JP7072202B2 - Pachinko machine - Google Patents

Description

The present invention relates to a gaming machine such as a pachinko gaming machine or a rotating body type gaming machine (pachislot gaming machine).

Conventionally, in a pachinko gaming machine, which is one of the gaming machines, various movable movable members are attached as described in, for example, Patent Document 1 below. A motor (driving means) capable of applying a driving force for moving the movable member is connected to the movable member. A driver IC (Integrated Circuit, drive circuit unit) capable of controlling the drive of the motor is mounted on the control board for moving the movable member. In this way, for example, when the winning of the jackpot is notified, the driver IC controls the driving of the motor. As a result, the movable member can be moved from the standby position to the operating position, and it is possible to enhance the interest of the effect given to the player.

Japanese Unexamined Patent Publication No. 2008-272111

By the way, for example, after moving a movable member from a standby position to an operating position, the movable member may be stopped at the operating position for a predetermined time. In this case, the drive circuit unit (driver IC) supplies a current for stop holding (stop excitation) to the drive means (motor) in order to generate a stop holding force for holding the stop of the movable member. At this time, if the drive circuit unit supplies a drive current having the same magnitude as when the movable member is moved to the drive means, the current consumption for holding the movable member stopped increases.

The present invention has been made in view of the above circumstances. That is, the object thereof is to provide a gaming machine capable of suppressing the current consumption for holding the movable member stopped.

The gaming machine of the present invention
In a gaming machine that controls an advantageous special gaming state based on the establishment of predetermined control conditions.
Displaceable movable members and
A driving means capable of applying a driving force for displacement of the movable member and a stop holding force for holding the stop of the movable member.
A drive circuit unit that can control the drive means,
A control means capable of controlling the drive circuit unit is provided.
The drive circuit unit can supply the drive means with a predetermined first reduction current or a second reduction current smaller than the first reduction current , while supplying a current smaller than the second reduction current . It is a constant current drive system that is configured to be impossible.
A current reduction circuit is provided between the drive circuit unit and the control means so that the drive circuit unit can supply an ultra-reduction current smaller than the second reduction current to the drive means.
The control means is
When the drive means applies a stop holding force to the movable member, the current reduction circuit can cause the drive circuit unit to supply the ultra-reduction current to the drive means. It is a game machine to play.

According to the gaming machine of the present invention, it is possible to suppress the current consumption for holding the movable member stopped.

It is a perspective view of the gaming machine which concerns on embodiment of this invention. It is an exploded perspective view of the gaming machine frame provided in the gaming machine. It is a front view of the gaming machine. It is a front view of the gaming board provided in the gaming machine. It is a vertical sectional view of the game board shown in FIG. It is a front view schematically showing the 2nd prize-winning apparatus provided in the gaming machine. It is an enlarged view of the part A shown in FIG. 4, and is the figure which shows the display which is provided with the said gaming machine. It is a perspective view which shows the relationship between the movable body unit which the gaming machine has, and a base frame. It is an exploded perspective view of the movable body unit shown in FIG. It is a perspective view which shows the connecting plate and a link unit shown in FIG. (A) is a diagram showing a state in which the frame face movable body has started to move from the standby position, and (B) is a diagram in which the frame face movable body is rotated toward the operating position from the state shown in FIG. 11 (A). It is a figure which shows the state which is. (A) is a diagram showing a state in which the frame ear movable body is in the retracted position, (B) is a diagram showing a state in which the frame ear movable body is in an exposed position, and (C) is a diagram showing a state in which the frame ear movable body is exposed. It is a figure which shows the state in a position. (A) is a diagram showing a state in which the frame jaw movable body is in the closed position, and (B) is a diagram showing a state in which the frame jaw movable body is in the open position. It is a perspective view of the gaming machine when the frame face movable body is in the operating position. It is a front view of the gaming machine when the frame face movable body is in the operating position. (A) is a diagram showing a state in which the frame sword movable body is in the storage position, (B) is a diagram showing a state in which the frame sword movable body is in the push-in position, and (C) is a diagram showing a state in which the frame sword movable body is in the push-in position. It is a figure which shows the state in the middle position. It is a perspective view which shows the right light emitter unit. It is a perspective view which shows the right frame drum. It is a perspective view which shows the right frame drum. It is a block diagram which shows the electric structure of the main control board side of the gaming machine. It is a block diagram which shows the electric structure of the sub-control board side of the gaming machine. It is a block diagram which shows the electric structure of the sub drive board side of the gaming machine. (A) is a diagram showing a bipolar type stepping motor, and (B) is a diagram showing a unipolar type stepping motor. (A) is a diagram for explaining two-phase excitation, and (B) is a diagram for explaining one-phase excitation. It is a figure which shows the electric circuit around a frame sword moving motor driver. It is a figure which shows the relationship between the production control microcomputer and the frame right relay board. It is a figure which shows the electric circuit around the left frame drum motor driver and the right frame drum motor driver. It is a figure which shows the relationship between the production control microcomputer and the relay board on a frame. It is an enlarged view around the left frame drum motor driver shown in FIG. 27. It is a figure which shows the relationship between the production control microcomputer and the frame upper right relay board. It is a figure which shows the state which the inspection controller is connected to the right decorative part. It is a figure which shows the relationship between the position of a movable member, and the control state by a driver. It is a jackpot type judgment table. It is a table which shows various random numbers acquired by a game control microcomputer. (A) is a jackpot determination table, (B) is a reach determination table, (C) is a normal symbol hit determination table, and (D) is a normal symbol variation pattern selection table. It is a fluctuation pattern determination table. It is an opening pattern determination table of the electric chew. It is a flowchart of a timer interrupt process on the main side. It is a flowchart of a sub-side 1ms timer interrupt processing. It is a flowchart of a drive control process. It is a flowchart of a sub-side 10ms timer interrupt processing. It is a flowchart of the received command analysis process. It is a flowchart of a variation effect start process. It is a flowchart of a serial signal output process. It is a flowchart of the serial signal output processing for a frame face movable body. It is a flowchart of the serial signal output processing for a frame drum. It is a flowchart of the serial signal output processing for a frame sword movable body. It is a flowchart of the serial signal output processing for a frame ear movable body. It is a flowchart of the serial signal output processing for a frame sword disk member. It is a flowchart of the serial signal output processing for a movable board. It is a figure which shows the frame sword operation promotion effect. It is a figure for demonstrating 1-2 phase excitation by a low current holding state in 2nd form. It is a figure which shows the relationship between the position of a movable member and the control state by a driver in 3rd form. (A) is a diagram showing a state in which a ram clear notification image is displayed, and (B) is a diagram showing a state in which an initial function setting image is displayed.

1. 1. Structure of a gaming machine A pachinko gaming machine according to an embodiment of the present invention will be described with reference to the drawings. In the following description, the left-right direction of each part of the pachinko gaming machine as an example of the gaming machine will be described so as to coincide with the left-right direction for the player facing the pachinko gaming machine. Further, the front direction of each part of the pachinko gaming machine will be described as a direction approaching the player facing the pachinko gaming machine, and the rear direction of each part of the pachinko gaming machine will be described as a direction away from the player facing the pachinko gaming machine.

As shown in FIG. 1, the pachinko gaming machine 1 includes a gaming machine frame 50 constituting the outer shell of the pachinko gaming machine 1. The gaming machine frame 50 includes an outer frame 51, an inner frame 52, and a front frame (glass door frame) 53. The outer frame 51 is a vertically rectangular frame that constitutes the outer shell of the gaming machine frame 50. The inner frame 52 is arranged inside the outer frame 51 and is a vertically rectangular frame body. The front frame 53 is arranged on the front side of the inner frame 52 and has a vertically rectangular shape.

As shown in FIG. 1, the lower portion of the front frame 53 is provided with a handle 60 for launching a game ball at a firing intensity according to a rotation angle at the lower part on the right side, and a hitting ball supply dish (a ball feeding plate) for storing the game ball at the rear portion. The upper plate) 61 is provided, and a surplus ball tray (lower plate) 62 for storing game balls that cannot be accommodated in the hit ball supply plate 61 is provided to the left of the handle 60. Further, in front of the upper plate 61, an effect button 63 (operation means) and a select button 68 that can be operated by the player at the time of the effect executed with the progress of the game are provided. The effect button 63 of this embodiment is configured to be vibrable. Therefore, by having the player operate the vibrating effect button 63, it is possible to enhance the game interest for the operation.

A rectangular curtain plate 51a long in the left-right direction is arranged on the front side of the lower end of the outer frame 51. In this embodiment, the outer frame 51 and the inner frame 52 correspond to the "base frame portion" of the gaming machine frame 50, and the front frame 53 corresponds to the "front frame portion or opening / closing frame portion" of the gaming machine frame 50.

The gaming machine frame 50 is provided with a hinge portion 54 on the left end side. As shown in FIG. 2, the hinge portion 54 allows the front frame 53 to rotate with respect to the outer frame 51 and the inner frame 52, respectively, and the inner frame 52 with respect to the outer frame 51 and the front frame 53, respectively. It is rotatable. An opening portion 53a is formed in the center of the front frame 53, and a transparent glass plate 55 is attached to the opening portion 53a. As a result, the player can visually recognize the rear side of the glass plate 55 through the glass plate 55. As shown in FIG. 2, the front frame 53 includes a base frame 56 on the rear side.

Further, as shown in FIG. 3, the front frame 53 includes an upper decorative portion 200, a left decorative portion 210, a right decorative portion 220, and an operation mechanism portion 230 on the front side. The upper decorative portion 200, the left decorative portion 210, the right decorative portion 220, and the operation mechanism portion 230 are detachably attached to the base frame 56.

The upper decorative portion (upper decorative portion) 200 decorates the upper portion of the gaming machine frame 50 (front frame 53). As shown in FIG. 3, the upper decorative portion 200 includes a movable body unit 201 in the center in the left-right direction, a left light emitter unit 202L on the left side, and a right light emitter unit 202R on the right side. When the left light emitter unit 202L and the right light emitter unit 202R are collectively referred to, they are referred to as a light emitter unit 202. The movable body unit 201 can be transformed into the main character of the work that is the motif of the pachinko gaming machine 1. The light emitter unit 202 is a unit having a frame drum 320 inside, and is attached to the base frame 56 in a state of being inclined diagonally upward toward the front.

The left side decoration portion 210 decorates the left side of the gaming machine frame 50 (front frame 53). The right side decoration unit 220 decorates the right side of the gaming machine frame 50. The right decorative portion 220 includes a frame sword movable body 221 (movable member) described later, and a sheath member 222 capable of accommodating the lower side of the frame sword movable body 221.

The operation mechanism unit 230 (game medium storage unit) is provided with an operation mechanism for advancing a game or an effect. The operation mechanism unit 230 includes the handle 60, the upper plate 61, the lower plate 62, the effect button 63, and the select button 68 described above.

By the way, as shown in FIG. 3, a data counter 160 is arranged above the pachinko gaming machine 1 among the vertical wall surface SHs standing in the vertical direction in the island equipment of the amusement park. The data counter 160 includes a fixing member 161 fixed to the vertical wall surface SH, and a data display device 162 attached so as to be tiltable with respect to the fixing member 161 so as to be in a forward leaning posture.

The data display device 162 has a substantially rectangular parallelepiped shape that displays the number of occurrences of the jackpot gaming state and the number of occurrences of the high probability state, which will be described later. Further, the data display device 162 has a call button or the like for the player to call an employee of the hall. In this data counter 160, the forward tilt angle of the data display device 162 with respect to the vertical wall surface SH can be changed from 15 degrees to 25 degrees. The rear portion of the upper decorative portion 200 has a shape that does not abut on the data display device 162 even when the data display device 162 is tilted forward at a maximum angle of 25 degrees.

Further, the upper decorative portion 200, the left decorative portion 210, the right decorative portion 220, and the operation mechanism portion 230 are provided with a large number of frame lamps 66 capable of emitting light in various emission colors.

Next, the game board 2 will be described with reference to FIG. The gaming board 2 is arranged inside the gaming machine frame 50 and is attached to the inner frame 52. The front side of the game board 2 is protected by the front frame 53. As shown in FIG. 4, a game surface 2a standing upright in the vertical direction is formed on the front surface side of the game board 2. In front of the game surface 2a, a game area 3 into which a game ball launched by the operation of the handle 60 flows down is formed by being surrounded by a rail member 4. Further, the game board 2 is provided with a large number of board lamps 5 capable of emitting light in various light emitting colors. The game board 2 includes a plate-shaped member arranged on the front side and a back unit (various control boards described later, a first image display device 6, a second image display device 7, a harness, etc.) arranged on the rear side. The unit to be mounted) is integrated.

A plurality of game nails (not shown) for guiding the game ball are projected on the game surface 2a of the game board 2. Further, behind the game surface 2a, a first image display device (first display means) 6 which is a liquid crystal display device is arranged. The first image display device 6 is fixed in an upright state in the vertical direction.

The display screen 6a of the first image display device 6 has a decorative symbol display area for variable display of decorative symbols (effect symbols) 8L, 8C, 8R. The decorative symbol display area is composed of, for example, three symbol display areas of "left", "middle", and "right". The left effect symbol 8L is displayed in the left symbol display area, the middle effect symbol 8C is displayed in the middle symbol display area, and the right effect symbol 8R is displayed in the right symbol display area. Each decorative symbol is composed of a plurality of symbols representing numbers from "1" to "9", for example. The first image display device 6 displays the result of the jackpot lottery in an easy-to-understand manner by combining the decorative symbols on the left, middle, and right.

For example, if a big hit is won, the decorative pattern is stopped and displayed with doublets such as "777". In addition, if it is out of alignment, the decorative pattern is stopped and displayed with a random stitch such as "263". This makes it easier for the player to grasp the progress of the game. That is, the player generally grasps the result of the jackpot lottery on the first image display device 6. The position of the symbol display area does not have to be fixed. Further, as a mode of variable display of the decorative pattern, for example, there is a mode of scrolling in the vertical direction. In addition, it is possible to arbitrarily change what kind of decorative symbol combination is stopped and displayed according to each lottery result.

In the first image display device 6, in addition to the decorative symbol variation effect using the above-mentioned decorative pattern (also referred to as “effect symbol variation effect” or simply “variation effect”), the jackpot effect performed in parallel with the jackpot game. Or, a demo effect for waiting for customers is displayed on the display screen 6a. In the decorative pattern variation effect, in addition to decorative patterns such as numbers, effect images other than decorative patterns such as background images and character images are also displayed.

As shown in FIG. 4, a center decorative body 10 is arranged near the center of the game area 3 and in front of the first image display device 6. At the lower part of the center decorative body 10, a stage portion 11 that can guide a game ball that rolls on the upper surface to the first starting port 20, which will be described later, is formed. Further, at the lower left of the center decoration body 10, a warp portion 12 is provided, which allows the game ball to flow in from the entrance and flow out from the exit to the stage portion 11.

Below the first image display device 6 in the game area 3, a fixed winning device 19 including a first starting opening (first starting winning opening, first ball entry opening, fixed starting opening) 20 is provided. The first starting opening 20 is a winning opening in which the ease of entering a game ball does not always change. The winning of the game ball to the first starting port 20 is an opportunity for the first special symbol lottery (big hit lottery, that is, determination of acquisition of a big hit random number or the like).

Further, below the first starting port 20, a normal variable winning device (so-called electric chew) 22 provided with a second starting opening (second starting winning opening, second ball entry opening, variable starting opening) 21 is provided. .. The second starting port 21 is a winning opening in which the ease of entering a game ball can be changed. The second starting port 21 of the present embodiment is an opening portion formed by a plane extending in the vertical direction and the front-rear direction. The winning of the game ball to the second starting port 21 is an opportunity for the lottery of the second special symbol.

The electric chew 22 includes a movable member (ball entry opening / closing member) 23 that can move forward and backward, and opens / closes the second starting port 21 by the operation of the movable member 23. The movable member 23 allows the game ball to enter the second starting port 21 only when the movable member 23 is advanced forward (that is, when the movable member 23 is in the open state). That is, when the movable member 23 is advancing forward, when the flowing game ball comes into contact with the upper side of the movable member 23, it is guided to the left. As a result, the game ball can enter the second starting port 21.

On the other hand, when the second starting port 21 is retracted backward (that is, when it is in the closed state), the game ball cannot enter the ball. That is, when the movable member 23 is retracted backward, the flowing game ball does not come into contact with the movable member 23. As a result, the game ball goes to the out port 16 described later without entering the second starting port 21. The second starting port 21 is completely closed when the movable member 23 is closed, as long as the game ball is more difficult to enter when the movable member 23 is in the closed state than when the movable member 23 is in the open state. It does not have to be something that makes it impossible to enter the ball.

Further, on the display screen 6a of the first image display device 6, the first effect hold display area 9a for displaying the effect hold image 9A according to the number of the first special figure hold and the second effect hold display area 9a according to the number of the second special figure hold are displayed. There is a second effect hold display area 9b for displaying the effect hold image 9B. The first special figure hold means that the jackpot lottery based on the entry into the first starting port 20 is held. The second special figure hold means that the jackpot lottery based on the entry into the second starting port 21 is held. By displaying the staging hold images 9A and 9B, it is possible to show the number of the first special figure hold and the number of the second special figure hold to the player in an easy-to-understand manner.

Further, a first large winning device (first special variable winning device) 31 provided with a first large winning opening (first special winning opening) 30 is provided diagonally upward to the right of the first starting opening 20. The first special winning device 31 includes an opening / closing member (first special winning opening opening / closing member) 32 that takes an open state and a closed state, and opens and closes the first special winning opening 30 by the operation of the opening / closing member 32. The first large winning opening 30 allows a game ball to enter only when the opening / closing member 32 is open (that is, when it is in the open state).

Further, above the first large winning opening 30, a gate (passing area) 28 through which a game ball can pass is provided. The passage of the game ball to the gate 28 is an opportunity to execute a normal symbol lottery (that is, acquisition and determination of a normal symbol random number (hit random number)) for determining whether or not to open the electric chew 22.

Further, a second large winning device (second special variable winning device) 36 provided with a second large winning opening (second special winning opening) 35 is provided diagonally above the right side of the gate 28. The second special winning device 36 includes an opening / closing member (second special winning opening opening / closing member) 37 that takes an open state and a closed state, and opens and closes the second special winning opening 35 by the operation of the opening / closing member 37. The second large winning opening 35 allows a game ball to enter only when the opening / closing member 37 is open (that is, when it is in the open state).

Further, as shown in FIG. 4, display devices 40 are arranged at the lower left of the game board 2. Further, a normal winning opening 27 is provided in the lower left and lower right of the game area 3. Further, at the lowermost portion of the game area 3, an out port 16 is provided to discharge a game ball that has been driven into the game area 3 but has not won a prize in any of the winning openings to the outside of the game area 3.

In the game area 3 in which various winning openings and the like are arranged, the left game area (first game area) 3A on the left side of the center in the left-right direction and the right game area (second game area) 3B on the right side are arranged. There is. The method of launching a game ball so that the game ball flows down in the left game area 3A is called left-handed. On the other hand, a method of launching a game ball so that the game ball flows down in the right game area 3B is called right-handed hitting. In the pachinko gaming machine 1 of the present embodiment, the flow path through which the game ball can flow down when playing left-handed is called the first flow path W1, and the flow path through which the game ball flows down when playing right-handed. Is referred to as a second flow path W2.

A normal winning opening 27, a first starting opening 20, a second starting opening 21, and an out opening 16 are provided on the first flow path W1. The player aims to win a prize in the first starting port 20 by hitting left. It should be noted that the game ball flowing down the first flow path W1 is configured so as to hardly win a prize in the second starting port 21.

On the other hand, on the second flow path W2, a second big winning device 36, a first big winning device 31, a normal winning opening 27, a second starting opening 21, and an out opening 16 are provided. By hitting right, the player can win the second prize opening 35 (passing through the specific area 39), pass through the gate 28, or win the first prize opening 30, or the second starting opening. Aim to win 21.

Further, as shown in FIGS. 4 and 5, the pachinko gaming machine 1 of the present embodiment is provided with a second image display device (second display means) 7 above the first image display device 6. On the display screen 7a of the second image display device 7, a background image or a character image is used in accordance with the decorative pattern variation effect, the jackpot effect, the demo effect for waiting for customers, etc. executed on the display screen 6a of the first image display device 6. Various staging images such as are displayed. In this embodiment, the display screen 6a of the first image display device 6 and the display screen 7a of the second image display device 7 can be linked to display a seamless image, and separate images can be displayed independently of each other. It can also be displayed.

As shown in FIG. 5, the second image display device 7 is fixed in a state of being inclined diagonally upward toward the front. The upper portion 7b of the display screen 7a of the second image display device 7 protrudes forward from the game surface 2a of the game board 2. This makes it possible for the player to show the upper portion 7b of the display screen 7a at a closer position. Further, as shown in FIG. 4, the upper portion 7b of the display screen 7a of the second image display device 7 protrudes above the upper end of the game area 3. As a result, it is possible for the player to show the upper portion 7b of the display screen 7a even outside the gaming area 3. In this way, in this embodiment, the display screen 6a of the first image display device 6 and the display screen 7a of the second image display device 7 form a novel display screen, and the player can see the effect image over a wide range and at a short distance. It is possible to show. As a result, it is possible to enhance the impact of the staging images displayed on the display screens 6a and 7a.

Further, as shown in FIG. 5, a board movable body (decorative movable body) 15 is provided behind the game surface 2a of the game board 2. The board movable body 15 is displaceable in front of the display screen 6a of the first image display device 6. The board movable body 15 can move from the origin position, which is almost invisible from the front, to the drive position appearing in front of the center of the display screen 6a of the first image display device 6.

As shown in FIG. 6A, a specific region (V region) 39 and a non-specific region 70 through which a game ball passing through the second prize opening 35 can pass are formed inside the second prize winning device 36. Has been done. In the second big winning device 36, a second big winning opening sensor 35a for detecting the winning of a game ball to the second big winning opening 35 is arranged upstream of the specific area 39 and the non-specific area 70. .. Further, in the specific area 39, a specific area sensor 39a for detecting the passage of the game ball to the specific area 39 is arranged. Further, in the non-specific area 70, a non-specific area sensor 70a for detecting the passage of a game ball to the non-specific area 70 is arranged. Further, the second prize-winning device 36 has a distribution member 71 that distributes the game ball that has passed through the second prize-winning opening 35 to either the specific area 39 or the non-specific area 70, and the distribution member 71 that drives the distribution member 71. It is provided with a member solenoid 73. The distribution member 71 moves forward and backward in the left-right direction, and takes a retracted state (first state) retracted to the right or an advanced state (second state) advanced to the left.

FIG. 6A shows the time when the distribution member solenoid 73 is energized. As shown in FIG. 6A, when the distribution member solenoid 73 is energized, the distribution member 71 is in the first state of allowing the game ball to pass through the specific area 39. When the distribution member 71 is in the first state, the game ball that has won the second special winning opening 35 passes through the specific area 39 after passing through the second special winning opening sensor 35a. The route of this game ball is called the first route.

FIG. 6B shows the non-energized state of the distribution member solenoid 73. As shown in FIG. 6B, when the distribution member solenoid 73 is not energized, the distribution member 71 is in a second state of hindering the passage of the game ball to the specific area 39. When the distribution member 71 is in the second state, the game ball that has won the second prize opening 35 passes through the second prize opening sensor 35a and then rolls on the upper surface of the distribution member 71 to be unspecified. Pass through region 70. The route of this game ball is called the second route.

In the pachinko gaming machine 1, the passage of the gaming ball to the specific area 39 triggers the transition to the high probability state described later. That is, the specific area 39 is a probabilistic operation port. On the other hand, the non-specific region 70 is not a probabilistic actuation port. Further, the first prize-winning device 31 is not provided with a specific area as a probabilistic operating port. That is, only a non-specific area is provided.

As shown in FIG. 7, the display device 40 variably displays the first special symbol display 41a and the second special symbol (second identification symbol) that variably display the first special symbol (first identification symbol). A second special symbol display 41b and a normal symbol display 42 that variably displays a normal symbol are included. Further, in the indicators 40, the operation hold of the first special symbol display 43a and the second special symbol display 41b for displaying the number of stored operations of the first special symbol display 41a (first special symbol hold) is displayed. Includes a second special figure hold indicator 43b that displays the number of stored items (second special figure hold), and a normal figure hold indicator 44 that displays the number of stored operations hold (normal figure hold) of the normal symbol display 42. It has been.

The variable display of the first special symbol is performed with the winning of the game ball to the first starting port 20 as an opportunity. The variable display of the second special symbol is performed with the winning of the game ball to the second starting port 21 as a trigger. In the following description, the first special symbol and the second special symbol may be collectively referred to as a special symbol (identification symbol). In addition, the first special figure hold and the second special figure hold may be collectively referred to as a special figure hold. Further, the first special symbol display 41a and the second special symbol display 41b may be collectively referred to as a special symbol display 41. Further, the first special figure hold indicator 43a and the second special figure hold indicator 43b may be collectively referred to as a special figure hold indicator 43.

The special symbol display 41 notifies the result of a lottery (special symbol lottery, big hit lottery) based on winning a prize in the first starting port 20 or the second starting port 21 by variably displaying the special symbol and then displaying the stop. .. The stop-displayed special symbol (stop symbol, special symbol derived and displayed as a display result of variable display) is one special symbol selected from a plurality of types of special symbols by a special symbol lottery. If the stop symbol is a predetermined special symbol (a special symbol of a specific stop mode, that is, a jackpot symbol), the first big winning opening 30 or the opening pattern according to the type of the specific special symbol displayed as stopped is used. A special game (big hit game) that opens the second big prize opening 35 is performed.

The special symbol display 41 is composed of, for example, eight LEDs arranged side by side, and displays a special symbol according to the result of the jackpot lottery depending on the lighting mode thereof. For example, if you win a jackpot (one of the multiple types of jackpots described below), you will see "○○ ●● ○○ ●●" (○: lit, ●: off) from the left 1, 2, The jackpot symbol with the 5th and 6th LEDs lit is displayed. If there is a loss, a lost pattern such as "●●●●●●● ○" is displayed, in which only the LED on the far right is lit. A mode in which all the LEDs are turned off may be adopted as a lost pattern. Further, before the special symbol is stopped and displayed, the variable display (variable display) of the special symbol is performed over a predetermined fluctuation time, and the mode of the variation display is, for example, so that light repeatedly flows from left to right. It is an aspect that the LED is turned on. It should be noted that the variable display mode may be any mode such that all the LEDs blink at the same time unless each LED is stopped display (lighting display in a specific mode). In this embodiment, the variable display and stop display of the effect symbols 8L, 8C, 8R are displayed on the display screen 6a of the first image display device 6 in synchronization with the variable display and stop display of the first special symbol or the second special symbol. Is done.

In this pachinko gaming machine 1, if there is a winning (winning) of a game ball in the first starting port 20 or the second starting port 21, the value of various random numbers such as the jackpot random number acquired for the winning (winning information). Equivalent to) is once memorized. Specifically, if the prize is won in the first starting port 20, it is stored as the first special figure hold, and if the prize is won in the second starting port 21, it is stored as the second special figure hold. There is an upper limit to the number of memorable first special figure reservations or the number of second special figure reservations, and the upper limit value in this embodiment is four each.

The stored special figure hold is digested when the variable display of the special symbol based on the special figure hold becomes possible. The digestion of the special figure hold means that the jackpot random number or the like corresponding to the special figure hold is determined, and the variable display of the special symbol for showing the determination result is executed. Therefore, in the pachinko gaming machine 1, when the variable display of the special symbol based on the winning of the game ball to the first starting opening 20 or the second starting opening 21 cannot be performed immediately after the winning, that is, the execution of the variable display of the special symbol. Even if a prize is won during the middle or special game, the right to the jackpot lottery for the prize can be reserved up to a predetermined number.

Then, the number of such special figure hold is displayed on the special figure hold indicator 43. Specifically, the first special figure hold indicator 43a and the second special figure hold indicator 43b are each composed of four LEDs, and the number of LEDs is the same as the number of the first special figure hold or the second special figure hold, respectively. By turning on, the number of the first special figure hold or the second special figure hold is displayed.

The variable display of the normal symbol is performed when the game ball passes through the gate 28. The normal symbol display 42 notifies the result of the normal symbol lottery based on the passage of the game ball to the gate 28 by displaying the normal symbol in a variable manner and then stopping the display. The normal symbol that is stopped and displayed (normal symbol, normal symbol that is derived and displayed as a display result of variable display) is one ordinary symbol selected from a plurality of types of ordinary symbols by the ordinary symbol lottery. When the stop-displayed normal symbol is a predetermined specific normal symbol (ordinary symbol in a predetermined stop mode, that is, a normal hit symbol), the second start opening 21 is opened with an opening pattern according to the current gaming state. Auxiliary games are played.

The ordinary symbol display 42 is composed of, for example, two LEDs, and displays ordinary symbols according to the result of the ordinary symbol lottery depending on the lighting mode thereof. For example, when the lottery result is a win, a normal hit symbol in which both LEDs are lit is displayed, such as "○○" (○: on, ●: off). If the lottery result is lost, a normal lost symbol such as "● ○" in which only the right LED is lit is displayed. A mode in which all the LEDs are turned off may be adopted as a normal loss pattern. Before the normal symbol is stopped and displayed, the fluctuation display (variable display) of the normal symbol is performed over a predetermined fluctuation time, and the mode of the fluctuation display is, for example, that both LEDs are turned on alternately. It should be noted that the variable display mode may be any mode such that all the LEDs blink at the same time unless each LED is stopped display (lighting display in a specific mode).

In the pachinko gaming machine 1, when the game ball passes through the gate 28, the value of the normal symbol random number (winning random number) acquired for the passage is temporarily stored as a normal figure hold. There is an upper limit to the number of memorable normal map reservations, and the upper limit in this embodiment is four.

The stored normal symbol hold is digested when the variable display of the normal symbol based on the normal figure hold becomes possible. The digestion of the normal symbol hold means to determine a normal symbol random number (hit random number) corresponding to the normal symbol hold and execute variable display of the normal symbol to show the determination result. Therefore, in the pachinko gaming machine 1, if the variable display of the normal symbol based on the passage of the game ball to the gate 28 cannot be performed immediately after the passage, that is, the prize is won during the execution of the variable display of the normal symbol or the execution of the auxiliary game. Even if there is, it is possible to reserve the right of the ordinary symbol lottery for the passage up to the predetermined number.

Then, the number of such a normal figure hold is displayed on the normal figure hold indicator 44. Specifically, the normal figure hold indicator 44 is composed of four LEDs, and displays the number of normal figure hold by turning on the LEDs as many as the number of normal figure hold.

2. 2. Configuration of Frame Movable Member Next, the configuration of the frame movable member will be described with reference to FIGS. 8 to 19. In this embodiment, a plurality of frame movable members are attached to the gaming machine frame 50 (front frame 53), and each of them can be moved by the driving force of the driving means (motor). The frame movable member means a movable member attached to the game machine frame 50 side, not to the game board 2 side.

As shown in FIG. 8, the movable body unit 201 can be attached to and detached from the horizontal upper wall portion 57 provided at the upper end of the base frame 56 of the front frame 53 by using a screw (not shown). As shown in FIG. 9, the movable body unit 201 can be divided into three parts, and is assembled to the upper lid member 240, the unit main body 250 arranged below the upper lid member 240, and the front side of the unit main body 250. The front cover 260 is provided. The unit main body 250 includes a frame face movable body 400.

As shown in FIG. 9, the front cover 260 stands upright and is formed long in the left-right direction so that the front side of the frame face movable body 400 can be hidden. A touch sensor (touch electrode) 261 is attached to the upper end of the front cover 260 along the left-right direction. The touch sensor 261 detects that the human body has touched or approached. Therefore, in this embodiment, it is possible not to move the frame face movable body 400 based on the detection by the touch sensor 261. Further, as shown in FIG. 9, a lower cover 510 is attached to the lower side of the frame face movable body 400, and a frame jaw movable body 600 is attached to the front side of the frame face movable body 400.

In addition to the frame face movable body 400, the unit main body 250 is provided with a connecting plate 301, a left side link unit 302L and a right side link unit 302R for rotating the frame face movable body 400, as shown in FIG. .. A relay board 310 on the frame that controls the movement of the frame face movable body 400 is attached to the connecting plate 301.

The configuration of the left link unit 302L and the configuration of the right link unit 302R are symmetrical and similar. Hereinafter, the configuration of the left side link unit 302L will be described as a representative. The left side link unit 302L makes the frame face movable body 400 movable to a standby position or an operating position. In this embodiment, when the frame face movable body 400 is in the standby position, the frame face movable body 400 is in a substantially horizontal state so that the face of the main character indicated by the frame face movable body 400 cannot be seen. On the other hand, when the frame face movable body 400 is in the operating position, the frame face movable body 400 is in an inclined state extending diagonally upward toward the front so that the face of the main character indicated by the frame face movable body 400 can be seen. ing.

As shown in FIG. 10, a left frame face moving motor 311L is attached to the left link unit 302L. The left frame face moving motor 311L imparts a rotational driving force for rotating the frame face movable body 400 between the standby position and the operating position. A right frame face moving motor is attached to the right link unit 302R. The right frame face moving motor also applies a rotational driving force for rotating the frame face movable body 400 between the standby position and the operating position.

A left side link member 340L is attached to the left side link unit 302L. Further, the right side link member 340R is attached to the right side link unit 302R. A frame face movable body 400 is attached to these link members 340L and 340R. The link members 340L and 340R can rotate around the axis center O1 and the axis center O2 by driving the left frame face moving motor 311L and the right frame face moving motor, respectively. As a result, when the frame face movable body 400 moves from the standby position to the operating position, as shown in FIGS. 11A and 11B, the frame face movable body 400 moves (rotates) so that the face of the main character rises forward. It is possible.

A large number of face LEDs 401 are arranged inside the frame face movable body 400. The light emission control of each face LED 401 is executed by the above-mentioned on-frame relay board 310. Specifically, the on-frame relay board 310 controls the face LED 401 to emit light when the frame face movable body 400 is in the operating position. This makes it possible to make the frame face movable body 400 in the operating position shine and stand out.

In this embodiment, when the player or the like pushes up the lower side (lower cover 510) of the frame face movable body 400 in the standby position (see FIG. 1) upward, the frame face movable body 400 is moved to the operating position. It is possible. On the other hand, when the player or the like pushes down the frame face movable body 400 in the operating position downward, the frame face movable body 400 can be moved to the standby position. In short, the frame face movable body 400 is configured to be movable between the standby position and the operating position even by an operation by a human body.

As shown in FIGS. 12A and 12B, the left frame ear movable body 500L and the right frame ear movable body 500R are assembled to the lower cover 510 so as to be swingable and linearly movable. The left frame ear movable body 500L and the right frame ear movable body 500R can swing in the left-right direction between the retracted position shown in FIG. 12 (A) and the exposed position shown in FIG. 12 (B). It can move linearly (movable linearly) between the exposed position shown in FIG. 12 (B) and the exposed position shown in FIG. 12 (C).

As shown in FIG. 12C, a left frame ear moving motor 520L is attached to the left side of the lower cover 510. A right frame ear moving motor 520R is attached to the right side of the lower cover 510. The left frame ear moving motor 520L and the right frame ear moving motor 520R impart a swinging force for swinging the left frame ear movable body 500L and the right frame ear movable body 500R between the retracted position and the exposed position, respectively. At the same time, a linear driving force for linearly moving between the exposed position and the exposed position is applied.

In this embodiment, when the frame face movable body 400 is in the standby position (see FIG. 1), the left frame ear movable body 500L and the right frame ear movable body 500R are each in the retracted position. At this time, the left frame ear movable body 500L and the right frame ear movable body 500R are hidden in the frame face movable body 400 and cannot be exposed from the frame face movable body 400. After that, when the frame face movable body 400 finishes moving from the standby position to the operating position, the left frame ear movable body 500L and the right frame ear movable body 500R first swing from the retracted position to the exposed position. As a result, the left frame ear movable body 500L and the right frame ear movable body 500R can be projected upward from the inside of the frame face movable body 400. Then, the left frame ear movable body 500L and the right frame ear movable body 500R move directly from the exposed position to the exposed position. In this way, the left frame ear movable body 500L and the right frame ear movable body 500R are exposed so as to project upward from the frame face movable body 400 (see FIG. 14).

When the frame face movable body 400 moves from the operating position to the standby position, it operates as follows. That is, first, with the frame face movable body 400 in the operating position, the left frame ear movable body 500L and the right frame ear movable body 500R move directly from the exposed position to the exposed position. Then, the left frame ear movable body 500L and the right frame ear movable body 500R swing from the exposed position to the retracted position. In this way, after the left frame ear movable body 500L and the right frame ear movable body 500R are housed inside the frame face movable body 400, the frame face movable body 400 moves from the operating position to the standby position.

As shown in FIGS. 13A and 13B, the frame jaw movable body 600 is assembled so as to be tiltable (rotatable) with respect to the frame face movable body 400. In this embodiment, the frame jaw movable body 600 can be tilted (rotated) between the closed position shown in FIG. 13 (A) and the open position shown in FIG. 13 (B). As shown in FIG. 13A, when the frame jaw movable body 600 is in the closed position, it is possible to give the impression that the mouth of the main character shown by the frame face movable body 400 is closed. On the other hand, as shown in FIG. 13B, when the frame jaw movable body 600 is in the open position, it is possible to give the impression that the mouth of the main character shown by the frame face movable body 400 is open.

As shown in FIGS. 13A and 13B, the frame jaw moving motor 610 is attached to the lower side of the frame face movable body 400 when it is in the operating position. The frame jaw moving motor 610 imparts a rotational driving force for rotating (tilting) the frame jaw movable body 600 between the closed position and the open position.

FIG. 14 is a perspective view of the pachinko gaming machine 1 when the frame face movable body 400 is in the operating position, and FIG. 15 is a front view of the pachinko gaming machine 1 when the frame face movable body 400 is in the operating position. It is a figure. As shown in FIG. 15, the frame jaw movable body 600 is adapted to tilt between the closed position and the operating position only when the frame face movable body 400 is in the operating position.

As shown in FIG. 16, the right decorative portion 220 is provided with a frame sword movable body 221 and a sheath member 222. The frame sword movable body 221 is assembled to the fixed sheath member 222 so as to be able to move linearly in the vertical direction. The frame sword movable body 221 has a sword tip portion 221a on the lower side. In this embodiment, the frame sword movable body 221 can move linearly between the storage position (second position) shown in FIG. 16 (A) and the pushing position (first position) shown in FIG. 16 (B). As shown in FIG. 16A, when the frame sword movable body 221 is in the storage position, the sword tip portion 221a is housed in the sheath member 222. On the other hand, when the frame sword movable body 221 is in the pushed-in position, the sword tip portion 221a moves upward from the sheath member 222 and is exposed.

A frame sword moving motor 223 (see the broken line in FIGS. 16A and 16B) is mounted inside the sheath member 222. The frame sword moving motor 223 (driving means) applies a linear driving force for linearly moving the frame sword movable body 221 between the storage position and the pushing position. In this embodiment, the frame sword movable body 221 is moved from the storage position to the push-in position by the linear driving force of the frame sword movement motor 223, and the frame sword movable body 221 is urged to be pushed downward by the player. The operation promotion effect (see FIG. 51) is executed. As a result, the player can push the frame sword movable body 221 from the pushing position to the storage position, and can be actively involved in the production.

The storage position shown in FIG. 16A is the position where the frame sword movable body 221 is arranged at the lowest position. A storage position detection sensor 226 capable of detecting that the frame sword movable body 221 is in the storage position is attached to the right decorative portion 220. Further, the pushing position shown in FIG. 16B is a position where the frame sword movable body 221 is arranged at the uppermost position. A push-in position detection sensor 227 capable of detecting that the frame sword movable body 221 is in the push-in position is attached to the right decorative portion 220.

The push-in position detection sensor (first position detection means) 227 is composed of a photo sensor, and detects by blocking the light in the light receiving unit. Specifically, the shielding portion provided on the upper side of the frame sword movable body 221 blocks the light from the light receiving portion of the push-in position detection sensor 227, so that the push-in position detection sensor 227 detects the light. In this embodiment, the shield provided on the upper side of the frame sword movable body 221 until the frame sword movable body 221 descends from the pushing position shown in FIG. 16 (B) to the pushing intermediate position shown in FIG. 16 (C). The unit blocks the light at the light receiving unit of the push-in position detection sensor 227. In short, when the frame sword movable body 221 is between the pushing position and the pushing middle position, there is detection by the pushing position detection sensor 227. On the other hand, as soon as the frame sword movable body 221 moves below the position during pushing, the pushing position detection sensor 227 does not detect it. The vertical distance from the pushing position to the pushing intermediate position is about 10 mm. Further, the storage position detection sensor 226 is also composed of a photo sensor, and detects by blocking the light in the light receiving unit. The push-in position detection sensor 227 and the storage position detection sensor 226 may be configured by a sensor other than the photo sensor.

In this embodiment, when the player or the like pulls out the frame sword movable body 221 in the storage position (see FIG. 16 (A)) upward, the frame sword movable body 221 is pushed in (see FIG. 16 (B)). It is possible to move to. Further, as described above, when the player or the like pushes the frame sword movable body 221 in the pushing position downward, the frame sword movable body 221 can be moved to the storage position. In short, the frame sword movable body 221 is configured to be movable between the storage position and the push-in position even by operation by a human body.

Further, a disk-shaped frame sword disk member 232 (movable member) is rotatably attached to the upper side of the frame sword movable body 221. Further, inside the upper side of the frame sword movable body 221, the broken line of the frame sword disk member rotation motor 231 (FIGS. 16 (A), (B), (C)) that applies a rotational driving force for rotating the frame sword disk member 232. See) is connected. Therefore, as shown in FIG. 16B, the frame sword disk member 232 can be rotated with respect to the frame sword movable body 221 by rotationally driving the frame sword disk member rotation motor 231.

Next, the illuminant unit 202 will be described with reference to FIG. Although the right side light emitter unit 202R will be described here, the left side light emitter unit 202L also has the same configuration. As shown in FIG. 17, the right light emitter unit 202R has a fixed portion 204 and an effect main body portion 206 attached to the front of the fixed portion 204. The fixing portion 204 is fixed to the base frame 56 of the front frame 53. The staging main body 206 can take a forward leaning posture in which the upper portion is located in front of the lower portion and an upright posture (not shown) along the vertical direction. The staging main body 206 includes an exterior body 309, and FIG. 18 shows a state in which the exterior body 309 is removed from the staging main body 206.

As shown in FIG. 18, the staging main body 206 has a lower member 312 on the lower side, and the right frame drum 320R is rotatably attached to the lower member 312. The right frame drum 320R (movable member) has a substantially cylindrical shape, and a large number of drum LEDs 331 (see the broken line in FIG. 18) are arranged inside. The upper portion 320U of the right frame drum 320R has four surfaces along the circumferential direction and is rotatable in the direction indicated by the arrow a in FIG. On the other hand, the lower portion 320D of the right frame drum 320R has four surfaces along the circumferential direction and is rotatable in the direction indicated by the arrow b in FIG.

The upper portion 320U and the lower portion 320D of the right frame drum 320R can be stopped so that the four surfaces form the same plane after each rotation. The four surfaces of the upper portion 320U and the four surfaces of the lower portion 320D are associated with each other on a one-to-one basis, and it is possible to form a specific motif by a combination in a corresponding relationship. .. In this embodiment, it is possible to form a letter "V", a letter "super hot", and a 7-segment display as motifs. Then, the drum LED 331 arranged inside the right frame drum 320R emits light, so that each motif can be emphasized and shown.

In the present embodiment, when the transition to the high probability state described later is acquired based on the passage of the game ball to the specific area 39, the character "V" is formed by the upper portion 320U and the lower portion 320D. Further, among the SP reach, when the SP reach indicating that the expectation for the big hit winning is particularly high is executed, the character "super hot" is formed by the upper portion 320U and the lower portion 320D. In this way, the right frame drum 320R can show information (characters "V", characters "super hot") related to the privilege to the player when the rotating upper portion 320U and the lower portion 320D are stopped. Is.

As shown in FIG. 19, a right frame drum rotation motor 321R is attached to the lower member 312 of the right frame drum 320R. The right frame drum rotation motor 321R (driving means) applies a rotational driving force for rotating the upper portion 320U and the lower portion 320D of the right frame drum 320R. When the right frame drum rotation motor 321R is rotationally driven, the upper portion 320U rotates in the direction indicated by the arrow a in FIG. 19 via a gear mechanism (not shown), and the lower portion 320D passes through a gear mechanism (not shown) in FIG. Rotate in the direction indicated by the arrow b.

Similar to the right light emitter unit 202R, a left frame drum (movable member) is also provided inside the exterior body 309 of the left light emitter unit 202L. Similar to the right frame drum rotation motor 321R, the left frame drum rotation motor (driving means) is attached to the lower member of the left frame drum.

3. 3. Electrical configuration of the gaming machine Next, the electrical configuration of the pachinko gaming machine 1 will be described with reference to FIGS. 20 to 22. As shown in FIG. 20, the pachinko gaming machine 1 includes a main control board (game control board) 80 that controls game profits such as a jackpot lottery and a transition of game states, and a payout control board 110 that controls payout of game balls. , A power supply board 150 for supplying power, and the like are provided. The main control board 80 constitutes a main control unit together with the payout control board 110.

As shown in FIG. 20, a game control one-chip microcomputer (hereinafter referred to as “game control microcomputer”) 81 that controls the progress of the game of the pachinko gaming machine 1 according to a program is mounted on the main control board 80. The game control microcomputer 81 contains a ROM (Read Only Memory) 83 that stores a program for controlling the progress of the game, a RAM (Random access memory) 84 that is used as a work memory, and a program stored in the ROM 83. It includes a CPU (Central Processing Unit) 82 for execution, and an I / O port unit (input / output circuit) 87 for inputting / outputting data and signals. The ROM 83 may be externally attached.

The RAM 84 is provided with a special figure holding storage unit 85 (a first special drawing holding storage unit 85a and a second special drawing holding storage unit 85b). The first special figure reservation storage unit 85a is composed of four storage areas corresponding to the number of storable first special figure reservations. Further, the second special figure reservation storage unit 85b is composed of four storage areas corresponding to the number of storable second special figure reservations. Each storage area is divided into four storage areas. These four storage areas are an area for storing a jackpot random number, which will be described later, an area for storing a hit type random number, an area for storing a reach random number, and an area for storing a variation pattern random number.

Further, the RAM 84 is provided with a general drawing reservation storage unit 86. The normal figure reservation storage unit 86 includes a storage area corresponding to the number of normal figure reservations that can be stored. Each storage area is an area for storing ordinary symbol random numbers.

Further, as shown in FIG. 20, various sensors and solenoids are connected to the main control board 80 via the relay board 88. Therefore, a signal is input to the main control board 80 from each sensor, and a signal is output to each solenoid from the main control board 80. Specifically, as the sensors, the first start port sensor 20a, the second start port sensor 21a, the gate sensor 28a, the first big winning opening sensor 30a, the second big winning opening sensor 35a, the specific area sensor 39a, and the non-specific The area sensor 70a and the normal winning opening sensor 27a are connected.

The first start port sensor 20a is provided in the first start port 20 and detects a game ball that has won a prize in the first start port 20. The second starting port sensor 21a is provided in the second starting port 21 and detects a game ball that has won a prize in the second starting port 21. The gate sensor 28a is provided in the gate 28 and detects a game ball that has passed through the gate 28. The first large winning opening sensor 30a is provided in the first large winning opening 30 and detects a game ball that has won a prize in the first large winning opening 30. The second large winning opening sensor 35a is provided in the second large winning opening 35 and detects a game ball that has won a prize in the second large winning opening 35. The specific area sensor 39a is provided in the specific area 39 in the second large winning opening 35 and detects a game ball that has passed through the specific area 39. The non-specific area sensor 70a is provided in the non-specific area 70 in the second special winning opening 35 and detects a game ball that has passed through the non-specific area 70. The ordinary winning opening sensor 27a is provided in each ordinary winning opening 27, and detects a game ball that has won a prize in the ordinary winning opening 27.

Further, as the solenoids, an electric chew solenoid 24, a first large winning opening solenoid 33, a second large winning opening solenoid 38, and a distribution member solenoid 73 are connected. The electric chew solenoid 24 drives the movable member 23 of the electric chew 22. The first prize-winning port solenoid 33 drives the opening / closing member 32 of the first prize-winning device 31. The second prize-winning port solenoid 38 drives the opening / closing member 37 of the second prize-winning device 36. The distribution member solenoid 73 drives the distribution member 71 of the second prize-winning device 36.

Further, the main control board 80 includes a first special symbol display 41a, a second special symbol display 41b, a normal symbol display 42, a first special symbol hold indicator 43a, a second special symbol hold indicator 43b, and a general. Figure Hold indicator 44 is connected. That is, the display control of these indicators 40 is performed by the game control microcomputer 81.

Further, the main control board 80 transmits various commands to the payout control board 110, and also receives a signal from the payout control board 110 for payout monitoring. On the payout control board 110, a prize ball payout device 120, a ball rental payout device 130, and a card unit 135 (installed adjacent to the pachinko gaming machine 1 and capable of ball lending based on information such as an inserted prepaid card). The launcher 112 is connected via the launch control circuit 111. The launcher 112 includes a handle 60.

The payout control board 110 drives the prize ball motor 121 of the prize ball payout device 120 based on the signal from the game control microcomputer 81 and the signal from the card unit 135 connected to the pachinko gaming machine 1. Is paid out, or the ball rental motor 131 of the ball rental payout device 130 is driven to pay out the ball rental. The prize balls to be paid out are detected by the prize ball sensor 122 for the counting. Further, the ball lending sensor to be paid out is detected by the ball lending sensor 132 for the counting. When the player operates the handle 60 of the launching device 112, the touch switch 114 detects contact with the handle 60, and the firing volume 115 detects the amount of rotation of the handle 60. Then, the launch motor 113 is driven so that the game ball is launched with a strength corresponding to the magnitude of the detection signal of the launch volume 115. In the pachinko gaming machine 1, one gaming ball is launched in about 0.6 seconds.

Further, the main control board 80 transmits various commands to the sub control board 90 shown in FIG. 21. The connection between the main control board 80 and the sub control board 90 is a unidirectional communication connection capable of only transmitting a signal from the main control board 80 to the sub control board 90. That is, a unidirectional circuit (for example, a circuit using a diode) (not shown) as a communication direction regulating means is interposed between the main control board 80 and the sub control board 90.

As shown in FIG. 21, the pachinko gaming machine 1 has a sub-control board (effect control board) 90 that controls an effect to be executed as the game progresses, an image control board 100 that performs image control, and voice control. It is provided with a voice control board 106 for performing. A one-chip microcomputer for effect control (hereinafter referred to as “microcomputer for effect control”) 91 that controls the effect of the pachinko gaming machine 1 according to a program is mounted on the sub control board 90. The effect control microcomputer 91 (effect control means) includes a ROM 93 that stores a program for controlling the effect as the game progresses, a RAM 94 that is used as a work memory, and a CPU 92 that executes a program stored in the ROM 93. , An I / O port unit (input / output circuit) 97 for inputting / outputting data and signals is included. The ROM 93 may be externally attached.

An image control board 100, a voice control board 106, and a sub drive board 107 are connected to the sub control board 90. The effect control microcomputer 91 of the sub control board 90 controls the display of the first image display device 6 and the display control of the second image display device 7 on the CPU 102 of the image control board 100 based on the command received from the main control board 80. To do. The RAM 104 of the image control board 100 is a memory for expanding image data. In the ROM 103 of the image control board 100, still image data and moving image data displayed on the first image display device 6 and the second image display device 7, specifically, characters, items, figures, characters, numbers, symbols, etc. ( Image data such as (including decorative patterns) and background images are stored. The CPU 102 of the image control board 100 reads image data from the ROM 103 based on a command from the effect control microcomputer 91. Then, display control is executed based on the read image data.

Further, the effect button detection switch (SW) 63a and the select button detection switch 68a are connected to the sub control board 90. The effect button detection switch 63a detects that the effect button 63 has been pressed. When the effect button 63 is pressed, a detection signal is output from the effect button detection switch 63a to the sub control board 90. Further, the select button detection switch 68a detects that the select button 68 has been pressed. When the select button is pressed, a detection signal is output from the select button detection switch 68a to the sub control board 90.

The effect control microcomputer 91 outputs voice, music, sound effects, and the like from the speaker 67 via the voice control board 106 based on the command received from the main control board 80. Acoustic data such as voice output from the speaker 67 is stored in the ROM 93 of the sub-control board 90. A CPU may be mounted on the voice control board 106, and in that case, the CPU may be made to execute voice control. Further, in this case, the ROM may be mounted on the voice control board 106, or the acoustic data may be stored in the ROM. Further, the speaker 67 may be connected to the image control board 100, and the CPU 102 of the image control board 100 may execute voice control. Further, in this case, the acoustic data may be stored in the ROM 103 of the image control board 100.

The power supply board 150 (power supply means) supplies power to the main control board 80, the sub control board 90, and the payout control board 110, and supplies power required for other devices via these boards. Supply. The power supply board 150 is provided with a backup power supply circuit 151. When the power is not supplied to the pachinko gaming machine 1, the backup power supply circuit 151 supplies power to the RAM 84 of the main control board 80 and the RAM 94 of the sub control board 90, which will be described later. Therefore, the information stored in the RAM 84 of the main control board 80 and the RAM 94 of the sub control board 90 is retained even when the pachinko gaming machine 1 is turned off. Further, a power switch 155 is connected to the power supply board 150. By turning the power switch 155 on and off, the power can be turned on / off. The backup power supply circuit for the RAM 84 of the main control board 80 may be provided on the main control board 80, or the backup power supply circuit for the RAM 94 of the sub control board 90 may be provided on the sub control board 90.

Further, as shown in FIG. 22, the pachinko gaming machine 1 includes a sub drive board 107. The staging control microcomputer 91 described above controls the lighting of lamps such as the frame lamp 66 and the panel lamp 5 via the sub drive board 107 shown in FIG. 22 based on the command received from the main control board 80, and also controls the lighting of the sub. Lighting control of the face LED 401 and the drum LED 331 is performed via the drive board 107 and the on-frame relay board 310. The effect control microcomputer 91 has light emission pattern data (also referred to as lighting / extinguishing data, light emission color, etc.) that determines the light emission mode of lamps such as a frame lamp 66, a panel lamp 5, a face LED 401, and a drum LED 331. Is created, and the light emission of lamps such as the frame lamp 66, the board lamp 5, the face LED 401, and the drum LED 331 is controlled according to the light emission pattern data. The data stored in the ROM 93 of the sub-control board 90 is used to create the light emission pattern data.

Further, the effect control microcomputer 91 controls the drive of the panel movable body moving motor 15a and the effect button vibration motor 63b connected to the sub drive board 107 based on the command received from the main control board 80. That is, the effect control microcomputer 91 creates operation pattern data (drive data) that determines the operation mode of the panel movable body 15, and controls the drive of the panel movable body moving motor 15a according to the operation pattern data. The board movable body moving motor 15a applies a driving force (rotational force) to the board movable body 15 to make the board movable body 15 movable. Further, the effect control microcomputer 91 creates an operation pattern that determines the operation mode of the effect button 63, and controls the drive of the effect button vibration motor 63b according to the operation pattern data. The effect button vibration motor 63b enables the effect button 63 to vibrate (move). The data stored in the ROM 93 of the sub control board 90 is used to create the operation pattern data. The operation pattern data includes drive data that determines the operation mode of the frame face movable body 400, drive data that determines the operation mode of the left frame drum and the right frame drum 320R, and drive data that determines the operation mode of the frame ear movable body 500. There are also drive data for determining the data of the frame jaw movable body 600, drive data for determining the operation mode of the frame sword movable body 221, and drive data for determining the operation mode of the frame sword disk member 232.

The above-mentioned on-frame relay board 310 is connected to the sub-drive board 107, and the frame right relay board 224 and the frame upper right relay board 225 are connected. As described above, the on-frame relay board 310 is a relay board attached to the connecting plate 301 (see FIG. 10) of the upper decorative portion 200. The frame right relay board 224 is a relay board provided in the right decorative portion 220. The frame upper right relay board 225 is a relay board provided in the right decorative portion 220 and arranged above the frame right relay board 224.

A frame face moving motor 311 for rotating the frame face movable body 400 is connected to the frame face relay board 310. The frame face moving motor 311 is a general term for the left frame face moving motor 311L and the right frame face moving motor. The sub drive board 107 controls the drive of the frame face moving motor 311 via the on-frame relay board 310 based on the drive signal (serial signal, clock signal, etc.) from the sub control board 90. Further, a frame drum rotation motor 321 for rotating the frame drum 320 is connected to the frame relay board 310. The frame drum 320 (movable member) is a general term for the right frame drum 320R and the left frame drum. The frame drum rotation motor 321 (driving means) is a general term for the right frame drum rotation motor 321R and the left frame drum rotation motor 321L. The sub drive board 107 controls the drive of the frame drum rotation motor 321 via the on-frame relay board 310 based on the drive signal from the sub control board 90.

Further, a frame ear moving motor 520 for swinging and linearly moving the frame ear movable body 500 is connected to the frame ear relay board 310. The frame ear movable body 500 is a general term for the left frame ear movable body 500L and the right frame ear movable body 500R. The frame ear moving motor 520 is a general term for the left frame ear moving motor 520L and the right frame ear moving motor 520R. The sub drive board 107 performs drive control of the frame ear moving motor 520 via the frame relay board 310 based on the drive signal from the sub control board 90. Further, a frame jaw moving motor 610 for rotating the frame jaw movable body 600 is connected to the frame upper relay board 310. Therefore, the sub drive board 107 controls the drive of the frame jaw moving motor 610 via the on-frame relay board 310 based on the drive signal from the sub control board 90.

A touch sensor 261 is connected to the relay board 310 on the frame. Therefore, upon contacting the touch sensor 261, a detection signal is output from the touch sensor 261 to the sub control board 90 via the on-frame relay board 310 and the sub drive board 107. Further, the face LED 401 and the drum LED 331 whose lighting is controlled as described above are connected to the frame relay board 310.

A frame sword moving motor 223 for directly moving the frame sword movable body 221 is connected to the frame right relay board 224. Therefore, the sub drive board 107 controls the drive of the frame sword moving motor 223 via the frame right relay board 224 based on the drive signal from the sub control board 90. Further, a storage position detection sensor 226 is connected to the frame right relay board 224. Therefore, when the detection is performed by the storage position detection sensor 226, a detection signal is output from the storage position detection sensor 226 to the sub control board 90 via the frame right relay board 224 and the sub drive board 107. Further, the push-in position detection sensor 227 is connected to the frame right relay board 224. Therefore, when the detection is performed by the push-in position detection sensor 227, a detection signal is output from the push-in position detection sensor 227 to the sub-control board 90 via the frame right relay board 224 and the sub-drive board 107.

A frame sword disk member rotation motor 231 for rotating the frame sword disk member 232 is connected to the frame upper right relay board 225. Therefore, the sub drive board 107 controls the drive of the frame sword disk member rotation motor 231 via the frame upper right relay board 225 based on the drive signal from the sub control board 90.

A CPU may be mounted on the sub drive board 107, the on-frame relay board 310, the frame right relay board 224, and the frame upper right relay board 225. In that case, drive control of each motor and lighting control of each lamp may be performed on the CPU. May be executed. Further, in this case, the ROM may be mounted on the sub drive board 107, the on-frame relay board 310, the frame right relay board 224, and the frame upper right relay board 225, or data related to the light emission pattern and the operation pattern may be stored in the ROM. good.

In the present embodiment, the sub control board 90 constitutes a sub control unit together with the image control board 100, the voice control board 106, and the sub drive board 107. The sub control unit includes at least a sub control board 90, and is an effect means (first image display device 6, second image display device 7, board lamp 5, frame lamp 66, speaker 67, frame face movable body 400, etc.). It suffices if it is possible to control the game effect using. In the pachinko gaming machine 1 of the present embodiment, a speaker 67 for outputting voice, music, sound effects, etc. is provided on the lower side on the rear side of the upper decorative portion 200.

In this embodiment, as described above as the frame movable member, the frame face movable body 400, the frame ear movable body 500, the frame jaw movable body 600, the frame sword movable body 221 and the frame sword disk member 232, and the frame drum. 320 is provided. Since many frame movable members are provided in this way, the current consumption (electric power) of the power supply board 150 is large.

Here, FIGS. 20 to 22 are only functional block diagrams for explaining the electrical configuration of the pachinko gaming machine 1, and not only the substrates shown in FIGS. 20 to 22 are provided. Except for the main control board 80, any plurality of boards shown in FIGS. 20 to 22 may be configured as one board, or one board shown in FIGS. 20 to 22 may be configured as a plurality of boards. good.

Here, the structure of the frame sword moving motor 223 of the present embodiment will be described with reference to FIG. 23 (A). As shown in FIG. 23 (A), the frame sword moving motor 223 of this embodiment is a bipolar type stepping motor. In this embodiment, in addition to the frame sword moving motor 223, the frame face moving motor 311, the frame drum rotating motor 321 and the frame ear moving motor 520, the frame jaw moving motor 610, the frame sword disk member rotating motor 231 and the board movable body moving motor. 15a is also a bipolar type stepping motor.

The bipolar type stepping motor is provided with two sets of coils A and B, as shown in FIG. 23 (A), to explain the functions schematically. The coil A is provided with a φ1 terminal and a φ2 terminal. Further, the coil B is provided with a φ3 terminal and a φ4 terminal. When driving this bipolar type stepping motor, the directions of the currents flowing through the coil A and the coil B are alternately shown as shown in (1) ⇒ (2) ⇒ (3) ⇒ (4) in FIG. 23 (A). It is designed to switch.

That is, first, as shown in (1) of FIG. 23 (A), a current is passed from the φ1 terminal to the φ2 terminal of the coil A. Next, as shown in (2) of FIG. 23 (A), a current is passed from the φ3 terminal to the φ4 terminal of the coil B. Subsequently, as shown in (3) of FIG. 23 (A), a current is passed from the φ2 terminal to the φ1 terminal of the coil A. Finally, as shown in (4) of FIG. 23 (A), a current is passed from the φ4 terminal to the φ3 terminal of the coil B. After that, by repeating the above (1), (2), (3), and (4), the rotation axis is rotated so as to be attracted by the generated magnetic force. In this way, the bipolar type stepping motor is characterized in that the direction of the current flowing through each terminal is switched.

Next, a unipolar type stepping motor that has been generally used as a motor for staging will be described with reference to FIG. 23 (B). The unipolar type stepping motor is also provided with two sets of coils A and B, as shown in FIG. 23B, to explain the functions schematically. The coil A is provided with a φ1 terminal and a φ2 terminal, and a tap TP is provided in the middle of the coil A. Further, the coil B is provided with a φ3 terminal and a φ4 terminal, and a tap TP is provided in the middle of the coil B. A + power supply (DC) is always connected to the tap TP. When driving this unipolar stepping motor, a current should flow from the tap TP to each terminal in one direction as shown in (1) ⇒ (2) ⇒ (3) ⇒ (4) in FIG. 23 (B). It has become.

That is, first, as shown in (1) of FIG. 23 (B), a current is passed from the tap TP of the coil A to the φ1 terminal. Next, as shown in (2) of FIG. 23 (B), a current is passed from the tap TP of the coil B to the φ3 terminal. Subsequently, as shown in (3) of FIG. 23 (B), a current is passed from the tap TP of the coil A to the φ2 terminal. Finally, as shown in (4) of FIG. 23 (B), a current is passed from the tap TP of the coil B to the φ4 terminal. After that, by repeating the above (1), (2), (3), and (4), the rotation axis is rotated so as to be attracted by the generated magnetic force. In this way, the unipolar type stepping motor is characterized in that the direction of the current flowing through each terminal is always constant.

As described above, in the unipolar type stepping motor shown in FIG. 23 (B), half of the coils in the coils A and B of each phase during rotation (at any time in (1), (2), (3), and (4)). The current is flowing only in (winding). On the other hand, in the bipolar type stepping motor shown in FIG. 23 (A), although the direction of the current is switched in the coils A and B in each phase during rotation, the current is flowing in the entire coil. .. That is, the coil always functions. Therefore, when a bipolar type stepping motor is used as in the present embodiment, the coil utilization efficiency is higher if the coils have the same number of turns as compared with the case where a unipolar type stepping motor is used as in the conventional case. .. As a result, the motor can be rotated efficiently, and the output torque at low speed rotation can be increased.

In this embodiment, two-phase excitation is used as an excitation method when a bipolar type stepping motor moves a movable member. As shown in FIG. 24A, the two-phase excitation is a method of simultaneously exciting two phases at the same time while shifting by one pulse with respect to the next phase to which a pulse is applied. For this two-phase excitation, for example, there is one-phase excitation. As shown in FIG. 24B, the one-phase excitation is a method of exciting one phase at a time each time a pulse is applied. The two-phase excitation of this embodiment can stabilize the rotation as compared with the one-phase excitation, which is advantageous for high-speed rotation. Further, there is an advantage that the output torque can be increased. However, there is a demerit that the current consumption (electric power) is doubled as compared with the one-phase excitation.

4. Electrical Circuits of Frame Right Relay Board and Frame Top Relay Board Next, the electric circuits of the frame right relay board 224, the frame top relay board 310, and the frame upper right relay board 225 will be described with reference to FIGS. 25 to 30. First, the electric circuit of the frame right relay board 224 will be described. As shown in FIG. 25, the frame sword moving motor driver IC1 is mounted on the frame right relay board 224. The frame sword moving motor driver IC1 (drive circuit unit) is a stepping motor driver that controls the driving of the frame sword moving motor 223.

As shown in FIG. 25, the frame sword moving motor driver IC1 has a Vcc terminal, a VREFA terminal, a VREFB terminal, a PHASEA terminal, a PHASEB terminal, an INA1 terminal, an INA2 terminal, an INB1 terminal, an INB2 terminal, a STANDBY terminal, and a 6-bit GND. Terminal, 2-bit OUTA + terminal, 2-bit OUTA- terminal, 2-bit OUTB + terminal, 2-bit OUTB- terminal, 2-bit RSA terminal, 2-bit RSB terminal, 18-bit It has an NC (unconnected) terminal and other terminals (OSCM terminal, VM terminal). As the frame sword moving motor driver IC1, a general-purpose driver such as "TB67S101AFTG" manufactured by Texas Instruments can be preferably used.

The Vcc terminal is a terminal to which a 5V power supply is supplied. The VREFA terminal is an A-phase motor output setting terminal for the frame sword moving motor 223. The VREFB terminal is a B-phase motor output setting terminal for the frame sword moving motor 223. Here, the current output from the OUTA + terminal and the OUTA− terminal, which will be described later, is switched by the voltage acting on the VREFA terminal. That is, if the voltage acting on the VREFA terminal is large, it is possible to increase the current output from the OUTA + terminal and the OUTA− terminal, which will be described later. Similarly, the voltage acting on the VREFB terminal switches the current output from the OUTB + terminal and the OUTB− terminal, which will be described later. That is, if the voltage acting on the VREFB terminal is large, it is possible to increase the current output from the OUTB + terminal and the OUTB− terminal, which will be described later.

The PHASEA terminal is an A-phase polarity setting terminal for the frame sword moving motor 223 (see FIG. 23 (A)). The PHASEB terminal is a B-phase polarity setting terminal for the frame sword moving motor 223. The INA1 terminal and the INA2 terminal are A-phase output control terminals for the frame sword moving motor 223. The INB1 terminal and the INB2 terminal are B-phase output control terminals for the frame sword moving motor 223. The STANDBY terminal is a power saving mode setting terminal. The GND terminal is a terminal for connecting to the ground.

The OUTA + terminal is a current output terminal for the A-phase φ1 terminal of the frame sword moving motor 223 (φ1 terminal of coil A, see FIG. 23 (A)). The OUTA-terminal is a current output terminal for the A-phase φ2 terminal (φ2 terminal of the coil A) of the frame sword moving motor 223. The OUTB + terminal is a current output terminal for the B-phase φ3 terminal (φ3 terminal of the coil B) of the frame sword moving motor 223. The OUTB-terminal is a current output terminal for the B-phase φ4 terminal (φ4 terminal of the coil B) of the frame sword moving motor 223. The RSA terminal is a terminal for detecting the current output to the A phase (coil A) of the frame sword moving motor 223. The RSB terminal is a terminal for detecting the current output to the B phase (coil B) of the frame sword moving motor 223.

By the way, the frame sword moving motor driver IC1 shown in FIG. 25 can supply a predetermined constant current to the terminals φ1 and φ2 of the coil A of the frame sword moving motor 223 and the terminals φ3 and φ4 of the coil B. It is a constant current drive system. In the constant current drive method, the current flowing through each coil A and B is constantly monitored so that it becomes a constant current, and when a current exceeding the specified current tries to flow, the voltage is repeatedly turned on and off at high speed to obtain a constant current. It is a method to keep. In contrast to this constant current drive method, there is a constant voltage drive method. The constant voltage drive method is a method in which the voltage acting on each of the coils A and B is maintained at a constant voltage.

Here, when the motor rotates, an induced electromotive force (counter electromotive force) is generated in each of the coils A and B, and a counter electromotive voltage acts on the coils. Therefore, in the case of the constant voltage drive method, the effective voltage (constant voltage by the constant voltage drive method) acting on each of the coils A and B is reduced by the counter electromotive voltage. In particular, as the motor rotates at a higher speed, a large counter electromotive voltage acts on each of the coils A and B, so that it becomes difficult for current to flow. As a result, it is difficult to increase the output torque of the motor in the constant voltage drive method. On the other hand, in the case of the constant current drive method, even if a counter electromotive voltage is generated, the current flowing through each of the coils A and B is controlled to be stable at a constant current. As a result, it is possible to improve the output characteristics at the time of high-speed rotation of the motor as compared with the constant voltage drive method. In the frame sword moving motor driver IC1 of this embodiment, the constant current supplied by the constant current drive method is set to be 230 mA.

The OUTA + terminal of the frame sword moving motor driver IC1 is connected to the first terminal of the connector CN1 via the control line L1. The first terminal of the connector CN1 is connected to the terminal φ1 (see FIG. 23 (A)) of the coil A of the frame sword moving motor 223 via a harness (not shown). Therefore, the current output from the OUTA + terminal of the frame sword moving motor driver IC1 can be passed through the control line L1 to the terminal φ1 of the coil A of the frame sword moving motor 223. Here, the present embodiment is characterized in that the current cutoff circuit 224A is provided in the control line L1, but the current cutoff circuit 224A will be described later.

Further, the OUTA- terminal of the frame sword moving motor driver IC1 is connected to the second terminal of the connector CN1 via the control line L2. The second terminal of the connector CN1 is connected to the terminal φ2 (see FIG. 23A) of the coil A of the frame sword moving motor 223 via a harness (not shown). Therefore, the current output from the OUTA- terminal of the frame sword moving motor driver IC1 can be passed through the control line L2 to the terminal φ2 of the coil A of the frame sword moving motor 223.

Further, the OUTB + terminal of the frame sword moving motor driver IC1 is connected to the third terminal of the connector CN1 via the control line L3. The third terminal of the connector CN1 is connected to the terminal φ3 (see FIG. 23A) of the coil B of the frame sword moving motor 223 via a harness (not shown). Therefore, the current output from the OUTB + terminal of the frame sword moving motor driver IC1 can be passed through the control line L3 to the terminal φ3 of the coil B of the frame sword moving motor 223. Here, the present embodiment is characterized in that the control line L3 is provided with the current cutoff circuit 224A, but the current cutoff circuit 224A will be described later.

Further, the OUTB- terminal of the frame sword moving motor driver IC1 is connected to the fourth terminal of the connector CN1 via the control line L4. The fourth terminal of the connector CN1 is connected to the terminal φ4 (see FIG. 23A) of the coil B of the frame sword moving motor 223 via a harness (not shown). Therefore, the current output from the OUTB- terminal of the frame sword moving motor driver IC1 can be passed through the control line L4 to the terminal φ4 of the coil B of the frame sword moving motor 223.

As shown in FIG. 25, a control line extending from the VREFA terminal of the frame sword moving motor driver IC1 and a control line extending from the VREFB line are combined to form one control line L5. The control line L5 is divided into a control line L5a extending from the branch point BT to the upper side in FIG. 25 and a control line L5b extending from the branch point BT to the lower side in FIG. 25. A resistor R1 is connected to the control line L5a, and a resistor R2 is connected to the control line L5b. The present embodiment is characterized in that the inspection external circuit 224B is incorporated in the control line L5a, but the inspection external circuit 224B will be described later.

Further, as shown in FIG. 25, an avalanche diode ZD1 is provided between the control line L1 and the ground, an avalanche diode ZD2 is provided between the control line L2 and the ground, and an avalanche diode is provided between the control line L3 and the grind. A diode ZD3 is provided, and an avalanche diode ZD4 is provided between the control line L4 and the ground. These avalanche diodes ZD1, ZD2, ZD3, ZD4 protect each control line L1, L2, L3, L4 when an overvoltage (for example, several thousand V) acts on each control line L1, L2, L3, L4. It is something to do.

As shown in FIG. 25, the control lines extending from the two OUTA + terminals of the frame sword moving motor driver IC1 are combined to form one control line L1. Further, the control lines extending from the two OUTA- terminals of the frame sword moving motor driver IC1 are combined to form one control line L2. Further, the control lines extending from the two OUTB + terminals of the frame sword moving motor driver IC1 are combined to form one control line L3. Further, the control lines extending from the two OUTB- terminals of the frame sword moving motor driver IC1 are combined to form one control line L4. This is because the current that can be output from one (1 bit) terminal of the frame sword moving motor driver IC1 is limited, so a larger current can be supplied by combining the control lines that extend from the two terminals. To do.

The frame sword moving motor driver IC1 performs pulse width modulation (PWM) based on the chopping reference frequency so that a constant current can be supplied. The chopping reference frequency means the speed at which the semiconductor element is switched between ON and OFF, and is appropriately set according to the resistance R6 and the capacitor C8 shown in FIG. 25. Further, the capacitor C9 shown in FIG. 25 is a bypass capacitor (decap) connected between the power supply line and the ground, and stabilizes the control circuit in the frame sword moving motor driver IC1.

Further, as shown in FIG. 26, the input / output IC 2 is mounted on the frame right relay board 224. The input / output IC 2 is for inputting / outputting a digital signal. The input / output IC2 has a serial data input / output terminal (SDA terminal), a serial clock input terminal (SCL terminal), a Vcc terminal, a 3-bit address setting terminal (A0 to A2 terminal), and a 5-bit input terminal P11 to. It is equipped with P15, 11-bit output terminals P00 to P10, and other terminals (GND terminal, INT terminal). As the input / output IC 2, GPIO (General Purpose Input Output) such as "SNB6006PWR" manufactured by Texas Instruments can be preferably used.

The input / output IC 2 and the effect control microcomputer 91 are communicably connected by an I2C (Inter Integrated Circuit) communication method. That is, the SDA terminal of the input / output IC 2 is connected to the data signal line to which the serial port 98 of the effect control microcomputer 91 is connected. Further, the SCL terminal of the input / output IC 2 is connected to the clock signal line to which the serial port 98 of the effect control microcomputer 91 is connected.

When communicating with the input / output IC 2 by the I2C communication method, the effect control microcomputer 91 first transmits the address information of the input / output IC 2 as serial data. Then, when the response signal is received from the input / output IC 2 to which the address matching the address information is assigned, the drive data for driving the frame sword movable body 221 is transmitted as serial data to the input / output IC 2. The input / output IC 2 outputs a control signal from the output terminals P00 to P10 based on the drive data input from the effect control microcomputer 91. Thereby, it is possible to drive the frame sword moving motor 223 so that the frame sword movable body 221 operates in an operation mode based on the drive data.

As shown in FIG. 26, the Vcc terminal is a terminal to which a 5V power supply is supplied. The A0 terminal (address setting terminal) is connected to a 5V power supply, while the A1 terminal and the A2 terminal are connected to the ground. The input terminals P11 to P15 for 5 bits are terminals for inputting a detection signal from a sensor (not shown) or the like that detects the position of the frame sword movable body 221. Of the 11-bit output terminals P00 to P10, the 6-bit output terminals P02 to P07 are the PHASEB terminal, PHASEA terminal, INB2 terminal, INB1 terminal, INA2 terminal, and INA1 of the frame sword moving motor driver IC1 shown in FIG. It is a terminal that outputs a control signal to the terminal. The functions of the output terminal P00, the output terminal P01, and the output terminal P10 will be described later.

Next, the electric circuit of the relay board 310 on the frame will be described. As shown in FIG. 27, the left frame drum motor driver IC 11 is mounted on the frame relay board 310. The left frame drum motor driver IC 11 (drive circuit unit) is a stepping motor driver that controls the drive of the left frame drum rotation motor 321L. Further, the right frame drum motor driver IC 21 is mounted on the frame relay board 310. The right frame drum motor driver IC21 (drive circuit unit) is a stepping motor driver that controls the drive of the right frame drum rotation motor 321R. Since the left frame drum motor driver IC 11 and the right frame drum motor driver IC 21 have the same configuration as the frame sword moving motor driver IC 1 shown in FIG. 25, detailed description of the configuration will be omitted.

Further, as shown in FIG. 27, the input / output IC 12 is mounted on the on-frame relay board 310. Since the input / output IC 12 has the same configuration as the input / output IC 2 shown in FIG. 26, detailed description of the configuration will be omitted. The 6-bit output terminals P02 to P07 of the input / output IC 12 are connected to the PHASEB terminal, PHASEA terminal, INB2 terminal, INB1 terminal, INA2 terminal, and INA1 terminal of the right frame drum motor driver IC21 via control lines, respectively. .. The 6-bit output terminals P10 to P15 of the input / output IC 12 are connected to the PHASEB terminal, PHASEA terminal, INB2 terminal, INB1 terminal, INA2 terminal, and INA1 terminal of the left frame drum motor driver IC11 via the control line, respectively. There is.

As shown in FIG. 28, the effect control microcomputer 91 and the input / output IC 12 communicate with each other by the I2C (Inter Integrated Circuit) communication method like the effect control microcomputer 91 and the input / output IC 2 (see FIG. 26) described above. It is connected as possible. As described above, as can be seen from FIG. 27, the electric circuit related to the left frame drum motor driver IC 11 and the electric circuit related to the right frame drum motor driver IC 21 are the same. Therefore, in the following, the electric circuit related to the left frame drum motor driver IC 11 will be described as a representative based on FIG. 29.

As shown in FIG. 29, the OUTA + terminal of the left frame drum motor driver IC 11 is connected to the first terminal of the connector CN11 via the control line L11. The first terminal of the connector CN11 is connected to the terminal φ1 (see FIG. 23A) of the coil A of the left frame drum rotation motor 321L via a harness (not shown). Further, the OUTA- terminal of the left frame drum motor driver IC 11 is connected to the second terminal of the connector CN11 via the control line L12. The second terminal of the connector CN11 is connected to the terminal φ2 (see FIG. 23A) of the coil A of the left frame drum rotation motor 321L via a harness (not shown).

Further, the OUTB + terminal of the left frame drum motor driver IC11 is connected to the third terminal of the connector CN11 via the control line L13. The third terminal of the connector CN11 is connected to the terminal φ3 (see FIG. 23A) of the coil B of the left frame drum rotation motor 321L via a harness (not shown). Further, the OUTB- terminal of the left frame drum motor driver IC 11 is connected to the fourth terminal of the connector CN11 via the control line L14. The fourth terminal of the connector CN11 is connected to the terminal φ4 (see FIG. 23A) of the coil B of the left frame drum rotation motor 321L via a harness (not shown).

Zener diodes D11, D12, D13, D14 are arranged between each control line L11, L12, L13, L14 and ground, respectively, and the power supply of each control line L11, L12, L13, L14 and 24V is arranged. Zener diodes D15, D16, D17, and D18 are arranged between them, respectively. The reason why the Zener diode is provided on both the ground side and the power supply side in this way is based on the following reasons.

As described above, the left frame drum rotation motor 321L of the present embodiment is a bipolar type stepping motor. Therefore, in the coils A and B of each phase during rotation of the left frame drum rotation motor 321L, the direction of the current is switched, so that the direction of the current is turned off even in each control line L11, L12, L13, L14 (see FIG. 29). It changes. Therefore, when an unintended excess current occurs, Zener diodes are provided on both the ground side and the power supply side so that the excess current can be reliably released to either the ground side or the power supply side.

As shown in FIG. 29, the control line extending from the VREFA terminal of the left frame drum motor driver IC11 and the control line extending from the VREFB line are combined to form one control line L15. The control line L15 is divided into a control line L15a extending from the branch point BT to the upper side in FIG. 29 and a control line L15b extending from the branch point BT to the lower side in FIG. 29. A resistor R11 is connected to the control line L15a, and a resistor R12 is connected to the control line L15b. An external inspection circuit 310A is incorporated in the control line L15a. The inspection external circuit 310A fulfills the same function as the inspection external circuit 224B shown in FIG. 25.

The chopping reference frequency when the left frame drum motor driver IC 11 performs pulse width modulation (PWM) is appropriately set according to the resistance R16 and the capacitor C18 shown in FIG. 29. Further, in order to stabilize the control circuit in the left frame drum motor driver IC11, the capacitor C19 (bypass capacitor) shown in FIG. 29 is provided.

Although the configuration of the electric circuit around the left frame drum motor driver IC 11 has been described above, the configuration of the electric circuit around the right frame drum motor driver IC 21 is also substantially the same. Therefore, in FIG. 27, with respect to the configuration of the electric circuit around the right frame drum motor driver IC 21, the 10s of each configuration shown in FIG. 29 will be replaced with the 20s, and detailed description thereof will be omitted.

Next, the electric circuit of the relay board 225 on the upper right of the frame will be described. As shown in FIG. 30, a frame sword disk member rotary motor driver IC 31 is mounted on the frame upper right relay board 225. The frame sword disk member rotation motor driver IC31 (drive circuit unit) is a stepping motor driver that controls the drive of the frame sword disk member rotation motor 231. Since the frame sword disk member rotary motor driver IC 31 has the same configuration as the left frame drum motor driver IC 11 shown in FIG. 29, detailed description of the configuration will be omitted.

Further, as shown in FIG. 30, an input / output IC 32 is mounted on the upper right relay board 225 of the frame. Since the input / output IC 32 has the same configuration as the input / output IC 12 shown in FIG. 29, detailed description of the configuration will be omitted. The 6-bit output terminals P10 to P15 of the input / output IC 32 are connected to the PHASEB terminal, PHASEA terminal, INB2 terminal, INB1 terminal, INA2 terminal, and INA1 terminal of the frame sword disk member rotation motor driver IC31 via control lines, respectively. ing.

As shown in FIG. 30, the OUTA + terminal of the frame sword disk member rotary motor driver IC31 is connected to the first terminal of the connector CN31 via the control line L31. The first terminal of the connector CN31 is connected to the terminal φ1 (see FIG. 23A) of the coil A of the frame sword disk member rotation motor 231 via a harness (not shown). Further, the OUTA- terminal of the frame sword disk member rotary motor driver IC31 is connected to the second terminal of the connector CN31 via the control line L32. The second terminal of the connector CN31 is connected to the terminal φ2 (see FIG. 23A) of the coil A of the frame sword disk member rotation motor 231 via a harness (not shown).

Further, the OUTB + terminal of the frame sword disk member rotary motor driver IC31 is connected to the third terminal of the connector CN31 via the control line L33. The third terminal of the connector CN31 is connected to the terminal φ3 (see FIG. 23A) of the coil B of the frame sword disk member rotation motor 231 via a harness (not shown). Further, the OUTB- terminal of the frame sword disk member rotary motor driver IC31 is connected to the fourth terminal of the connector CN31 via the control line L34. The fourth terminal of the connector CN31 is connected to the terminal φ4 (see FIG. 23A) of the coil B of the frame sword disk member rotation motor 231 via a harness (not shown).

The configuration of the electric circuit around the frame sword disk member rotary motor driver IC 31 has been described above, but it is the same as the configuration of the electric circuit around the left frame drum motor driver IC 11 described above (see FIG. 29). Therefore, in FIG. 30, other configurations around the frame sword disk member rotary motor driver IC 31 will be described in detail by substituting the 10-series of each configuration shown in FIG. 29 with the 30-series. As shown in FIG. 30, the electric circuit around the frame sword disk member rotary motor driver IC 31 does not have a configuration corresponding to the inspection external circuit 310A shown in FIG. 29.

Next, in the frame right relay board 224 shown in FIG. 25, a problem when the current cutoff circuit 224A is not provided will be described. In this embodiment, the frame sword movable body 221 provided on the right side decorative portion 220 of the front frame 53 can be touched and operated by the player. In particular, the player may mischievously move the frame sword movable body 221 linearly between the storage position shown in FIG. 16A and the pushing position shown in FIG. 16B. Then, a counter electromotive force is generated in the frame sword moving motor 223, and an unintended counter electromotive force may act on the frame sword moving motor driver IC1 via the control lines L1, L2, L3, and L4 shown in FIG.

In particular, in this embodiment, since the frame sword movable body 221 can move linearly in the vertical direction, the player may mischiefly move the frame sword movable body 221 straight at high speed many times. In that case, a very large counter electromotive force is generated in the frame sword moving motor 223, and an excess voltage exceeding the withstand voltage (50V as the absolute maximum rating in this embodiment) may act on the frame sword moving motor driver IC1. .. As a result, there is a problem that the frame sword moving motor driver IC1 may break down.

Therefore, in this embodiment, as shown in FIG. 25, a current cutoff circuit 224A is incorporated in the control lines L1 and L3 in order to solve the above-mentioned problems. The current cutoff circuit 224A (conduction switching means) includes a photomos relay PM1 provided in the control line L1 and a photomos relay PM2 provided in the control line L3.

The photomos relay PM1 switches the control line L1 to a conductive state in which a current flows or a non-conducting state in which a current does not flow. The control line L1 is connected to the control line L2 via a coil A (see FIG. 23A) of the frame sword moving motor 223. Therefore, if the control line L1 is switched to the non-conducting state, the control line L2 is also switched to the non-conducting state. That is, it can be said that the photomos relay PM1 switches between the conductive state and the non-conducting state of both the control lines L1 and L2.

The photomos relay PM2 switches the control line L3 to a conductive state in which a current flows or a non-conducting state in which a current does not flow. The control line L3 is connected to the control line L4 via a coil B (see FIG. 23A) of the frame sword moving motor 223. Therefore, if the control line L3 is switched to the non-conducting state, the control line L4 is also switched to the non-conducting state. That is, it can be said that the photomos relay PM2 switches between the conductive state and the non-conducting state of both control lines L3 and L4.

The photomos relay PM1 and the photomos relay PM2 are provided with a first terminal as an anode terminal, a second terminal as a cathode terminal, and an unconnected third terminal as input sides. The output side is provided with a 4th terminal as a drain terminal, a 5th terminal as a source terminal, and a 6th terminal as a drain terminal. As the photomos relay PM1 and the photomos relay PM2, for example, a photo relay such as "TLP3107" manufactured by Texas Instruments can be preferably used.

In FIG. 25, when an “L” level signal is input as a K-FC control signal, a current flows from the 1st terminal (anode terminal) to the 2nd terminal (cathode terminal) of the photomos relays PM1 and PM2. .. As a result, the LEDs on the input side of the photomos relays PM1 and PM2 emit light, and the MOSFET (Metal Oxide Semiconductor Field Effect) gate on the output side is charged. As a result, the MOSFET becomes conductive. That is, there is a conduction state between the 4th terminal (drain terminal) and the 6th terminal (drain terminal) of the photomos relays PM1 and PM2. In this state, the frame sword moving motor driver IC1 can pass a current through the coils A and B of the frame sword moving motor 223.

Here, when an "H" level control signal is output from the output terminal P10 of the input / output IC 2 shown in FIG. 26, the level of the control signal is converted to an "L" level by the inverter element INV1. Therefore, in this case, an “L” level signal is output as the K-FC control signal shown in FIG. 25. Therefore, the staging control microcomputer 91 can control the drive of the frame sword movement motor 223 by controlling the output terminal P10 of the input / output IC 2 to output an “H” level control signal. can.

On the other hand, in FIG. 25, when an “H” level signal is input as a K-FC control signal, a current is applied from the 1st terminal (anode terminal) to the 2nd terminal (cathode terminal) of the photomos relays PM1 and PM2. Does not flow. As a result, the LEDs on the input side of the photomos relays PM1 and PM2 do not emit light, so that the MOSFET gate on the output side is not charged. As a result, the MOSFET becomes non-conducting. That is, the non-conducting state is established between the 4th terminal (drain terminal) and the 6th terminal (drain terminal) of the photomos relays PM1 and PM2. In this state, the frame sword moving motor driver IC1 cannot pass a current through the coils A and B of the frame sword moving motor 223. Even if a counter electromotive force is generated in the frame sword moving motor 223, it is possible to prevent the counter electromotive force from acting on the frame sword moving motor driver IC1.

Here, when an "L" level control signal is output from the output terminal P10 of the input / output IC 2 shown in FIG. 26, the level of the control signal is converted to an "H" level by the inverter element INV1. Therefore, in this case, an “H” level signal is output as the K-FC control signal shown in FIG. 25. Therefore, the effect control microcomputer 91 controls the output terminal P10 of the input / output IC2 to output an “L” level control signal, so that an excess voltage based on the counter electromotive force acts on the frame sword moving motor driver IC1. It is possible to make it non-existent.

In this embodiment, in the state where the power is not turned on to the pachinko gaming machine 1, or in the initial state (default state) immediately after the power is turned on, the level of the K-FC control signal shown in FIG. 25 becomes the “L” level. It has become. Therefore, the control lines L1 and L2 and the control lines L3 and L4 are in a non-conducting state for most of the period. Therefore, even if the player does not play and mischievously moves the frame sword movable body 221 directly at high speed, the counter electromotive force generated by the frame sword moving motor 223 does not act on the frame sword moving motor driver IC1. As a result, it is possible to prevent the frame sword moving motor driver IC1 from breaking down.

Further, in the present embodiment, when it is shown that the expectation of winning the jackpot is high, the frame sword operation promotion effect for urging the player to push the frame sword movable body 221 downward is executed. In this frame sword operation promotion effect, as shown in FIG. 51, an image KO showing the frame sword movable body 221 and “pushing the sword” is displayed on the display screen 7a. When the frame sword operation promotion effect is started in this way, the frame sword movable body 221 is automatically raised from the storage position shown in FIG. 16A to the pushing position shown in FIG. 16B. If the player does not push the frame sword movable body 221 from the pushing position to the storage position during the operation valid period (for example, 10 seconds) after the frame sword operation promotion effect is started, the frame sword movable body 221 is not pushed. Is automatically lowered from the push-in position to the storage position. In this way, there is a period during which the frame sword movable body 221 (frame sword moving motor 223) must be driven.

Therefore, in the present embodiment, the effect control microcomputer 91 sets the frame sword movable body drive period (drive period) in which the frame sword moving motor 223 can be driven. Then, only during this frame sword movable body drive period, control is performed so that an "H" level control signal is output from the output terminal P10 (see FIG. 26) of the input / output IC 2. As a result, the control lines L1 and L2 and the control lines L3 and L4 are switched to the conduction state, and the drive current can be supplied to the coils A and B of the frame sword moving motor 223. As a result, it is possible to appropriately operate the frame sword movable body 221 at the timing of moving the frame sword movable body 221.

Next, the problem when the external circuit for inspection 224B is not provided in the frame right relay board 224 shown in FIG. 25 will be described. As described above, the frame sword moving motor driver IC1 is of a constant current drive system. In this constant current drive type driver (frame sword moving motor driver IC1), the constant current (230 mA in this embodiment) output from the OUTA + terminal, OUTA- terminal, OUTB + terminal, and OUTB- terminal is applied to the VREFA terminal and VREFB terminal. It depends on the magnitude of the acting voltage. The magnitude of the voltage acting on the VREFA terminal and the VREFB terminal is the combined resistance value of the resistance value of the resistor R1 connected to the control line L5a and the resistance value of the resistor R2 connected to the control line L5b. Dependent.

Here, the magnitude of the output torque of the motor (frame sword moving motor 223) is proportional to the magnitude of the supplied current (current flowing through the control lines L1, L2, L3, L4). Therefore, the magnitude of the constant current (230 mA in this embodiment) is determined by the driver of the constant current drive system so that a desired output torque can be obtained. Then, the resistance value of the resistor R1 and the resistance value of the resistor R2 are set so that the constant current can be supplied. In short, in the constant current drive type driver, the resistance R1 and the resistance R2 are appropriately selected so that the frame sword moving motor 223 can obtain a desired output torque.

By the way, in the field of gaming machines, before assembling the entire pachinko gaming machine 1, a parts manufacturer or the like confirms the operation of a unit (for example, the right decorative portion 220) provided with a movable member (for example, a frame sword movable body 221). Perform an inspection. In this operation check inspection, it is checked whether or not the movable member operates properly in a state where the output torque is reduced by a predetermined ratio (for example, 15%) with respect to the output torque that should be originally obtained by the motor. In other words, if the movable member operates properly even when the output torque of the motor is reduced by a predetermined ratio, the movable member can be reliably operated when 100% of the original output torque is generated (in the case of the final product). With the idea, we are conducting an operation check inspection. In recent gaming machines, since the structure of the unit is complicated, there is a possibility that the movable member may not operate properly due to the influence of an assembly error or the like. Therefore, it is possible to find defective products caused by assembly errors and the like by inspecting the operation check.

In a conventional game machine, it is common to use a unipolar type stepping motor (hereinafter, also referred to as "unipolar motor", see FIG. 23 (B)) as a motor, and it is fixed as a driver for driving the unipolar motor. It is common to use a driver other than the current drive method (constant voltage drive method, etc.). In the case of a unipolar motor, the output torque changes depending on the resistance of the motor itself. Therefore, in the operation check inspection when using a unipolar motor, the inspection is performed by replacing the unipolar motor that generates 100% of the original output torque with a unipolar motor that reduces the output torque by a predetermined ratio (for example, 10%). It was supposed to be. Alternatively, while using a unipolar motor that generates 100% of the original output torque, the drive voltage applied to the unipolar motor is forcibly changed from the outside to reduce the output torque by a predetermined ratio (for example, 10%). Was supposed to be inspected.

On the other hand, in this embodiment, as described above, a bipolar type stepping motor (hereinafter, also referred to as “bipolar motor”, see FIG. 23 (A)) capable of increasing the output torque at low speed rotation is used. .. Then, as a driver suitable for the bipolar motor, a constant current drive type driver (frame sword moving motor driver IC1) is used. However, when using a constant current drive type driver, a constant current value (230 mA) is set (fixed) in advance so that 100% output torque can be obtained with the motor (frame sword moving motor 223). .. Therefore, the value of the constant current supplied to the motor cannot be changed.

If the resistance value of the resistor R1 and the resistance value of the resistor R2 are changed, the magnitude of the current that should have been set to obtain the desired output torque changes, so that 100% of the original output torque cannot be generated. Will end up. Further, even if the drive voltage is forcibly changed from the outside, the magnitude of the current supplied to the motor does not change as long as the constant current drive method is used, and the output torque cannot be reduced by a predetermined ratio. The above-mentioned problems have been described as an example when the frame sword moving motor driver IC1 shown in FIG. 25 is used, but when the left frame drum motor driver IC11 shown in FIG. 27 is used or the right frame drum motor shown in FIG. 27 is used. The same applies when the driver IC 21 is used.

Therefore, in this embodiment, as shown in FIG. 25, an external inspection circuit 224B is incorporated in the control line L5a in order to solve the above-mentioned problems. The external circuit for inspection 224B (state switching means) is mainly connected to the NPN type transistor TR1, the control line L6 connected to the collector of the transistor TR1, the NPN type transistor TR2, and the collector of the transistor TR2. It is provided with a control line L7.

An "L" level signal or an "H" level signal is input to the base of the transistor TR1 as a K-CHECK1 control signal. The K-CHECK1 control signal is a signal output from the output terminal P01 of the input / output IC 2 shown in FIG. 26. Further, the emitter of the transistor TR1 is connected to the ground. A resistor R3 is connected to the control line L6. The control line L6 is connected to the control line L5a in a state of being coupled to the control line L7.

An "L" level signal or an "H" level signal is input to the base of the transistor TR2 as a K-CHECK2 control signal. The K-CHECK2 control signal is a signal output from the output terminal P00 of the input / output IC 2 shown in FIG. 26. Further, the emitter of the transistor TR2 is connected to the ground. A resistor R4 is connected to the control line L7. The control line L7 is connected to the control line L5a in a state of being coupled to the control line L6.

Here, an "L" level signal is output as a K-CHECK1 control signal from the output terminal P01 of the input / output IC2 shown in FIG. 26, and an "L" level signal is output as a K-CHECK2 control signal from the output terminal P00. Will be described when is output. In this case, as shown in FIG. 25, no voltage is applied between the base and the emitter of the transistor TR1, and no voltage is applied between the base and the emitter of the transistor TR2. Therefore, in each of the transistors TR1 and TR2, no current flows from the collector to the emitter. Therefore, the resistance R3 connected to the control line L6 does not function, and the resistance R4 connected to the control line L7 also does not function. Therefore, in this case, the magnitude of the voltage acting on the VREFA terminal and the VREFB terminal of the frame sword moving motor driver IC1 depends only on the resistance value of the resistor R1 and the resistance value of the resistor R2. As a result, a preset constant current (230 mA in this embodiment) can be output from the OUTA + terminal, OUTA- terminal, OUTB + terminal, and OUTB- terminal, and the desired (100%) output is achieved by the frame sword moving motor 223. It is possible to generate torque. As described above, the state in which the frame sword moving motor driver IC1 can supply a preset constant current corresponds to the "normal state".

Next, an "L" level signal is output as a K-CHECK1 control signal from the output terminal P01 of the input / output IC2 shown in FIG. 26, and an "H" level signal is output as a K-CHECK2 control signal from the output terminal P00. Will be described when is output. In this case, as shown in FIG. 25, no voltage is applied between the base and the emitter of the transistor TR1, while the voltage is applied between the base and the emitter of the transistor TR2. Therefore, in the transistor TR1, the current does not flow from the collector to the emitter, while in the transistor TR2, the current flows from the collector to the emitter. Therefore, the resistance R3 connected to the control line L6 does not function, while the resistance R4 connected to the control line L7 functions. Therefore, in this case, the magnitude of the voltage acting on the VREFA terminal and VREFB terminal of the frame sword moving motor driver IC1 is not only the resistance value of the resistance R1 and the resistance value of the resistance R2 but also the resistance value of the resistance R4. Dependent. In this embodiment, the current output from the OUTA + terminal, OUTA- terminal, OUTB + terminal, and OUTB- terminal is reduced by 15% from the above-mentioned constant current due to the combined resistance value of the resistor R1, the resistor R2, and the resistor R4. (In this embodiment, the resistance is about 196 mA), a resistor R4 is provided. As a result, in this case, the frame sword moving motor 223 can generate an output torque that is 15% less than the desired output torque. As described above, the state in which the frame sword moving motor driver IC1 can supply a current (first reduced current) reduced by 15% with respect to a constant current corresponds to the "first reduced state".

Subsequently, an “H” level signal is output as a K-CHECK1 control signal from the output terminal P01 of the input / output IC2 shown in FIG. 26, and an “L” level signal is output as a K-CHECK2 control signal from the output terminal P00. Will be described when is output. In this case, as shown in FIG. 25, a voltage is applied between the base and the emitter of the transistor TR1, but no voltage is applied between the base and the emitter of the transistor TR2. Therefore, in the transistor TR1, a current flows from the collector to the emitter, but in the transistor TR2, a current does not flow from the collector to the emitter. Therefore, while the resistance R3 connected to the control line L6 functions, the resistance R4 connected to the control line L7 does not function. Therefore, in this case, the magnitude of the voltage acting on the VREFA terminal and VREFB terminal of the frame sword moving motor driver IC1 is not only the resistance value of the resistance R1 and the resistance value of the resistance R2 but also the resistance value of the resistance R3. Dependent. In this embodiment, the current output from the OUTA + terminal, OUTA- terminal, OUTB + terminal, and OUTB- terminal is reduced by 20% from the above-mentioned constant current due to the combined resistance value of the resistor R1, the resistor R2, and the resistor R3. The resistance R3 is provided in (so as to be 184 mA in this embodiment). As a result, in this case, the frame sword moving motor 223 can generate an output torque that is 20% less than the desired output torque. As described above, the state in which the frame sword moving motor driver IC1 can supply a current (second reduced current) reduced by 20% with respect to a constant current corresponds to the "second reduced state".

Next, a case where a parts manufacturer or the like inspects the operation confirmation of the unit (right side decorative portion 220) provided with the frame sword movable body 221 will be described with reference to FIG. 31. In this case, as shown in FIG. 31, the inspection controller KC, which is a dedicated jig, is connected to the right decorative portion 220, which is a single unit. Then, the serial data is set to be transmitted from the serial port of the inspection controller KC to the SDA terminal of the input / output IC2, and the clock signal is set to be transmitted to the SCL terminal of the input / output IC2.

After that, when the frame sword moving motor 223 generates an output torque that is 15% less than the desired output torque, the output terminal P01 of the input / output IC 2 shown in FIG. The inspection controller KC is set so that the signal is output and the “H” level signal is output as the K-CHECK2 control signal from the output terminal P00. This makes it possible to confirm whether or not the frame sword movable body 221 operates properly in a state where the frame sword moving motor 223 generates an output torque that is 15% less than the desired output torque. ..

Further, when the frame sword moving motor 223 generates an output torque that is 20% less than the desired output torque, the output terminal P01 of the input / output IC 2 shown in FIG. The inspection controller KC is set so that the signal is output and the “L” level signal is output as the K-CHECK2 control signal from the output terminal P00. This makes it possible to confirm whether or not the frame sword movable body 221 operates properly in a state where the frame sword moving motor 223 generates an output torque that is 20% less than the desired output torque. ..

Thus, in this embodiment, as shown in FIG. 25, even if the frame sword moving motor driver IC1 of the constant current drive system is used, the frame sword moving motor 223 is incorporated by incorporating the inspection external circuit 224B into the frame right relay board 224. On the other hand, it is possible to supply a current smaller than a preset constant current. Therefore, it is possible to easily inspect the operation confirmation of the unit provided with the frame sword movable body 221.

In this embodiment, the external circuit for inspection 224B includes two sets of the transistor TR1 and the resistor R3, and the transistor TR2 and the resistor R4. Therefore, the output torque generated by the frame sword moving motor 223 can be selected and reduced at two ratios of 15% or 20%. Therefore, it is possible to more accurately determine whether the frame sword movable body 221 operates properly no matter how much the output torque is reduced.

When a constant current drive type driver is used as in this embodiment, there are the following merits. That is, for example, in the frame sword moving motor driver IC1 shown in FIG. 25, as described above, the constant current output from the OUTA + terminal, OUTA- terminal, OUTB + terminal, and OUTB- terminal is the voltage acting on the VREFA terminal and the VREFB terminal. The magnitude of the voltage acting on the VREFA terminal and the VREFB terminal depends on the combined resistance value of the resistors R1 and R2. Therefore, only one type of frame sword moving motor 223 is prepared, and different output torques can be generated from the frame sword moving motor 223 only by changing the resistance R1 and the resistance R2. On the other hand, when a driver other than the constant current drive method is used as in the conventional case, different output torques are generated by changing each motor (bipolar type stepping motor). As described above, by using a constant current drive type driver, there is an advantage that it is easy to deal with (easy to design) when the output torque is to be changed during development.

Further, as shown in FIG. 1, when the pachinko gaming machine 1 is assembled as a whole (such as when it is installed in a game hall), the effect control microcomputer 91 is an output terminal of the input / output IC 2 shown in FIG. 25. It is controlled so that the “L” level signal is output as the K-CHECK1 control signal from P01 and the “L” level signal is output as the K-CHECK2 control signal from the output terminal P00. Therefore, in this case, as shown in FIG. 25, the resistance R3 connected to the control line L6 does not always function, and the resistance R4 connected to the control line L7 does not always function. Therefore, it is possible to supply a preset constant current (230 mA in this embodiment) to the frame sword moving motor 223, and the frame sword moving motor 223 always generates a desired (100%) output torque. Is possible.

In the above, the operation and effect when the external circuit for inspection 224B (see FIG. 25) is provided on the right relay board 224 of the frame has been described, but the external circuits 310A and 320A for inspection (state) on the relay board 310 on the frame have been described. The same applies to the action and effect when the switching means (see FIG. 27) is provided. That is, when the operation is confirmed for the unit (movable body unit 201) provided with the left side frame drum and the right side frame drum 320R, the inspection controller, which is a dedicated jig, is connected to the movable body unit 201. Then, the inspection controller is set so that the current supplied to the left frame drum rotation motor 321L is reduced by 15% or 20%, and the current supplied to the right frame drum rotation motor 321R is reduced by 15% or 20%. To set. As a result, the left frame drum or the right frame drum 320R can be driven in a state where the output torque is reduced by 15% or 20% from the desired output torque, and the operation confirmation inspection can be easily performed. ..

In this embodiment, the desired (100%) output torque generated by the frame sword moving motor 223 is set to about 108 mN · m. The constant current supplied by the frame sword moving motor driver IC1 to generate this output torque is set to 230 mA as described above. Further, the desired (100%) output torque generated by the left frame drum rotation motor 321L and the right frame drum rotation motor 321R is set to about 1200 gf · cm. The constant current supplied by the left frame drum motor driver IC 11 and the right frame drum motor driver IC 21 in order to generate this output torque is set to 200 mA. However, the above-mentioned output torque value and constant current value are shown as an example of this embodiment, and can be appropriately changed according to the size of the movable member, the moving speed, and the like.

In the above description, the external inspection circuit 224B provided on the right relay board 224 of the frame and the external inspection circuits 310A and 320A provided on the relay board 310 on the frame have been described. However, in this embodiment, the control board for controlling the drive of the frame face moving motor 311, the frame ear moving motor 520, the frame jaw moving motor 610, and the board movable body moving motor 15a also has the above-mentioned inspection external circuits 224B, 310A. Similar to the 320A, an external inspection circuit is incorporated. Therefore, when inspecting the operation confirmation of the unit including the frame face movable body 400, the frame ear movable body 500, the frame jaw movable body 600, and the board movable body 15, the output torque of each of the above-mentioned motors is reduced by 15% or 20%. It is possible to make it. Therefore, it is possible to easily inspect the operation confirmation.

By the way, the constant current drive type driver of the present embodiment (for example, the frame sword moving motor driver IC1) is configured to be able to supply a constant current and to be able to supply a reduced current smaller than the constant current. Specifically, taking the frame sword moving motor driver IC1 shown in FIG. 25 as an example, an "H" level signal is input to the PHASEA terminal, an "H" level signal is input to the PHASEB terminal, and an "H" level signal is input to the INA1 terminal. When inputting a level signal, inputting an "H" level signal to the INA2 terminal, inputting an "H" level signal to the INB1 terminal, and inputting an "H" level signal to the INB2 terminal, It is configured to be able to supply a preset constant current (230 mA in this embodiment). In other words, the effect control microcomputer 91 uses the input / output IC 2 shown in FIG. 26 to obtain an “H” level PHASEA control signal, an “H” level PHASEB control signal, an “H” level INA1 control signal, and “H” level INA1 control signal. By controlling to output the "H" level INA2 control signal, the "H" level INB1 control signal, and the "H" level INB2 control signal, it is possible to supply a constant current as 100% current. Is.

On the other hand, the frame sword moving motor driver IC1 inputs an "H" level signal to the PHASEA terminal, inputs an "H" level signal to the PHASEB terminal, and inputs an "H" level signal to the INA1 terminal. Then, when inputting an "L" level signal to the INA2 terminal, inputting an "H" level signal to the INB1 terminal, and inputting an "L" level signal to the INB2 terminal, the above-mentioned constant current (this). In the form, it is configured to be able to supply a current having a magnitude of 71% with respect to 230 mA). In other words, the effect control microcomputer 91 uses the input / output IC 2 shown in FIG. 26 to obtain an “H” level PHASEA control signal, an “H” level PHASEB control signal, an “H” level INA1 control signal, and “H” level INA1 control signal. When controlled to output an "L" level INA2 control signal, an "H" level INB1 control signal, and an "L" level INB2 control signal, the reduced current is 29% (predetermined ratio) smaller than the constant current. Can be supplied.

Further, the frame sword moving motor driver IC1 inputs an "H" level signal to the PHASEA terminal, inputs an "H" level signal to the PHASEB terminal, inputs an "L" level signal to the INA1 terminal, and inputs the INA2. When an "H" level signal is input to the terminal, an "L" level signal is input to the INB1 terminal, and an "H" level signal is input to the INB2 terminal, the above-mentioned constant current (230 mA in this embodiment) is input. ) Is configured to be able to supply a current having a magnitude of 38%. In other words, the effect control microcomputer 91 uses the input / output IC 2 shown in FIG. 26 to obtain an “H” level PHASEA control signal, an “H” level PHASEB control signal, an “L” level INA1 control signal, and “L” level INA1 control signal. When controlled to output an "H" level INA2 control signal, an "L" level INB1 control signal, and an "H" level INB2 control signal, the reduced current is 62% (predetermined ratio) smaller than the constant current. Can be supplied.

The frame sword moving motor driver IC1 inputs an "L" level signal to the INA1 terminal and an "L" level signal to the INA2 terminal regardless of the signal level input to the PHASEA terminal or the PHASEB terminal. , When an "L" level signal is input to the INB1 terminal and an "L" level signal is input to the INB2 terminal, no current is supplied.

In the above, the function that the frame sword moving motor driver IC1 can supply a constant current or a decrease current that is smaller than a constant current by a predetermined ratio (29% or 62%) has been described. However, the left frame drum motor driver IC11 and the right frame drum have been described. Motor driver IC21, frame sword disk member rotation motor driver IC31, driver that controls the drive of the frame face movement motor 311, driver that controls the drive of the frame ear movement motor 520, and driver that controls the drive of the board movable body movement motor 15a. , Has similar functions.

Next, a case where the movable member of the present embodiment is held stationary will be described. Here, first, the frame face movable body 400 will be described as an example. The frame face movable body 400 is in a substantially horizontal state when it is in the standby position (see FIG. 9), and is in a relatively stable state. Therefore, the frame face movable body 400 in the standby position is not strictly required to hold the stop. Therefore, when the frame face movable body 400 is in the standby position, the driver that controls the drive of the frame face movable body 400 does not supply the current to the frame face moving motor 311 to suppress the current consumption. Even if no current is supplied to the frame face moving motor 311, the frame face moving motor 311 which is a stepping motor originally has a certain holding force, so that the frame face movable body 400 in the standby position is held stopped. can do.

On the other hand, when the frame face movable body 400 is in the operating position, it is in an inclined state extending diagonally upward toward the front (see FIG. 14), and is visible to the player and above the player. It becomes unstable. Therefore, the frame face movable body 400 in the operating position is strictly required to hold the stop. In particular, since the frame face movable body 400 is relatively large and heavy, there is a possibility that the frame face movable body 400 in the operating position cannot be reliably held only by the holding force originally provided as a function of the stepping motor. Therefore, the driver that controls the drive of the frame face movable body 400 supplies a current to the frame face moving motor 311 to cause stop excitation in the frame face moving motor 311. That is, the frame face moving motor 311 generates a magnetic field (stop excitation) for holding the stop of the frame face movable body 400 at the operating position based on the supplied current. As a result, the frame face movable body 400 can reliably maintain the stopped state by applying the stop holding force at the operating position.

In this embodiment, two-phase excitation is used as an excitation method when each stepping motor such as the frame face moving motor 311 generates stop excitation. As described above, the two-phase excitation is a method of simultaneously exciting two phases at the same time while shifting the next phase to which a pulse is applied by one pulse (see FIG. 24 (A)). In the case of stop excitation by two-phase excitation, it is possible to increase the stop holding force as compared with, for example, stop excitation by one-phase excitation (see FIG. 24 (B)), and it is possible to make the stopped state more stable. It is possible.

Here, the magnitude of the current supplied by the driver to the motor (frame face moving motor 311) when holding the stop of the movable member (frame face movable body 400) becomes a problem. If the current supplied by the driver to the motor is large, it is possible to increase the stop holding force for holding the stop of the movable member, but the current consumption becomes large. On the other hand, if the current supplied by the driver to the motor is small, the current consumption can be suppressed, but the stop holding force for holding the stop of the movable member becomes small.

Therefore, in the present embodiment, when the frame face movable body 400 in the operating position is stopped, the driver that controls the drive of the frame face moving motor 311 determines a constant current (preset in advance) for the frame face moving motor 311. In this embodiment, a current having a magnitude of 71% of 245 mA) is supplied. As a result, while suppressing the current consumption as compared with the case of supplying a constant current (driving current when driving the frame face movable body 400), sufficient stop and hold for the unstable and heavy frame face movable body 400. It is possible to apply force.

The case of holding the stop of the frame face movable body 400 has been described above, but the case of holding the stop of other movable members is as shown in FIG. 32. In FIG. 32, the “no-current state” means a state in which the driver that controls the drive of the movable member does not apply a stop holding force to the movable member based on the fact that the driver that controls the drive of the movable member does not supply a current to the motor that drives the movable member. .. The "holding state (71%)" means that the driver that controls the drive of the movable member supplies the motor that drives the movable member with a current having a magnitude of 71% of the constant current, so that the movable member is stopped and held. It means a state in which force is applied.

As shown in FIG. 32, when the frame sword movable body 221 is in the standby position, it is controlled to the no-current state as described above, and when the frame sword movable body 221 is in the operating position, it is in the holding state (71) as described above. %) Is controlled. Further, when the frame drum 320 is in the stop position, that is, when the upper portion 320U and the lower portion 320D of the frame drum 320 are stopped so as to form a specific motif (see FIGS. 18 and 19), the low current is generated. It is controlled to the holding state. This embodiment is characterized by a low current holding state, and the low current holding state will be described in detail later.

When the frame sword movable body 221 is in the storage position, as shown in FIG. 16A, the frame sword movable body 221 is arranged at the lowermost position and is housed in the sheath member 222. Therefore, the frame sword movable body 221 in the storage position is in a relatively stable state, and is not strictly required to hold the stop. Therefore, as shown in FIG. 32, when the frame sword movable body 221 is in the retracted position, it is controlled to be in a non-current state and a non-conducting state. The non-conducting state means a state in which the control lines L1 and L2 and the control lines L3 and L4 are in the non-conducting state by the current cutoff circuit 224A (see FIG. 25) as described above. Even if a counter electromotive force is generated in the frame sword moving motor 223 due to the non-conducting state, it is possible to prevent the counter electromotive force from acting on the frame sword moving motor driver IC1.

On the other hand, the frame sword movable body 221 is arranged at the uppermost position as shown in FIG. 16B when it is in the pushed-in position, and it is necessary to hold the frame sword movable body 221 in the pushed-in position so as not to descend. be. Therefore, as shown in FIG. 32, when the frame sword movable body 221 is in the pushed-in position, it is controlled to the holding state (71%). As a result, it is possible to impart a sufficient stop holding force to the frame sword movable body 221 while suppressing the current consumption.

Here, in the present embodiment, when the frame sword operation promotion effect (see FIG. 51) that prompts the frame sword movable body 221 in the pushed position to be pushed downward is executed, the frame sword movable body 221 is pushed by the player. Can move from the push-in position to the storage position. At this time, if the stop holding force is still applied to the frame sword movable body 221 by the stop excitation by the frame sword moving motor 223, it becomes difficult for the player to perform the pushing operation. On the other hand, if the stop excitation by the frame sword moving motor 223 is released before the pushing operation is performed by the player, the frame sword movable body 221 at the pushing position may descend.

Therefore, in this embodiment, when the player pushes the frame sword movable body 221 in the exposed position, the frame sword can be moved by the stop excitation by the frame sword moving motor 223 while the push position detection sensor 227 detects it. The body 221 is given a stop holding force. That is, the frame sword movable body 221 is controlled to be in the holding state until it descends from the pushing position shown in FIG. 16 (B) to the pushing intermediate position shown in FIG. 16 (C). As a result, the player pushes the frame sword movable body 221 against the stop holding force.

Then, when the detection by the push-in position detection sensor 227 is stopped, the stop excitation force by the frame sword moving motor 223 is released, so that the stop holding force on the frame sword movable body 221 is released. That is, when the frame sword movable body 221 passes through the pushing intermediate position shown in FIG. 16C, it is controlled to be in a no-current state. As a result, the player can smoothly push the frame sword movable body 221 into the storage position shown in FIG. 16A without feeling the stop holding force while suppressing the current consumption.

In this way, in this embodiment, the resistance force (stop holding force) is released after the player slightly pushes the frame sword movable body 221 in the pushed position. As a result, it is possible to achieve both the holding of the frame sword movable body 221 in the pushed-in position and the operability of the frame sword movable body 221. Furthermore, it is possible to give the player a new feeling of operation that the frame sword movable body 221 can be made a little difficult to push at the beginning of movement and then the frame sword movable body 221 can be smoothly pushed to the storage position. Is. In addition, by setting the frame sword movable body 221 to a non-current state before moving to the storage position, it is possible to enhance the effect of reducing the current consumption as much as possible.

Returning to the description of FIG. 32. The frame ear movable body 500 is hidden in the frame face movable body 400 when it is in the retracted position (see FIG. 12A). At this time, the frame face movable body 400 can be moved from the standby position (see FIG. 1) to the operating position (see FIG. 14). That is, if the frame ear movable body 500 is in an exposed position due to rocking (see FIG. 12B), the frame face movable body 400 cannot move from the standby position to the operating position. In order to ensure that the frame face movable body 400 can move in this way, the frame ear movable body 500 in the retracted position is strictly required to hold the stop. Therefore, as shown in FIG. 32, when the frame ear movable body 500 is in the retracted position, it is controlled to the holding state (71%). Thereby, it is possible to impart a sufficient stop holding force to the frame ear movable body 500 while suppressing the current consumption.

On the other hand, when the frame ear movable body 500 is in the exposed position, as shown in FIG. 14, the frame ear movable body 500 projects upward from the frame face movable body 400 and is exposed. However, since the frame ear movable body 500 is relatively small, it can be sufficiently held only by the holding force originally provided in the frame ear moving motor 520, which is a stepping motor. Therefore, as shown in FIG. 32, when the frame ear movable body 500 is in the exposed position, it is controlled to be in a non-current state. As a result, it is possible to enhance the effect of reducing the current consumption as compared with the case of holding the holding state.

The frame jaw movable body 600 slightly tilts between the closed position shown in FIG. 13 (A) and the open position shown in FIG. 13 (B), and does not affect the movement of the surrounding movable members. Therefore, the holding of the stop is not strictly required regardless of whether the frame jaw movable body 600 is in the closed position or the open position. Therefore, as shown in FIG. 32, when the frame jaw movable body 600 is in the closed position or the open position, it is controlled to be in a no-current state. As a result, it is possible to enhance the effect of reducing the current consumption as compared with the case of holding the holding state.

When the frame sword disk member 232 is in the normal position (see FIG. 16A), that is, when it is not rotating, the predetermined decorative portion 232a applied to the frame sword disk member 232 can be visually recognized. .. The frame sword disk member 232 does not affect the operation of the surrounding movable members, and basically, the holding of the stop is not strictly required. Therefore, as shown in FIG. 32, when the frame sword disk member 232 is in the normal position, it is controlled to be in a non-current state. As a result, it is possible to enhance the effect of reducing the current consumption as compared with the case of holding the holding state.

Here, in the present embodiment, the effect button 63 can vibrate as an effect that encourages the operation of the effect button 63. The effect button 63 is attached to the front frame 53 (operation mechanism portion 230), and the frame sword disk member 232 is also attached to the front frame 53 (right decorative portion 220). Therefore, when the effect button 63 vibrates, the vibration is transmitted to the frame sword disk member 232 via the front frame 53, and the frame sword disk member 232 may rotate slightly. In that case, the orientation of the decorative portion 232a applied to the frame sword disk member 232 may change, which may give a false impression to the player.

Therefore, in this embodiment, the frame sword disk member 232 is switched from the non-current state to the holding state (71%) only during the vibration of the effect button 63 (another movable member). As a result, it is possible to prevent the frame sword disk member 232 from rotating due to the vibration of the effect button 63, and it is possible to prevent the decorative portion 232a provided on the frame sword disk member 232 from changing its orientation. Is. When the vibration of the effect button 63 is completed, the frame sword disk member 232 switches from the holding state (71%) to the non-current state. As a result, it is possible to enhance the effect of reducing the current consumption as compared with the case of holding the holding state.

When the board movable body 15 is in the origin position (see FIGS. 4 and 5), it is almost invisible to the player, and the holding of the stop is not strictly required. Therefore, as shown in FIG. 32, when the board movable body 15 is at the origin position, it is controlled to be in a non-current state. As a result, it is possible to enhance the effect of reducing the current consumption as compared with the case of holding the holding state. On the other hand, when the board movable body 15 is in the drive position, it appears in front of the center of the display screen 6a of the first image display device 6. At this time, if the board movable body 15 at the drive position should move, it may interfere with the electric devices (solenoids and sensors) provided on the game board 2 and affect the progress of the game. Therefore, as shown in FIG. 32, when the board movable body 15 is in the drive position, it is controlled to the holding state (71%). As a result, it is possible to impart a sufficient stop holding force to the board movable body 15 while suppressing the current consumption.

By the way, in this embodiment, since many movable members are provided, the upper limit value (peak current) of the current that can be supplied by the power supply board 150 may be exceeded, and the allowable loss determined by the power supply board 150 may be exceeded. .. Therefore, it is necessary to reduce the current supplied to the movable member as much as possible. In particular, when keeping the movable member stopped, it is desired to suppress the current consumption in the motor as much as possible.

Here, in the present embodiment, when the frame drum 320 is in the stop position (see FIGS. 18 and 19), a specific motif can be formed by the upper portion 320U and the lower portion 320D, so that the stop is required to be held. .. Therefore, the left frame drum motor driver IC 11 and the right frame drum motor driver IC 21 are connected to the left frame drum rotation motor 321L and the right frame drum rotation motor 321R, respectively, at 71% or 38% of a predetermined constant current (200 mA in this embodiment). It is conceivable to supply a current (decreasing current) of the magnitude of to hold the frame drum 320 stopped. However, even if the frame drum 320 is controlled to a holding state in which a current of 38% of a constant current is supplied, there is a possibility that the above-mentioned peak current or allowable loss may be exceeded.

Therefore, it is desired that the left frame drum motor driver IC 11 and the right frame drum motor driver IC 21 supply a current even smaller than the current of 38% of the constant current. However, as long as the left frame drum motor driver IC 11 and the right frame drum motor driver IC 21 are constant current drive type drivers, it is not possible to supply a current smaller than 38% of the constant current as a function of the driver itself. There was a problem.

Therefore, in this embodiment, as shown in FIG. 27, a current reduction external circuit 310B (current reduction means) is provided around the left frame drum motor driver IC 11 in order to deal with the above-mentioned problems, and the right frame drum motor driver IC 21 is provided. A current reduction external circuit 320B (current reduction means) is provided around the circuit. The current reduction external circuit 310B enables the left frame drum motor driver IC 11 to supply a current (ultra-reduction current) even smaller than a current having a magnitude of 38% of a constant current (200 mA in this embodiment). .. Further, the current reduction external circuit 320B enables the right frame drum motor driver IC 21 to supply a current (ultra-reduction current) smaller than the current having a size of 38% of the constant current (200 mA in this embodiment). be. Since the configuration of the current reduction external circuit 310B and the current reduction external circuit 320B is the same, the current reduction external circuit 310B shown in FIG. 29 will be described below as a representative.

As shown in FIG. 29, the current reduction external circuit 310B mainly includes an NPN type transistor TR3, a control line L16 connected to the collector of the transistor TR3, and a control line L17 connected to the base of the transistor TR3. And an inverter element INV2 connected to the control line L17. A resistor R15 is connected to the control line L16. The upper end of the control line L16 shown in FIG. 29 is connected to the control line L15, and the lower end of the control line L16 shown in FIG. 29 is connected to the ground.

The control line L17 is a control line branched from the control line L18 connecting the output terminal P15 of the input / output IC 12 and the INA1 terminal of the left frame drum motor driver IC 11. When an "L" level control signal is output as an INA1 control signal from the output terminal P15 of the input / output IC 12, the control signal is converted to an "H" level by the inverter element INV2. On the other hand, when an "H" level control signal is output as an INA1 control signal from the output terminal P15 of the input / output IC 12, the control signal is converted to an "L" level by the inverter element INV2. The control signal thus converted is input to the base of the transistor TR3.

Here, a case where a constant current (200 mA in this embodiment) is controlled to be supplied as a function of the left frame drum motor driver IC 11 will be described. In this case, as described above, the effect control microcomputer 91 receives the “H” level PHASEA control signal, the “H” level PHASEB control signal, and the “H” level INA1 control signal from the input / output IC2. , The "H" level INA2 control signal, the "H" level INB1 control signal, and the "H" level INB2 control signal are controlled to be output. At this time, in the control line L17, the “H” level INA1 control signal is converted to the “L” level by the inverter element INV2. Therefore, no voltage is applied between the base and the emitter of the transistor TR3. Therefore, in the transistor TR3, no current flows from the collector to the emitter, and the resistor R15 connected to the control line L16 does not function.

Therefore, in this case, the magnitude of the voltage acting on the VREFA terminal and the VREFB terminal of the left frame drum motor driver IC11 depends only on the resistance value of the resistor R11 and the resistance value of the resistor R12. As a result, the current output from the OUTA + terminal, the OUTA− terminal, the OUTB + terminal, and the OUTB− terminal becomes a constant current (200 mA in this embodiment) due to the combined resistance value of the resistor R11 and the resistor R12. In this way, by supplying a constant current to the left frame drum rotation motor 321L, the left frame drum rotation motor 321L can rotate the left frame drum.

On the other hand, as a function of the left frame drum motor driver IC11, a case where control is performed so as to supply a current having a magnitude of 38% of a constant current will be described. In this case, as described above, the effect control microcomputer 91 receives the “H” level PHASEA control signal, the “H” level PHASEB control signal, and the “L” level INA1 control signal from the input / output IC2. , The "H" level INA2 control signal, the "L" level INB1 control signal, and the "H" level INB2 control signal are controlled to be output. At this time, in the control line L17, the "L" level INA1 control signal is converted to the "H" level by the inverter element INV2. Therefore, a voltage is applied between the base and the emitter of the transistor TR3. Therefore, in the transistor TR3, a current flows from the collector to the emitter, and the resistor R15 connected to the control line L16 functions.

Therefore, in this case, the magnitude of the voltage acting on the VREFA terminal and the VREFB terminal of the left frame drum motor driver IC11 is not only the resistance value of the resistance R11 and the resistance value R12 but also the resistance value of the resistance R15. Dependent. As a result, the current output from the OUTA + terminal, OUTA- terminal, OUTB + terminal, and OUTB- terminal is 38% of the constant current (76 mA) due to the combined resistance value of the resistor R11, the resistor R12, and the resistor R15. ) Is even smaller. Specifically, a current (40 mA) having a magnitude of 20% of the constant current is supplied to the left frame drum rotation motor 321L.

In this way, in this embodiment, when the effect control microcomputer 91 controls to supply a current having a magnitude of 38% of the constant current from the left frame drum motor driver IC 11, the resistor R15 automatically functions. This makes it possible for the left frame drum motor driver IC 11 to supply an ultra-low current (40 mA) that is even smaller than the magnitude of 38% of the constant current. Therefore, the left frame drum motor can apply a stop holding force to the left frame drum by generating stop excitation based on this ultra-low current. As a result, it is possible to further suppress the current consumption as compared with the case where stop excitation is generated based on a current (76 mA) having a magnitude of 38% of the constant current.

In the frame drum 320 of the present embodiment, the upper portion 320U and the lower portion 320D rotate in the horizontal direction, and are in a relatively stable state when stopped (see FIGS. 18 and 19). Therefore, it is not necessary to apply a large stop holding force to the frame drum 320 that is stopped (in the normal position). Therefore, in the present embodiment, it is possible to sufficiently hold the stop of the frame drum 320 even with a stop holding force based on a small current of an ultra-low current (40 mA).

Further, in the present embodiment, as described above, the effect control microcomputer 91 automatically controls the left frame drum motor driver IC 11 to supply a current having a magnitude of 38% of the constant current, thereby automatically supplying the left frame drum. A current (ultra-reduced current) smaller than a current having a magnitude of 38% of a constant current is supplied from the motor driver IC 11. That is, the current reduction external circuit 310B is configured so that the left frame drum motor driver IC 11 can supply the ultra-reduction current by inputting the INA1 control signal in the control line L17 branching from the control line L18. In this way, by using the INA1 control signal output from the input / output IC 12 (control signal output unit) as it is, it is not necessary to newly increase the signal to be output from the input / output IC 12. In other words, there is no need to make soft changes. In this way, as shown in FIG. 29, the above-mentioned ultra-reduced current (40 mA) can be supplied from the left frame drum motor driver IC 11 by simply incorporating the current reduction external circuit 310B around the left frame drum motor driver IC 11. It is possible. As described above, if a software change is made, the cost and labor due to the design change are large, but in this embodiment, a configuration capable of supplying an ultra-reduced current can be easily realized only by a hardware change.

In the above, the case where the left frame drum motor driver IC11 supplies a constant current (200 mA) or an ultra-decreasing current (40 mA) has been described, but the right frame drum motor driver supplies a constant current (200 mA) or an ultra-decreased current (40 mA). The same applies when supplying. The state in which the frame drum rotation motor 321 applies a driving force to the frame drum 320 based on the supply of a constant current (driving current) by the left frame drum motor driver IC 11 and the right frame drum motor driver IC 21 is a “driving state”. Is equivalent to. On the other hand, the state in which the frame drum rotation motor 321 applies a stop holding force to the frame drum 320 based on the supply of the ultra-reduced current by the left frame drum motor driver IC 11 and the right frame drum motor driver IC 21 is the "low current holding state". Is equivalent to.

5. Explanation of big hits, etc. In the pachinko gaming machine 1 of this embodiment, there are "big hits" and "missing" as a result of the big hit lottery (special symbol lottery). At the time of "big hit", the "big hit symbol" is stopped and displayed on the special symbol display 41. In the case of "off", the "missing symbol" is stopped and displayed on the special symbol display 41. When a big hit is won, the big winning opening (1st big winning opening 30 and 2nd big winning opening 35) is opened with an opening pattern according to the type of special symbol (type of big hit) that is stopped and displayed. Is executed. The jackpot game is an example of a special game.

In this form, the jackpot game consists of multiple round games (unit open game), an opening before the first round game is started (also referred to as OP), and an ending after the final round game is completed. (Also referred to as ED) and is included. Each round game begins with the end of the OP or the end of the previous round game and ends with the start of the next round game or the start of the ED. The closing time (interval time) of the large winning opening between round games is included in the open round game before the closing.

There are multiple types of jackpots. The types of jackpots are as shown in FIG. 33. As shown in FIG. 33, in this embodiment, there are roughly two types of jackpots (V long jackpot and V short jackpot). The "V long jackpot" is a jackpot that operates the opening / closing member 32 and the opening / closing member 37 in the first opening pattern (V long opening pattern) in which the game ball can pass through the specific area 39 during the jackpot game. The "V short jackpot" is a jackpot that operates the opening / closing member 32 and the opening / closing member 37 in a second opening pattern (V short opening pattern) in which the game ball cannot pass through the specific area 39 during the jackpot game.

More specifically, the total number of rounds of "V long jackpot" is 16R. From 1R to 13R and 15R, the first big winning opening 30 is opened for a maximum of 29.5 seconds per 1R. 14R and 16R open the second big winning opening 35 for a maximum of 29.5 seconds per 1R. In the 14R and 16R, it is possible to easily pass through the specific area 39 in the second large winning opening 35.

On the other hand, in the "V short jackpot", the total number of rounds is 16R, but the actual total number of rounds is 13R. That is, from 1R to 13R, the first big winning opening 30 is opened for a maximum of 29.5 seconds per 1R, but in 15R, the first big winning opening 30 is opened only for 0.1 seconds per 1R, and 14R. Even with 16R, the second big prize opening 35 is opened only for 0.1 seconds per 1R. Therefore, in this V-short jackpot, from 14R to 16R, the opening time of the big winning opening is extremely short, and it is a round in which a prize ball cannot be expected. That is, the V short jackpot is actually a jackpot of 13R.

Further, although the second big winning opening 35 is opened in 14R and 16R in the V short jackpot, the opening time is extremely short, and it is almost impossible for the game ball to pass through the specific area 39 in the second big winning opening 35. It is possible. In the 14R and 16R in the V short jackpot, not only the opening time of the second big winning opening 35 is short, but also the opening timing of the second big winning opening 35 and the operation timing of the distribution member 71 (second state (Fig.)). 6 (B)) to the first state (timing controlled from the first state (see FIG. 6A)), it is almost impossible for the game ball to pass through the specific area 39.

In the pachinko gaming machine 1 of the present embodiment, based on the passage of the gaming ball to the specific area 39 during the jackpot game, the gaming state after the end of the jackpot game is shifted to the high probability state described later. Therefore, when the above-mentioned V-long jackpot is won, the gaming state after the jackpot game can be changed to a high probability state by passing the game ball to the specific area 39 during the execution of the jackpot game. On the other hand, when the V short jackpot is won, the gaming ball cannot be passed to the specific area 39 during the execution of the jackpot game, so that the gaming state after the jackpot game is the normal probability state described later. (Non-high probability state).

As shown in FIG. 33, the distribution rate of the jackpot in the lottery of the first special symbol (special figure 1) is 50% for the V long jackpot and 50% for the V short jackpot. On the other hand, the jackpots won in the lottery for the second special symbol (special figure 2) are all V-long jackpots. That is, if a big hit is won by a lottery based on a prize in the second starting port 21 that can be entered by executing the electric support control described later, the V long big hit is always obtained. In this way, in the pachinko gaming machine 1, the game ball wins in the second starting port 21 rather than the big hit lottery (lottery of the first special symbol) in which the game ball wins in the first starting port 20. The jackpot lottery (lottery of the second special symbol) is set to be more advantageous to the player.

Here, in the pachinko gaming machine 1, the lottery for whether or not the jackpot is a big hit is performed based on the "big hit random number", and the lottery for the winning jackpot type is performed based on the "winning type random number". As shown in FIG. 34 (A), the jackpot random number takes a value in the range of 0 to 65535. The hit type random number takes a value in the range of 0 to 9. The random numbers acquired based on the winning of the first starting port 20 or the second starting port 21 include "reach random numbers" and "variable pattern random numbers" in addition to the jackpot random numbers and the hit type random numbers.

The reach random number is a random number that determines whether or not to generate reach in the effect symbol variation effect indicating the result when the result of the jackpot determination is out of order. Reach is a state in which there is only one staging symbol that is variablely displayed out of a plurality of staging symbols (decorative symbols), and it depends on which symbol the variablely displayed staging symbol is stopped and displayed. It is a state (for example, a state of "7 ↓ 7") in which a combination of staging symbols indicating a big hit is won. It should be noted that the staging symbol that is stopped and displayed in the reach state may be displayed as if it is slightly shaken in the display screen 7a. This reach random number takes a value in the range of 0 to 127.

Further, the fluctuation pattern random number is a random number for determining the fluctuation pattern including the fluctuation time. The fluctuation pattern random number takes a value in the range of 0 to 127. Further, the random numbers acquired based on the passage of the gate 28 include ordinary symbol random numbers (hit random numbers) shown in FIG. 34 (B). The ordinary symbol random number is a random number for a lottery (ordinary symbol lottery) as to whether or not to perform an auxiliary game for opening the electric chew 22. Ordinary symbol random numbers take a value in the range of 0 to 255.

6. Description of the gaming state Next, the gaming state of the pachinko gaming machine 1 of the present embodiment will be described. The special symbol display 41 and the normal symbol display 42 of the pachinko gaming machine 1 each have a probability variation function and a variation time shortening function. The state in which the probability fluctuation function of the special symbol display 41 is operating is called a "high probability state", and the state in which it is not operating is called a "normal probability state (non-high probability state)". In the high probability state, the jackpot probability is higher than in the normal probability state. That is, the jackpot determination is performed using a jackpot determination table in which the value of the jackpot random number determined to be a jackpot is larger than the jackpot determination table used in the normal probability state (see FIG. 35 (A)). That is, when the probability fluctuation function of the special symbol display 41 is activated, the probability that the display result (that is, the stopped symbol) of the variable display of the special symbol by the special symbol display 41 becomes a jackpot symbol as compared with the case where it is not activated. Will be higher.

Further, the state in which the fluctuation time shortening function of the special symbol display 41 is operating is referred to as a "time saving state", and the state in which the special symbol display 41 is not operating is referred to as a "non-time saving state". In the time-reduced state, the fluctuation time of the special symbol (time from the start of the fluctuation display to the derivation display of the display result) is shorter than in the non-time-reduced state. That is, the fluctuation pattern is determined using the fluctuation pattern table in which the fluctuation pattern having a short fluctuation time is selected more often than in the non-time reduction state (see FIG. 36). That is, when the variable time shortening function of the special symbol display 41 is activated, it becomes easier to select a short variable time as the variable time of the variable display of the special symbol as compared with the case where the special symbol display 41 is not activated. As a result, in the time-saving state, the pace of digestion of the special figure hold becomes faster, and an effective prize (a prize that can be memorized as the special figure hold) to the starting port is likely to occur. Therefore, it is possible to aim for a big hit with the smooth progress of the game.

The probability fluctuation function and the fluctuation time shortening function of the special symbol display 41 may be operated at the same time, or only one of them may be operated. The probability fluctuation function and the fluctuation time shortening function of the normal symbol display 42 operate in synchronization with the fluctuation time shortening function of the special symbol display 41. That is, the probability fluctuation function and the fluctuation time shortening function of the normal symbol display 42 operate in the time saving state and do not operate in the non-time saving state. Therefore, in the time-saving state, the winning probability in the normal symbol lottery is higher than in the non-time-saving state. That is, the hit judgment (judgment of the normal symbol) is performed using the normal symbol hit judgment table in which the value of the normal symbol random number (hit random number) judged to be a hit is larger than the normal symbol hit judgment table used in the non-time saving state (judgment of the normal symbol). See FIG. 35 (C)). That is, when the probability fluctuation function of the normal symbol display 42 is activated, the probability that the display result of the variable display of the normal symbol by the normal symbol display 42 becomes a normal hit symbol is higher than when it is not activated. ..

Also, in the time-saving state, the fluctuation time of the normal symbol is shorter than in the non-time-saving state. In this embodiment, the fluctuation time of the normal symbol is 30 seconds in the non-time saving state, but 1 second in the time saving state (see FIG. 35 (D)). Further, in the time saving state, the opening time of the electric chew 22 in the auxiliary game is longer than in the non-time saving state (see FIG. 37). That is, the opening time extension function of the electric chew 22 is operating. In addition, in the time-saving state, the number of times the electric chew 22 is opened in the auxiliary game is larger than in the non-time-saving state (see FIG. 37). That is, the function of increasing the number of times of opening of the electric chew 22 is operating.

In the situation where the probability fluctuation function and the fluctuation time shortening function of the normal symbol display 42, and the opening time extending function and the opening number of times increasing function of the electric chew 22 are operating, those functions are not activated as compared with the case where these functions are not activated. Therefore, the electric chew 22 is frequently opened, and the game ball frequently wins a prize at the second starting port 21. As a result, the base, which is the ratio of the number of prize balls to the number of fired balls, becomes high. Therefore, the state in which these functions are operating is referred to as a "high base state", and the state in which these functions are not operating is referred to as a "low base state". In the high base state, you can aim for a big hit without significantly reducing the number of game balls you have. The high base state is a state in which so-called electric support control (control for supporting winning of the second starting port 21 by the electric chew 22) is being executed.

The high base state (electric support control state) does not have to operate all the above functions. That is, the operation of one or more of the probability fluctuation function of the normal symbol display 42, the fluctuation time shortening function of the normal symbol display 42, the opening time extension function of the electric chew 22, and the opening frequency increasing function of the electric chew 22. It suffices if the electric chew 22 is more easily released than when the function is not operating. Further, the high base state (electric support control state) may be controlled independently without being accompanied by the time saving state.

In the pachinko gaming machine 1 of the present embodiment, the gaming state after the jackpot game by winning the V-long jackpot is a high probability state, a time saving state, and a high base if the passage to the specific area 39 is made during the jackpot game. It is a state. This gaming state is particularly called "high accuracy and high base state". The high-accuracy high-base state ends when the variable display of the special symbol is executed a predetermined number of times (160 times in this embodiment), or when the jackpot is won and the jackpot game is executed.

In addition, the gaming state after the jackpot game by winning the V-short jackpot is a normal probability state (non-high probability state, that is, if the specific area 39 is not passed during the jackpot game (it is not abbreviated)). It is a low-probability state), a short-time state, and a high-base state. This gaming state is particularly called "low accuracy and high base state". The low accuracy high base state ends when the variable display of the special symbol is executed a predetermined number of times (100 times in this embodiment), or when the jackpot is won and the jackpot game is executed.

When playing the pachinko gaming machine 1 for the first time, the gaming state after the power is turned on is a normal probability state, a non-time saving state, and a low base state (non-electric support control state). This gaming state is particularly referred to as a "low probability low base state". The low probability low base state may be referred to as a "normal game state". Further, the state in which the special game (big hit game) is being executed is referred to as a "special game state (big hit game state)". Further, a state controlled by at least one of a high probability state and a high base state is referred to as a "specific gaming state".

In a high base state such as a high accuracy high base state or a low accuracy high base state, it is more advantageous to allow the game ball to enter the right game area 3B by right-handed. This is because the electric support control makes it easier to open the electric chew 22 than in the low base state, and it is easier to win the second starting port 21 than to win the first starting port 20. .. Therefore, while passing the game ball through the gate 28, which is an opportunity for the normal symbol lottery, the game ball is hit right to win the second starting port 21. As a result, it is possible to obtain a large number of starting prizes (winning to the starting port) rather than hitting left. In this pachinko gaming machine 1, the game is played by right-handed even during the jackpot game.

On the other hand, in the low base state, it is more advantageous to allow the game ball to enter the left game area 3A (see FIG. 4) by hitting the left side. Since the electric support control is not executed, it is difficult to open the electric chew 22 compared to the high base state, and it is easier to win the first starting port 20 than to win the second starting port 21. Because it has become. Therefore, a left-handed strike is performed so that the game ball can be won in the first starting port 20. This allows you to get more start-up prizes than right-handed.

7. Operation of Pachinko Game Machine 1 Next, the operation of the game control microcomputer 81 will be described with reference to FIG. 38, and the operation of the staging control microcomputer 91 will be described with reference to FIGS. 39 to 50. First, the operation of the game control microcomputer 81 will be described.

[Main-side timer interrupt processing] The game control microcomputer 81 repeats the main-side timer interrupt processing shown in FIG. 38 every short time, for example, 4 msec. First, the game control microcomputer 81 determines a jackpot random number used for a jackpot lottery, a hit type random number for determining the type of jackpot, a reach random number for determining whether or not to reach a reach state in a fluctuation effect, and a variation pattern. Random number update processing is performed to update the variable pattern random number, the normal symbol random number (winning random number) used for the normal symbol lottery, and the like (S101). At least a part of each random number may be a hardware random number generated by using a known random number generation circuit including a counter IC or the like. Further, the random number generation circuit may be built in the game control microcomputer 81.

Next, the game control microcomputer 81 performs an input process (S102). In the input process (S102), various sensors mainly attached to the pachinko gaming machine 1 (first starting port sensor 20a, second starting port sensor 21a, first large winning opening sensor 30a, second large winning opening sensor 35a). , The detection signal detected by the normal winning slot sensor 27a or the like (see FIG. 20) is read, and the payout data for paying out the winning ball according to the type of the winning slot is set in the output buffer of the RAM 84.

Subsequently, the game control microcomputer 81 executes the start port sensor detection process (S103), the special operation process (S104), and the normal operation process (S105). In the start port sensor detection process (S103), if the first start port sensor 20a is ON, various random numbers such as big hit random numbers (big hit random numbers, big hits) on condition that the number of stored first special figures is less than four. A symbol random number, a reach random number, and a fluctuation pattern random number (see FIG. 34 (A)) are acquired. Further, if the second start port sensor 21a is ON, various random numbers such as a jackpot random number are acquired on condition that the number of stored second special figure hold is less than four. Further, if the gate sensor 28a is ON, a normal symbol random number (see FIG. 34 (B)) is acquired on condition that the number of stored normal symbols is less than four.

In the special operation process (S104), a random number such as a jackpot random number acquired in the start port sensor detection process (S103) is determined, and a special symbol is displayed (variation display and stop display) for notifying the determination result. .. When displaying this special symbol, a variation start command containing information on the variation pattern is set in the output buffer of the RAM 84 at the start of the variation display of the special symbol, and a variation stop command is set in the output buffer of the RAM 84 at the start of the stop display of the special symbol. Set to. The fluctuation pattern is determined using the fluctuation pattern determination table shown in FIG. 33 based on the determination of various random numbers such as jackpot random numbers. Then, as a result of the determination of the big hit random number, if the big hit is won, the big hit game (opening time) or the second big winning opening 35 is opened according to a predetermined opening pattern (opening time or number of opening times). Special game) is performed. Here, as shown in FIG. 36, once the fluctuation pattern is determined, the fluctuation time during which the fluctuation display of the special symbol is executed is also determined. The SP reach (super reach) shown in the remarks column of FIG. 36 is a reach in which the fluctuation time after the reach is longer than that of the normal reach. The distribution rate of the table is set so that the SP reach has a higher expectation of winning (expectation for big hit winning) than the normal reach. In this embodiment, super reach is carried out progressively through normal reach.

In the normal operation process (S105), the normal symbol random number acquired by the start port sensor detection process is determined, and the normal symbol is displayed (variable display and stop display) for notifying the determination result. As a result of the determination of the normal symbol random number, if the normal symbol is won, the auxiliary game of opening the electric chew 22 according to a predetermined opening pattern (opening time, opening number of times, see FIG. 37) according to the game state is performed. conduct.

Next, the game control microcomputer 81 performs an output process of outputting the command or the like set in each of the above processes to the sub control board 90 or the like (S106). In parallel with the above processing in the game control microcomputer 81, the staging control microcomputer 91 performs the processing shown in FIGS. 39 to 50. Hereinafter, the operation of the staging control microcomputer 91 will be described.

[Sub-side 1ms timer interrupt processing] The effect control microcomputer 91 repeats the sub-side 1ms timer interrupt processing shown in FIG. 39 every short time such as 1 msec. The effect control microcomputer 91 executes the sub-side 1 ms timer interrupt process and also executes the sub-side 10 ms timer interrupt process (see FIG. 41) as described later. As shown in FIG. 39, in the sub-side 1 ms timer interrupt process, first, input process is performed (S201). In the input process (S201), switch data (edge data and level data) are created based on the detection signals from the effect button detection switch 63a and the select button detection switch 68a (see FIG. 21).

Subsequently, the lamp data output process is performed (S202). In the lamp data output process (S202), in order to make the frame lamp 66, the board lamp 5, the face LED 401, and the drum LED 331 emit light at a timing suitable for the effect, in another process (S406) in the sub-side 10 ms timer interrupt process described later. The created lamp data is output to the sub drive board 107. That is, according to the lamp data, the panel lamp 5, the frame lamp 66, the face LED 401, and the drum LED 331 are made to emit light in a predetermined light emitting mode.

Next, a drive control process described later is performed (S203). The drive control process (S203) controls the drive of the frame face movable body 400, the frame ear movable body 500, the frame jaw movable body 600, the frame drum 320, the frame sword movable body 221, the frame sword disk member 232, and the board movable body 15. It is a process to do. Then, the watchdog timer process (S204) for resetting the watchdog timer is performed, and this process is completed.

[Drive control process] As shown in FIG. 40, in the drive control process (S203), first, it is determined whether or not the frame face movable body drive data is set in a predetermined storage area of the RAM 94 (S301). The frame face movable body drive data is operation pattern data for moving the frame face movable body 400 from the standby position to the operation position and then moving the frame face movable body 400 from the operation position to the standby position after a predetermined period has elapsed. Is. In this embodiment, when a specific variable effect pattern accompanied by SP reach is selected, the frame face movable body drive data is set at a predetermined effect timing. If the frame face movable body drive data is set (YES in S301), the control process for driving the frame face moving motor 311 according to the frame face movable body drive data (serial data and clock signal are output from the serial port 98). Processing) (S302). On the other hand, if the frame face movable body drive data is not set (NO in S301), the process proceeds to step S303.

In step S303, it is determined whether or not the frame ear movable body drive data is set in a predetermined storage area of the RAM 94. The frame ear movable body drive data is operation pattern data for moving the frame ear movable body 500 from the retracted position to the exposed position and then moving the frame ear movable body 500 from the exposed position to the retracted position after a predetermined period has elapsed. Is. In this embodiment, when the frame face movable body drive data is set, the frame ear movable body drive data is also set. If the frame ear movable body drive data is set (YES in S303), the control process for driving the frame ear moving motor 520 according to the frame ear movable body drive data (serial data and clock signal are output from the serial port 98). Processing) (S304). On the other hand, if the frame ear movable body drive data is not set (NO in S303), the process proceeds to step S305.

In step S305, it is determined whether or not the frame jaw movable body drive data is set in a predetermined storage area of the RAM 94. The frame jaw movable body drive data is motion pattern data for moving the frame jaw movable body 600 from the closed position to the open position and then moving the frame jaw movable body 600 from the open position to the closed position after a predetermined period has elapsed. Is. In this embodiment, when the frame face movable body drive data is set, the frame jaw movable body drive data is also set. If the frame jaw movable body drive data is set (YES in S305), the control process for driving the frame jaw movement motor 610 according to the frame jaw movable body drive data (serial data and clock signal are output from the serial port 98). Processing) (S306). On the other hand, if the frame jaw movable body drive data is not set (NO in S305), the process proceeds to step S307.

In step S307, it is determined whether or not the frame drum drive data is set in a predetermined storage area of the RAM 94. The frame drum drive data is operation pattern data for rotating the upper portion 320U and the lower portion 320D of the frame drum 320 and then stopping them so that a predetermined display mode (motif) is formed. In this embodiment, when a specific variable effect pattern with SP reach (a variable effect pattern with SP reach indicating that the expectation for a big hit win is particularly high among SP reach) is selected, or when the game ball is in a specific area 39. When passing through, the frame drum drive data is set. If the frame drum drive data is set (YES in S307), control processing for driving the frame drum rotation motor 321 according to the frame drum drive data (processing to output serial data and clock signals from the serial port 98) is performed. (S308). On the other hand, if the frame drum drive data is not set (NO in S307), the process proceeds to step S309.

In step S309, it is determined whether or not the frame sword movable body drive data is set in a predetermined storage area of the RAM 94. The frame sword movable body drive data moves the frame sword movable body 221 from the storage position to the push-in position, and then the player pushes the frame sword movable body 221 from the push-in position to the storage position during the operation valid period. If not, it is the operation pattern data for moving the frame sword movable body 221 from the pushing position to the storage position. In this embodiment, when a specific variable effect pattern with SP reach (a variable effect pattern for executing a frame sword operation promotion effect) is selected, the frame sword movable body drive data is set at a predetermined effect timing. It has become. If the frame sword movable body drive data is set (YES in S309), the control process for driving the frame sword moving motor 223 according to the frame sword movable body drive data (serial data and clock signal are output from the serial port 98). Processing) (S310). On the other hand, if the frame sword movable body drive data is not set (NO in S309), the process proceeds to step S311.

In step S311, it is determined whether or not the frame sword disk member drive data is set in a predetermined storage area of the RAM 94. For the frame sword disk member drive data, the frame sword disk member 232 is rotated so that the decorative portion 232a applied to the frame sword disk member 232 is oriented in a predetermined direction. This is the operation pattern data to be stopped. In this embodiment, when the frame sword movable body drive data is set, the frame sword disk member drive data is also set. If the frame sword disk member drive data is set (YES in S311), the control process for driving the frame sword disk member rotation motor 231 according to the frame sword disk member drive data (serial data and clock signal from the serial port 98). Output processing) is performed (S312). On the other hand, if the frame sword disk member drive data is not set (NO in S311), the process proceeds to step S313.

In step S313, it is determined whether or not the panel movable body drive data is set in a predetermined storage area of the RAM 94. The board movable body drive data is operation pattern data for moving the board movable body 15 from the origin position to the drive position and then moving the board movable body 15 from the drive position to the origin position after a predetermined period has elapsed. In this embodiment, when a specific variable effect pattern accompanied by SP reach is selected, the board movable body drive data is set at a predetermined effect timing. If the panel movable body drive data is set (YES in S313), the control process for driving the panel movable body moving motor 15a according to the panel movable body drive data (process to output serial data and clock signal from the serial port 98). ) (S314). On the other hand, if the panel movable body drive data is not set (NO in S313), the process proceeds to step S315.

In step S315, as other processing, for example, each movable member (frame face movable body 400, frame ear movable body 500, frame jaw movable body 600, frame drum 320, frame sword movable body 221, board movable body 15) is driven. After the end, the drive data set in the RAM 94 is cleared. Then, the drive control process (S203) is completed.

[Sub-side 10 ms timer interrupt process] The effect control microcomputer 91 repeats the sub-side 10 ms timer interrupt process shown in FIG. 41 every short time such as 10 msec. As shown in FIG. 41, in the sub-side 10 ms timer interrupt process, first, the received command analysis process described later is performed (S401). Next, a switch state acquisition process is performed in which the switch data created by the sub-side 1 ms timer interrupt process is stored in the RAM 94 as the switch data for the 10 ms timer interrupt process (S402). Subsequently, a switch process for setting the display contents of the display screen 6a of the first image display device 6 and the display screen 7a of the second image display device 7 based on the switch data stored in the switch state acquisition process is performed (S403). ).

Subsequently, the effect control microcomputer 91 performs voice control processing (S404). In the voice control process (S404), voice data (data for outputting voice from the speaker 67) is created, voice data is output to the voice control board 106, and time management of voice production is performed. As a result, the sound suitable for the effect to be executed is output from the speaker 67.

Subsequently, the effect control microcomputer 91 performs serial signal output processing described later (S405). After that, other processing such as creating lamp data (data for controlling light emission of frame lamp 66, panel lamp 5, face LED 401, drum LED 331) and updating random numbers for determining various effects are executed. Then (S406), this process is completed.

[Received Command Analysis Process] As shown in FIG. 42, in the received command analysis process (S401), first, the effect control microcomputer 91 determines whether or not a fluctuation start command has been received from the main control board 80 (S501). If it has been received, the variable effect start processing described later is performed (S502).

Subsequently, the effect control microcomputer 91 determines whether or not a fluctuation stop command has been received from the main control board 80 (S503), and if has received it, performs a variation effect end process (S504). In the variation effect end process (S504), the variation stop command is analyzed, and the variation effect end command for ending the variation effect is set in the output buffer of the RAM 94 based on the analysis result.

Subsequently, the effect control microcomputer 91 determines whether or not an opening command indicating the start of execution of the opening of the jackpot game has been received from the main control board 80 (S505), and if received, performs an opening effect selection process (S505). S506). In the opening effect selection process (S506), the opening command is analyzed, and the pattern (content) of the opening effect to be executed during the opening of the jackpot game is selected based on the analysis result. Then, the opening effect start command for starting the opening effect with the selected opening effect pattern is set in the output buffer of the RAM 94.

Subsequently, the effect control microcomputer 91 determines whether or not a round designation command indicating the start of execution of the round game of the jackpot game has been received from the main control board 80 (S507), and if received, the round effect selection process is performed. Do (S508). In the round effect selection process (S508), the round designation command is analyzed, and the pattern (content) of the round effect to be executed during the round game of the jackpot game is selected based on the analysis result. Then, a round effect start command for starting the round effect with the selected round effect pattern is set in the output buffer of the RAM 94.

Subsequently, the effect control microcomputer 91 determines whether or not an ending command indicating the start of execution of the ending of the jackpot game has been received from the main control board 80 (S509), and if received, performs an ending effect selection process (S509). S510). In the ending effect selection process (S510), the ending command is analyzed, and the pattern (content) of the ending effect to be executed during the ending of the jackpot game is selected based on the analysis result. Then, the ending effect start command for starting the ending effect with the selected ending effect pattern is set in the output buffer of the RAM 94.

In step S511, as another process, a process based on a reception command other than the above command (for example, a process of performing V passage notification on the first image display device 6 based on a V pass command indicating passage to the specific area 39). Or, processing for setting the frame drum drive data for forming the character "V" by the upper portion 320U and the lower portion 320D of the frame drum 320) is performed. Then, the received command analysis process (S401) is completed.

[Variation effect start process] As shown in FIG. 43, in the variation effect start process (S502), the effect control microcomputer 91 first analyzes the variation start command (S601). The fluctuation start command includes information on the fluctuation pattern (see FIG. 36) and information on the special symbol stop symbol data based on the determination of a jackpot or the like. Next, the effect control microcomputer 91 selects the effect symbols 8L, 8C, 8R to be finally stopped and displayed in the variable effect (S602). Subsequently, the effect control microcomputer 91 selects a variation effect pattern, which is the content of the variation effect, based on the analysis result of the variation start command (S603). Once the variable effect pattern is determined, the time of the variable effect, the variable display mode of the effect pattern, the presence or absence of reach effect, the content of reach effect, the presence or absence of SW effect (effect button effect), the content of SW effect, the effect development configuration, and the effect pattern. The details of the content of the variable staging consisting of the type of background of the above will be decided. This variation effect pattern includes a variation effect pattern that executes a frame sword operation promotion effect (see FIG. 51).

Subsequently, the effect control microcomputer 91 selects the advance notice effect (S604). As a result, the content of the advance notice effect such as the so-called step-up advance notice effect and the chance-up advance notice effect is determined. Then, it is determined whether or not the variable effect pattern selected in step S603 is the variable effect pattern that executes the frame sword operation promotion effect (S605). If it is a variable effect pattern that executes the frame sword operation promotion effect (YES in S605), the frame sword movable body drive period setting process is performed (S606). The frame sword movable body drive period is a period during which the frame sword moving motor 223 can be driven by keeping the control lines L1 to L4 shown in FIG. 25 in a conductive state. By this frame sword movable body drive period setting process (S606), the frame sword movable body drive period is set from the start time of the frame sword operation promotion effect to the end time of the frame sword operation promotion effect (about 15 seconds in this embodiment). Set. If NO in step S605, pass step S606 and proceed to step S607.

In step S607, the effect control microcomputer 91, the selected effect pattern, the variation effect pattern, and the variation effect start command for starting the variation effect in the advance notice effect are set in the output buffer of the RAM 94, and the variation effect start process ( Exit S502). When the variation effect start command set in step S607 is transmitted to the image control board 100, the CPU 102 of the image control board 100 reads a predetermined effect image from the ROM 103 and displays the display screen 6a of the first image display device 6. And the variable effect is performed on the display screen 7a of the second image display device 7.

[Serial signal output processing] As shown in FIG. 44, in the serial signal output processing (S405), the effect control microcomputer 91 is a frame face movable body serial signal output processing (S701) and a frame drum serial signal output, which will be described later. Processing (S702), serial signal output processing for frame sword movable body (S703), serial signal output processing for frame ear movable body (S704), serial signal output processing for frame sword disk member (S705), serial signal for board movable body Execute output processing (S706). After that, other processing for outputting the serial signal is executed (S707), and this processing is completed.

[Serial signal output processing for frame face movable body] As shown in FIG. 45, in the frame face movable body serial signal output processing (S701), first, in the effect control microcomputer 91, the frame face movable body 400 moves to the operating position. It is determined whether or not it has been completed (S801). Specifically, it is determined whether or not the photo sensor that detects that the frame face movable body 400 is in the operating position is switched from OFF to ON. If it is determined that the frame face movable body 400 has finished moving to the operating position (YES in S801), the driver that controls the drive of the frame face movable body 400 supplies 71% of the constant current to the frame face moving motor 311. As described above, the serial signal and the clock signal are output from the serial port 97 (S802), and this processing is completed. As a result, it is possible to generate stop excitation in the frame face moving motor 311 to hold the frame face movable body 400 in the operating position stopped.

On the other hand, if the determination result in step S801 is NO, it is subsequently determined whether or not the frame face movable body 400 has finished moving to the standby position (S803). Specifically, it is determined whether or not the photo sensor that detects that the frame face movable body 400 is in the standby position has been switched from OFF to ON. If it is determined that the frame face movable body 400 has finished moving to the standby position (YES in S803), the serial port 97 prevents the driver controlling the drive of the frame face movable body 400 from supplying current to the frame face moving motor 311. A serial signal and a clock signal are output from (S804), and this processing is completed. As a result, the frame face movable body 400 in the standby position is in a non-current state, and the current consumption can be suppressed. If the determination result in step S803 is NO, the serial signal output processing (S701) for the frame face movable body is completed. In the pachinko gaming machine 1, in the initial state immediately after the power is turned on, the frame face movable body 400 is in the standby position and is in a non-current state.

[Serial signal output processing for frame drum] As shown in FIG. 46, in the serial signal output processing for frame drum (S702), the effect control microcomputer 91 determines whether or not the rotation of the frame drum 320 is completed ( S801). Specifically, the number of steps of the pulse signal for driving the frame drum rotation motor 321 becomes a predetermined number, and it is determined whether or not the frame drum 320 is stopped. If the rotation of the frame drum 320 is completed (YES in S901), the left frame drum motor driver IC 11 and the right frame drum motor driver IC 21 apply 38% of the constant current to the left frame drum motor driver IC 11 and the right frame, respectively. A serial signal and a clock signal are output from the serial port 97 so as to be supplied to the drum motor driver IC 21 (S902), and this processing is completed.

As a result, the current (40 mA) smaller than the current 38% of the constant current (200 mA in this embodiment) is generated on the left side by the current drop external circuit 310B and the current drop external circuit 320B (see FIG. 27). It is supplied to the frame drum rotation motor 321L and the right frame drum rotation motor 321R. This makes it possible to achieve a low current holding state. As a result, it is possible to further suppress the current consumption in the frame drum 320 that is stopped (in the normal position). If the determination result in step S901 is NO, the frame drum serial signal output process (S702) is finished.

Here, in the pachinko gaming machine 1, a stop holding force is applied so that the upper portion 320U and the lower portion 320D of the frame drum 320 can be held stopped in the frame drum 320 from the initial state immediately after the power is turned on. ing. Therefore, except when the frame drum 320 rotates, the frame drum rotation motor 321 causes stop excitation in most of the period. Therefore, the heat generated by the frame drum rotation motor 321 tends to increase. Therefore, in this embodiment, as described above, the left frame drum rotation motor 321L and the right frame drum rotation motor 321L have a current (40mA) smaller than the current (76mA) which is 38% of the constant current (200mA in this embodiment). It is supplied to 321R to generate stop excitation. As a result, in addition to the effect of suppressing the current consumption, it is possible to achieve the effect of suppressing the heat generation of the frame drum rotation motor 321 as much as possible.

[Serial signal output processing for frame sword movable body] As shown in FIG. 47, in the frame sword movable body serial signal output processing (S703), first, the effect control microcomputer 91 is within the frame sword movable body driving period described above. Determine if it exists (S1001). If it is within the frame sword movable body drive period (YES in S1001), an "H" level signal is output from the output terminal P10 of the input / output IC2 in order to make the photomos relays PM1 and PM2 shown in FIG. 25 conductive. The serial signal and the clock signal are output from the serial port 97 (S1002), and the process proceeds to step S1005. As a result, the control lines L1 to L4 are in a conductive state, so that the frame sword moving motor 223 can be driven. That is, the frame sword movable body 221 can be moved by the driving force of the frame sword moving motor 223.

On the other hand, if the determination result in step S1001 is NO, it is determined in step S1003 whether or not the frame sword movable body 221 has finished moving to the storage position. Specifically, it is determined whether or not the storage position detection sensor 226 is switched from OFF to ON. If it is determined that the frame sword movable body 221 has finished moving to the storage position (YES in S1003), the photomos relays PM1 and PM2 shown in FIG. The serial signal and the clock signal are output from the serial port 97 so that the level signal is output (S1004), and the process proceeds to step S1005. This makes it possible to bring the control lines L1 to L4 into a non-conducting state. Therefore, even if the player subsequently mischievously moves the frame sword movable body 221 directly at high speed, it is possible to prevent the counter electromotive force generated by the frame sword moving motor 223 from acting on the frame sword moving motor driver IC1. If the determination result in step S1003 is NO, the process proceeds to step S1005.

In this embodiment, in the state where the power is not turned on to the pachinko gaming machine 1 or in the initial state immediately after the power is turned on, the level of the K-FC control signal shown in FIG. 25 becomes the “L” level. There is. Therefore, the photomos relays PM1 and PM2 are in a non-conducting state except during the frame sword movable body driving period. Therefore, even if a counter electromotive force is generated in the frame sword moving motor 223, it is possible to prevent an excess voltage based on the counter electromotive force from acting on the frame sword moving motor driver IC1.

In step S1005, it is determined whether or not the frame sword movable body 221 has finished moving to the pushing position. Specifically, it is determined whether or not the push-in position detection sensor 227 is switched from OFF to ON. If it is determined that the frame sword movable body 221 has finished moving to the pushing position (YES in S1005), the serial port is such that the frame sword moving motor driver IC1 supplies 71% of the constant current to the frame sword movable body 221. A serial signal and a clock signal are output from 97 (S1006), and this processing is completed. As a result, it is possible to generate stop excitation in the frame sword moving motor 223 to hold the frame sword movable body 221 in the pushed position stopped.

On the other hand, if the determination result in step S1005 is NO, has the push-in position detection sensor switched from ON to OFF in the holding state (the state in which the frame sword moving motor 223 is generating stop excitation) in step S1007? Judge whether or not. If it is determined that the push-in position detection sensor has been switched to OFF (YES in S1007), the frame sword movable body 221 descends from the push-in position (see FIG. 16 (B)) and is in the middle of being pushed in (see FIG. 16 (C)). Will have passed.

As a result, as soon as the frame sword movable body 221 passes through the position in the middle of being pushed in, it becomes a non-current state, and the stop holding force is not applied. In this way, when the player pushes the frame sword movable body 221 in the pushing position into the storage position, the pushing operation can be smoothly performed after the resistance force is felt at the beginning of pushing. Therefore, it is possible to give an appropriate feeling of operation compared to the case where the resistance force is not always felt from the pushing position to the storage position, and the operability is improved as compared with the case where the resistance force is always felt from the pushing position to the storage position. It is possible to do. It is also possible to suppress the current consumption by switching from the holding state to the no-current state. If the determination result in step S1007 is NO, the serial signal output processing (S703) for the movable frame sword is completed.

[Serial signal output processing for movable frame ear] As shown in FIG. 48, in the serial signal output processing for movable frame ear (S704), first, in the effect control microcomputer 91, the movable frame ear 500 moves to the exposed position. It is determined whether or not it has been completed (S1101). Specifically, it is determined whether or not the photo sensor that detects that the frame ear movable body 500 is in the exposed position is switched from OFF to ON. If it is determined that the frame ear movable body 500 has finished moving to the exposed position (YES in S1101), the serial port 97 prevents the driver controlling the drive of the frame ear movable body 500 from supplying current to the frame ear moving motor 520. A serial signal and a clock signal are output from (S1102), and this processing is completed. As a result, the frame ear movable body 500 in the exposed position is in a non-current state, and the current consumption can be suppressed.

On the other hand, if the determination result in step S1101 is NO, it is subsequently determined whether or not the frame ear movable body 500 has finished moving to the retracted position (S1103). Specifically, it is determined whether or not the photo sensor that detects that the frame ear movable body 500 is in the retracted position is switched from OFF to ON. If it is determined that the frame ear movable body 500 has finished moving to the retracted position (YES in S1103), the driver that controls the drive of the frame ear movable body 500 supplies 71% of the constant current to the frame ear moving motor 520. As described above, the serial signal and the clock signal are output from the serial port 97 (S1104), and this processing is completed. As a result, it is possible to generate stop excitation in the frame ear moving motor 520 to hold the frame ear movable body 500 in the retracted position stopped. If the determination result in step S1103 is NO, the serial signal output process (S704) for the movable frame ear is completed. In the pachinko gaming machine 1, in the initial state immediately after the power is turned on, the frame ear movable body 500 is in the storage position and is in the holding state.

[Serial signal output processing for frame sword disk member] As shown in FIG. 49, in the serial signal output processing for frame sword disk member (S705), first, the effect control microcomputer 91 is at the timing when the vibration of the effect button 63 starts. Determine if it exists (S1201). That is, it is determined whether or not it is the timing to start driving the effect button vibration motor 63b. If it is the timing when the vibration of the effect button 63 starts (YES in S1201), the driver that controls the drive of the frame sword disk member 232 should supply 71% of the constant current to the frame sword disk member rotation motor 231. , A serial signal and a clock signal are output from the serial port 97 (S1202), and this processing is completed. As a result, it is possible to generate stop excitation in the frame sword disk member rotation motor 231 to hold the frame sword disk member 232 stopped.

On the other hand, if the determination result in step S1201 is NO, it is subsequently determined whether or not it is the timing when the vibration of the effect button 63 ends (S1203). That is, it is determined whether or not it is the timing to end the driving of the effect button vibration motor 63b. If it is the timing when the vibration of the effect button 63 ends (YES in S1203), serial from the serial port 97 so that the driver controlling the drive of the frame sword disk member 232 does not supply the current to the frame sword disk member rotation motor 231. A signal and a clock signal are output (S1204), and this processing is completed. As a result, the frame sword disk member 232 is in a non-current state, and the current consumption can be suppressed. If the determination result in step S1203 is NO, the serial signal output processing (S705) for the frame sword disk member is completed.

In this way, in this embodiment, only when the effect button 63 is vibrating, the frame sword disk member 232 is put into a holding state. As a result, even if the vibration of the effect button 63 is transmitted to the frame sword disk member 232, it is possible to prevent the frame sword disk member 232 from rotating. Therefore, it is possible to prevent the player from giving a false impression that the frame sword disk member 232 has moved because the orientation of the decorative portion 232a applied to the frame sword disk member 232 changes during the vibration of the effect button 63. It is possible. In this embodiment, the vibration of the effect button 63 and the rotation of the frame sword disk member 232 are set not to be executed at the same time. In the pachinko gaming machine 1, in the initial state immediately after the power is turned on, the frame sword disk member 232 is in a non-current state.

[Serial signal output processing for movable panel] As shown in FIG. 50, in the serial signal output processing for movable panel (S706), first, in the effect control microcomputer 91, the movable panel 15 finishes moving to the drive position. Judge whether or not (S1301). Specifically, it is determined whether or not the photo sensor that detects that the board movable body 15 is in the drive position is switched from OFF to ON. If it is determined that the panel movable body 15 has finished moving to the drive position (YES in S1301), the driver that controls the drive of the panel movable body 15 supplies 71% of the constant current to the panel movable body moving motor 15a. The serial signal and the clock signal are output from the serial port 97 (S1302), and this processing is completed. As a result, it is possible to generate stop excitation in the board movable body moving motor 15a to hold the board movable body 15 at the drive position stopped.

On the other hand, if the determination result in step S1301 is NO, it is subsequently determined whether or not the board movable body 15 has finished moving to the origin position (S1303). Specifically, it is determined whether or not the photo sensor that detects that the board movable body 15 is at the origin position is switched from OFF to ON. If it is determined that the board movable body 15 has finished moving to the origin position (YES in S1303), the driver controlling the drive of the board movable body 15 does not supply current to the board movable body moving motor 15a from the serial port 97. A serial signal and a clock signal are output (S1304), and this processing is completed. As a result, the board movable body 15 at the origin position is in a non-current state, and the current consumption can be suppressed. If the determination result in step S1303 is NO, the serial signal output processing (S706) for the movable panel is completed. In the pachinko gaming machine 1, in the initial state immediately after the power is turned on, the board movable body 15 is at the origin position and is in a non-current state.

8. Effect of the present embodiment As described in detail above, according to the pachinko gaming machine 1 of the present embodiment, the left frame drum motor driver IC 11 and the right frame drum motor driver IC 21 have a predetermined constant current (200 mA in this embodiment). Not only is it configured to be able to supply, but it is also configured to be able to supply a current with a magnitude of 71% of the constant current or a current with a magnitude of 38% of the constant current. In addition, due to the current reduction external circuits 310B and 320B shown in FIG. 27, the left frame drum motor driver IC 11 and the right frame drum motor driver IC 21 are further smaller than the current (76 mA) having a magnitude of 38% of the constant current. It is possible to supply a current (40 mA, ultra-low current) to the frame drum rotary motor 321. As a result, the frame drum rotation motor 321 uses the above-mentioned small current (40 mA) to generate stop excitation, so that the current consumption for holding the stop of the frame drum 320 can be suppressed as much as possible. Further, it is possible to suppress heat generation of the frame drum rotation motor 321 as much as possible. As a result, it is possible to prevent a failure or malfunction due to heat generation of the frame drum rotation motor 321. In the following, the left frame drum motor driver IC 11 and the right frame drum motor driver IC 21 will be collectively referred to as "frame drum motor driver IC11, IC21 (drive circuit unit)".

Further, according to the pachinko gaming machine 1 of the present embodiment, the frame drum motor drivers IC11 and IC21 previously input an "H" level signal to the PHASEA terminal, input an "H" level signal to the PHASEB terminal, and input an "H" level signal to the INA1 terminal. When inputting an "L" level signal to the INB2 terminal, inputting an "H" level signal to the INA2 terminal, inputting an "L" level signal to the INB1 terminal, and inputting an "H" level signal to the INB2 terminal. Is configured to be able to supply a current having a magnitude of 38% with respect to the above-mentioned constant current. An "H" level signal to be input to the PHASEA terminal, an "H" level signal to be input to the PHASEB terminal, an "L" level signal to be input to the INA1 terminal, and an "H" level signal to be input to the INA2 terminal. The "L" level signal input to the INB1 terminal and the "H" level signal input to the INB2 terminal are referred to as "specific control signals".

Here, the current drop external circuits 310B and 320B shown in FIG. 27 input control signals output from the output terminals P15 and P07 of the input / output IC 12 to the INA1 terminals of the frame drum motor driver IC 11 and IC 21. As a result, the frame drum motor drivers IC11 and IC21 for inputting the above-mentioned specific control signal are supplied with a smaller current (40 mA, ultra-low current) instead of a current (76 mA) that is 38% of the constant current. Is possible. Therefore, as shown in FIG. 27, even if the current reduction external circuits 310B and 320B are newly provided, it is not necessary to newly increase the control signals to be output to the input / output IC 12. In short, there is no difference in the control by the staging control microcomputer 91 between the case where a current of 38% with respect to a constant current is supplied and the case where a smaller current is supplied by the current reduction external circuits 310B and 320B. Therefore, it is possible to easily supply the above-mentioned ultra-reduced current only by making a hardware change without making a software change in the staging control microcomputer 91.

Further, according to the pachinko gaming machine 1 of the present embodiment, the frame drum 320 can show information related to the privilege of the character "V" or the character "super hot" by the upper portion 320U and the lower portion 320D. (See FIGS. 18 and 19). Therefore, if the upper portion 320U and the lower portion 320D move when the frame drum 320 indicates information related to the privilege, the player may be misunderstood. Therefore, in the present embodiment, when the frame drum 320 is stopped, the effect control microcomputer 91 puts the frame drum motor driver IC11, IC21 and the current reduction external circuits 310B, 320B into a low current holding state based on the control. .. This makes it possible to suppress the current consumption while preventing the frame drum 320 from moving, which may give a misunderstanding to the player.

In the pachinko gaming machine 1 of the present embodiment, as shown in FIG. 27, the current reduction external circuits 310B and 320B are provided on the frame relay board 310 that controls the drive of the frame drum 320. However, the control board that controls the drive of other movable members (for example, the frame right relay board 224 that controls the drive of the frame sword movable body 221) is not provided with the current reduction external circuit. This is based on the following reasons.

The frame sword movable body 221 is a relatively large movable member. Therefore, in order to hold the stop of the frame sword movable body 221 in the pushed-in position, a relatively large stop holding force is required. That is, if the frame sword moving motor driver IC1 supplies a current smaller than a current of 71% of the constant current, the frame sword moving motor 223 cannot generate a sufficient stop holding force. Therefore, the frame right relay board 224 does not require a current reduction external circuit that further reduces the current for generating the stop holding force.

On the other hand, in the frame drum 320, the upper portion 320U and the lower portion 320D rotate in the horizontal direction, and the stopped state is relatively stable. Therefore, a relatively small stop holding force is sufficient to hold the frame drum 320 stopped. That is, even if the frame drum motor drivers IC11 and IC21 supply a current smaller than a current having a magnitude of 38% of the constant current, the frame drum 320 can be sufficiently held to be stopped. Therefore, the on-frame relay board 310 is provided with current reduction external circuits 310B and 320B that further reduce the current for generating the stop holding force.

As described above, in the present embodiment, the current reduction external circuits 310B and 320B are provided only on the on-frame relay board 310 that controls the drive of the frame drum 320 based on the required magnitude of the stop holding force. However, from the viewpoint of suppressing the current consumption of the entire pachinko gaming machine 1 as much as possible, the control board that controls the drive of other movable members (frame right relay board 224 that controls the drive of the frame sword movable body 221, frame sword disk member). Frame upper right relay board 225 that controls the drive of 232, control board that controls the drive of the frame face movable body 400, control board that controls the drive of the frame ear movable body 500, control board that controls the drive of the frame jaw movable body 600. , A control board that controls the drive of the panel movable body 15) may be provided with an external circuit for reducing current. In other words, the movable member other than the frame drum 320 may be in a low current holding state.

9. Modification example The modification will be described below. In the description of the modified example, the same components as those of the pachinko gaming machine 1 of the above-described embodiment are designated by the same reference numerals and the description thereof will be omitted. Of course, the configurations according to the modified examples may be appropriately combined and configured. Further, the technical features in the above-described embodiment and the following modifications can be appropriately deleted unless they are described as essential in the present specification.

<Second form>
In the above embodiment, two-phase excitation (see FIG. 24 (A)) is used as an excitation method when each stepping motor such as the frame face moving motor 311 generates stop excitation. On the other hand, in the second embodiment, one-phase excitation (see FIG. 24B) is used as an excitation method when each stepping motor generates stop excitation. For example, when holding the stop of the frame drum 320, the staging control microcomputer 91 controls the frame drum motor drivers IC11 and IC21 to generate a stop holding force by one-phase excitation in the frame drum rotation motor 321. At this time, the effect control microcomputer 91 further controls the frame drum motor drivers IC11 and IC21 to a low current holding state in which a current having a magnitude of 38% of the constant current is supplied. As a result, the current consumption (electric power) when holding the frame drum 320 stopped can be reduced to half of the above-mentioned form. In short, it is possible to suppress the current consumption not only by providing the external circuits 310B and 320B for reducing the current but also by changing the excitation method when the stop excitation is generated.

Further, 1-2 phase excitation may be used as the excitation method when each stepping motor generates stop excitation. In 1-2 phase excitation, as shown in FIG. 52, one pulse and two pulses are alternately shifted with respect to the next phase to which a pulse is applied, so that only one phase is excited and two phases are excited at the same time. It is a method of alternately creating a state of being excited. In the case of stop excitation by 1-2 phase excitation, the current consumption (electric power) can be reduced to 3/4 as compared with the above-mentioned form (stop excitation by two-phase excitation). The stop holding force is larger in the case of stop excitation by 2-phase excitation than in the case of stop excitation by 1-2 phase excitation, and in the case of stop excitation by 1-2 phase excitation, stop excitation by 1-phase excitation. Will be larger than in the case of.

<Third form>
In the above embodiment, as shown in FIG. 32, when the frame drum 320 is held stopped, the frame drum motor drivers IC11 and IC21 supply a current (decreased current) having a magnitude of 38% of the constant current. Controlled to state. On the other hand, in the third embodiment, the current reduction external circuit corresponding to the current reduction external circuits 310B and 320B described in the above embodiment is used on the control board for controlling the drive of the frame ear movable body 500 (movable member) (illustrated). Omitted) is provided. Then, as shown in FIG. 53, when the frame ear movable body 500 in the retracted position is held stopped, the driver (drive circuit unit) capable of controlling the frame ear moving motor 520 has a constant current (for example, 150 mA) of 71. The first low current holding state is controlled so as to supply a current (for example, 56 mA, the first ultra-decreasing current) smaller than the current having a magnitude of% (for example, 106.5, the first reduced current). Further, when holding the stop of the frame ear movable body 500 in the exposed position, the driver capable of controlling the frame ear moving motor 520 has a current (for example, 57 mA, second reduced current) of 38% of the constant current. May be controlled so as to be in a second low current holding state that supplies a smaller current (for example, 30 mA, a second ultra-low current).

According to this third embodiment, it is possible to apply a stop holding force based on a current smaller than 71% of the constant current to the frame ear movable body 500 in the retracted position. Further, it is possible to apply a stop holding force based on a current smaller than 38% of the constant current to the frame ear movable body 500 in the exposed position. In this way, it is possible to adjust the current consumption and the stop holding force according to the situation of the movable member. That is, it is possible to appropriately select the first low current holding state or the second low current holding state according to the required stop holding force, and to minimize the waste of current consumption. In the third embodiment, the frame ear movable body 500 is controlled to the first low current holding state or the second low current holding state, but other movable members (frame face movable body 400, frame jaw movable body 600, The frame sword movable body 221, the frame sword disk member 232, the board movable body 15, etc.) may be controlled to the first low current holding state or the second low current holding state.

<Other variants>
In the above embodiment, the driver (frame drum motor driver IC11, IC21, etc.) that controls the drive of the movable member (frame drum 320, etc.) has a current (from a constant current) of 71% of the constant current (200 mA in this embodiment). It is configured to be able to supply a current (decrease current that is 29% smaller than the constant current) or a current that is 38% larger than the constant current (decrease current that is 62% smaller than the constant current). However, the above-mentioned 71% or 38% ratio is determined by the driver. Therefore, a driver capable of supplying a current having a magnitude other than 71% or 38% with respect to the constant current (for example, a current having a magnitude of 50% or 25% with respect to the constant current) may be used. In addition, instead of using a driver that can supply two types of reduced current of 71% or 38% with respect to a constant current, a driver that can supply only one type of reduced current is used, or three or more types of reduction are used. A driver capable of supplying current may be used.

Further, in the above embodiment, the frame drum motor drivers IC11 and IC21 have a current (super) smaller than 38% of the constant current by the current reduction external circuits 310B and 320B (current reduction means) including the NPN type transistor TR3. Reduced current) can be supplied. However, the current reducing means may be configured by a transistor other than the NPN type transistor TR3 (PNP type transistor, FET (unipolar transistor), etc.). Further, the current reducing means does not have to be composed of a transistor, and may be configured to include, for example, a varistor (variable resistor).

Further, in the above embodiment, the current reduction external circuits 310B and 320B shown in FIG. 27 are output from the output terminals P15 and P07 of the input / output IC12 to the INA1 terminals of the frame drum motor drivers IC11 and IC21 (specific control signals. Based on the input of a part), it was configured to be able to supply the above-mentioned ultra-low current. That is, it is configured so that the ultra-reduced current can be supplied only by the hardware change without making the software change in the staging control microcomputer 91. However, the configuration that enables the supply of the ultra-reduced current is not limited to the above configuration, and can be appropriately changed. For example, the effect control microcomputer 91 may be controlled so as to transmit a dedicated control signal from the input / output IC 12 to the current reduction external circuits 310B and 320B shown in FIG. 27 so that the ultra-reduction current can be supplied. ..

Further, in the above embodiment, as shown in FIG. 32, for example, the frame sword movable body 221 in the storage position is in a non-current state, and the frame sword movable body 221 in the push-in position is in a holding state. However, the relationship between the position of the movable member and the no-current state or the holding state is not limited to the case shown in FIG. 32, and can be appropriately changed. Therefore, for example, even a movable member other than the frame drum 320 may be in a holding state from the initial state immediately after the power is turned on.

Further, in the above embodiment, the switching from the holding state to the non-current state is performed for the frame sword movable body 221 and the frame sword disk member 232. However, other movable members (for example, the frame face movable body 400, the board movable body 15, the opening / closing member, etc.) may be switched from the holding state to the non-current state.

Further, in the above embodiment, switching from the no-current state to the holding state is performed on the frame sword disk member 232. However, other movable members (for example, the frame jaw movable body 600, the board movable body 15, the opening / closing member, etc.) may be switched from the no-current state to the holding state. For example, the frame jaw movable body 600 (movable member) is limited to the movement of the frame face movable body 400 (other movable member) (moving from the standby position to the operating position or moving from the operating position to the standby position). May be switched from the no-current state to the holding state. In this case, it is possible to prevent the frame face movable body 400 from interfering with the frame jaw movable body 600 due to strange behavior of the frame jaw movable body 600 while the frame face movable body 400 is moving. It is possible.

Further, in the above embodiment, the player switches the frame sword movable body 221 from the holding state to the non-current state based on the pushing operation from the pushing position to the storage position. However, it is possible to switch from the holding state to the no-current state regardless of the pushing operation of the player. For example, the holding state may be switched to the non-current state based on the establishment of a predetermined effect condition (for example, the start of the frame sword operation promotion effect shown in FIG. 51). In this case, since the stop holding force for the frame sword movable body 221 is released after the predetermined effect condition is satisfied, the frame sword movable body 221 gradually descends from the pushing position. This makes it possible to provide a novel effect that the frame sword movable body 221 gradually descends due to gravity even before the player pushes it in.

Further, in the above embodiment, the push-in position detection sensor 227 capable of detecting that the frame sword movable body 221 is in the push-in position (first position) is provided, and the frame sword movable body 221 is stored from the push-in position (second position). When the push-in position detection sensor 227 stopped detecting (switched from ON to OFF) when moving to, the holding state was switched to the non-current state. However, the timing for switching from the holding state to the no-current state can be appropriately changed. For example, an intermediate position detection sensor capable of detecting that the frame sword movable body 221 is in an intermediate position between the pushed position and the stored position is provided. Then, when the intermediate position detection sensor detects when the frame sword movable body 221 moves from the pushed position to the stored position (when switched from OFF to ON), the holding state may be switched to the non-current state. In this case, it is possible to give a strange operation feeling that the player can feel the resistance until the frame sword movable body 221 is pushed in half, and then push it smoothly without feeling the resistance. Is.

Further, in the above embodiment, the player switches the frame sword movable body 221 from the holding state to the non-current state based on the pushing operation from the pushing position to the storage position. However, the player may switch from the holding state to the non-current state based on the pulling operation of the frame sword movable body 221 from the storage position (first position) to the pushing position (second position). That is, it is configured to be able to execute a pull-out operation promotion effect that urges the player to pull out the frame sword movable body 221 in the storage position upward. Then, before the pull-out operation promotion effect is executed, the frame sword movable body 221 is put into a holding state. Then, with the execution of the pull-out operation promotion effect, the player switches the frame sword movable body 221 from the holding position to the non-current state based on the pull-out operation from the storage position to the push-in position. This makes it possible for the player to first make it difficult to pull out the frame sword movable body 221 and then to give a new effect and operation feeling that the frame sword movable body 221 can be smoothly pulled out to the pushing position. Is.

In the above embodiment, as shown in FIG. 25, the current cutoff circuit 224A (conduction switching means) for switching the control lines L1 to L4 to the conduction state or the non-conduction state is configured to include the photomos relays PM1 and PM2. However, the continuity switching means may be configured to include a relay (mechanical relay, photocoupler, electromagnetic relay, etc.) other than the photomos relays PM1 and PM2. Further, the continuity switching means does not have to be configured by a relay, and may be configured to include, for example, a physical analog switch.

Further, in the above embodiment, the effect control microcomputer 91 controls the current cutoff circuit 224A, the inspection external circuits 224B, 310A, 320A, and the current reduction external circuits 310B, 320B by I2C communication. However, the current cutoff circuit 224A, the inspection external circuits 224B, 310A, 320A, and the current reduction external circuits 310B, 320B may be controlled by serial communication other than I2C communication or parallel communication.

Further, in the above embodiment, the effect control microcomputer 91 sets the frame sword movable body drive period based on the selection of the variable effect pattern for executing the frame sword operation promotion effect (establishment of the effect drive condition). The control lines L1 to L4 were controlled to be in a conductive state during the frame sword movable body driving period. However, the frame sword movable body driving period may be set based on other conditions. For example, the frame sword movable body driving period may be set only during a predetermined specific period (for example, during business hours (between 9:00 am and 11:00 pm) or within one year after being installed in the amusement park). .. Further, the frame sword movable body driving period may be set only while the power is turned on to the pachinko gaming machine 1.

Further, in the above embodiment, the current cutoff circuit 224A is provided on the frame right relay board 224 that controls the drive of the frame sword movable body 221. However, a current cutoff circuit such as the current cutoff circuit 224A is used on a control board that controls the drive of other movable members such as an effect movable body that can move directly in the horizontal direction and buttons and levers that can be moved by the driving force of a motor. Continuity switching means) may be provided.

Further, in the above embodiment, the external circuit for inspection 224B for reducing the constant current supplied by the constant current drive type driver (frame sword moving motor driver IC1, left frame drum motor driver IC11, right frame drum motor driver IC21), The 310A and 320A (state switching means) are configured to include NPN type transistors TR1 and TR2. However, the state switching means may be configured by a transistor other than the NPN type transistors TR1 and TR2 (PNP type transistor, FET (unipolar transistor), etc.). Further, the state switching means does not have to be composed of a transistor, and may be configured to include, for example, a varistor (variable resistor).

Further, in the above embodiment, the frame face moving motor 311, the frame drum rotating motor 321, the frame ear moving motor 520, the frame jaw moving motor 610, the frame sword moving motor 223, the frame sword disk member rotating motor 231, and the board movable body moving motor 15a. The drivers for controlling the drive (frame sword moving motor driver IC1, left frame drum motor driver IC11, right frame drum motor driver IC21, frame sword disk member rotation motor driver IC31, etc.) were of a constant current drive system. However, the driver is not limited to the constant current drive system, and may be, for example, a constant voltage drive system.

Further, in the above embodiment, the frame face moving motor 311, the frame drum rotating motor 321, the frame ear moving motor 520, the frame jaw moving motor 610, the frame sword moving motor 223, the frame sword disk member rotating motor 231, and the board movable body moving motor 15a are , The bipolar type stepping motor shown in FIG. 23 (A). However, other types of motors may be used, and for example, a unipolar type stepping motor shown in FIG. 23 (B) may be used.

Further, in the above embodiment, two-phase excitation is used as the excitation method when the stepping motor on the bipolar side moves the movable member (driving state). However, when moving the movable member, one-phase excitation may be used from the viewpoint of reducing the power consumption as much as possible rather than increasing the torque. Further, 1-2 phase excitation may be used from the viewpoint of reducing vibration. Further, 2-phase excitation, 1-phase excitation, and 1-2-phase excitation may be controlled so as to be switched at predetermined timings.

Further, in the above embodiment, the constant current supplied by the driver (frame sword moving motor driver IC1, left frame drum motor driver IC11, right frame drum motor driver IC21) by the inspection external circuits 224B, 310A, 320A (state switching means). Was made smaller at two ratios of 15% or 20%. However, it may be possible to reduce the ratio to either 15% or 20%. Alternatively, it may be made smaller by other ratios of 15% or 20% so that it can be made smaller by three or more kinds of ratios. The ratio of reducing the constant current supplied by the driver is not limited to 15% or 20%, and may be, for example, 10% or 30%, and can be appropriately changed.

Further, in the above embodiment, the inspection controller KC (see FIG. 31) controls the transistors TR1 and TR2 of the inspection external circuits 224B, 310A and 320A. However, the effect control microcomputer 91 outputs an "H" level or "L" level signal as a K-CHECK1 control signal from the input / output ICs 12 and IC21, and also outputs an "H" level or "L" level signal as a K-CHECK2 control signal. Control to output a level signal. As a result, the effect control microcomputer 91 may control the transistors TR1 and TR2 of the inspection external circuits 224B, 310A and 320A. In this case, the following may be further performed.

When the initialization (ram clear) of the RAM 94 is executed when the power is turned on, the ram clear notification image RK is displayed on the display screen 7a as shown in FIG. 54 (A). Then, when a predetermined operation (for example, an operation of continuously pressing the effect button 63 five times) is performed within a predetermined time (for example, 30 seconds) after the execution of the ram clear, as shown in FIG. 54 (B), the initial display screen 7a is displayed. The function setting image SG is displayed. While displaying this initial function setting image SG, either "100%", "15% reduction" or "20% reduction" can be set as the output torque setting, and "automatic" or "automatic" or "automatic" or "20% reduction" can be set as the current cutoff setting. It may be configured so that either "always shut off" can be set.

That is, while the initial function setting image SG shown in FIG. 54 (B) is being displayed, the select button 68 is operated to set the cursor to "100%" of the output torque setting. Then, the effect button 63 is pressed and operated. In this case, the effect control microcomputer 91 outputs an “L” level signal as a K-CHECK1 control signal from the input / output ICs 12 and IC21, and outputs an “L” level signal as a K-CHECK2 control signal. To control. As a result, a desired (100%) constant current can be passed from the frame sword moving motor driver IC1, and the frame sword moving motor 223 can be driven with a desired output torque.

Further, while the initial function setting image SG shown in FIG. 54 (B) is being displayed, the select button 68 is operated to set the cursor to "15% reduction" of the output torque setting. Then, the effect button 63 is pressed and operated. In this case, the effect control microcomputer 91 outputs an “L” level signal as a K-CHECK1 control signal from the input / output ICs 12 and IC21, and outputs an “H” level signal as a K-CHECK2 control signal. To control. As a result, it is possible to flow a current reduced by 15% with respect to a desired constant current from the frame sword moving motor driver IC1, and it is possible to drive the frame sword moving motor 223 with an output torque reduced by 15%. be. By setting in this way, for example, a gaming machine maker or the like can properly operate the frame sword moving motor 223 even with an output torque reduced by 15% in a state where the entire pachinko gaming machine 1 shown in FIG. 1 is assembled. It is possible to make a final check on whether or not.

Further, while the initial function setting image SG shown in FIG. 54 (B) is being displayed, the select button 68 is operated to set the cursor to "20% reduction" of the output torque setting. Then, the effect button 63 is pressed and operated. In this case, the effect control microcomputer 91 outputs an “H” level signal as a K-CHECK1 control signal from the input / output ICs 12 and IC21, and outputs an “L” level signal as a K-CHECK2 control signal. To control. As a result, it is possible to flow a current reduced by 20% with respect to a desired constant current from the frame sword moving motor driver IC1, and it is possible to drive the frame sword moving motor 223 with an output torque reduced by 20%. be. By setting in this way, for example, a gaming machine maker or the like can properly operate the frame sword moving motor 223 even with an output torque reduced by 20% in a state where the entire pachinko gaming machine 1 shown in FIG. 1 is assembled. It is possible to make a final check on whether or not.

Further, while the initial function setting image SG shown in FIG. 54 (B) is being displayed, the select button 68 is operated to set the cursor to "automatic" of the current cutoff setting. Then, the effect button 63 is pressed and operated. In this case, as described in the present embodiment, the effect control microcomputer 91 outputs an “H” level signal as a K-FC control signal from the input / output IC 12 only during the frame sword movable body drive period. Thereby, it is possible to move the frame sword movable body 221 by the driving force of the frame sword moving motor 223 at the time of the frame sword operation promotion effect. Then, when the frame sword movable body driving period ends, an "H" level signal is output from the input / output IC 12 as a K-FC control signal. As a result, the control lines L1 to L4 are automatically put into a non-conducting state, and it is possible to prevent an excess voltage from acting on the frame sword moving motor driver IC1.

On the other hand, while the initial function setting image SG shown in FIG. 54 (B) is being displayed, the select button 68 is operated to set the cursor to the current cutoff setting "always cut off". Then, the effect button 63 is pressed and operated. In this case, the effect control microcomputer 91 does not output an “H” level signal as a K-FC control signal from the input / output IC 12, and the control lines L1 to L4 are always in a non-conducting state. By setting in this way, it is possible to suppress the consumption of electric current by making the frame sword movable body 221 not always operate. When the frame sword movable body 221 has a defect, it is possible to prevent the degree of the defect from further deteriorating.

In the above-mentioned modification example, the employee of the amusement park (hall) can set the output torque and the current cutoff. However, by setting a hidden command or the like, only the gaming machine maker or the component maker may be able to set the output torque and the current cutoff.

Further, in the above-mentioned modification example, the output torque when the driving force is applied to the movable member is arbitrarily set to "100%", "15% reduction (85%)" or "20% reduction (80%)". I made it possible. On the other hand, the stop holding force when the stop holding force is applied to the movable member can be arbitrarily set to "100%", "71%", "38%", or "less than 38%". Is also good. Further, it may be possible to arbitrarily set whether or not to hold the frame sword disk member 232 (movable member) while the effect button 63 is vibrating (while the other movable member is moving).

Further, in the above embodiment, the frame sword moving motor driver IC1 which is a constant current drive system is set to supply, for example, 230 mA as a constant current. However, this constant current means a current (230 ± αmA) that is almost within a constant range when the voltage acting on the VREFA terminal and the VREFB terminal is a voltage in a predetermined range. In short, "constant current" does not mean only exactly the same current value (for example, 230 mA), but means a current within a range that a person skilled in the art considers to be almost constant.

Further, in the above embodiment, four random numbers such as a jackpot random number are acquired as random numbers (determination information) acquired based on the winning of the first starting port 20 or the second starting port 21, but one random number. And based on the random number, whether or not it is a big hit, the type of big hit, the presence or absence of reach, and the type of fluctuation pattern may be determined. That is, the number of random numbers to be acquired based on the starting prize and what is to be determined for each random number can be arbitrarily set.

Further, in the above embodiment, it is configured as a so-called V-probability machine (a gaming machine that controls to a high-probability state based on the passage of a specific area 39), but the transition to the high-probability state is determined based on the type of the winning jackpot symbol. It may be configured as a gaming machine. Further, in the above embodiment, it is configured as a so-called ST machine (a gaming machine that cuts the number of probabilistic changes), but once it is controlled to a high probability state, the control to the high probability state continues until the start of the next big hit game (so-called). It may be configured as a probabilistic loop type gaming machine). Further, in the above embodiment, the variation of the special figure 2 is configured to be executed in preference to the variation of the special figure 1. On the other hand, the variation of the special figure 2 and the variation of the special figure 1 may be configured to be executed according to the winning order to the starting port. In this case, a storage area that can be stored by adding the first special figure hold and the second special figure hold is provided in the RAM 84, and the determination information is stored in the storage area according to the winning order, and the oldest one in the storage order is digested. It may be configured to do so. Further, the variation of the special figure 1 may be executed even during the change of the special figure 2, and the variation of the special figure 2 may be executed even during the change of the special figure 1. That is, it may be configured as a so-called simultaneous fluctuation gaming machine. Further, it may be configured as a so-called 1-type / 2-type mixer or a honey-mono type gaming machine. That is, the present invention can be suitably adopted for a game machine having various game characteristics regardless of the game nature of the game machine.

Further, in the above embodiment, the pachinko gaming machine is configured to be controlled to the jackpot gaming state (special gaming state) under the control condition that the special symbol indicating that the jackpot is won is stopped and displayed. On the other hand, it may be configured as a slot machine (rotary drum type gaming machine, pachislot gaming machine). In this case, in the case of a so-called normal machine that increases the number of medals earned by winning a big bonus or a regular bonus, the state in which the bonus such as the big bonus or the regular bonus is executed corresponds to the special gaming state. In addition, if it is a so-called ART machine or AT machine that increases the number of medals won during a special game period such as ART (assist replay time) or AT (assist time) that can frequently win small roles, it is in the state of ART or AT. Corresponds to the special gaming state. In addition, in the normal machine, the control conditions for the special game state are a combination of symbols that triggers the transition to the big bonus and regular bonus on the activated winning line after winning the big bonus and regular bonus. It is derived and displayed as the display result of the reel. Further, in the ART machine and the AT machine, the control condition to the special game state is, for example, after winning the execution lottery of the ART or AT, the specified number of games is exhausted, and the activation timing of the ART or AT is reached. be.

In the above-mentioned form, "the establishment of a predetermined control condition" in the present specification means that a jackpot is won in the lottery of the first special symbol or the lottery of the second special symbol, and the jackpot symbol indicating the winning is stopped and displayed. Is Rukoto.

10. Inventions Shown in the Above Embodiments The inventions of the following means are shown in the above-mentioned embodiments. In the description of the means described below, the corresponding configuration names and expressions in the above-described embodiment and the reference numerals used in the drawings are added in parentheses for reference. However, the components of each invention are not limited to this appendix.

<Means A>
The invention according to means A1 is
In a gaming machine (pachinko gaming machine 1) that controls an advantageous special gaming state based on the establishment of predetermined control conditions.
Movable member (frame drum 320) and
A driving means (frame drum rotation motor 321) capable of imparting a driving force for moving the movable member and a stop holding force for holding the stop of the movable member.
A drive circuit unit (frame drum motor driver IC11, IC21) capable of controlling the drive means is provided.
The drive circuit unit
A driving state in which the driving means applies a driving force to the movable member based on supplying a predetermined driving current (constant current, for example, 200 mA) to the driving means, or
Retention that the drive means imparts a stop holding force to the movable member based on supplying the drive means with a lower current smaller than the drive current (for example, 142 mA which is 71%, 76 mA which is 38%, for example). It is a gaming machine characterized in that it can be put into a state.

According to the gaming machine having this configuration, it is possible to move the movable member in a driving state in which the driving means applies a driving force to the movable member. On the other hand, in the holding state in which the driving means applies a stop holding force to the movable member, it is possible to hold the movable member stopped. In this holding state, the drive circuit unit supplies the drive means with a lowering current smaller than the drive current, so that it is possible to suppress the current consumption for holding the movable member stopped.

The invention according to means A2 is
In the gaming machine described in means A1,
The drive circuit unit is configured to be capable of supplying the drive means with a current (for example, 76 mA, which is 38%) smaller than the drive current by a predetermined ratio (for example, 62%) as the decrease current.
The drive circuit unit may be supplied with an ultra-reduced current (for example, 40 mA, which is 20%) smaller than the reduced current to bring the drive means into a low current holding state in which the movable member is provided with a stop holding force. It is a gaming machine characterized by being provided with a possible current reduction means (current reduction external circuits 310B, 320B).

According to the gaming machine having this configuration, it is possible to bring the drive circuit unit into a low current holding state in which the drive circuit unit supplies an ultra-reduced current smaller than the reduced current to the drive means by the current reducing means. Therefore, it is possible to further suppress the current consumption for holding the movable member stopped.

The invention according to means A3 is
In the gaming machine described in means A2,
Specific control signals for the drive circuit unit (“H” level signal input to the PHASEA terminal, “H” level signal input to the PHASEB terminal, “L” level signal input to the INA1 terminal, to the INA2 terminal It is equipped with a control signal output unit (input / output IC12) that can output "H" level signals to be input, "L" level signals to be input to the INB1 terminal, and "H" level signals to be input to the INB2 terminal.
The drive circuit unit is configured to be able to output the reduced current based on the input of the specific control signal.
The current reducing means is
Based on the input of at least a part of the specific control signal output by the control signal output unit (the "L" level signal input to the INA1 terminal), the drive circuit unit for inputting the specific control signal It is a gaming machine characterized in that it supplies the ultra-reduced current instead of the reduced current.

According to the gaming machine having this configuration, the drive circuit unit is configured in advance to output a reduced current when a specific control signal is input. Here, the current reducing means can input a part of the specific control signal output by the control signal output unit to supply the drive circuit unit for inputting the specific control signal not the reduced current but the ultra-reduced current. Is. Therefore, even if the current reducing means is newly provided, it is not necessary to newly increase the control signal to be output to the control signal output unit. Therefore, it can be easily implemented without making any software changes.

The invention according to means A4 is
In the gaming machine according to means A2 or means A3,
The drive circuit unit (driver capable of controlling the frame ear moving motor 520) is
A first decrease current (for example, 71%, 106.5 mA) smaller than the drive current (for example, 150 mA) by a first predetermined ratio (for example, 29%), or a second predetermined ratio (for example, 62%) smaller than the drive current. It is configured to be able to supply a second reduction current (for example, 57 mA, which is 38%), which is smaller than the first reduction current and smaller than the first reduction current.
The current reducing means is
A first ultra-low current (for example, 56 mA) smaller than the first low current is supplied to the drive circuit unit to bring the drive means into a first low current holding state in which a stop holding force is applied to the movable member. It is possible, and the drive circuit unit is supplied with a second ultra-reducing current (for example, 30 mA) smaller than the second reduced current, and the driving means imparts a stop holding force to the movable member. 2 It is a gaming machine characterized in that it can be in a low current holding state (see FIG. 53).

According to the gaming machine having this configuration, the drive circuit unit is configured in advance to be able to supply a first reduced current smaller than the drive current or a second reduced current smaller than the first reduced current. Then, by the current reducing means, the drive circuit unit supplies the first ultra-reduced current smaller than the first reduced current to the drive means in the first low current holding state, or the drive circuit unit is further smaller than the second reduced current. It is possible to set the second low current holding state in which the two ultra-low current is supplied to the drive means. Therefore, when a relatively large stop holding force is required, the first low current holding state is set, and when a relatively small stop holding force is sufficient, the second low current holding state is set. In this way, it is possible to select the first low current holding state or the second low current holding state according to the required stop holding force.

The invention according to means A5 is
In the gaming machine according to any one of means A2 to means A4,
The movable member can show information related to the privilege to the player (for example, the character "super hot", the character "V") (see FIGS. 18 and 19).
A staging control means (microcomputer 91 for staging control) capable of controlling the drive circuit unit and the current reducing means is provided.
When the movable member indicates information related to the privilege to the player, the staging control means may bring the low current holding state based on the control of the drive circuit unit and the current reducing means. It is a gaming machine characterized by being possible (execution of step S902).

According to the gaming machine having this configuration, if the movable member moves while the movable member indicates information related to the privilege to the player, the player may be misunderstood. Therefore, at this time, the staging control means sets the low current holding state based on the control of the drive circuit unit and the current reduction means. As a result, it is possible to suppress the current consumption while preventing the movement of the movable member that may give a misunderstanding to the player.

By the way, in the gaming machine described in Japanese Patent Application Laid-Open No. 2008-272111, for example, after moving a movable member from a standby position to an operating position, the movable member may be stopped at the operating position for a predetermined time. .. In this case, the drive circuit unit (driver IC) supplies a current for stop holding (stop excitation) to the drive means (motor) in order to generate a stop holding force for holding the stop of the movable member. At this time, if the drive circuit unit supplies a drive current having the same magnitude as when the movable member is moved to the drive means, the current consumption for holding the movable member stopped increases. Therefore, the inventions according to the above-mentioned A1 to A5 are based on the fact that the drive circuit unit supplies the drive means with a lower current smaller than the drive current for the gaming machine described in Japanese Patent Application Laid-Open No. 2008-272111. The difference is that the driving means can be in a holding state in which a stop holding force is applied to the movable member. This makes it possible to solve the problem of providing a gaming machine capable of suppressing the current consumption for holding the movable member stopped (effectively acting).

<Means B>
The invention according to means B1 is
In a gaming machine (pachinko gaming machine 1) that controls an advantageous special gaming state based on the establishment of predetermined control conditions.
Movable members (frame sword movable body 221 and frame sword disk member 232) and
A driving means (frame sword moving motor 223, frame sword disk member rotating motor 231) capable of imparting a driving force for moving the movable member and a stop holding force for holding the stop of the movable member, and
A drive circuit unit (frame sword moving motor driver IC1, frame sword disk member rotating motor driver IC31) capable of controlling the driving means, and
A control means (microcomputer 91 for staging control) capable of controlling the drive circuit unit is provided.
The control means is
A drive state in which the drive means applies a drive force to the movable member based on the drive circuit unit supplying a predetermined drive current to the drive means, or
A holding state in which the driving means applies a stop holding force to the movable member based on the driving circuit unit supplying the driving means with a lowering current smaller than the driving current, or
Based on the fact that the drive circuit unit does not supply a current to the drive means, the drive means can switch to a non-current state in which the movable member is not subjected to a stop holding force (see FIG. 32). It is a game machine to play.

According to the gaming machine having this configuration, when the movable member is moved, the drive circuit unit supplies a drive current to the drive means to bring the movable member into a drive state in which the drive force is applied. Further, in the case of holding the stop of the movable member, the drive circuit unit supplies a reduced current to the drive means to bring the movable member into a holding state in which the stop holding force is applied. When the movable member is not moved and it is not necessary to hold the movable member stopped, the drive circuit unit does not supply a current to the drive means, so that the movable member is not given a stop holding force. To. In this way, it is possible to suppress the current consumption by appropriately switching between the driving state, the holding state, and the non-current state according to the situation of the movable member.

The invention according to means B2 is
In the gaming machine described in means B1,
The movable member (frame sword movable body 221) can be operated by the player from a predetermined first position (pushing position shown in FIG. 16B) to a second position (storage position shown in FIG. 16A). It is a thing
The control means is
When the movable member is in the first position, it is in the holding state.
A game characterized in that the player can switch from the holding state to the no-current state based on operating the movable member from the first position to the second position (see FIG. 32). It is a machine.

According to the gaming machine having this configuration, when the movable member is in the first position, it is possible to hold the movable member stopped at the first position by putting it in the holding state. However, when the player operates the movable member from the first position to the second position, if the holding state is always maintained, it is difficult for the player to operate the movable member. Therefore, at this time, the stop holding force on the movable member is released by switching from the holding state to the non-current state. This makes it possible for the player to easily operate the movable member to the second position.

The invention according to means B3 is
In the gaming machine described in means B2,
A first position detecting means (pushing position detection sensor 227) capable of detecting that the movable member is at least in the first position is provided.
The first position detecting means does not detect the movable member while moving from the first position to the second position (when passing through the pushing intermediate position shown in FIG. 16C).
The control means switches from the holding state to the no-current state when the player operates the movable member from the first position to the second position and the detection by the first position detecting means disappears. It is a gaming machine characterized by being present (see FIG. 32).

According to the gaming machine having this configuration, when the movable member in the first position starts to move to the second position by the operation by the player, it is still in the holding state. Therefore, the player moves the movable member against the stop holding force. After that, while the movable member is moving from the first position to the second position, the holding state is switched to the non-current state. As a result, the stop holding force on the movable member is released, so that the player can smoothly move the movable member to the second position. In this way, it is possible to give the player a new feeling of operation that he / she can feel a little resistance at the beginning of movement and then can smoothly operate the movable member.

The invention according to means B4 is
In the gaming machine described in means B1,
Equipped with other movable members (effect button 63) that can be moved,
The control means is
While the other movable member is in the holding state when it is moving,
The gaming machine is characterized in that the non-current state can be achieved when the other movable member is not moving (see FIG. 32).

According to the gaming machine having this configuration, when the other movable member is moving in the no-current state, it is in the holding state. Therefore, it is possible to hold the movable member stopped. After that, when the movement of the other movable member is completed, the state is switched to the no-current state. As a result, the stop holding force on the movable member is released. In this way, it is possible to avoid a situation in which the movable member moves while the other movable member is moving, while reducing the current consumption as much as possible.

The invention according to means B5 is
In the gaming machine described in means B4,
A gaming machine frame (50) including a frame-shaped base frame portion (outer frame 51 and inner frame 52) and a front frame portion (front frame 53) located on the front side of the base frame portion is provided.
The movable member and the other movable member are attached to the gaming machine frame.
The other movable member is vibrable and can be vibrated.
The control means is
While the other movable member is in the holding state when it is vibrating,
The gaming machine is characterized in that the non-current state can be achieved when the other movable member is not vibrating (see FIG. 32).

According to the gaming machine having this configuration, when other movable members attached to the gaming machine frame vibrate, the movable members attached to the gaming machine frame may move. Therefore, it is possible to avoid the movable member from moving due to the vibration by putting it in the holding state during the vibration of the other movable member.

By the way, in the gaming machine described in Japanese Patent Application Laid-Open No. 2008-272111, for example, after moving a movable member from a standby position to an operating position, the movable member may be stopped at the operating position for a predetermined time. .. In this case, the drive circuit unit (driver IC) supplies a current for stop holding (stop excitation) to the drive means (motor) in order to generate a stop holding force for holding the stop of the movable member. At this time, if the drive circuit unit supplies a drive current having the same magnitude as when the movable member is moved to the drive means, the current consumption for holding the movable member stopped increases. Further, for example, the movable member may be in the standby position in a relatively stable state. That is, it may not be necessary to apply a stop holding force for holding the stop of the movable member to the movable member in the standby position. At this time, if the drive circuit unit supplies the stop holding current to the drive means, the current consumption for holding the stop of the movable member is wasted. From the above, there is room for improvement in suppressing the current consumption depending on the situation of the movable member. Therefore, the above-mentioned inventions according to B1 to B5 are based on the fact that the drive circuit unit supplies a predetermined drive current to the drive means for the game machine described in Japanese Patent Application Laid-Open No. 2008-272111. Based on the drive state in which the drive means applies a drive force to the movable member, or the drive circuit unit supplies the drive means with a lower current smaller than the drive current, the drive means causes the movable member to stop and hold the force. The difference is that the drive means can be switched to a holding state in which the current is applied, or a non-current state in which the drive means does not apply a stop holding force to the movable member based on the fact that the drive circuit unit does not supply current to the drive means. ing. This makes it possible to solve the problem of providing a gaming machine capable of suppressing current consumption according to the situation of the movable member (effectively exerting an action effect).

<Means C>
The invention according to means C1 is
In a gaming machine (pachinko gaming machine 1) that controls an advantageous special gaming state based on the establishment of predetermined control conditions.
Movable member (frame sword movable body 221) and
A driving means (frame sword moving motor 223) capable of applying a driving force for moving the movable member, and
A drive circuit unit (frame sword moving motor driver IC1) capable of controlling the drive of the drive means, and
A control line (L1, L2, L3, L4) between the drive means and the drive circuit unit, and
The gaming machine is provided with a conduction switching means (current cutoff circuit 224A) capable of switching the control line to a conduction state or a non-conduction state.

According to the gaming machine having this configuration, it is possible to make the control line between the drive means and the drive circuit unit in a non-conducting state by the continuity switching means. As a result, when the movable member is not moved, it is possible to prevent an unintended excess voltage or the like from acting from the drive means side to the drive circuit unit side and prevent a failure of the drive circuit unit.

The invention according to the means C2 is
In the gaming machine described in means C1,
A gaming machine frame (50) including a frame-shaped base frame portion (outer frame 51 and inner frame 52) and a front frame portion (front frame 53) located on the front side of the base frame portion is provided.
The movable member is a gaming machine that is attached to the gaming machine frame and can be moved by a human body (player or the like) (see FIG. 1).

According to the gaming machine having this configuration, the player may move the movable member attached to the gaming machine frame by mischief. In this case, a counter electromotive force may be generated in the driving means. Therefore, by keeping the control line between the drive means and the drive circuit unit in a non-conducting state by the continuity switching means, it is possible to prevent an overvoltage that exceeds the withstand voltage of the drive circuit unit from acting. be. Therefore, it is possible to prevent the drive circuit unit from failing due to the counter electromotive force.

The invention according to the means C3 is
In the gaming machine described in means C2,
The movable member shall be movable linearly between a predetermined first position (storage position shown in FIG. 16A) and a second position (pushing position shown in FIG. 16B). A gaming machine featuring.

According to the gaming machine having this configuration, when the player mischievously moves the movable member linearly at high speed, a large counter electromotive force may be generated in the driving means. Even in this case, by keeping the control line between the drive means and the drive circuit unit in a non-conducting state, it is possible to prevent a large counter electromotive force from acting on the drive circuit unit.

The invention according to the means C4 is
In the gaming machine according to any one of means C1 to C3,
An effect control capable of driving the drive means by controlling the drive circuit unit based on the establishment of a predetermined effect drive condition (a variable effect pattern for executing a frame sword operation promotion effect is selected). Means (microcomputer 91 for effect control that executes step S310) and
With the drive period setting means (the effect control microcomputer 91 that executes step S606) that sets the drive period (frame sword movable body drive period) capable of driving the drive means based on the establishment of the effect drive condition. , Equipped with
The staging control means
The continuity switching means can be controlled.
When the drive period is set, the continuity switching means is switched so that the control line is in a conductive state (step S702 is executed), while the conduction switching means is switched.
The gaming machine is characterized in that the continuity switching means is switched (execution of step S704) so that the control line is in a non-conducting state when the drive period is not set.

According to the gaming machine having this configuration, the control line is switched to the conduction state by the staging control means while the drive period is set based on the establishment of the staging drive condition. Therefore, the drive circuit unit can control the drive of the drive means to move the movable member. On the other hand, while the drive period is not set, the control line is switched to the non-conducting state by the staging control means. Therefore, it is possible to prevent an excess voltage that exceeds the withstand voltage of the drive circuit unit from acting from the drive means side to the drive circuit unit side. In this way, it is possible to automatically switch between the conductive state and the non-conducting state of the control line as appropriate to prevent an excessive voltage from acting on the drive circuit unit.

The invention according to the means C5 is
In the gaming machine according to any one of means C1 to C4,
A power supply means (power supply board 150) capable of supplying power to the gaming machine is provided.
The continuity switching means is a gaming machine characterized in that the control line is switched to a non-conducting state when the power is not turned on to the gaming machine by the power supply means.

According to the gaming machine having this configuration, the control line is switched to the non-conducting state when the power is not turned on to the gaming machine. Therefore, it is possible to prevent an excess voltage from acting from the drive means side to the drive circuit unit side even when the game is not being played, and it is possible to further enhance the safety of the drive circuit unit.

By the way, in the gaming machine described in Japanese Patent Application Laid-Open No. 2008-272111, if a large electric power (reverse electromotive force, surge based on static electricity, etc.) is generated by the driving means (motor), the large electric power is the driving means (motor). It may act from the side to the drive circuit unit (driver) side. In that case, an unintended excess voltage acts on the drive circuit section, which may cause the drive circuit section to fail. Therefore, the invention according to the above-mentioned means C1 to C5 can switch the control line between the drive means and the drive circuit unit to a conductive state or a non-conducting state for the gaming machine described in Japanese Patent Application Laid-Open No. 2008-272111. It differs in that it is provided with various conduction switching means. This makes it possible to solve the problem of providing a gaming machine capable of preventing a failure of the drive circuit unit (having an effect).

<Means D>
The invention according to means D1 is
In a gaming machine (pachinko gaming machine 1) that controls an advantageous special gaming state based on the establishment of predetermined control conditions.
Movable members (frame sword movable body 221, frame drum 320) and
A driving means (frame sword moving motor 223, frame drum rotating motor 321) capable of applying a driving force for moving the movable member, and
A drive circuit unit (frame sword moving motor driver IC 1, left frame drum motor driver IC 11, right frame drum motor driver IC 21) capable of controlling the drive of the drive means is provided.
The drive circuit unit is a gaming machine characterized by being of a constant current drive system capable of supplying a predetermined constant current (230 mA, 200 mA in this embodiment) to the drive means.

In the driving means (motor), since a counter electromotive force (voltage based on the counter electromotive force) is generated during driving, the effective voltage is not a little reduced. Therefore, the higher the speed of driving by the driving means, the more difficult it is for the current to flow through the driving means, and the more difficult it is for the driving means to generate a desired torque. Therefore, according to the gaming machine having this configuration, the drive circuit unit is of a constant current drive system capable of supplying a predetermined constant current to the drive means. Therefore, even if a counter electromotive voltage is generated, a constant current can be supplied to the driving means, and it is possible to suppress a decrease in torque. Therefore, it is possible to realize high-speed movement of the movable member.

The invention according to means D2 is
In the gaming machine described in means D1,
Switching to a normal state in which the drive circuit unit can supply the constant current to the drive means, or a reduced state in which the drive circuit unit can supply a reduced current smaller than the constant current to the drive means. It is a gaming machine characterized by being provided with possible state switching means (external circuits for inspection 224B, 310A, 320A).

When inspecting the operation of the movable member, it is inspected whether or not the movable member can operate properly even when the torque generated by the driving means is reduced. Here, when the drive circuit unit is of a constant current drive system, even if the voltage acting on the drive circuit unit is lowered, the drive circuit unit supplies a constant current to the drive means. Therefore, the current supplied to the drive means cannot be reduced, and the torque generated by the drive means cannot be reduced. Therefore, according to the gaming machine having this configuration, by providing the state switching means and switching to the lowered state, the drive circuit unit can supply the reduced current smaller than the constant current to the drive means. As a result, it is possible to inspect whether or not the movable member operates properly while the torque generated by the drive means is reduced.

The invention according to means D3 is
In the gaming machine described in means D2,
The state switching means is output from input control signals (K-CHECK1 control signal, K-CHECK2 control signal, signals output from output terminals P08, 09 of input / output IC 12, and output terminals P00, 01 of input / output IC 12. The gaming machine is characterized in that it can be switched to the normal state or the lowered state based on the signal).

According to the gaming machine having this configuration, since it is possible to switch to the normal state or the lowered state by software, the movable member operates appropriately as compared with the case of switching to the normal state or the lowered state by hardware such as a manual switch. It is possible to easily inspect whether or not it is.

The invention according to means D4 is
In the gaming machine according to means D2 or means D3,
The state switching means is
The normal state, or the first reduced state in which the drive circuit unit can supply the first reduced current (15% reduced current) smaller than the constant current to the drive means, or the drive circuit unit. A gaming machine characterized in that it can switch to a second reduced state capable of supplying a second reduced current (current reduced by 20%) smaller than the first reduced current to the drive means. Is.

According to the gaming machine having this configuration, it is possible to inspect whether or not the movable member operates properly in a state where the drive circuit unit supplies the first reduced current to the drive means. Further, it is possible to inspect whether or not the movable member operates properly even in a state where the drive circuit unit supplies the second reduced current to the drive means. Therefore, it is possible to determine whether the movable member operates properly no matter how much the torque generated by the drive means is reduced.

The invention according to means D5 is
In the gaming machine according to any one of means D1 to D4,
The driving means is a gaming machine characterized by being a bipolar type stepping motor in which a current flows in both directions with respect to a coil (coils A and B shown in FIG. 23A).

In the case of a unipolar stepping motor that draws current in one direction for half the windings of one coil, at a certain moment, half of the coils are not functioning. Therefore, the utilization efficiency of the coil is poor. Therefore, according to the gaming machine with this configuration, it is possible to increase the efficiency of coil utilization compared to the unipolar type stepping motor by using a viparara type stepping motor that allows current to flow bidirectionally through the entire coil. Is. As a result, it is possible to increase the torque at low speed rotation.

By the way, in the gaming machine described in JP-A-2007-295970, when the driving means (motor) is driven, a counter electromotive force (voltage based on the counter electromotive force) is generated, so that the effective voltage is not a little. It will decrease. Therefore, the higher the speed of driving by the driving means, the more difficult it is for the current to flow through the driving means, and the more difficult it is for the driving means to generate a desired torque. Therefore, there was room for improvement in moving the movable member at high speed. Therefore, the invention according to the above-mentioned means D1 to D5 is a constant current drive method capable of supplying a predetermined constant current to the drive means for the gaming machine described in Japanese Patent Application Laid-Open No. 2007-295970. It differs in that it is a thing. This makes it possible to solve the problem of providing a gaming machine capable of moving a movable member at high speed (effectively exerting an action effect).

1 ... Pachinko game machine 50 ... Game machine frame 51 ... Outer frame 52 ... Inner frame 53 ... Front frame 91 ... Production control microcomputer 221 ... Frame sword movable body 223 ... Frame sword moving motor 224 ... Frame right relay board 225 ... Frame right upper right Relay board 227 ... Push-in position detection sensor 231 ... Frame sword disk member rotation motor 232 ... Frame sword disk member 310 ... Frame relay board 310B, 320B ... Current reduction external circuit 320 ... Frame drum 321 ... Frame drum rotation motor IC1 ... Frame Sword moving motor driver IC11 ... Left frame drum motor driver IC21 ... Right frame drum motor driver IC31 ... Frame sword disk member Rotating motor driver TR3 ... Transistor

Claims (1)

In a gaming machine that controls an advantageous special gaming state based on the establishment of predetermined control conditions.
Displaceable movable members and
A driving means capable of applying a driving force for displacement of the movable member and a stop holding force for holding the stop of the movable member.
A drive circuit unit that can control the drive means,
A control means capable of controlling the drive circuit unit is provided.
The drive circuit unit can supply the drive means with a predetermined first reduction current or a second reduction current smaller than the first reduction current , while supplying a current smaller than the second reduction current . It is a constant current drive system that is configured to be impossible.
A current reduction circuit is provided between the drive circuit unit and the control means so that the drive circuit unit can supply an ultra-reduction current smaller than the second reduction current to the drive means.
The control means is
When the drive means applies a stop holding force to the movable member, the current reduction circuit can cause the drive circuit unit to supply the ultra-reduction current to the drive means. A game machine to play.

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