevention piece 200,
θ4=rotation angle position corresponding to 1/2 of section length Y from steering wheel rotation angle θ0 to steering wheel rotation angle θ1,
Assuming that θA is the steering wheel rotation angle position at which energization is started,
Equation (6) below θ4<θA≦θ1 (6)
θA (handle rotation angle at which energization starts) is set so that the relationship of

In this way, the range of launch rotation angles θ0 to θ4 out of the launch rotation angle range (θ0 to θ1) corresponding to the launch intensity range (F0 to F1) where the game ball cannot exceed the return prevention piece 200 Since the energization is stopped not only in the section of the left half of the section length Y, but also in the range from the firing rotation angle θ4 to θA, compared to the case where the energization is started in this section of the firing rotation angle θ4 to θA. , the number of foul balls at the start of the game can be reduced. Note that the steering wheel rotation angle position θA at which energization is started can be expanded up to the position θ1 at the maximum.

Although Embodiment 5 of FIG. 10 (e) has been described above as a single one, in Embodiments 1 to 4 of FIGS. 10 (a) to (d), Embodiment 5 It is possible to add a configuration for controlling the relationship of "θ4<θA≦θ1".

<Specific example>
FIG. 12 shows a game board 16 constructed by sequentially providing a guide rail 46 and a center case 47 on a base plate 45 shown in FIG. When attaching the center case 47 (FIG. 13) to the game board 16 provided with the guide rails 46, consideration is given so that the vertex 201 comes to a position that satisfies any one of the above formulas (1) to (4). In other words, the game board 16 is not designed so that the apex 201 of the center case 47 is uniformly positioned at the same position regardless of the type of launcher, but constitutes a mounted launcher. Considering the characteristics of the firing handle 32, the firing mechanism 17, and the firing control device 90, the apex 201 is designed so that it satisfies any of the above equations (1) to (4). There is FIG. 12 shows the game board 16 as a result of arranging the vertex 201 at a position that satisfies any one of the above expressions (1) to (4).

Further, with respect to the game board 16 shown in FIG. 12, the rotation angle position .theta.A to which the power is supplied is controlled so as to satisfy the above formula (5), and the generation of foul balls is suppressed as much as possible.

<Modification 1>
In Embodiments 1 to 5 above, a B-curve variable resistor whose resistance value changes linearly with respect to the rotation angle is used as the firing intensity VR74 (see FIG. 11(a)). was described as being characteristic of the linear θ-F graph 97 shown in FIG. However, as the emission intensity VR74, it is also possible to use an A-curve variable resistor whose resistance value changes logarithmically with respect to the rotation angle.

Further, as shown in FIG. 11(b), a resistor R3 is connected between the potential application side terminal a having a firing intensity VR74 and the slider side terminal c, and the ground side terminal b and the slider side terminal c are connected. By connecting the resistor R4 between , it is possible to obtain a non-linear characteristic other than the B-curve, for example, a curved characteristic similar to that of a variable resistor with an A-curve. In this way, the rate of increase in the resistance value can be reduced to the lower side of the resistance value, that is, beyond the small to middle range of the firing rotation angle. Due to the overall resistance value characteristics of the firing intensity VR74, the angle range of left-handed steering wheel operation is further expanded to a region exceeding 50% of the maximum angle range, making it easier to adjust the firing force when hitting left-handed. can do.

<Modification 2>
In the above embodiment, the apex 201 is formed by a step that is low on the left side and high on the right side when viewed in the radial direction of the arc of the guide rail 46, but it acts as a branching point that divides the hit ball into the left flow path and the right flow path. The vertex 201 can be configured by means other than steps. For example, the highest point on the outer peripheral surface of the armor frame portion 106 can be the vertex 201 .

INDUSTRIAL APPLICABILITY The present invention is useful for gaming machines.

1 game machine body,
2 outer frame,
3 front frame,
7 glass doors,
16 game board,
17 firing mechanism (launching device body),
32 firing handle,
42 ball feeding unit,
45 base plate,
46 guide rails,
46a to 46c 1st rail to 3rd rail,
47 center case,
71 firing lever,
72 fire stop button,
73 touch sensor,
74 firing intensity VR (variable resistor),
75 firing stop switch,
81 launch rail,
85 Hammer,
87 firing solenoid,
90 launch control device,
104 launch guide passage,
106 armor frame,
108a left downstream path,
108b right downstream path,
200 anti-return piece,
201 vertex,
202 ricochets.

Claims (1)

a firing handle;
A variable resistor whose resistance value changes according to the operation of the firing handle;
a launching means for launching the game ball along the launch rail;
a guide rail arranged on the game board surface to form a game area;
a center case arranged in the game area of the game board;
a launch guide passage formed by a part of the guide rail and guiding a game ball launched from the launch rail to the game area;
a return prevention piece provided at the exit of the firing guide passage;
a vertex that is formed integrally with or separately from the center case and serves as a branch point that divides the flowing direction of the game ball into the left side and the right side of the center case;
a rebounding body that receives the impact of the game ball flying to the right beyond the vertex;
a shooting control means for controlling the shooting intensity of the game ball by the shooting means based on the resistance value of the variable resistor when the shooting handle is rotated;
with
The variable resistor has a constant B-curve characteristic in a range from at least the rotation angle position θ1 of the handle when the game ball reaches the game area beyond the return prevention piece to the maximum rotation angle position θMAX,
A range A2 is from the rotation angle position θ1 of the shooting handle at which the game ball reaches the game area beyond the return prevention piece to the rotation angle position θ2 of the shooting handle at which the game ball reaches the vertex,
Rotation corresponding to 50% of the handle rotation angle range from the rotation angle position θ1 of the shooting handle at which the game ball reaches the game area over the return prevention piece to the handle rotation angle θ3 at which the game ball reaches the rebounding body. When the range B2 is up to the angular position θC,
Range A2 > Range B2
The vertices are arranged so that the relationship of
A pinball game machine characterized by:

Images