JP5109106B2 - Game machine - Google Patents

Description

  The present invention relates to a gaming machine using game balls.

  In some conventional gaming machines, a center case having an opening window facing a display unit of a variable display device that displays a plurality of identification information in a variable manner is disposed in a game area of the game board.

  At the bottom of the center case, a stage on which a game ball taken from an opening provided on the side of the center case rolls is arranged, and the game ball discharged from the stage to the game area wins a winning opening. Whether or not a game is played.

As this type of gaming machine, Patent Document 1 discloses that a magnet arranged above a stage is moved and a ball suspended by the magnet is guided to a ball passage section in which a winning opening is arranged directly below. Is disclosed.
JP 2005-177083 A

  In the gaming machine disclosed in Patent Document 1, since the entrance of the ball passage portion is provided in the center of the stage and the magnet reciprocates in the left-right direction of the stage, when the magnet is located on one end side of the stage, Magnetic force does not act on the game ball that rolls on the other side of the stage, reducing the interest of the player.

  The present invention has been made in view of the above problems, and an object thereof is to improve the interest of games.

According to a first aspect of the present invention, there is provided a variable display device that displays a plurality of pieces of identification information in a variable manner, a center case that is provided in a game area of a game board and has an opening window that faces the display portion of the variable display device, A winning area disposed below, wherein the center case has a warp passage for guiding a game ball flowing down the gaming area of the game board into the center case, and an inner side of the center case. A stage extending in the left-right direction at the bottom and rolling the game ball guided from the warp passage, and the stage is disposed on the back side, and the game ball guided from the warp passage is rolled. A first stage portion that moves, a second stage portion that is disposed on the near side and that causes a rolling game ball to flow down to a game region in which a winning area is disposed, the first stage portion, and the first stage 2 stage Partition the bets, comprising a partition wall for regulating the back and forth to each other, and upward disposed rod of the stage along the partition wall, the electromagnet is more supported at predetermined intervals, the electromagnet Swings in the front-rear direction over the first stage portion and the second stage within a predetermined angle range with the rod as a rotation axis, and the electromagnet is in an excited state above the first stage portion, by a demagnetized state at above the second stage unit, game ball adsorbed to the electromagnet of the first stage portion during rolling is induced in the second stage portion across said partition wall, said The first stage portion is provided with a first guide path for guiding a game ball not attracted to the electromagnet to a lower stage disposed below the stage, and a central portion of the lower stage is provided at the center portion of the lower stage. , The ridge formed The game balls guided from the first guide path to the lower stage are in contact with the raised portion and distributed in the left-right direction, flow down to the game area, and roll to the second stage portion. A second guiding path for guiding the game ball to the winning area is provided.

According to a second aspect of the present invention, the stage is formed in an arc shape with both right and left sides being high and the center portion being low, and the magnetic force of the electromagnet disposed on the center side of the first stage portion is that of the electromagnet disposed on the side portion side. It is characterized by being set larger than the magnetic force.

According to a third aspect of the present invention, excitation and demagnetization of the electromagnet can be switched separately by each electromagnet, and the number of the electromagnets that are in an excited state above the first stage portion is determined by the swing of the electromagnet. It is set so that it may change every period.

According to a fourth aspect of the present invention, in accordance with the number of the electromagnets that are in an excited state above the first stage portion, a time for maintaining the excited state of the electromagnets is set.

According to a fifth aspect of the present invention, the time for maintaining the excitation state of the electromagnet is set such that the total time for which the plurality of electromagnets are in the excitation state above the first stage portion is constant for each oscillation period. It is characterized by being.

In a sixth aspect of the present invention, the control of energization to the electromagnet is performed by duty control, and the duty ratio of the energization signal to the electromagnet is changed according to the distance between the electromagnet and the first stage unit. Features.

The seventh invention is characterized in that the duty ratio is set to be larger as the distance between the electromagnet and the first stage portion is larger.

According to the first invention, the stage is partitioned by the partition wall into the first stage part where the game ball guided from the warp passage rolls and the second stage part for causing the game ball to flow down to the game area. A plurality of electromagnets are provided above the stage along the partition wall, and the game ball lifted and attracted by the excited electromagnet while the first stage is rolling is moved to the second stage by the swinging of the electromagnet. When the electromagnet is demagnetized, it is guided to the second stage portion. In this way, a plurality of electromagnets are provided along the partition wall of the stage, and magnetic force can be applied to each game ball that rolls the first stage portion in the left-right direction. To do. The second stage portion is provided with a second guide path for guiding the rolling game ball to the winning area, so that the game ball is guided from the first stage portion to the second stage portion by the electromagnet. The possibility of winning in the winning area increases. Therefore, the game value that the possibility of winning in the winning area is increased by lifting the game ball rolling on the first stage portion with the electromagnet is given. That is, the player can have a sense of expectation that the game ball will win the winning area when the game ball rolling on the first stage portion is lifted by the electromagnet, and the interest of the game is improved.

According to the second invention, since the magnetic force of the electromagnet arranged on the center side of the first stage portion is large, the game ball that rolls around the center portion of the first stage portion and has a high rolling speed is designated as the first stage portion. It can be lifted in the same manner as a game ball that rolls on its side.

According to the third aspect of the invention, the number of electromagnets that are excited in the upper part of the first stage portion changes every swing period, so that the player can determine which of the plurality of electromagnets is in the excited state. Since it cannot be predicted whether it will be, the interest of the game is improved.

According to the fourth and fifth inventions, the winning probabilities in the winning area for each swing period are substantially equal, and there is no disadvantage for both the player and the game store.

According to the sixth and seventh inventions, the ability to lift the game ball can be made substantially constant regardless of the swing position of the electromagnet.

  Embodiments of the present invention will be described below with reference to the drawings. In the following description of the embodiments, the front, rear, left, and right refer to directions viewed from the player, that is, viewed from the game board.

  First, a gaming board 1 of a gaming machine (pachinko machine) according to an embodiment of the present invention will be described with reference to FIG. FIG. 1 is a perspective view of the game board 1.

  The game board 1 is a rectangular member made of plywood, plastic, or the like, and a substantially fan-shaped game area 11 is defined by guide rails (not shown) disposed on the surface.

  The gaming machine plays a game by firing a game ball from a launching device (not shown) based on the operation of the player and flowing it down into the game area 11. The player can visually recognize the game area 11 through a cover glass (not shown) that covers the game board 1.

  In the game area 11, a center case 21 having an opening window 21a is disposed. Behind the center case 21, a variable display device 22 that displays a plurality of identification information in a variable manner is disposed in a state where the display portion 22 a faces the opening window portion 21 a of the center case 21.

  An opening having a shape along the outer periphery of the center case 21 is formed in the game board 1, and the center case 21 is fitted into the opening from the front of the game board 1. Further, the opening window portion 21 a of the center case 21 is formed so that the display portion 22 a of the variable display device 22 that faces the opening window portion 21 a is disposed substantially at the center of the game area 11.

  The variable display device 22 sets a plurality of variable display areas (for example, three variable display areas on the left side, the center, and the right side) on the display unit 22a, and displays the images independently in each display area. Device. In the present embodiment, for example, a display screen portion is configured by a liquid crystal display or the like capable of displaying an arbitrary image, and a plurality of identification information (special symbols) and a variable display game are displayed in each variable display area on the display screen. An image based on the progress of the game, such as a character that produces the game, is displayed.

  Below the center case 21 in the game area 11 and substantially in the center of the game area 11 corresponds to a tulip type variable display start port 24 (“winning area”) having a normal variable winning device (normal electric accessory) 23. ) Is disposed. On the left side of the starting port 24, a special variable winning device (large winning port) 25 that can be converted into a state in which a game ball is not received and a state in which it is easily received depending on the operation result of the variable display device 22 is disposed. A decoration 26 similar in shape to the special variable winning device 25 is disposed on the right side of the start port 24.

  In the game area 11, a normal symbol start gate 27 for the normal variation display game is arranged between the center case 21 and the special variation winning device 25 and between the center case 21 and the decoration 26.

  In addition to the above, the game area 11 includes a general winning opening (not shown) in which only a condition for paying out a prize ball when a game ball is won, a windmill or a nail (not shown) for changing the falling direction of the game ball, etc. A direction changing member, an out port 30 for collecting game balls that have flowed down without winning, and lamps / LEDs (not shown) for displaying various decorations by light emission are disposed.

  The game balls launched by the launcher are fired into the game area 11 from a launch ball guide passage (not shown) that is partitioned on the left side of the guide rail and guides the game balls, and are arranged at various locations in the game area 11. The game area 11 flows down while changing the falling direction by the direction changing member, and wins the general winning opening, the starting opening 24, or the special variable winning apparatus 25, or is discharged from the out opening 30 provided at the bottom of the gaming area 11. Is done.

  When a game ball wins the general winning opening, the start opening 24, or the special variable winning device 25, the number of winning balls corresponding to the type of the winning winning port is discharged from the payout device (not shown).

  The winning of a game ball to the start port 24 is detected by a start port sensor 24A (see FIG. 2). The special symbol random number counter value extracted by the game ball passing through the start port sensor 24A is stored in a special symbol storage area in the game control device 100 (see FIG. 2) as a special symbol winning memory (start memory). For example, a maximum of 4 times) is stored. Then, the number of start memories is displayed on the special figure display 111 (see FIG. 2). The game control device 100 plays a special figure variation display game (auxiliary game) on the variation display device 22 based on the start memory.

  Specifically, when a game ball wins at the start opening 24, the variable display device 22 starts a variable display game in which the identification information composed of the numbers and the like described above is sequentially displayed, and displays an image related to the variable display game. Is done.

  When the game ball is won at the start opening 24 at a predetermined timing (specifically, when the winning random number at the time of winning detection is a winning value), it becomes a big hit state, and three display symbols are aligned. Stop in state (big hit symbol). At this time, the special variable prize winning device 25 is energized to the special prize opening solenoid 113 (see FIG. 2), and from the closed state (a disadvantageous condition for the player) in which the special prize opening does not accept the game ball for a predetermined time. The game ball is converted into an open state (a state advantageous to the player) that can easily accept the game ball. In other words, since the special winning opening is greatly opened for a predetermined time, the player is given a game value that allows a large number of game balls to be acquired. In addition, the winning of the game ball to the special variation winning device 25 is detected by the count sensor 25A (see FIG. 2).

  The passing of the game ball to the normal symbol start gate 27 is detected by a normal symbol start gate sensor 27A (see FIG. 2). The normal symbol random number counter value extracted by the game ball passing through the normal symbol start gate sensor 27A is stored as a normal symbol winning memory in the normal symbol storage area in the game control device 100 a predetermined number of times (for example, up to four times). It is memorized to the limit. Then, the number stored in the normal symbol winning memory is displayed on the general symbol display 112 (see FIG. 2).

  When the game ball passes through the normal symbol starting gate 27, the general symbol display 112 starts a general symbol variation display game. When the passing of the game ball to the normal symbol starting gate 27 is made at a predetermined timing (specifically, when the common random number counter value at the time of passing is a winning value), the normal symbol is hit. The normal symbol displayed on the general-purpose display 112 stops in a hit state. At this time, the normal variation winning device 23 provided at the start port 24 is converted so that the entrance to the start port 24 is expanded for a predetermined time by energizing the normal electric accessory solenoid 114 (see FIG. 2). Thus, the possibility of winning a game ball at the start port 24 is increased.

  Next, each control device of the gaming machine will be described with reference to FIG. FIG. 2 is a block diagram of the gaming machine.

  The gaming machine includes a gaming control device 100 that comprehensively controls gaming performed in the gaming machine, various LED boards 211, a liquid crystal display 212, an effect control device 200 that controls the speaker 213, and a discharge device 301 that pays out gaming balls. A discharge control device 300 that controls the above is provided.

  Below, the game control apparatus 100 and the effect control apparatus 200 are demonstrated.

  First, the game control device 100 will be described.

  The game control device 100 includes a game microcomputer 101, an input I / F (Interface) 102, an output I / F (Interface) 103, and an external communication terminal 104.

  The gaming microcomputer 101 includes a CPU 105, a ROM (Read Only Memory) 106, and a RAM (Random Access Memory) 107.

  The CPU 105 is a main control device that controls the game in an integrated manner, and controls the game. The ROM 106 stores invariant information (programs, data, etc.) for game control. The RAM 107 is used as a work area during game control.

  The external communication terminal 104 connects the gaming microcomputer 101 and an external device such as an inspection device that inspects setting information and the like of the gaming microcomputer 101.

  The CPU 105 receives detection signals from various input devices (starting port sensor 24A, count sensor 25A, and normal symbol starting gate sensor 27A) via the input I / F 102, and performs various processes such as a big hit lottery.

  In addition, the CPU 105 instructs the special figure display 111, the status display 115, the universal display 112, the big prize opening solenoid 113, the ordinary electric accessory solenoid 114, and the discharge control device 300 via the output I / F 103. Send a signal to control the game centrally.

  The special figure display 111 displays a variable display game that is performed when a game ball wins the start opening 24. The universal display 112 displays a variable display game that is played when a game ball wins the normal symbol starting gate 27.

  On the status indicator 115, the progress state of the special figure variation display game, the number of execution rounds of the jackpot game, and the probability state of occurrence of the special prize are displayed.

  The special winning opening solenoid 113 is in an open state (advantageous to the player) from a closed state (a disadvantageous state for the player) that does not accept the gaming ball for a predetermined time. ).

  The ordinary electric accessory solenoid 114 opens the normal variation winning device 23 provided at the start port 24, and opens the entrance to the start port 24 for a predetermined time.

  The game control device 100 outputs game data (occurrence of a special game state, execution of a special figure change display game, the number of prize balls discharged, etc.) to the information collecting terminal device 400 via the external terminal board 116.

  In addition, the game control apparatus 100 sends a change start command, a customer waiting demo command, a fanfare command, a probability information command, an error designation command, and the like as an effect control command signal to the effect control device 200 via the output I / F 103. Send.

  Next, the production control device 200 will be described.

  The effect control device 200 controls the various LED substrates 211, the liquid crystal display 212, and the speaker 213 based on various signals input from the game control device 100.

  The effect control device 200 includes a CPU 201, a ROM 202, a RAM 203, a communication I / F 204, and an output I / F 205.

  The CPU 201 is a main control device that controls various effects based on commands from the game control device 100. The ROM 202 stores invariant information (program, data, etc.) for game control. The RAM 203 is used as a work area during game control.

  The effect control device 200 is connected to the game control device 100 via the communication I / F 204.

  Various LED substrates 211, a liquid crystal display 212, and a speaker 213 are connected to the output I / F 205. Various LED substrates 211 are provided inside the decorative member, and light the decorative member.

  Next, the center case 21 will be described with reference to FIGS. 1, 3, and 4. FIG. 3 is a perspective view of the front side of the center case 21, and FIG. 4 is a perspective view of the back side of the center case 21.

  The center case 21 is a ring-shaped member having an opening window portion 21a formed on the back surface. The center case 21 is fitted into the opening formed in the game board 1 from the front of the game board 1 and is fixed to the game board 1. The The center case 21 is formed of a synthetic resin.

  On the outer periphery of the center case 21, a flange portion 39 that protrudes outward is formed. The center case 21 is fixed to the game board 1 via the heel portion 39, and the front side of the heel portion 39 is disposed in the game area 11.

  In a state where the center case 21 is fixed to the game board 1, the game board 1 is formed with a concave chamber 40 in which the display unit 22 a of the variable display device 22 is disposed on the back surface.

  The center case 21 is formed with a guide 41 that is erected forward from the surface of the game board 1 and guides the game ball while being fixed to the game board 1. The guide 41 includes a left arcuate guide 41 a and a right arcuate guide 41 b that extend in an arc shape from the upper center of the center case 21 to the left and right sides.

  The game balls launched into the game area 11 from the shot ball guide passage partitioned adjacent to the left side of the game area 11 flow down the area between the guide rail and the guide 41.

  The center case 21 is provided with a warp passage 45 for guiding a game ball flowing down the game area 11 into the concave chamber 40 of the center case 21.

  At the bottom of the concave chamber 40, which is the inner bottom of the center case 21, a gaming ball guided from the warp passage 45 can roll, and the rolling gaming ball 11 is provided with a start port 24. A stage 50 for flowing down is provided. The stage 50 will be described later.

  The warp passage 45 includes inlet portions 46a and 46b formed in the left arc-shaped guide 41a and the right arc-shaped guide 41b, and an inlet portion formed in connection with the end portions of the left arc-shaped guide 41a and the right arc-shaped guide 41b. A game ball is received from 46c and 46d. In this way, the center case 21 is formed with the inlet portions 46a to 46d of the four warp passages 45, and the game balls flowing down the game area 11 on the left side of the center case 21 enter the inlet portions 46a and 46c. The game balls that flow in and flow down the game area 11 on the right side of the center case 21 flow into the inlet portions 46b and 46d.

  The game balls that have flowed into the inlet portions 46 a and 46 b flow down the first flow path 47 a disposed along the inner peripheral surface of the center case 21, and are the inner peripheral surface of the center case 21 and the left and right end portions of the stage 50. Is discharged toward the stage 50 from the first discharge port 48a (see FIG. 4) that is open.

  Further, the game balls that have flowed into the inlet portions 46c and 46d roll in the second flow path 47b formed to be inclined downward toward the rear, and at the downstream end of the second flow path 47b and on the left and right sides of the stage 50 It discharges | emits toward the stage 50 from the 2nd discharge port 48b (refer FIG. 4) opened facing the edge part.

  As shown in FIG. 4, the first discharge port 48a and the second discharge port 48b are arranged side by side in the front-rear direction.

  Next, the stage 50 will be described mainly with reference to FIGS. 1 and 3 to 5. FIG. 5 is a sectional view of the center case 21.

  The stage 50 extends in the left-right direction at the inner bottom portion of the center case 21 and is disposed so that the lowest center portion is directly above the start port 24. The stage 50 is formed in an arc shape that is high on both the left and right sides and has a low center. That is, it is formed so as to be gently inclined downward from both sides toward the center. The stage 50 is formed of a transparent synthetic resin.

  The stage 50 includes a first stage portion 51 disposed on the back side and extending in the left-right direction, and a second stage portion 52 disposed on the near side and extending in the left-right direction. The first stage portion 51 and the second stage portion 52 are disposed in parallel in the left-right direction, and a partition wall 53 that restricts the passage between them is disposed at the boundary between them.

  Since the first discharge port 48a and the second discharge port 48b (see FIG. 4) of the warp passage 45 are opened opposite to the left and right ends of the first stage portion 51, the first discharge port 48a and the second discharge port 48a. The game ball discharged from the outlet 48 b flows into the first stage portion 51 and rolls toward the center portion of the first stage portion 51.

  In the lowest part of the center of the first stage portion 51, a guide port 56 that leads the game ball to the lower stage 55 disposed below the stage 50 is formed to open.

  The lower stage 55 is formed in an arc shape like the stage 50, and is formed along the stage 50 at a predetermined interval from the lower surface of the stage 50. The lower stage 55 is formed so as to be inclined downward gently toward the front, that is, toward the game area 11, and the front end portion opens to the game area 11 over the entire left and right. Therefore, the game ball rolling on the lower stage 55 flows down to the game area 11.

  A raised portion 57 bulging upward is formed at the lowest center of the lower stage 55. That is, the raised portion 57 is formed immediately above the start port 24.

  The raised portion 57 has inclined portions 57b that are inclined downward from the top portion 57a to the left and right, respectively, and the top portion 57a extends in the short direction of the lower stage 55 and directly below the guide port 56 of the first stage portion 51. (Refer to FIG. 5).

  Therefore, the game balls that flow into the guide port 56 of the first stage portion 51 and are guided to the lower stage 55 are in contact with the top portion 57a of the raised portion 57 and are distributed in the left-right direction, and the inclined portion 57b is moved down the lower stage 55. It flows down to the game area 11 by the downward inclination of the front. Since the raised portion 57 is formed immediately above the start port 24, there is a low possibility that a game ball flowing down from the lower stage 55 to the game area 11 will win the start port 24. As described above, the route that flows into the guide port 56 of the first stage unit 51 and is guided to the lower stage 55 is a disadvantageous route for the player, and the guide port 56 of the first stage unit 51 becomes the first guide path. Applicable.

  Since the second stage portion 52 is separated from the first stage portion 51 by the partition wall 53, the game ball rolling on the first stage portion 51 rolls into the second stage portion 52 and flows in. Absent. A part of the game ball rolling on the first stage portion 51 is guided to the second stage portion 52 by the action of an electromagnet 60 described later.

  The second stage portion 52 is formed so as to be inclined downward gently toward the front, that is, toward the game area 11. At the front end portion of the second stage portion 52, a guide wall 58 for preventing the rolling game ball from dropping into the game area 11 is disposed over the entire left and right.

  The guide wall 58 is formed with a notch 58a that is partially cut away, and the second stage 52 opens to the game area 11 through the notch 58a.

  The cutout portion 58 a is located at the lowest center portion of the second stage portion 52. Therefore, the game ball rolling on the second stage portion 52 rolls back and forth in the left-right direction, and the amplitude of the reciprocating roll gradually decreases, and finally all the game balls are moved to the game area 11 through the notch 58a. Discharged. As described above, the second stage unit 52 is for causing the game ball to flow down to the game area 11.

  A notch 58 a of the guide wall 58 is formed immediately above the start port 24. For this reason, the game ball discharged to the game area 11 through the notch 58a flows down toward the start port 24 and is guided to the start port 24, so that the possibility of winning the start port 24 is increased. Thus, the route discharged from the second stage unit 52 to the game area 11 is a route that is advantageous to the player, and the notch 58a of the second stage unit 52 corresponds to the second guide path.

  Next, mainly with reference to FIGS. 1 to 4 and FIGS. 6 to 8, the electromagnet 60 that guides the game ball rolling on the first stage portion 51 to the second stage portion 52 will be described. FIG. 6 is an exploded perspective view of the electromagnet unit, and FIGS. 7 and 8 are cross-sectional views around the electromagnet 60.

  As shown in FIGS. 1, 3, and 4, a plurality of electromagnets 60 are supported on a rod 61 disposed above the stage 50 along the partition wall 53 at a predetermined interval. In the present embodiment, there are three electromagnets 60: an electromagnet 60C supported opposite to the lowest part of the stage 50, and an electromagnet 60L and an electromagnet 60R supported on the left and right of the electromagnet 60C.

  As shown in FIG. 6, the electromagnet 60 includes a ring-shaped support portion 60a supported by the rod 61 and a magnet portion 60b that generates a magnetic force by excitation so that each magnet portion 60b faces the same direction. Supported by the rod 61. The support portion 60 a has an inner peripheral shape that is D-shaped so that it cannot rotate relative to the rod 61.

  Both ends of the rod 61 are rotatably supported on the left and right sides of the inner peripheral surface of the center case 21.

  An output shaft 63 a of a motor 63 is connected to one end of the rod 61 via a connecting member 62. Thereby, the rod 61 rotates when the motor 63 rotates.

  The motor 63 is fastened and fixed inside the center case 21 through the flange portion 63b.

  The rod 61 includes a plurality of cylindrical divided rods 61a to 61d. The opposing ends of the adjacent split rods 61 a to 61 d are formed in a D shape on the outer periphery and are inserted into the support portion 60 a of the electromagnet 60. As described above, the electromagnet 60 is supported by the split rods 61 a to 61 d via the rotation preventing structure, and therefore cannot rotate relative to the rod 61 and rotates integrally with the rod 61.

  A conducting wire 64 for energizing the electromagnet 60 is inserted through the rod 61. The conducting wire 64 is separately connected to the electromagnets 60C, 60L, and 60R, and energization and de-energization of the electromagnets 60C, 60L, and 60R can be performed separately.

  As shown in FIG. 2, each of the electromagnets 60C, 60L, 60R is connected to the game control device 100 via a conductor 64, and is excited and demagnetized by an energization command or an energization stop command transmitted from the game control device 100. Can be switched. The excitation and demagnetization of the electromagnets 60C, 60L, 60R can be switched separately by the electromagnets 60C, 60L, 60R.

  Since the electromagnet 60 generates a magnetic force when in an excited state, the game ball rolling on the stage 50 is lifted and attracted to the electromagnet 60 by the magnetic force. Further, since the magnetic force is not generated when the electromagnet 60 is in a demagnetized state, the game ball rolling on the stage 50 is not attracted to the electromagnet 60. Further, when the electromagnet 60 changes from the excited state to the demagnetized state while the game ball is attracted to the electromagnet 60 by the magnetic force, the attracted game ball falls.

  At the other end of the rod 61, a light shielding plate 66 that transmits and blocks light from a position detection sensor 65 (see FIG. 4) that is an optical sensor disposed inside the center case 21 is not rotatable relative to the rod 61. Combined with

  The position detection sensor 65 is formed in a U shape, one convex portion is a light emitting portion, and the other convex portion is a light receiving portion.

  The light shielding plate 66 has a fan-shaped light shielding portion 66 a that can communicate with the concave portion of the position detection sensor 65.

  As shown in FIG. 2, the detection result of the position detection sensor 65 is output to the game control device 100, and the game control device 100 outputs a command signal to the motor 63 based on the detection result of the position detection sensor 65. Control its operation.

  Specifically, when the position detection sensor 65 is in a light-shielded state, an operation command is output from the game control device 100 to the motor 63. When the motor 63 rotates by a predetermined angle, the light shielding portion 66a of the light shielding plate 66 passes through the concave portion of the position detection sensor 65, and when the position detection sensor 65 enters a light-transmitting state, the game control device 100 A stop command is output to the motor 63, and the motor 63 stops. After the motor 63 is stopped and a predetermined time has elapsed, an operation command for reverse rotation is output from the game control device 100 to the motor 63, the motor 63 rotates reversely, and the position detection sensor 65 is again in the light shielding state. Then, as the motor 63 rotates by a predetermined angle in the reverse direction, the light shielding portion 66a of the light shielding plate 66 passes through the concave portion of the position detection sensor 65, and the position detection sensor 65 enters a light transmission state. A stop command is output from the game control device 100 to the motor 63, and the motor 63 stops. Then, after the motor 63 is stopped and a predetermined time has elapsed, an operation command for reverse rotation is output from the game control device 100 to the motor 63.

  As described above, the light and light shielding of the position detection sensor 65 causes the motor 63 to repeatedly start and stop, such as normal rotation, stop, reverse rotation, stop, and normal rotation.

  As a result, the rod 61 reciprocates within a range of a predetermined angle around the axis, and accordingly, the electromagnet 60 supported by the rod 61 also swings back and forth around the rod 61 as a rotation axis. Specifically, the electromagnet 60 oscillates within a range of about 50 degrees in the front-rear direction around the vertically downward direction.

  Since the electromagnet 60 is disposed above the partition wall 53, as shown in FIGS. 7 and 8, the electromagnet 60 swings around the partition wall 53 over the first stage portion 51 and the second stage portion 52. It will be. FIG. 7 is a cross-sectional view of a cross section passing through the electromagnet 60 </ b> L, in which the electromagnet 60 </ b> L having the game ball P attracted to the tip swings forward and is positioned above the second stage portion 52. FIG. 8 is a cross-sectional view of a cross section passing through the electromagnet 60 </ b> C, in which the electromagnet 60 </ b> C with the game ball P attracted to the tip swings backward and is positioned above the first stage portion 51. is there.

  The electromagnets 60C, 60L, 60R are connected to the rod 61 so as not to rotate relative to each other and swing in synchronism, so that the cycle of each electromagnet 60C, 60L, 60R is the same.

  Next, the operation of the electromagnet 60 and the movement of the game ball on the stage 50 will be described with reference to FIG. FIG. 9 is a timing chart of signals input from the position detection sensor 65 to the game control device 100 and signals output from the game control device 100 to the motor 63 and the electromagnet 60. Hereinafter, rotation of the motor 63 that swings the electromagnet 60 forward is referred to as “forward rotation”, and rotation of the motor 63 that swings the electromagnet 60 rearward is referred to as “reverse rotation”.

  In a state where the electromagnet 60 is stopped at the forefront portion above the second stage portion 52, the electromagnets 60C, 60L, 60R are all in a deenergized state and are in a demagnetized state. The electromagnet 60 starts moving backward by the reverse rotation of the motor 63 after stopping for a predetermined time at the forefront. The electromagnet 60 moves from above the second stage portion 52 across the partition wall 53 to above the first stage portion 51 and stops at the last portion above the first stage portion 51. During this time, the electromagnets 60C, 60L, 60R are all in a deenergized state and maintain a demagnetized state. Therefore, the game balls that have flowed into the first stage portion 51 from the warp passage 45 until the electromagnet 60 moves from the foremost portion above the second stage portion 52 to the last portion above the first stage portion 51 are transferred to each electromagnet. The first stage 51 is reciprocated in the left-right direction without being lifted by 60C, 60L, 60R, and the amplitude of the reciprocating rolling gradually becomes smaller. Finally, the center stage 56 leads to the lower stage 55. Led. Then, it comes into contact with the top portion 57 a of the raised portion 57 and is discharged from the inclined portion 57 b to the down game area 11. Thus, a game ball that rolls on the first stage portion 51 and cannot be lifted by the electromagnet 60 is less likely to win the start opening 24.

  The electromagnet 60 maintains a demagnetized state while stopped at the rearmost part. Then, after stopping for a predetermined time, the motor 63 switches to forward rotation. Immediately after the motor 63 is switched to the forward rotation, the electromagnets 60C, 60L, 60R are all energized and excited. The electromagnets 60C, 60L, and 60R start moving toward the front, and move above the first stage portion 51 while maintaining the excited state. Further, since the electromagnets 60C, 60L, and 60R are provided along the partition wall 53, the first stage portion is moved while the electromagnets 60C, 60L, and 60R are moving forward over the first stage portion 51. A magnetic force is generated in 51 in the entire left-right direction. Accordingly, during this time, the magnetic force acts on all the game balls flowing into the first stage portion 51 from the warp passage 45 and rolling the first stage portion 51 in the left-right direction. Thereby, the game ball rolling on the first stage portion 51 is lifted on one of the electromagnets 60C, 60L, and 60R, and is attracted to the tip of the electromagnet 60 (state shown in FIG. 8).

  The excitation state of the electromagnet 60 is maintained until the electromagnet 60 straddles the partition wall 53 and moves above the second stage portion 52, and the game ball attracted to the tip of the electromagnet 60 completely straddles the partition wall 53 (see FIG. 7), the demagnetization state. As a result, the game ball that has been attracted to the electromagnet 60 falls onto the second stage portion 52. In this way, the excitation state of the electromagnet 60 is maintained until the electromagnet 60 straddles the partition wall 53 so as to reliably drop the game ball that has been attracted onto the second stage portion 52.

  Switching between excitation and demagnetization of the electromagnets 60C, 60L, and 60R described above is regularly performed at every swinging period of the electromagnet 60, as shown in FIG.

  In this manner, the game ball attracted to the electromagnet 60 by the magnetic force while rolling the first stage portion 51 is guided to the second stage portion 52 across the partition wall 53 by the swinging of the electromagnet 60. The game ball guided to the second stage portion 52 is discharged to the game area 11 through the cutout portion 58a. Since the game balls discharged to the game area 11 in this manner flow down toward the start port 24, there is a high possibility that the game ball will win the start port 24. That is, there is a high possibility of winning the game ball at the start port 24 guided from the first stage portion 51 to the second stage portion 52 by the electromagnet 60.

  Here, since the stage 50 is formed in an arc shape with both right and left sides being high and the center portion being low, the game ball rolling on the first stage portion 51 reciprocally rolls in the left-right direction around the center portion. For this reason, the speed of the game ball rolling on the central portion of the first stage portion 51 is higher than the speed of the game ball rolling on the side portion side. For this reason, it is difficult for the game ball to be attracted to the electromagnet 60 </ b> C disposed above the center of the first stage unit 51. Therefore, it is desirable to set the magnetic force of the electromagnet 60 </ b> C larger than the magnetic force of the electromagnets 60 </ b> L and 60 </ b> R disposed above the side portion of the first stage portion 51. That is, it is desirable to set the magnetic force of the electromagnet disposed on the center side of the first stage portion 51 to be larger than the magnetic force of the electromagnet disposed on the side portion side. By setting in this way, it is possible to lift a game ball that rolls fast at the center of the first stage unit 51 in the same manner as a game ball that rolls on the side of the first stage unit 51. it can.

  According to the above embodiment, there exist the effects shown below.

  The stage 50 is partitioned by a partition wall 53 into a first stage portion 51 on which a game ball guided from the warp passage 45 rolls and a second stage portion 52 for allowing the game ball to flow down to the game area 11. Above the 50, a plurality of electromagnets 60 are provided along the partition wall 53. The game ball lifted and attracted to the excited electromagnet 60 while rolling the first stage portion 51 is carried to the second stage portion 52 by the swinging of the electromagnet 60, and the electromagnet 60 is demagnetized to make the first demagnetization state. Guided to the two-stage unit 52. In this way, a plurality of electromagnets 60 are provided along the partition wall 53 of the stage 50, and magnetic force can be applied to each game ball that rolls the first stage portion 51 in the left-right direction. The interest of will improve.

  Further, the second stage portion 52 is provided with a notch 58a for guiding the rolling game ball to the starting port 24, and all the game balls rolling on the second stage portion 52 are passed through the notch 58a. It is discharged to the game area 11. Therefore, the player can have a sense of expectation that the game ball that rolls on the first stage portion 51 is lifted by the electromagnet 60, and that the game ball will win the start opening 24. improves.

  Next, another mode of switching between excitation and demagnetization in the electromagnet 60 will be described with reference to FIG. FIG. 10 is a timing chart of signals input from the position detection sensor 65 to the game control device 100 and signals output from the game control device 100 to the motor 63 and the electromagnet 60, as in FIG.

  In the embodiment shown in FIG. 9, all the electromagnets 60C, 60L, 60R are excited and demagnetized at the same timing.

  Since the excitation and demagnetization of the electromagnet 60 can be switched separately by the electromagnets 60C, 60L, and 60R, as shown in FIG. 10, the number of electromagnets 60 that are in an excited state above the first stage unit 51 is determined. Alternatively, the electromagnet 60 may be changed at random for each oscillation cycle. That is, only some of the electromagnets 60 </ b> C, 60 </ b> L, and 60 </ b> R may be set to be excited above the first stage unit 51.

  In FIG. 10, in the first swing period, only the electromagnet 60C is excited above the first stage portion 51, and in the second swing period, all three electromagnets 60C, 60L, 60R are in the first stage. The electromagnet is excited above the portion 51, and the two electromagnets 60C and 60L are energized above the first stage portion 51 in the third oscillation period.

  In this way, the number of electromagnets 60 that are in an excited state above the first stage unit 51 is randomly changed for each swing period, so that the player can determine which of the electromagnets 60 is in an excited state. Since it cannot be predicted whether it will be, the interest of the game is improved.

  When only some of the electromagnets 60 are in an excited state above the first stage 51, the time for which the electromagnets 60C, 60L, and 60R are in the excited state above the first stage 51 is set. The total will decrease. In this case, the game ball that rolls on the first stage portion 51 is hardly lifted by the electromagnet 60, so that the possibility that the game ball wins the start opening 24 is reduced.

  Therefore, it is desirable to set the time for maintaining the excitation state of the electromagnet 60 according to the number of electromagnets 60 that are in the excitation state above the first stage portion 51. Specifically, as shown in FIG. 10, when the number of electromagnets 60 in the excited state is small above the first stage portion 51, the time for maintaining the excited state of the electromagnet 60 is set longer. By setting in this way, even when only some of the electromagnets 60 are excited above the first stage portion 51, the possibility that the game ball will win the start opening 24 is reduced. There is nothing.

  This will be specifically described with reference to FIG. 10. In the first swing period, only the electromagnet 60C is in an excited state above the first stage portion 51, and therefore the electromagnet 60C has the first stage portion 51. While moving upward, that is, while reciprocating the first stage portion 51, the excited state is maintained.

  Further, in the second swing period, all three electromagnets 60C, 60L, 60R are excited above the first stage portion 51, so that each electromagnet 60C, 60L, 60R is maintained in an excited state from the time when it starts moving forward from the state stopped at the last part above the first stage part 51 to the time when it moves across the partition wall 53 and above the second stage part 52. Is done.

  Further, in the third swing cycle, the two electromagnets 60C and 60L are excited above the first stage portion 51, so the electromagnets 60C and 60L are stopped at the last portion above the first stage portion 51. The excited state is maintained from the point of time until it moves forward and moves across the partition wall 53 and above the second stage unit 52.

  Thus, the sustaining time of the excited state of the electromagnet 60 is the longest during the first swing period in which one electromagnet 60C is in the excited state, and the second in which the three electromagnets 60C, 60L, 60R are in the excited state. Is the shortest oscillation period, and the third oscillation period when the two electromagnets 60C and 60L are in the excited state is about half of the first oscillation period and the second oscillation period. .

  As a result, even when the number of electromagnets 60 in the excited state is different above the first stage portion 51, the time for which the electromagnets 60C, 60L, 60R are in the excited state above the first stage portion 51 for each swing period. Can be made substantially equal. In other words, it is desirable that the time for maintaining the excitation state of the electromagnet 60 is set such that the total time for which each electromagnet 60 is in the excitation state above the first stage portion 51 is constant for each oscillation period. . As a result, the winning probabilities for the start opening 24 for each swinging cycle are substantially equal, and there is no disadvantage for both the player and the game store.

  Next, control of energization to the electromagnet 60 will be described with reference to FIG.

  FIG. 11 is a timing chart of signals input from the position detection sensor 65 to the game control device 100 and signals output from the game control device 100 to the motor 63 and the electromagnet 60, as in FIG.

  Since the electromagnet 60 swings in the front-rear direction with the rod 61 as the rotation axis, the distance between the electromagnet 60 and the first stage portion 51 continuously changes as the electromagnet 60 swings. Specifically, the distance between the electromagnet 60 and the first stage portion 51 is minimum when the electromagnet 60 is positioned in the vertical direction, and is maximum when the electromagnet is positioned at the rearmost portion (the state shown in FIG. 8). .

  For this reason, when the electromagnet 60 is always excited above the first stage portion 51 and the electromagnet 60 is positioned in the vertical direction, the electromagnet 60 received by the game ball rolling on the first stage portion 51. When the electromagnet 60 is located at the rearmost portion, the magnetic force of the electromagnet 60 received by the game ball rolling on the first stage portion 51 is minimized. Therefore, the ability of the electromagnet 60 to lift the game ball changes depending on the swinging position of the electromagnet 60. When the electromagnet 60 is located at the rearmost part, the ability to lift the game ball is reduced.

  Therefore, it is desirable to control the energization to switch between excitation and demagnetization of the electromagnet 60 by duty control, and to change the duty ratio of the energization signal to the electromagnet 60 according to the distance between the electromagnet 60 and the first stage unit 51.

  Specifically, as shown in FIG. 11, when the distance between the electromagnet 60 and the first stage portion 51 is small where the electromagnet 60 swings near the upper portion of the partition wall 53, the duty ratio is set small. Further, when the distance between the electromagnet 60 and the first stage unit 51 is large, the duty ratio is set large.

  Thus, the duty ratio is set to be larger as the distance between the electromagnet 60 and the first stage portion 51 is larger. By setting in this way, the ability to lift the game ball can be made almost constant regardless of the swing position of the electromagnet 60, and a stable game can be performed.

  The present invention is not limited to the above-described embodiment, and it is obvious that various modifications can be made within the scope of the technical idea.

  The gaming machine of the present invention is not limited to the pachinko gaming machine as shown in the above embodiment, and uses, for example, gaming balls such as other pachinko gaming machines, arrange ball gaming machines, and sparrow ball gaming machines. Applicable to all gaming machines.

1 is a perspective view of a game board of a gaming machine according to an embodiment of the present invention. It is a block diagram of a gaming machine. It is a perspective view of the front side of a center case. It is a perspective view of the back side of a center case. It is sectional drawing of a center case. It is a disassembled perspective view of an electromagnet unit. It is sectional drawing of the cross section which passes through the left electromagnet 60L, and is a figure of the state in which the electromagnet 60L is located above a 1st stage part. It is sectional drawing of the cross section which passes through the center electromagnet 60C, and is a figure of the state in which the electromagnet 60C is located above a 2nd stage part. It is a timing chart of the signal input to a game control apparatus from a position detection sensor, and the signal output to a motor and an electromagnet from a game control apparatus. It is a timing chart of the signal input to a game control apparatus from a position detection sensor, and the signal output to a motor and an electromagnet from a game control apparatus. It is a timing chart of the signal input to a game control apparatus from a position detection sensor, and the signal output to a motor and an electromagnet from a game control apparatus.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Game board 21 Center case 50 Stage 51 1st stage part 52 2nd stage part 53 Partition wall 55 Lower stage 56 Guide port 57 Raised part 58 Guide wall 58a Notch part 60 Electromagnet 60C Center electromagnet 60L Left electromagnet 60R Right electromagnet 61 Rod 63 Motor 64 Conductor 65 Position detection sensor 66 Light shielding plate

Claims (7)

A variation display device that variably displays a plurality of identification information, a center case that is disposed in a game area of a game board and that has an opening window that faces the display portion of the variation display device, and is disposed below the center case In a gaming machine comprising a winning area,
The center case is
A warp passage for guiding a game ball flowing down the game area of the game board into the center case;
A stage that extends in the left-right direction at the inner bottom of the center case, and on which a game ball guided from the warp passage rolls,
The stage is
A first stage portion disposed on the back side and rolling a game ball guided from the warp passage;
A second stage portion disposed on the near side and for causing the rolling game ball to flow down to the game area in which the winning area is disposed;
A partition wall that partitions the first stage portion and the second stage portion and restricts the mutual travel;
A plurality of electromagnets are supported at predetermined intervals on rods disposed above the stage along the partition wall,
The electromagnet swings in the front-rear direction across the first stage portion and the second stage within a predetermined angle range with the rod as a rotation axis,
A game ball that is attracted to the electromagnet while rolling the first stage part by the electromagnet being excited above the first stage part and demagnetizing above the second stage part. Is guided to the second stage section across the partition wall ,
The first stage portion is provided with a first guide path for guiding a game ball that has not been attracted to the electromagnet to a lower stage disposed below the stage,
A raised portion is formed at the center of the lower stage,
The game balls guided from the first guide path to the lower stage are in contact with the raised portion and distributed in the left-right direction, and flow down to the game area,
A gaming machine, wherein the second stage portion is provided with a second guiding path for guiding a rolling game ball to the winning area . The stage is formed in an arc shape that is high on both the left and right sides and has a low central portion,
2. The gaming machine according to claim 1, wherein the magnetic force of the electromagnet disposed on the center side of the first stage portion is set larger than the magnetic force of the electromagnet disposed on the side portion side. The excitation and demagnetization of the electromagnet can be switched separately for each electromagnet,
The number of the electromagnet to be excited state at above the first stage portion, a game according to claim 1 or claim 2, characterized in that it is set to change every swinging period of the electromagnet Machine. The gaming machine according to claim 3 , wherein a maintenance time of the excited state of the electromagnet is set according to the number of the electromagnets that are excited above the first stage portion. The time for maintaining the excitation state of the electromagnet is set such that the total time for the plurality of electromagnets to be in the excitation state above the first stage portion is constant for each oscillation period. The gaming machine according to claim 4 . Control of energization to the electromagnet is performed by duty control,
Depending on the distance between the electromagnet and the first stage unit, the gaming machine of any one of claims 1 to 5, characterized in that varying the duty ratio of the energization signal to the electromagnet. The gaming machine according to claim 6 , wherein the duty ratio is set to be larger as the distance between the electromagnet and the first stage portion is larger.

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