JP7118432B2 - game machine - Google Patents

Description

TECHNICAL FIELD The present invention relates to gaming machines typified by pachinko gaming machines and the like.

2. Description of the Related Art Conventionally, a pachinko game machine, which is an example of a game machine, is provided with various light-emitting means such as a frame lamp and a board lamp, as described in Patent Document 1 below. The light emission mode of the light emitting means is controlled based on the light emission data by an effect control microcomputer (light emission control means) capable of controlling the effect. Therefore, for example, the light emitting means emits light in a specific lighting mode based on the light emission data to enhance the presentation effect, or turns off the lighting mode based on the light emission data to suppress the presentation effect.

JP 2015-092893 A

However, the luminescence data is prepared in advance by the designer, and the information contained in the luminescence data is not always correct. That is, it cannot be completely denied that the light emission data may contain erroneous information due to human error. Therefore, when the light emitting means is controlled based on the light emission data, it is possible that the light emitting means does not emit light as intended.

The present invention has been made in view of the above circumstances. That is, the object is to provide a game machine capable of making the light-emitting means intended to emit light.

The gaming machine of the present invention is
a light emitting means capable of emitting light;
A gaming machine comprising light emission control means capable of controlling the light emission mode of the light emission means based on light emission data,
a movable body; and
a specific position detection means capable of detecting that the movable body is at a specific position;
The light emission control means is
a detection signal indicating that the movable body is at the specific position can be input from the specific position detection means;
When the detection signal is not input, the light emission mode of the light emission means can be controlled based on the light emission data. It is a game machine characterized by controlling in a manner .

According to the gaming machine of the present invention, it is possible to make the lighting mode intended for the lighting means.

1 is a perspective view of a game machine according to an embodiment of the present invention; FIG. It is an exploded perspective view of a game machine frame provided in the same game machine. It is a front view of the gaming machine. It is a front view of a game board provided in the gaming machine. (A) is a diagram showing the flow of game balls when the distribution member is in the first state, and (B) is a diagram showing the flow of game balls when the distribution member is in the second state. It is an enlarged view of the A portion shown in FIG. 4, and is a view showing display devices provided in the gaming machine. 5 is a longitudinal sectional view of the game board shown in FIG. 4; FIG. 8 is a perspective view showing the transmissive liquid crystal display device and the rear liquid crystal display device shown in FIG. 7; FIG. FIG. 9 is an exploded perspective view of the transmissive liquid crystal display device shown in FIG. 8; (A) is a diagram in which a daytime background image is displayed on the rear liquid crystal display device while no effect image is displayed on the transmissive liquid crystal display device, and (B) is a diagram in which a darkened image is displayed on the transmissive liquid crystal display device. FIG. 10 is a diagram showing a daytime background image displayed on the rear liquid crystal display device in a state in which the operator is in the position; (A) is a diagram showing a state in which the board movable body is at the initial position, (B) is a diagram showing a state in which the board movable body is in the middle of movement, and (C) is a diagram showing the state in which the board movable body is at the drive position. It is a figure which shows a state. It is a figure which shows the example of production|presentation of this form. It is a figure which shows the example of production|presentation of this form. It is a table|surface which shows the light emission control of a board movable body lamp. It is a block diagram showing the electrical configuration of the game control board side of the gaming machine. It is a block diagram showing the electrical configuration of the effect control board side of the gaming machine. It is a hit classification determination table. It is the table|surface which shows the various random numbers which the microcomputer for game control acquires. (A) is a jackpot determination table, (B) is a ready-to-win determination table, (C) is a normal symbol hit determination table, and (D) is a normal symbol variation pattern selection table. It is a special figure variation pattern determination table. It is an electric chew opening pattern determination table. 4 is a flowchart of main control main processing; 10 is a flowchart of main-side timer interrupt processing; 6 is a flowchart of sensor detection processing; It is a flow chart of gate passage processing. 4 is a flowchart of normal operation processing; 4 is a flowchart of special action processing; It is a flowchart of a special symbol standby process. It is a flowchart of big hit determination processing. It is a flow chart of variation pattern selection processing. It is a flow chart of variation pattern selection processing. It is a flowchart of processing during special symbol fluctuation. It is a flowchart of special design decision processing. It is a flowchart of a game state management process. It is a flowchart of special electric auditors processing (jackpot game). It is a flowchart of a game state setting process. 8 is a flowchart of specific area sensor detection processing; 9 is a flowchart of sub-control main processing; 4 is a flowchart of reception interrupt processing; 10 is a flowchart of 1 ms timer interrupt processing; 6 is a flowchart of lamp data output processing; 4 is a flowchart of drive control processing; 4 is a flowchart of drive control processing; 10 is a flowchart of 10 ms timer interrupt processing; 8 is a flowchart of received command analysis processing; It is a flow chart of the fluctuation effect start processing. It is a table|surface which shows the light emission control of a board movable body lamp in a modification.

1. Configuration of Gaming Machine A pachinko gaming machine, which is 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 a pachinko game machine as an example of the game machine will be explained as being the same as the left-right direction for the player facing the pachinko game machine. Also, the front direction of each part of the pachinko game machine is defined as the direction approaching the player facing the pachinko game machine, and the rear direction of each part of the pachinko game machine is defined as the direction away from the player facing the pachinko game machine.

As shown in FIG. 1, the pachinko game machine PY1 of the embodiment includes a game machine frame 2 and a game board 1 (see FIG. 4) mounted inside the game machine frame 2. As shown in FIG. The game machine frame 2 forms the outer shell of the pachinko game machine PY1, and includes an outer frame 22 arranged outside, an inner frame 21 assembled inside the outer frame 22, the outer frame 22 and the inner frame. 21 is provided with a front door 23 (front frame). The front door 23 has a vertical rectangular shape that protects the game board 1, and as shown in FIG. A transparent glass plate 23t (window) is attached to the central portion of the front door 23 so that the player can visually recognize the game area 6, which will be described later.

As shown in FIG. 3, the front door 23 has a handle 72k (game ball hitting means) for shooting game balls with a shooting intensity corresponding to the rotation angle, and a hitting ball supply tray (upper tray) for storing game balls. 34, and a surplus ball receiving tray (lower tray) 35 for storing game balls that cannot be accommodated in the batted ball supply tray 34 are provided. Further, the front door 23 is provided with an effect button 40k and a select button 42k that can be operated by the player during effects executed as the game progresses. The select button (cross key) 42k is composed of an up button, a down button, a left button, and a right button. Further, the front door 23 is provided with a decorative frame lamp 212 and a speaker (not shown in FIG. 1) for outputting sound.

As shown in FIG. 4, the game board 1 is formed with a game area 6 surrounded by a rail member 62 in which a game ball shot by operating the handle 72k flows down. Also, the game board 1 is provided with a large number of board lamps 54 for decoration. The game board 1 includes a plate-shaped member arranged on the front side, and a back unit arranged on the rear side (various control boards described later, a transmissive liquid crystal display device 7, a rear liquid crystal display device 50, a unit for attaching a harness, etc.). ) are integrated.

A game area 6 is provided with a plurality of game pegs for guiding game balls. In the vicinity of the center of the game area 6, a transmissive liquid crystal display device 7 (display means) and a rear liquid crystal display device 50 are arranged apart from each other in the front-rear direction (see FIG. 8). The transmissive liquid crystal display device 7 will be detailed later. The rear liquid crystal display device 50 is a liquid crystal display device capable of displaying an image, but may be another image display device such as an organic EL display device. On the display screen 50a of the rear liquid crystal display device 50, an effect to perform variable display (variable display) of the effect symbol (decorative symbol) EZ synchronized with the variable display (variable display) of the first special symbol and the second special symbol to be described later. There is a pattern display area. Incidentally, the effect of displaying the effect symbol EZ is called the effect symbol variation effect. The production design fluctuation production is sometimes called "decorative design fluctuation production" or simply "variation production".

The performance symbol display area is composed of, for example, three symbol display areas of "left", "middle" and "right". A left pattern display area displays a left performance pattern EZ1, a middle pattern display area displays a medium performance pattern EZ2, and a right pattern display area displays a right performance pattern EZ3. Each of the effect symbols EZ consists of a plurality of symbols representing numbers "1" to "9", for example. The rear liquid crystal display device 50 displays a first special figure display device 81a and a second special figure display device 81b (see FIG. 6), which will be described later, by a combination of the left performance symbol EZ1, the middle performance symbol EZ2, and the right performance symbol EZ3. To clearly display the result of variable display of a first special symbol and a second special symbol (that is, the result of a jackpot lottery).

For example, when a jackpot is won, the performance symbol EZ is stopped and displayed with double numbers such as "777". In addition, when it is a miss, the performance symbol EZ is stopped and displayed with a loose pattern such as "637". This makes it easier for the player to grasp the progress of the game. That is, the player grasps the result of the jackpot lottery not from the first special figure display device 81a (see FIG. 6) or the second special figure display device 81b, but from the rear liquid crystal display device 50. FIG. The position of the pattern display area may not be fixed. Further, as a form of variable display of the effect symbols, for example, there is a form of scrolling in the vertical direction.

The rear liquid crystal display device 50 displays, in addition to the effect symbol variation effect using the effect symbol EZ as described above, a jackpot effect performed in parallel with the jackpot game, a demo effect for waiting for customers (customer waiting effect), and the like. displayed on the screen 50a. In addition, in the effect symbol variation effect, effect images other than the effect symbol EZ such as a background image and a character image are displayed in addition to the effect symbol EZ such as numbers.

Further, the display screen 50a of the rear liquid crystal display device 50 has a first pending icon display area for displaying a first pending icon HA (effect pending image) according to the number of stored first special figure pending to be described later. By displaying the first pending icon HA, it is possible to clearly show the player the number of stored first special figure pending displayed on the first special symbol pending display 83a (see FIG. 6) which will be described later. In addition, there is a second pending icon display area for displaying a second pending icon HB (effect pending image) according to the number of stored second special figure pending, which will be described later. By displaying the second pending icon HB, it is possible to clearly show the number of stored second special symbol pending displayed on a second special symbol pending display 83b (see FIG. 6) described later to the player.

A center frame 61 (inner wall portion) is arranged near the center of the game area 6 and in front of the rear liquid crystal display device 50 . In the lower portion of the center frame 61, a stage portion 61s is formed which can guide a game ball rolling on the upper surface to the first starting port 11, which will be described later. A warp portion 61w is provided on the left side of the center frame 61 to allow game balls to flow in from the entrance and flow out to the stage portion 61s from the exit. An upper board movable body 55U and a lower board movable body 55D are provided above and below the rear side of the center frame 61 (see FIG. 7). Furthermore, the upper board movable body 55U and the lower board movable body 55D are provided with board movable body lamps 53 capable of emitting light (see FIG. 7). The upper board movable body 55U, the lower board movable body 55D, and the board movable body lamp 53 will be described later in detail.

Below the rear liquid crystal display device 50 in the game area 6, in the center in the left-right direction, there is a first start-up opening 11 (ball entry opening) in which the ease with which a game ball enters is always constant. is provided. The first starting port 11 is also referred to as a first ball-in port, a fixed ball-in port, a first starting prize-winning port, or a first starting region. Further, the first start winning device 11D is also called first ball entry means, fixed ball entry means, or first start prize winning device. Winning of the game ball to the first starting port 11 triggers lottery for the first special symbol (big hit lottery, ie, acquisition and determination of big hit random numbers, etc.).

Also, a big winning device 14D having a big winning opening 14 (special winning opening) is provided on the upper right side of the first start opening 11 in the game area 6 . The big winning device 14D is also called an attacker (AT), a special winning means, or a special variable winning device. The big prize winning device 14D has an AT opening/closing member 14k that takes an open state and a closed state. The AT opening/closing member 14k is driven by a large winning opening solenoid 14s (see FIG. 15). A game ball can enter the big winning opening 14 only when the AT opening/closing member 14k is in an open state. The big winning opening 14 is opened during execution of a jackpot game, which will be described later.

In addition, on the upper right side of the big winning device 14D in the game area 6, there is a second starting winning device (normal electric accessory so-called electric chew) 12D provided with a second starting port 12 that can change the ease with which a game ball enters. is provided. The second starting port 12 is also called a variable entrance port. Also, the electric chew 12D is also referred to as variable ball entry means. The winning of the game ball into the second starting port 12 (entrance) triggers the second special symbol lottery (big hit lottery, ie, acquisition and determination of a big hit random number, etc.). The electric chew 12D is provided with an electric chew opening/closing member 12k (opening/closing member) that is movable (advances and retreats) in the front-rear direction and takes an open state and a closed state. It opens and closes.

The electric tuning opening/closing member 12k (opening/closing member) is driven by an electric tuning solenoid 12s, which will be described later. When the electric chew opening/closing member 12k is in the open state, it is retracted to the rear side, and the game ball can be entered into the second starting port 12.例文帳に追加On the other hand, when the electric chew opening/closing member 12k is in the closed state, it advances to the front side, making it impossible for the game ball to enter the second starting port 12.例文帳に追加In this way, the second starting hole 12 is a starting hole in which the ease with which a game ball enters can be changed. In addition, if the electric chew makes it easier for the ball to enter the second starting port when the electric chew opening and closing member is in the open state than when it is in the closed state, 2 It does not have to be something that makes it impossible to enter the starting hole. Further, the electric chew is not limited to having an opening/closing member that can move (advance and retreat) in the front-rear direction, but may have a rotatable opening/closing member or a left/right moving opening/closing member.

A gate 13 through which a game ball can pass is provided above the electric chew 12D in the game area 6. As shown in FIG. The gate 13 is also called a passage opening or a passage area. Passage of the game ball to the gate 13 is a trigger for execution of a normal symbol lottery (that is, normal symbol random number (hit random number) acquisition and determination) that determines whether or not to open the electric chew 12D. Furthermore, a plurality of general prize winning openings 10 are provided in the lower portion of the game area 6 . Also, at the bottom of the game area 6, an out port 19 is provided for discharging out of the game area 6 game balls that have been hit into the game area 6 but have not won in any of the winning openings.

In the game area 6 in which various winning openings are arranged, there are a left game area 6L (first game area) on the left side of the center in the horizontal direction (first game area) and a right game area 6R (second game area) on the right side. There is. A hitting method of shooting a game ball so that the game ball flows down the left game area 6L is called left hitting. On the other hand, a hitting method of shooting a game ball so that the game ball flows down the right game area 6R is called right hitting. In the pachinko machine PY1 of this embodiment, the flow path through which the game balls flow down when the game is played with the left hand is called the first flow path R1, and the flow path through which the game balls flow down when the game is played with the right hand. , the second flow path R2.

A first starting port 11, a general prize winning port 10, and an out port 19 are arranged on the first flow path R1. A player can aim to win a prize to the first starting opening 11 or the general winning opening 10 by hitting a game ball so as to flow down the first flow path R1. In addition, the gate 13 is not arranged on the first flow path R1. Therefore, the electric chew 12D will not be released when the player is hitting to the left.

On the other hand, on the second flow path R2, there are a gate 13, a second starting port 12 (electric chew 12D), a big winning port 14 (big winning device 14D), a general winning port 10, and an out port 19. are distributed. By hitting the game ball so as to flow down the second flow path R2, the player can aim to pass through the gate 13, or win a prize in the second start opening 12, the big winning opening 14, or the general winning opening 10. can.

Next, based on FIG. 5, the flow of the game ball entering the big winning hole 14 will be described. As shown in FIGS. 5A and 5B, inside the big winning device 14D, a specific area (V area) 16 and a non-specific area 17 through which a game ball that has passed through the big winning opening 14 can pass are formed. ing. In the big winning device 14D, a big winning hole sensor 14a for detecting the winning of a game ball into the big winning hole 14 is arranged upstream of the specific area 16 and the non-specific area 17. FIG. A specific area sensor 16a for detecting passage of a game ball to the specific area 16 is arranged in the specific area 16. As shown in FIG. A non-specific area sensor 17a for detecting passage of a game ball to the non-specific area 17 is arranged in the non-specific area 17. As shown in FIG. The big winning device 14D includes a distribution member 16k that distributes game balls that have passed through the big winning opening 14 to either the specified area 16 or the non-specific area 17, and a distribution solenoid 16s that drives the distribution member 16k (Fig. 5 ( A) (not shown in (B)).

FIG. 5(A) shows when the distribution solenoid 16s is energized. As shown in FIG. 5(A), when the distribution solenoid 16s is energized, the distribution member 16k is in the first state (passage permission state) that allows the game ball to pass through the specific area 16. As shown in FIG. When the sorting member 16k is in the first state, the game ball that has entered the big winning hole 14 passes through the specific area 16 after passing through the big winning hole sensor 14a. The route of this game ball is called a first route.

FIG. 5(B) shows the time when the distribution solenoid 16s is not energized. As shown in FIG. 5(B), when the distribution solenoid 16s is energized, the distribution member 16k is in a second state (passage prevention state) that prevents passage of game balls to the specific region 16. FIG. When the sorting member 16k is in the second state, the game ball that has entered the big winning hole 14 passes through the non-specific area 17 after passing through the big winning hole sensor 14a. This game ball route is called a second route.

In this pachinko game machine PY1, passage of a game ball to the specific area 16 triggers a transition to a high-probability state, which will be described later. That is, the specific area 16 is a probability variable operation opening. On the other hand, the non-specific area 17 is not a probability variable operation opening.

Returning to the description of the game board 1 shown in FIG. As shown in FIG. 4, a display device 8 is arranged in the lower right part of the game board 1. As shown in FIG. In the display devices 8, as shown in FIG. 6, a first special symbol display device 81a that variably displays the first special symbol, a second special symbol display device 81b that variably displays the second special symbol, and a normal symbol. A normal figure display 82 for variably displaying is included. The first special design is also referred to as the first special design or special design 1, the second special design is also referred to as the second special design or special design 2, and the first special design and the second special design are collectively referred to as the "special design ( identification pattern)”. In addition, the normal pattern is also called a general pattern.

In addition, in the display device 8, the first special figure suspension display 83a that displays the number of storage of the operation suspension (first special figure suspension) of the first special figure display 81a, the operation suspension of the second special figure display 81b (Second special figure suspension) 2nd special figure suspension display 83b for displaying the number of memories, and normal figure suspension display 84 for displaying the number of operation suspension (normal figure suspension) of the normal figure display 82 is

The variable display of the first special symbol is performed with the winning of the game ball to the first starting port 11 as a trigger. The variable display of the second special symbol is performed with the winning of the game ball to the second starting port 12 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 (special symbol). Moreover, the 1st special figure indicator 81a and the 2nd special figure indicator 81b may be generically called the special figure indicator 81. As shown in FIG. Also, the first special figure reservation display 83a and the second special figure reservation display 83b may be collectively referred to as the special figure reservation display 83. In addition, the first special figure reservation and the second special figure reservation may be collectively referred to as special figure reservation.

In the special figure display device 81, the special symbols are variably displayed (variable display) and then stopped, so that a lottery (special symbol lottery, jackpot lottery) based on the winning of the first start port 11 or the second start port 12 is performed. Notify the results. A special symbol to be stopped and displayed (a stop symbol, a 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. When the stop pattern is a predetermined jackpot pattern (special pattern of a specific stop mode), the big prize opening 14 is opened in an opening pattern corresponding to the type of the stopped jackpot pattern (that is, the type of jackpot won). A jackpot game (an example of a special game) to open is performed. The opening pattern of the big winning opening 14 in the big winning game will be described later.

Specifically, the special figure indicator 81 is composed of, for example, eight LEDs (Light Emitting Diodes) arranged side by side. to display. For example, if you win a jackpot (one of the multiple types of jackpots described later), ``○○●●○○●●'' (○: lights up, ●: lights out) 1, 2, from the left A jackpot pattern in which the fifth and sixth LEDs are lit is displayed. In addition, if the game is lost, a lost pattern is displayed in which only the rightmost LED lights up, such as "●●●●●●●○". A mode in which all the LEDs are extinguished may be adopted as the lost pattern. In addition, the lost design is not a specific special design. In addition, before the special symbols are stopped and displayed, the special symbols are variably displayed for a predetermined variable time. It is a mode. It should be noted that the variable display mode may be anything, such as blinking all the LEDs all at once, unless each LED is stopped (lighted up in a specific mode).

In this pachinko game machine PY1, when there is a winning (entering a ball) of a game ball into the first start port 11 or the second start port 12, the value of various random numbers such as jackpot random numbers (numerical information , determination information) is temporarily stored in the special figure reservation storage unit 105 described later. Specifically, if the winning to the first start port 11 is stored as the first special figure reservation, it is stored in the first special figure reservation storage unit 105a described later, and if the winning to the second start opening 12 is the second special It is stored in the later-described second special figure suspension storage unit 105b as figure suspension. There is an upper limit to the number of special figure reservations that can be stored in each special figure reservation storage unit 105, and the upper limit value in this embodiment is "4".

The special figure reservation stored in the special figure reservation storage unit 105 is terminated when the variable display of the special symbol based on the special figure reservation becomes possible. Digestion of the special figure reservation means to determine the jackpot random number or the like corresponding to the special figure reservation, and to execute the variable display of the special symbol for showing the determination result. Therefore, in the pachinko game machine PY1, when the variable display of the special symbols based on the winning of the game ball to the first starting port 11 or the second starting port 12 cannot be performed immediately after the winning, that is, during the execution of the jackpot game Even if there is a prize, the right of the jackpot lottery for the prize can be reserved up to a predetermined number as the upper limit.

The number of special figure reservations is displayed on the special figure reservation indicator 83. Specifically, each special figure reservation indicator 83 is composed of, for example, four LEDs, and displays the number of special figure reservations by lighting the LEDs by the number of special figure reservations.

The variable display of normal symbols is performed with the passage of the game ball to the gate 13 as a trigger. The normal symbol display device 82 notifies the result of the normal symbol lottery based on the passage of the game ball to the gate 13 by displaying the normal symbol variably (variably displaying) and then stop-displaying it. A normal pattern to be stopped and displayed (a normal pattern stop pattern, a normal pattern derived and displayed as a display result of variable display) is one normal pattern selected from a plurality of types of normal patterns by a normal pattern lottery. When the stop-displayed normal symbol is a predetermined specific normal symbol (a normal symbol in a predetermined stop mode, that is, a normal winning symbol), the second starting port 12 is opened in an opening pattern according to the current game state. Auxiliary game is played to make it possible. The opening pattern of the second starting port 12 will be described later.

Specifically, the normal symbol display 82 is composed of, for example, two LEDs (see FIG. 6), and displays normal symbols according to the result of the normal symbol lottery according to the lighting mode thereof. For example, if the lottery result is a win, a normal win pattern with both LEDs lit up is displayed, such as "○○" (○: lit, ●: unlit). When the lottery result is a loss, a normal losing pattern is displayed, such as "●○", in which only the right LED lights up. A mode in which all the LEDs are extinguished may be employed as a normal losing pattern. It should be noted that the normal losing design is not a specific normal design. Before the normal symbols are stopped and displayed, the normal symbols are variably displayed for a predetermined variable time. It should be noted that the variable display mode may be anything, such as blinking all the LEDs all at once, unless each LED is stopped (lighted up in a specific mode).

In the pachinko game machine PY1, when a game ball passes through the gate 13, the value of the normal symbol random number (hit random number) acquired for the passage is stored in the normal pattern reservation storage unit 106 described later as normal pattern reservation. memorized once. There is an upper limit to the number of normal pattern reservations that can be stored in the general pattern reservation storage unit 106, and the upper limit value in this embodiment is "4".

The normal pattern reservation stored in the normal pattern reservation storage unit 106 is terminated when the variable display of the normal pattern based on the normal pattern reservation becomes possible. The digestion of the normal pattern reservation means that the normal design random number (hit random number) corresponding to the normal pattern reservation is determined, and the normal design variable display is performed to show the determination result. Therefore, in this pachinko game machine PY1, when the variable display of the normal symbols based on the passage of the game ball through the gate 13 cannot be performed immediately after the passage, that is, during the execution of the variable display of the normal symbols or during the execution of the auxiliary game, a prize is won. Even if there is, with a predetermined number as the upper limit, it is possible to reserve the right of the normal symbol lottery for the passage.

And the number of such normal map reservations is displayed on the normal map reservation display 84 . Specifically, the normal map hold indicator 84 is composed of, for example, four LEDs, and displays the number of normal map reserves by lighting the LEDs by the number of normal map reserves.

Here, FIG. 7 is a longitudinal sectional view of the game board 1. As shown in FIG. As shown in FIG. 7, this pachinko game machine PY1 is characterized in that the transmissive liquid crystal display device 7 (image display means) stands vertically in front of the rear liquid crystal display device 50 . That is, as shown in FIG. 8, the transmissive liquid crystal display device 7 and the rear liquid crystal display device 50 are spaced apart in the front-rear direction and arranged in parallel.

In the rear liquid crystal display device 50, similarly to the liquid crystal display device of the conventional pachinko game machine, a variable effect accompanied by variable display and stop display of the effect symbol EZ is executed, or a customer waiting effect is executed. . On the other hand, in the transmissive liquid crystal display device 7, basically nothing is displayed, and the rear side of the transmissive liquid crystal display device is visible. Therefore, the player is made to be conscious of the presence of the transmissive liquid crystal display device 7 as little as possible, and is made to pay attention to the performance on the rear liquid crystal display device 50 behind the transmissive liquid crystal display device 7.例文帳に追加However, the display screen 7 a of the transmissive liquid crystal display device 7 also appropriately displays the effect image according to the effect (effect image, etc.) executed on the rear liquid crystal display device 50 . As a result, the game player can be presented with a new performance image that has not existed in the past by showing the performance on the rear liquid crystal display device 50 while newly showing the performance image in front of the performance. It is possible.

As shown in FIG. 7, an upper panel movable body 55U and a lower panel movable body 55D are arranged between the transmissive liquid crystal display device 7 and the rear liquid crystal display device 50 in the front-rear direction. FIG. 7 shows the positions of the upper board movable body 55U and the lower board movable body 55D in the normal state (initial state). In the normal state, the upper board movable body 55U is arranged above the display screen 7a of the transmissive liquid crystal display device 7 and does not overlap the display screen 7a in the front-rear direction. The lower board movable body 55D is arranged below the display screen 7a of the transmissive liquid crystal display device 7 and does not overlap the display screen 7a in the front-rear direction. The positions when the upper board movable body 55U and the lower board movable body 55D are in the normal state (see FIG. 7) are called "initial positions". When the upper board movable body 55U and the lower board movable body 55D are collectively described, they will be referred to as "board movable body 55 (movable body)".

Further, as shown in FIG. 7, a lower decorative member 61x is arranged below the transmissive liquid crystal display device 7 and immediately behind the transmissive liquid crystal display device 7. As shown in FIG. That is, the lower decorative member 61x (see FIG. 4) is arranged between the transmissive liquid crystal display device 7 and the rear liquid crystal display device 50 in the front-rear direction. Therefore, when an effect image is displayed on the display screen 50a of the rear liquid crystal display device 50, the effect image does not appear to overlap the front side of the lower decorative member 61x (see FIG. 10A). On the other hand, when an effect image is displayed on the display screen 7a of the transmissive liquid crystal display device 7, the effect image may appear to be superimposed on the front side of the lower decorative member 61x (FIG. 10B). reference). As a result, it is possible to surprise the player who thinks that the performance image will not overlap the lower decorative member 61x.

As shown in FIG. 8, the transmissive liquid crystal display 7 is larger than the rear liquid crystal display 50 . Specifically, the display screen 7a of the transmissive liquid crystal display device 7 is 19 inches, while the display screen 50a of the rear liquid crystal display device 50 is 17 inches. When viewed from the player's side (when the transmissive liquid crystal display device 7 is viewed while facing the transmissive liquid crystal display device 7), the frame edges (upper edge, lower edge, left edge) of the display screen 7a of the transmissive liquid crystal display device 7 10 (A ) (B)). That is, the display screen 7a of the transmissive liquid crystal display device 7 has an outer display area 7x located outside the display screen 50a of the rear liquid crystal display device 50. FIG.

Therefore, for example, when the player is conscious of the display screen 50a of the rear liquid crystal display device 50, the effect image is displayed on the display screen 7a of the transmissive liquid crystal display device 7 including the outer display area 7x (FIG. 10). (B)). As a result, the effect image appears to the player outside the display screen 50 a of the rear liquid crystal display device 50 . Therefore, it is possible to show the effect image at an unexpected position to the player, thereby providing a novel game interest.

Next, the structure of the transmissive liquid crystal display device 7 will be described with reference to FIG. The transmissive liquid crystal display device 7 is a display device that can switch between a state in which the rear side of the display screen 7a can be visually recognized and a state in which the rear side of the display screen 7a cannot be visually recognized or is difficult to be visually recognized. As shown in FIG. 9, the transmissive liquid crystal display device 7 mainly includes a frame frame 700, an upper structural portion 710, a lower structural portion 720, a left structural portion 730, a right structural portion 740, and a light guide plate 750. , a liquid crystal panel 760 , a transmissive film 770 , and a protection panel 780 .

The frame frame 700 constitutes the outline of the transmissive liquid crystal display device 7, and has an upper surface portion 701 on the upper side, a lower surface portion 702 on the lower side, a left surface portion 703 on the left side, and a right side portion 703 on the right side. It has a face portion 704 and a front face portion 705 on the front side. The upper surface portion 701 and the lower surface portion 702 are symmetrical in the vertical direction, and each has a rectangular shape. The left surface portion 703 and the right surface portion 704 are symmetrical and each has a rectangular shape. The front part 705 has a rectangular frame shape, and the liquid crystal panel 760 faces forward through a central opening.

The upper structural portion 710 is assembled to the inner side (lower surface side) of the upper surface portion 701 of the frame 700 . The upper structural section 710 includes an upper control board 711, an upper heat sink 712, and an upper assembly cover 713, as shown in FIG. An upper heat sink 712 is placed above the upper control board 711, and an upper assembly cover 713 is attached to the upper control board 711 and the upper heat sink 712 from below. It is integrated with the upper assembly cover 713 .

The upper control board 711 performs image control on the liquid crystal panel 760 and controls light emission of each LED. The upper control board 711 has a large number of upper display LEDs 714 mounted along the left-right direction on the edge on the front end side. Each of the upper display LEDs 714 emits display light downward toward the upper surface of the peripheral surface of the light guide plate 750 . Therefore, the upper control board 711 controls the lighting and extinguishing of the upper display LED 714 to switch between a state in which display light from the upper display LED 714 is supplied to the upper surface of the light guide plate 750 and a state in which it is not supplied. is possible.

Further, the upper control board 711 has a large number of upper accessory lights 715 mounted in the left-right direction behind the upper display LEDs 714 . The upper accessory light 715 emits illumination light downward. Therefore, the upper control board 711 controls the lighting and extinguishing of the upper accessory light 715 to switch between a state in which the upper accessory light 715 illuminates the board movable body 55 and the like and a state in which the upper accessory light 715 does not illuminate it. It is possible to switch.

The upper heat sink 712 is for releasing heat generated by lighting of the upper display LED 714 or the upper accessory light 715, and is made of aluminum or an aluminum alloy. Heat generated by lighting the upper display LED 714 or the upper accessory light 715 is transmitted to the upper heat sink 712 and the upper surface portion 701 of the frame 700 and cooled by the air above the upper surface portion 701 .

The lower structural portion 720 is assembled inside (upper surface side) of the lower surface portion 702 of the frame 700 . The lower structural section 720 includes a lower control board 721, a lower heat sink 722, and a lower assembly cover 723, as shown in FIG. A large number of lower display LEDs 724 and a large number of lower accessory lights 725 are mounted on the lower control board 721 along the horizontal direction. Since the structures of the lower structural part 720 and the upper structural part 710 are vertically symmetrical and similar, detailed description thereof will be omitted.

The left structural portion 730 is assembled to the inner side (right side) of the left side portion 703 of the frame 700 . The left structure section 730 includes a left control board 731, a left heat sink 732, and a left assembly cover 733, as shown in FIG. By placing the left heat sink 732 on the left side of the left control board 731 and assembling the left assembly cover 733 from the right side to the left control board 731 and the left heat sink 732, the left control board 731 and the left heat sink are assembled. 732 and the left assembly cover 733 are integrated.

The left control board 731 has a large number of left display LEDs 734 mounted along the vertical direction on the front edge. Each of the left display LEDs 734 emits display light rightward toward the left surface of the peripheral surface of the light guide plate 750 . Therefore, the left control board 731 controls the lighting and extinguishing of the left display LED 734 to switch between a state in which display light from the left display LED 734 is supplied to the left surface of the light guide plate 750 and a state in which it is not supplied. is possible.

Further, the left control board 731 has a large number of left accessory lights 735 mounted in the vertical direction behind the left display LEDs 734 . The left accessory light 735 emits illumination light rightward. Therefore, the left control board 731 controls the lighting and extinguishing of the left accessory light 735 to switch between a state in which the left accessory light 735 illuminates the board movable body 55 and the like and a state in which the left accessory light 735 does not illuminate it. It is possible to switch.

The left heat sink 732 is for releasing heat generated by lighting of the left display LED 734 or the left accessory light 735, and is made of aluminum or an aluminum alloy. A plurality of leftwardly extending fins (not shown) are formed on the left heat sink 732 in order to improve cooling performance. The heat generated by lighting the left display LED 734 or the left accessory light 735 is transmitted to the left heat sink 732 and the left surface portion 703 of the frame 700, and is cooled by the air on the left side of the left surface portion 703. .

The right side structural portion 740 is attached to the inside (left side) of the right side portion 704 of the frame 700 . The right structural section 740 includes a right control board 741, a right heat sink 742, and a right assembly cover 743, as shown in FIG. A large number of right display LEDs 744 and a large number of right accessory lights 745 are mounted in the vertical direction on the right control board 741 . Since the structures of the right structural portion 740 and the left structural portion 730 are bilaterally symmetrical and similar, detailed description thereof will be omitted.

The light guide plate 750 is made of a transparent synthetic resin plate that allows light to pass therethrough, and has a rectangular shape. The light guide plate 750 receives display light from display LEDs (not shown) through its peripheral surfaces (upper surface, lower surface, left surface, and right surface). The incident display light is internally reflected and emitted from the front surface 751 . The rear surface of the light guide plate 750 is formed with an uneven rough surface (not shown) for reflecting display light forward.

As shown in FIG. 9 , a transmissive film 770 is arranged in front of the light guide plate 750 and a liquid crystal panel 760 is arranged in front of the transmissive film 770 . Therefore, when the display LED is turned on, display light is emitted from the front surface 751 of the light guide plate 750 as surface light emission. Display light emitted from the front surface 751 of the light guide plate 750 can be supplied to the liquid crystal panel 760 through the transmission film 770 . Note that the display LEDs and the light guide plate 750 are collectively called a "backlight".

Liquid crystal panel 760 has a large number of pixels arranged in a matrix, and controls the transmittance of each pixel. Accordingly, the liquid crystal panel 760 can display an image on the front surface (the display screen 7a) by transmitting display light from the backlight forward. That is, when display light from the backlight is supplied to each pixel of the liquid crystal panel 760, an image displayed on the display screen 7a can be viewed from the front. The liquid crystal panel 760 is in the form of a rectangular thin plate and is arranged on the rear side of the front portion 705 of the frame 700 . The front surface of the liquid crystal panel 760 is the display screen 7a of the transmissive liquid crystal display device 7 described above.

The transparent film 770 (transparency switching means) can be switched between a transparent state (first state) in which the rear is visible and a non-transmissive state (second state) in which the rear is invisible. As shown in , it is in the form of a rectangular thin plate. This transmissive film 770 is interposed between the liquid crystal panel 760 and the light guide plate 750 and connected to the upper control board 711 via two flexible printed circuit boards (FPC) 775 . Therefore, the upper control board 711 can switch the transmission state and the non-transmission state of the transmission film 770 by applying a voltage to the transmission film 770 via the flexible printed circuit board 775 .

Thus, if the transmissive film 770 is in a non-transmissive state, it is not possible to visually recognize the rear (rear liquid crystal display device 50) of the display screen 7a (transmissive film 770). This will draw the player's attention to the effect image displayed in 7a. On the other hand, if the transmissive film 770 is in the transmissive state, the rear side of the display screen 7a can be visually recognized, and the effect image mainly displayed on the display screen 50a of the rear liquid crystal display device 50 and the movement of the board can be seen. The attention is directed to the body 55 and the like. Although the non-transmissive state is defined as a state in which the rear side of the transmissive film 770 is completely invisible, it may be a state in which the rearward side is slightly visible.

As shown in FIG. 9, the protective panel 780 is arranged behind the transmissive film 770 and protects the transmissive film 770, the light guide plate 750, and the liquid crystal panel 760 against the external force from behind the transmissive liquid crystal display device 7. It protects. The protective panel 780 is made of a transparent synthetic resin plate that allows light to pass through, and has a rectangular shape.

Next, based on FIGS. 10A and 10B, the difference between the case where the effect image is not displayed on the transmissive liquid crystal display device 7 and the case where the effect image is displayed will be described. FIG. 10A shows a state in which no effect image is displayed on the display screen 7a of the transmissive liquid crystal display device 7 (the entire display area of the display screen 7a). In this state, since the transmissive film 770 is in the transmissive state, the area behind the transmissive film 770 (behind the transmissive liquid crystal display device 7) is visible. Here, in FIG. 10A, the display screen 50a of the rear liquid crystal display device 50 displays the daytime background image H1 showing the daytime background, and the variable effect is executed. In this manner, the player is basically made to pay attention to the effect image executed on the display screen 50 a of the rear liquid crystal display device 50 .

Next, FIG. 10B shows a state in which a black image BL is displayed on the display screen 7a of the transmissive liquid crystal display device 7, and a part of the black image BL is cut out in a circular shape. A notch portion BLa is provided. 10A, the transmissive film 770 is in the transmissive state, and the daytime background image H1 is displayed on the display screen 50a of the rear liquid crystal display device 50. FIG. Therefore, a part of the daytime background image H1 (the part showing the sun) displayed on the display screen 50a of the rear liquid crystal display device 50 can be visually recognized through the cutout portion BLa of the black image BL. .

As described above, in the present embodiment, even if the transmissive liquid crystal display device 7 is arranged in front of the rear liquid crystal display device 50 as shown in FIG. 8, the player sees the rear liquid crystal display device as shown in FIG. It is possible to show an effect image displayed at 50 or to show an effect image displayed by the transmissive liquid crystal display device 7 as shown in FIG. 10(B). Furthermore, as shown in FIG. 10B, it is possible to show a part of the effect image displayed on the rear liquid crystal display device 50 while also showing the effect image displayed on the transmissive liquid crystal display device 7 .

In this embodiment, as shown in FIG. 8, the display screen 7a of the transmissive liquid crystal display device 7 arranged in front is larger than the display screen 50a of the rear liquid crystal display device 50 arranged in the rear. As described above, basically, no effect image is displayed on the display screen 7a of the transmissive liquid crystal display device 7 (see FIG. 10A). attention is drawn to the effect image displayed on the display screen 50a. Then, by suddenly displaying the effect image on the display screen 7a of the transmissive liquid crystal display device 7, the effect image is enlarged for the player whose consciousness is directed toward the display screen 7a of the rear liquid crystal display device 50. And it is possible to make it look as if it is approaching.

In addition, in the case of a player who is playing the pachinko game machine PY1 for the first time or a player who does not know the existence of the transmissive liquid crystal display device 7, generally, the display screen 50a of the rear liquid crystal display device 50 is displayed outside the display screen 50a. I don't think the image will show up. Therefore, a black image BL is displayed on the display screen 7a of the transmissive liquid crystal display device 7, as shown in FIG. 10B, for example. That is, of the display area of the display screen 7a of the transmissive liquid crystal display device 7, the effect image is displayed in the outer display area 7x that does not overlap the display area of the display screen 50a of the rear liquid crystal display device 50 in the front-rear direction. As a result, it seems to the player that the effect image is displayed outside the display screen 50a of the rear liquid crystal display device 50. - 特許庁As a result, the effect image can be shown at a position unexpected for the player, and it is possible to provide a novel game interest.

2. Movable Board Appearance Effect Next, the appearance effect of the movable board body will be described. The board movable body appearance production is a production for showing the appearance of the board movable body 55 to the player. Here, based on FIG. 11, the position of the board movable body 55 will be described. FIG. 11 shows a state in which the upper board movable body 55U and the lower board movable body 55D are at their initial positions (standby position, specific position). As shown in FIG. 11, the upper board movable body 55U and the lower board movable body 55D are arranged outside the display screen 7a of the transmissive liquid crystal display device 7 when they are at their initial positions. Therefore, as shown in FIG. 4, the upper board movable body 55U and the lower board movable body 55D at the initial position are hidden behind the game area 6 (the plate-shaped member of the game board 1). The upper board movable body 55U and the lower board movable body 55D at the initial position cannot be visually recognized.

Although not shown, the game board 1 is provided with an upper initial position detection sensor 55Ua capable of detecting that the upper board movable body 55U is at the initial position (see FIG. 16). The upper initial position detection sensor 55Ua (specific position detection means) is composed of a photosensor, and detects when the upper board movable body 55U at the initial position blocks the light from the light receiving section. Although not shown, the game board 1 is provided with a lower initial position detection sensor 55Da capable of detecting that the lower board movable body 55D is in the initial position (see FIG. 16). The lower initial position detection sensor 55Da (specific position detection means) is composed of a photosensor, and detects when light from the light receiving section is blocked by the lower board movable body 55D at the initial position.

Although not shown, the game board 1 is provided with an upper board movable body moving motor 55Um capable of generating a driving force for moving the upper board movable body 55U. Therefore, when the upper board movable body moving motor 55Um is rotationally driven in a predetermined forward direction, it moves the upper board movable body 55U downward from the initial position shown in FIG. 11(A) as shown in FIG. 11(B). It is possible. Although not shown, the game board 1 is provided with a lower board movable body moving motor 55Dm capable of generating a driving force for moving the lower board movable body 55D. Therefore, when the lower board movable body moving motor 55Dm is rotationally driven in a predetermined positive direction, the lower board movable body 55D is moved upward from the initial position shown in FIG. 11(A) to as shown in FIG. 11(B). It can be moved.

Here, FIG. 11(C) shows a position where the upper board movable body 55U has finished moving downward. The position shown in FIG. 11(C) of the upper board movable body 55U is called a "driving position". FIG. 11(C) also shows a position where the lower board movable body 55D has finished moving upward. The position shown in FIG. 11(C) of the lower board movable body 55D will be called the "driving position". When the upper panel movable body 55U and the lower panel movable body 55D are at the drive position (operating position) shown in FIG. 7 overlaps the display screen 7a in the front-rear direction. Therefore, when the transmissive film 770 of the transmissive liquid crystal display device 7 is in the transmissive state, the player can visually recognize the board movable body 55 (upper board movable body 55U, lower board movable body 55D) in the drive position.

Further, the upper board movable body 55U and the lower board movable body 55D come into contact with each other when they are in the drive position. The front side of the upper board movable body 55U is in the form of the upper half of the face of the main character of the pachinko gaming machine PY1, and the front side of the lower board movable body 55D is the main character of the pachinko gaming machine PY1. It is in the form of the lower half of the character's face. Therefore, when the upper board movable body 55U and the lower board movable body 55D respectively move to the drive positions, the main character's face (specific motif) is completed. Therefore, as shown in FIG. 11(C), when the upper board movable body 55U and the lower board movable body 55D are in the drive position and the transparent film 770 is in the transparent state, the player can see the completed main character. You can show your face.

When the upper board movable body 55U rotates in a predetermined reverse direction from the drive position shown in FIG. 11C, the upper board movable body moving motor 55Um moves the upper board movable body 55U to ) toward the initial position shown in FIG. 11A. The lower board movable body moving motor 55Dm rotates the lower board movable body 55D from the driving position shown in FIG. It is possible to move downward from the drive position shown in (C) to the initial position shown in FIG. 11 (A). Also, as shown in FIG. 11A, when the upper board movable body 55U and the lower board movable body 55D are at their initial positions, the main character's face is not complete.

By the way, most of the conventional movable board bodies are arranged in front of the display means (image display device). This is because if the movable board body were arranged behind the display means, the movable board body would be hidden by the display means, and the player would not be able to see the movable board body. In addition, when the movable board is placed in front of the display means as in the conventional case, there is a case where the driving effect is executed in which the movable board moves from a position where it cannot be seen to a position overlapping the central portion of the display means. be. However, in the case of this driving effect, the player can see the movement of the board movable body from a position where it cannot be seen to a position overlapping the central portion of the display means. That is, from the moment the board movable body starts to move, the player will be aware of the existence of the board movable body. Therefore, the effect of making the board movable body appear did not have a strong impact.

Therefore, in the board movable body appearance effect of this embodiment, it is configured as follows. Here, the board movable body appearance effect is to move the board movable body 55 (upper board movable body 55U, lower board movable body 55D) from the initial position shown in FIG. 11(A) to the drive position shown in FIG. 11(C). It is an effect until it is moved and the player visually recognizes the board movable body 55 at the driving position.

Therefore, when the board movable body appearance effect is started, the board movable body 55 is at the initial position shown in FIG. 11(A). At this time, since the board movable body 55 is arranged outside the display screen 7a of the transmissive liquid crystal display device 7, the player cannot visually recognize the board movable body 55 at the initial position. Furthermore, at this time, the transmissive film 770 is controlled to a non-transmissive state. As a result, the rear side of the display screen 7a of the transmissive liquid crystal display device 7 is prevented from being visually recognized. In this embodiment, when the movable board appearance effect is started as described later, a battle victory image WI (a specific effect image, see FIG. 13B) is displayed on the display screen 7a of the transmissive liquid crystal display device 7. Display is started.

Then, while the transmissive film 770 is in the non-transmissive state, as shown in FIG. 11B, the upper panel movable body 55U is moved downward from the initial position (see FIG. 11A). The side plate movable body 55D is moved upward from the initial position (see FIG. 11(A)). At this time, since the area behind the display screen 7a of the transmissive liquid crystal display device 7 cannot be visually recognized, the player cannot visually recognize the moving board movable body 55 behind the display screen 7a. In this way, it is possible to prevent the player from grasping the existence of the board movable body 55 by not visually recognizing the board movable body 55 during movement.

In particular, in this embodiment, as will be described later, before the transmissive film 770 is controlled to the transmissive state in the production of the appearance of the movable board, a battle victory image WI (see FIG. 13B) is displayed on the display screen 7a of the transmissive liquid crystal display device 7. ) is displayed. As a result, the player is directed to the battle victory image WI displayed on the display screen 7a so as not to notice the existence of the board movable body 55 behind the display screen 7a. .

Then, as shown in FIG. 11C, after the plate movable body 55 moves to the drive position, the transparent film is switched from the non-transmissive state to the transparent state. Thereby, the rear side of the display screen 7a of the transmissive liquid crystal display device 7 becomes visible. Also, at this timing, the battle victory image WI displayed on the display screen 7a of the transmissive liquid crystal display device 7 is hidden. That is, nothing is displayed on the display screen 7a of the transmissive liquid crystal display device 7 except for the effect pattern EZ (see FIG. 13(C)). As a result, the back of the display screen 7a of the transmissive liquid crystal display device 7 can be easily seen, and the player's consciousness can be directed toward the back of the display screen 7a. Thus, as shown in FIG. 13(C), it is possible for the player to see as if the board movable body 55 in the driving position suddenly appeared. It is possible to give a strong impact.

Then, as shown in FIG. 11C, when the board movable body 55 is at the driving position, the upper board movable body 55U and the lower board movable body 55D are in contact with each other, and the main character of the pachinko game machine PY1. face is formed (completed). This makes it possible for the player to see the three-dimensional face of the main character suddenly appear as a structure after the battle victory image WI, thereby providing novel game amusement.

Next, based on FIG.13 and FIG.14, the example of the production|presentation of this form is demonstrated. First, as shown in FIG. 13A, on the display screen 50a of the rear liquid crystal display device 50, a daytime background image H1 representing a daytime background is displayed, and the effect symbol EZ is displayed in a variable manner. At this time, no effect image is displayed on the display screen 7a of the transmissive liquid crystal display device 7, and the transmissive film 770 is controlled to be in a transmissive state. Therefore, the player can visually recognize the effect image (daytime background image H1, effect pattern EZ) displayed on the display screen 50a of the rear liquid crystal display device 50 through the transparent film 770 (transmissive liquid crystal display device 7). be. In this way, basically, the player is made to pay attention to the variable effect executed on the display screen 50a of the rear liquid crystal display device 50, and the transmissive liquid crystal display device 7 is not made to be conscious. In this rendering example, the transmissive film 770 is controlled to the transmissive state also in the states shown in FIGS. 12B to 12D and 13A, which will be described later.

Next, the production pattern EZ is stopped at "4↓4" to enter the ready-to-win state, and as shown in FIG. . Specifically, the display screen 50a of the rear liquid crystal display device 50 displays an armor summoning image YS1 indicating that the main character is summoning armor. After the SP reach development effect suggesting effect is executed, the left effect symbol EZ1 indicating "4" is displayed small (inconspicuously) at the upper left part of the display screen 50a, and the right effect indicating "4" is displayed. A symbol EZ3 is stopped and displayed small (inconspicuously) at the upper right portion of the display screen 50a.

Subsequently, as shown in FIG. 12(C), an SP ready-to-win development rendering is executed to suggest that the game has developed into an SP ready-to-win. Specifically, the display screen 50a of the rear liquid crystal display device 50 displays a main character appearance image SK1 indicating that the main character has transformed into the main character of the pachinko gaming machine PY1. After that, the SP reach is started, and on the display screen 50a of the rear liquid crystal display device 50, an effect image corresponding to the SP reach is appropriately displayed.

Next, as shown in FIG. 12(D), on the display screen 50a of the rear liquid crystal display device 50, the SP reach battle effect is started. Specifically, the display screen 50a of the rear liquid crystal display device 50 displays a battle start image BK1 showing the characters "Destroy the enemy character!" Subsequently, an effect image showing a battle between the main character (protagonist character) and the enemy character is appropriately displayed.

Then, as shown in FIG. 13A, a winning/losing branch image SB1 is displayed on the display screen 50a of the rear liquid crystal display device 50 to indicate whether or not the main character can defeat the enemy character. As a result, the player is made to pay attention to the outcome of the subsequent performance. Here, when the winning/losing split image SB1 is displayed, the upper board movable body 55U and the lower board movable body 55D are at their initial positions and arranged outside the display screen 50a of the rear liquid crystal display device 50. there is Therefore, the player does not see the upper board movable body 55U and the lower board movable body 55D at the initial position.

After that, the board movable body appearance effect is started. Specifically, first, as shown in FIG. 13B, the display screen 7a of the transmissive liquid crystal display device 7 displays a battle victory image WI indicating that the main character has defeated the enemy character. That is, the battle victory image WI is not displayed on the display screen 50 a of the rear liquid crystal display device 50 . Then, the transmissive film 770 is switched from the transmissive state to the non-transmissive state at the timing when the display of the battle victory image WI is started. As a result, the rear side of the transmissive liquid crystal display device 7 cannot be visually recognized. Therefore, after the transmissive film 770 is switched to the non-transmissive state, the upper board movable body 55U and the lower board movable body 55D each move from the initial position toward the drive position. Therefore, the player is made to pay attention to the battle victory image WI displayed on the display screen 7a of the transmissive liquid crystal display device 7 without seeing the board movable body 55 moving behind the transmissive liquid crystal display device 7.例文帳に追加is possible.

Then, as shown in FIG. 13C, after the upper board movable body 55U and the lower board movable body 55D move to the driving positions, the transmission film 770 is switched from the non-transmission state to the transmission state. Also, the battle victory image WI displayed on the display screen 7a of the transmissive liquid crystal display device 7 disappears at the timing when the transmissive film 770 is switched to the transmissive state. As a result, nothing is displayed on the display screen 7a except for the left effect symbol EZ1 indicating "4" and the right effect symbol EZ3 indicating "4". Thus, it is possible for the player to view a wide area behind the display screen 7a of the transmissive liquid crystal display device 7 and see the board movable body 55 at the driving position. Therefore, it is possible to give a strong impact that the face of the main character, which is a three-dimensional structure, suddenly appears immediately after the battle victory image WI.

After the movable board appearance effect is completed, as shown in FIG. 13(D), the display screen 7a of the transmissive liquid crystal display device 7 stops and displays the effect symbol EZ "444" in a large winning manner. Also, the transmissive film 770 is switched from the transmissive state to the non-transmissive state in accordance with the timing when the stop display of the effect pattern EZ is started. As a result, the back of the transmission liquid crystal display device 7 becomes invisible while the performance pattern EZ is stopped and displayed in the jackpot mode. Therefore, while the performance symbol EZ is stopped and displayed in the jackpot mode, the upper board movable body 55U and the lower board movable body 55D move from the drive position to the standby position. As a result, the player can be made to pay attention to the big win mode production pattern EZ displayed on the display screen 7a without seeing the board movable body 55 moving to the retracted position behind the transmissive liquid crystal display device 7.例文帳に追加be.

3. Light Emission Control of Movable Board Lamp Next, light emission control of the movable board lamp 53 will be described. As shown in FIG. 11(C), the board movable body lamp 53 is arranged corresponding to the eyes of the main character's face in the upper board movable body 55U. Further, the board movable body lamp 53 is arranged corresponding to the mouth portion of the main character's face in the lower board movable body 55D, as shown in FIG. 11(C). When the movable board 55 (upper board movable body 55U, lower board movable body 55D) is at the driving position (see FIG. 13C), the board movable body lamp 53 emits light. is controlled to be Therefore, when the movable board body 55 suddenly appears behind the transmissive liquid crystal display device 7 by the appearance effect of the movable board body, the movable board lamp 53 emits light. As a result, the main character suddenly appears with his eyes and mouth shining, which enhances the effect of the appearance of the board movable body.

On the other hand, the movable board lamp 53 is turned off (non-light emitting mode, specific light emitting mode) when the movable board 55 (upper board movable body 55U, lower board movable body 55D) is not at the drive position. controlled. This is based on the following reasons. This is because power consumption is wasted if the movable board lamp 53 continues to emit light until the movable board 55 is not required to be seen. That is, in recent pachinko game machines, a large number of motors, LEDs, and the like are mounted, so the load on the power supply board 190 is extremely large. Therefore, in order to reduce the load on the power supply board 190 as much as possible, the board movable body lamp 53 is controlled to be extinguished except when the board movable body 55 is shown to the player in the board movable body driving presentation.

Furthermore, if the movable board body 55 emits light even when it is unnecessary to show the movable board body 55, the existence of the movable board body 55 will be easily noticed. In other words, as shown in FIG. 13B, if the movable board lamp 53 were to emit light even though the movable board 55 was moving behind the transmissive liquid crystal display device 7 so that it could not be seen, This is because the effect of making the board movable body 55 suddenly appear in the board movable body appearance effect becomes meaningless.

By the way, light emitting means such as lamps are generally controlled based on lamp data. The lamp data includes information such as when to emit light, in what color to emit light, at what luminance to emit light, and when to turn off the light. In this embodiment, the effect control microcomputer 121 outputs lamp data to the sub-drive board 162 when controlling the light emission mode of the lamp. Thereby, the sub-drive board 162 controls the lighting mode of the lamp based on the input lamp data.

However, the lamp data is created (prepared) in advance by the design developer, and may contain incorrect information due to human error. For example, in light emission control of the movable board lamp 53, as described above, when the movable board 55 is not at the drive position, the light must be turned off. However, the movable board lamp data (light emission data) for controlling the light emission mode of the movable board lamp 53 may not accurately include information on the movement timing of the movable board 55 . In this case, for example, even though the movable board body 55 is at the initial position, the movable board body 55 emits light, resulting in wasted power consumption and the intended effect of the appearance of the movable board body. I can't.

Therefore, in this embodiment, light emission control is performed as shown in FIG. 14 so that the design developer can reliably control the board movable body lamp 53 as intended. That is, when at least one of the upper initial position detection sensor 55Ua and the lower initial position detection sensor 55Da is OFF, the movable board lamp 53 normally emits light in a lighting mode based on the movable board lamp data. Let Specifically, when performing light emission control of the movable board lamp 53, if at least one of the upper board movable body 55U and the lower board movable body 55D is not at the initial position, the board movable body lamp 53 The light is emitted or extinguished based on the information contained in the lamp data.

On the other hand, when both the upper initial position detection sensor 55Ua and the lower initial position detection sensor 55Da are ON, the board movable body lamp 53 is forcibly turned off. Specifically, when both the upper board movable body 55U and the lower board movable body 55D are at the initial position, the effect control microcomputer 121 outputs board movable body lamp data (board movable body unlit lamp data ) to the sub-drive board 162 . As a result, the sub-drive board 162, to which the board movable body extinguishing lamp data is input, is always turned off as long as the board movable body 55 (upper board movable body 55U, lower board movable body 55D) is in the initial position. Control.

As a result, even if the movable board lamp data contains erroneous information due to human error, the movable board lamp 53 does not emit light when the movable board 55 is at the initial position. It is possible to prevent In this way, it is possible to prevent wasteful power consumption by always turning off the board lamp 54 based on the detections of the upper initial position detection sensor 55Ua and the lower initial position detection sensor 55Da. Furthermore, when the board movable body 55 is at the initial position, the board movable body lamp 53 provided on the board movable body 55 erroneously emits light, and the board movable body appearance presentation cannot exhibit the intended effect. It is possible to prevent the situation.

4. Electrical Configuration of Gaming Machine Next, the electrical configuration of the pachinko gaming machine PY1 will be described with reference to FIGS. 15 and 16. FIG. As shown in FIGS. 15 and 16, the pachinko game machine PY1 includes a game control board 100 (main control board) for controlling game profits such as jackpot lottery and game state transitions, It has an effect control board 120 (sub control board) for control, a payout control board 170 for controlling payout of game balls, and the like. The game control board 100 constitutes a main control section, and the effect control board 120 constitutes a sub-control section together with an image control board 140, an audio control board 161, and a sub-drive board 162, which will be described later.

The sub-control unit includes at least the effect control board 120, and the effect means (transmissive liquid crystal display device 7, rear liquid crystal display device 50, board movable body lamp 53, board lamp 54, board movable body 55 (upper board movable body 55U , lower panel movable body 55D), frame lamp 212, speaker 610, etc.) can be controlled.

The pachinko game machine PY1 also has a power board 190. As shown in FIG. The power board 190 supplies power to the game control board 100, the performance control board 120, and the payout control board 170, and supplies necessary power to other devices through these boards. A backup power supply circuit 192 is provided on the power supply board 190 . The backup power supply circuit 192, when power is not supplied to the pachinko gaming machine PY1, for a game RAM (Random Access Memory) 104 of the game control board 100 and a performance RAM 124 of the performance control board 120, which will be described later. to supply power. Therefore, the information stored in the game RAM 104 of the game control board 100 and the performance RAM 124 of the performance control board 120 is retained even when the pachinko game machine PY1 is powered off. A power switch 191 is connected to the power board 190 . ON/OFF operation of the power switch 191 switches on/off of the power supply. In addition, a backup power supply circuit for the game RAM 104 of the game control board 100 may be provided in the game control board 100 or a backup power supply circuit for the effect RAM 124 of the effect control board 120 may be provided in the effect control board 120 .

As shown in FIG. 15, the game control board 100 is mounted with a game control one-chip microcomputer (hereinafter referred to as "game control microcomputer") 101 for controlling the progress of the game of the pachinko game machine PY1 according to a program. A game control microcomputer (game control means) 101 includes a game ROM (Read Only Memory) 103 that stores a program for controlling the progress of a game, a game RAM 104 that is used as a work memory, and a game ROM 103. A game CPU (Central Processing Unit) 102 for executing stored programs and a game I/O (Input/Output) port 118 for inputting and outputting data and signals are included. The game RAM 104 is provided with the above-described special figure suspension storage unit 105 (first special figure suspension storage unit 105a and second special figure suspension storage unit 105b) and normal figure suspension storage unit 106 . Note that the game ROM 103 may be externally attached.

Various sensors and solenoids are connected to the game control board 100 via the relay board 110 . Therefore, a signal is input from each sensor to the game control board 100, and a signal is output from the game control board 100 to each solenoid. Specifically, the sensors include a first starting opening sensor 11a, a second starting opening sensor 12a, a gate sensor 13a, a big winning opening sensor 14a, a general winning opening sensor 10a, a specific area sensor 16a, and a non-specific area sensor 17a. is connected.

The first starting hole sensor 11 a is provided in the first starting hole 11 and detects a game ball that has entered the first starting hole 11 . The second starting hole sensor 12 a is provided in the second starting hole 12 and detects a game ball that has entered the second starting hole 12 . The gate sensor 13 a is provided inside the gate 13 and detects a game ball that has passed through the gate 13 . The big winning hole sensor 14 a is provided in the big winning hole 14 and detects a game ball that has won the big winning hole 14 . The general winning hole sensor 10 a is provided in each general winning hole 10 and detects a game ball that has won the general winning hole 10 . The specific area sensor 16 a is provided within the specific area 16 and detects a game ball passing through the specific area 16 . The non-specific area sensor 17 a is provided within the non-specific area 17 and detects a game ball passing through the non-specific area 17 .

As the solenoids, an electric tuning solenoid 12s and a big winning opening solenoid 14s are connected. The electric chew solenoid 12s drives the electric chew opening/closing member 12k of the electric chew 12D. The big winning opening solenoid 14s drives the AT opening/closing member 14k of the big winning device 14D. The distribution solenoid 16s drives the distribution member 16k of the big winning device 14D.

Furthermore, the game control board 100 includes a special figure indicator 81 (first special figure indicator 81a and second special figure indicator 81b), a general figure indicator 82, a special figure reservation indicator 83 (first special figure reservation display Device 83a and second special figure reservation indicator 83b), and general figure reservation indicator 84 are connected. That is, display control of these display devices 8 is performed by the game control microcomputer 101 .

The game control board 100 also transmits various commands and signals to the payout control board 170 and receives signals from the payout control board 170 for payout monitoring. The payout control board 170 includes a card unit CU (which is installed adjacent to the pachinko game machine PY1 and enables ball lending based on information such as an inserted prepaid card) and a prize ball payout device 73. , and a launcher 72 is connected via a launch control circuit 175 . Launcher 72 includes a handle 72k (see FIG. 1).

The payout control board 170 drives the prize ball motor 73m of the prize ball payout device 73 based on the signal from the game control microcomputer 101 and the signal from the card unit CU connected to the pachinko game machine PY1 to release the prize balls. or pay out rental balls. The prize balls to be paid out are detected by the prize ball sensor 73 a for counting, and a detection signal by the prize ball sensor 73 a is output to the payout control board 170 .

When the player operates the handle 72k (see FIG. 1) of the shooting device 72, the touch switch 72a detects contact with the handle 72k, and the shooting volume 72b detects the amount of rotation of the handle 72k. Then, the shooting solenoid 72s is driven so that the game ball is shot with an intensity corresponding to the magnitude of the detection signal of the shooting volume 72b. In this pachinko game machine PY1, one game ball is shot in about 0.6 seconds.

The game control board 100 also transmits various commands to the effect control board 120 . The connection between the game control board 100 and the effect control board 120 is a unidirectional communication connection that allows only transmission of signals from the game control board 100 to the effect control board 120 . That is, between the game control board 100 and the effect control board 120, a unidirectional circuit (for example, a circuit using a diode) is interposed as communication direction control means (not shown).

As shown in FIG. 16, the effect control board 120 is mounted with a one-chip microcomputer for effect control (hereinafter "effect control microcomputer") 121 for controlling the effect of the pachinko game machine PY1 according to a program. The production control microcomputer (production control means) 121 includes a production ROM 123 that stores a program for controlling production as the game progresses, a production RAM 124 that is used as a work memory, and a production ROM 123 that stores programs. It includes an effect CPU 122 for executing a program, and an effect I/O port 138 for inputting and outputting data and signals. Note that the performance ROM 123 may be externally attached.

Further, as shown in FIG. 16, the effect control board 120 is connected with an image control board 140, an audio control board 161 (audio control circuit), and a sub-drive board 162. FIG. The sub-drive board 162 includes a movable board lamp 53, a board lamp 54, a frame lamp 212, an upper board movable body moving motor 55Um (upper board movable body 55U), a lower board movable body moving motor 55Dm (lower board movable body 55D) are connected.

The effect control microcomputer 121 of the effect control board 120 causes the image CPU 141 of the image control board 140 to control the rear liquid crystal display device 50 and the transmissive liquid crystal display device 7 based on the command received from the game control board 100 . The image control board 140 includes an image ROM 142 storing programs for controlling image display and the like, an image RAM 143 used as a work memory, and an image CPU 141 for executing the programs stored in the image ROM 142. I have. The image ROM 142 stores still image data and moving image data to be displayed on the rear liquid crystal display device 50 and the transmissive liquid crystal display device 7, specifically characters, items, graphics, characters, numbers, symbols, etc. ) and image data such as background images are stored.

Also, the effect control microcomputer 121 outputs sounds, music, sound effects, etc. from the speaker 610 via the sound control board 161 based on commands received from the game control board 100 . Acoustic data such as voice output from the speaker 610 is stored in the performance ROM 123 of the performance control board 120 . A CPU may be mounted on the audio control board 161, and in that case, the CPU may be caused to execute audio control. Furthermore, in this case, a ROM may be mounted on the audio control board 161, and acoustic data may be stored in the ROM. Alternatively, the speaker 610 may be connected to the image control board 140 to cause the image CPU 141 of the image control board 140 to perform audio control. Furthermore, in this case, the sound data may be stored in the image ROM 142 of the image control board 140 .

In addition, the production control microcomputer 121 performs lighting control of lamps such as the frame lamp 212, the board lamp 54, the board movable body lamp 53, etc. via the sub-drive board 162 based on the command received from the game control board 100. Specifically, the production control microcomputer 121 creates lamp data (data for deciding on/off, emission color, etc., also referred to as emission pattern data) that determines the emission mode of each lamp (LED), and creates each lamp according to the emission pattern data. (LED) light emission control. In addition, the data stored in ROM123 for production|presentation of the production|presentation control board 120 is used for preparation of lamp data.

Furthermore, the production control microcomputer 121, based on the command received from the game control board 100, via the sub-drive board 162 upper board movable body moving motor 55Um (upper board movable body 55U), lower board movable body moving motor 55Dm (Lower board movable body 55D) drive control. Specifically, the effect control microcomputer 121 creates operation pattern data (also referred to as drive data) that determines the operation mode of the board movable body 55, and according to the drive data, the upper board movable body moving motor 55Um and the lower board movable body movement motor 55Um. Drive control of the motor 55Dm is performed. The data stored in ROM123 for production|presentation of the production|presentation control board 120 is used for preparation of drive data.

In addition, the effect control board 120 includes a effect button detection sensor 40a, a select button detection sensor 42a, an upper initial position detection sensor 55Ua, an upper drive position detection sensor 55Ub, a lower initial position detection sensor 55Da, and a lower drive position detection sensor 55Db. It is connected. The performance button detection sensor 40a detects that the performance button 40k (see FIG. 1) has been pressed. When the effect button 40k is pressed down, a detection signal is output to the effect control board 120 from the effect button detection sensor 40a. The select button detection sensor 42a detects that the select button 42k (see FIG. 1) has been pressed. When the select button 42k is pressed down, a detection signal is output to the effect control board 120 from the select button detection sensor 42a.

As described above, the upper initial position detection sensor 55Ua detects that the upper board movable body 55U is at the initial position. When the upper board movable body 55U moves to the initial position, a detection signal (signal indicating ON state) is output to the effect control board 120 from the upper initial position detection sensor 55Ua. The upper drive position detection sensor 55Ub detects that the upper board movable body 55U is at the drive position. When the upper board movable body 55U moves to the drive position, a detection signal (signal indicating ON state) is output to the effect control board 120 from the upper drive position detection sensor 55Ub. The lower initial position detection sensor 55Da detects that the lower board movable body 55D is at the initial position. When the lower board movable body 55D moves to the initial position, a detection signal (signal indicating ON state) is output to the effect control board 120 from the lower initial position detection sensor 55Da. The lower drive position detection sensor 55Db detects that the lower board movable body 55D is at the drive position. When the lower board movable body 55D moves to the drive position, a detection signal (signal indicating ON state) is output to the effect control board 120 from the lower drive position detection sensor 55Db.

15 and 16 are functional block diagrams for explaining the electrical configuration of the pachinko game machine PY1, and the boards shown in FIGS. 15 and 16 are not the only ones provided. Except for the game control board 100, any one or more boards shown in FIG. 15 or FIG. 16 may be configured as one board, or one board shown in FIG. 15 or FIG. good.

5. Explanation of Jackpots, etc. In the pachinko game machine PY1 of this embodiment, the results of the jackpot lottery (special symbol lottery) include "jackpot (jackpot winning)" and "losing". At the time of the "big win", the special figure display 81 stops displaying the "big win pattern". When it is "losing", the "losing pattern" is stop-displayed on the special figure display 81. - 特許庁

When a jackpot is won in the special pattern lottery, a "jackpot game" is executed to open the jackpot 14 in an opening pattern corresponding to the type of the stopped and displayed jackpot pattern (jackpot type). In this form, the jackpot game includes multiple round games (unit open games), the opening (also referred to as OP) before the first round game starts, and the ending after the final round game ends. (also referred to as ED). Each round game starts 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 big winning hole between round games is included in the open round game before closing.

As shown in FIG. 17, there are a plurality of types of jackpots (jackpot symbols). In this embodiment, there are roughly two types. They are "variable jackpot" and "normal jackpot". A "probable variable jackpot" is a jackpot that operates the AT opening/closing member 14k in a passage opening pattern (V long opening pattern) that allows the game ball to easily pass through the specific area 16 during the jackpot game. A "normal jackpot" is a jackpot that actuates the AT opening/closing member 14k in a non-passing open pattern (V-short open pattern) that makes it impossible or difficult for the game ball to pass through the specific area 16 during the jackpot game.

In the pachinko game machine PY1 of this embodiment, based on the passage of the game ball to the specific area 16 during the jackpot game, the game state after the jackpot game ends is shifted to the high probability state described later. Therefore, when the variable probability jackpot is won, the gaming state after the jackpot game can be shifted to a high probability state by passing the game ball through the specific area 16 during execution of the jackpot game. On the other hand, when the normal jackpot is won, the game ball cannot pass through the specific area 16 during the execution of the jackpot game, so the game state after the jackpot game is the normal probability state ( non-high-probability state). It should be noted that even if the "probability variable jackpot" is won, if the game ball does not pass through the specific area 16 during execution of the jackpot game, the normal probability state is entered.

Even if any jackpot is won, the game state after the jackpot game is controlled to a time-saving state, which will be described later. In addition, when the time saving state is controlled, the number of time saving times is set to 160 times or 100 times. The time-saving number of times is the upper limit execution number of times of variable display of special symbols in the time-saving state.

Here, the game state of the pachinko game machine PY1 is roughly divided into three game states. Normal probability state and non-time-saving state (hereinafter also referred to as “low-probability non-time-saving state”), high probability state and time-saving state (hereinafter also referred to as “high-probability non-time-saving state”), normal probability state and time-saving state (hereinafter “low (Also called "short time state"). In addition, in the initial setting, it is in a low-probability short-time state (normal game state).

There are two types of jackpots (jackpot symbols stopped and displayed on the first special symbol display 81a) that can be won in the lottery of the first special symbol (special symbol 1). Specifically, there is a “variable probability jackpot (1, 2 probability probability jackpot)” or “normal jackpot”.

As shown in FIG. 17, the "probability variable jackpot 1" is a 10R (round) jackpot, and is a jackpot that opens the big prize opening 14 for a maximum of 29.5 seconds per 1R. In this embodiment, the operation of the distribution member 16k (see FIG. 5(A)) is controlled so as to facilitate passage (V winning) to the specific area 16 in the big winning opening 14 on the ninth R. The operation of the distribution member 16k (see FIG. 5(B)) is controlled so that the V prize cannot be won except for the ninth round.

In the present embodiment, when "probability variable jackpot 1" is won and V prize is won, the game state after the jackpot game is controlled to a high-probability time-saving state. At this time, the number of times of time saving is set to 160 times. Also, the number of STs is set to 160 times. The number of times of ST is the upper limit execution number of times of variable display of special symbols in a high probability state. However, as an irregular case, in the case of non-V winning, the game state after the jackpot game is controlled to a low-probability time-saving state. It should be noted that when the "probability variation jackpot 1" is won, the "special figure 1_probability variation pattern" is stopped and displayed on the first special figure display device 81a.

Further, as shown in FIG. 17, the "normal jackpot" is a 16R (round) jackpot, and is a jackpot in which the big prize opening 14 is opened for a maximum of 29.5 seconds per 1R. In the ninth round of the normal jackpot, the opening timing of the big winning opening 14 and the operation timing of the distribution member 16k (second state (see FIG. 5(B)) are controlled to the first state (see FIG. 5(A)). timing), it is almost impossible for the game ball to pass through the specific area 16.例文帳に追加However, as an irregular case, in the case of V winning, the game state after the jackpot game is controlled to a highly reliable time-saving state. When the "normal jackpot" is won, the "special figure 1_normal symbol" is stopped and displayed on the first special figure display device 81a.

Subsequently, a description will be given of the types of jackpots (jackpot symbols stopped and displayed on the second special symbol display 81b) that can be won in the lottery of the second special symbol (special symbol 2). There is only one kind of jackpot that can be won in the special drawing 2 lottery. Specifically, it is only "probability variable jackpot 2". That is, the jackpot won in the lottery of the special figure 2 becomes a jackpot in which the game ball can easily pass through the specific area 16 during the jackpot game.

As shown in FIG. 17, the "probable variable jackpot 2" is a 10R jackpot, and is a jackpot in which the big prize opening 14 is opened for a maximum of 29.5 seconds per 1R. As described above, at the ninth R, the operation of the distribution member 16k (see FIG. 5(A)) is controlled so as to facilitate passage to the specific area 16 (V winning) in the big winning opening 14. . In this form, if the "probability variable jackpot 2" is won and the V prize is won, the number of times of time saving is set to 160 times. Also, the number of STs is set to 160 times. However, as an irregular case, in the case of non-V winning, the game state after the jackpot game is controlled to a low-probability time-saving state. It should be noted that when the "probability variation jackpot 2" is won, the "special figure 2_probability variation pattern" is stop-displayed on the second special figure display device 81b.

In the present embodiment, the opening pattern when winning a jackpot is as shown in FIG. That is, first, the opening is performed for 4.0 seconds. After that, a round game is executed in which the AT opening/closing member 14k is opened as described above. Finally, the ending is executed for 1.5 seconds.

Also, as shown in FIG. 17, in the allocation rate of each jackpot in the lottery of the special figure 1, while the probability variable jackpot 1 is 35%, the normal jackpot is 65%. Also, in the jackpot in the lottery of special figure 2, the probability variable jackpot 2 is 100% as described above. It should be noted that the big winning opening 14 may be opened a plurality of times during one round of the jackpot game.

Here, in the pachinko game machine PY1, the lottery to determine whether a big win is made is based on the ``random number for the jackpot'', and the lottery for the winning type is based on the ``random number for the winning type''. As shown in FIG. 18(A), the jackpot random number takes a value in the range of 0-65535. As shown in FIG. 18B, the winning type random number takes a value in the range of 0-99. In addition to the jackpot random number and the winning type random number, the random numbers obtained based on the winning of the first start port 11 or the second start port 12 include "reach random numbers" and "fluctuation pattern random numbers".

The ready-to-win random number is a random number that determines whether or not to generate a ready-to-win in the effect symbol variation effect indicating the result when the result of the big hit determination is a loss. The ready-to-win state is a state in which only one performance symbol EZ that is variably displayed among a plurality of performance symbols EZ remains, and it depends on which symbol the variably displayed performance symbol EZ is stopped and displayed. It is a state (for example, the state of "7↓7") which is a combination of the performance symbols EZ indicating the jackpot winning. The effect symbol EZ that is stopped and displayed in the ready-to-win state may be displayed as if it is slightly swaying within the display screen 50a, or may be displayed so as to repeat enlargement and reduction. This reach random number takes a value in the range of 0-127.

In addition, the fluctuation pattern random number is a random number for determining the fluctuation pattern including the fluctuation time of the special symbol. The fluctuation pattern random number takes a value in the range of 0-99. Random numbers acquired based on passing through the gate 13 include normal symbol random numbers (hit random numbers) shown in FIG. 18(B). The normal symbol random number is a random number for a lottery (normal symbol lottery) for determining whether or not to perform an auxiliary game for opening the electric chew 12D. The normal symbol random number takes a value in the range from 0 to 65535.

6. Explanation of Game State Next, the game state of the pachinko game machine PY1 of this embodiment will be explained. The special figure indicator 81 and the normal figure indicator 82 of the pachinko game machine PY1 respectively have a probability variation function and a variation time shortening function. The state in which the probability variation function of the special figure indicator 81 is operating is called "high probability state", and the state in which it is not operating is called "normal probability state (non-high probability state, low 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. 19A). That is, when the probability variation function of the special figure indicator 81 is activated, the probability that the display result of the variable display of the special symbol by the special figure indicator 81 (that is, the stop symbol) is a jackpot symbol is higher than when it is not activated. becomes higher.

Moreover, the state in which the variable time reduction function of the special figure indicator 81 is operating is called "time saving state", and the state in which it is not operating is called "non-working time saving state". In the time saving state, the fluctuation time of the special symbol (the time from the start of the fluctuation display to the time of derivation display of the display result) is shorter than in the non-working time saving state. That is, the variation pattern is determined using the special figure variation pattern table defined so that the variation pattern with a short variation time is selected more than the non-time saving state (see FIG. 20). That is, when the variable time shortening function of the special figure display 81 operates, it becomes easy to select a short variable time as the variable display of the special symbol compared to when it is not operating. As a result, in the time-saving state, the pace of digestion of the special figure reservation is accelerated, and an effective winning to the starting opening (a winning that can be stored as a special figure reservation) is likely to occur. Therefore, it is possible to aim for winning a big prize under the smooth progress of the game.

The probability variation function and the variation time reduction function of the special figure indicator 81 may operate simultaneously, or only one of them may operate. Then, the probability variation function and the variation time shortening function of the normal figure indicator 82 are designed to operate in synchronization with the variation time shortening function of the special figure indicator 81 . That is, the probability fluctuation function and the fluctuation time reduction function of the normal figure display 82 operate|moves in a time saving state, and do not operate|move in a 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 value of the normal design random number (hit random number) determined to be a hit is determined using a normal design hit determination table that is larger than the normal design hit determination table used in the non-time saving state, and the hit determination (normal design determination) is performed ( See FIG. 19(C)). That is, when the probability variation 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 is a normal winning symbol is higher than when it is not activated. .

In addition, in the time saving state, the fluctuation time of the normal pattern is shorter than in the non-working time saving state. In the present embodiment, as shown in FIG. 19(D), the fluctuation time of the normal design is 30 seconds in the non-time saving state even if the result of the lottery of the normal design is either hit or lost, It is 1 second in the short time state. Incidentally, the stop time of the normal design is set to 8 ms (not shown) in the time saving state, and is set to 500 ms (not shown) in the non working time saving state.

Furthermore, in the time saving state, the opening time of the electric chew 12D in the auxiliary game is longer than in the non-time saving state. That is, the opening time extension function of the electric chew 12D is operating. Specifically, as shown in FIG. 21, in the non-time saving state, the electric chew 12D is opened only for 0.2 seconds, while in the time saving state, the electric chew 12D is opened only for 2.0 seconds.

In addition, in the time-saving state, the number of times the electric chew 12D is opened in the auxiliary game is greater than in the non-time-saving state (see FIG. 21). That is, the function of increasing the number of openings of the electric chew 12D is activated. Specifically, as shown in FIG. 21, in the non-time saving state, the electric chew 12D is opened only once, while in the time saving state, the electric chew 12D is opened three times. In the time saving state, the interval time from the closing of the electric chew 12D to the next opening is set to 1.0 second.

When the probability variation function and variation time reduction function of the normal map display 82 and the opening time extension function and opening frequency increase function of the electric chew 12D are operating, compared to when these functions are not operating As a result, the electric chew 12D is frequently opened, making it easier for the game ball to enter the second starting port 12.例文帳に追加Therefore, the state in which these functions are activated is called the "easy entry state", and the state in which they are not activated is called the "non-entry easy state". It should be noted that the easy-ball-entering state is a state in which so-called electric support control (control for supporting winning to the second starting port 12 by the electric chew 12D) is being executed. Therefore, the easy ball entry state is also referred to as an electric sapo control state or a high base state. On the other hand, the non-entering easy state is also referred to as a non-electric support control state or a low base state.

In the easy ball entry state (high base state), not all of the above functions may operate. That is, one or more of the probability variation function of the normal map display device 82, the variation time shortening function of the normal map display device 82, the opening time extension function of the electric chew 12D, and the opening number increasing function of the electric chew 12D It is sufficient that the activation facilitates the opening of the electric tube 12D more than when the function is not activated. Also, the easy-ball-entry state may be independently controlled without accompanying the time-saving state.

In the pachinko gaming machine PY1 of this embodiment, when it is controlled to a high probability state after a jackpot game, the high probability state is a predetermined number of times (160 times in this embodiment) of variable display of special symbols, or The game ends when a big win is won and the big win game is executed. That is, in the present embodiment, the number of STs is set to 160 when the state is shifted to the high probability state.

When the pachinko game machine PY1 is played for the first time, the game state after the power is turned on is the normal probability state, the non-time saving state, and the low base state. This game state is particularly referred to as a "low probability low base state". The low probability low base state is referred to as "normal game state". Also, the state during execution of the special game (jackpot game) is referred to as "special game state (jackpot game state)". Further, a state in which at least one of the high probability state and the high base state is controlled will be referred to as a "privilege game state".

In a high base state such as a high probability high base state or a low probability high base state, it is possible to advance the game more advantageously by entering the game ball into the right game area 6R (see FIG. 4) by hitting to the right. This is because it is easier to open the electric chew 12D than in the low base state due to the electric sapo control, and it is easier to win the second start opening 12 than to win the first start opening 11. . Therefore, the game ball is passed to the gate 13 which triggers the normal symbol lottery, and the game ball is hit to the right to win the game ball to the second starting port 12.例文帳に追加As a result, it is possible to obtain a larger number of starting prizes (winning at the starting opening) than when hitting left. In addition, in this pachinko game machine PY1, the game is played by hitting to the right even during the jackpot game.

On the other hand, in the low base state, the game can be played more advantageously by entering the game ball into the left game area 6L (see FIG. 4) by hitting to the left. Since the electric sapo control is not executed, it is difficult to open the electric chew 12D compared to the high base state, and it is easier to win the first starting port 11 than winning the second starting port 12. It is because Therefore, left-handed hitting is performed in order to make the game ball enter the first starting port 11.例文帳に追加This allows you to get more starting prizes than hitting right.

7. Operation of Game Control Microcomputer 101 [Main Control Main Processing] Next, the operation of the game control microcomputer 101 will be described with reference to FIGS. Note that counters, timers, flags, statuses, buffers, etc. appearing in the explanation of the operation of the game control microcomputer 101 are provided in the game RAM 104 . The game control microcomputer 101 provided on the game control board 100 reads and executes the main control main processing program shown in FIG. 22 from the game ROM 103 when the pachinko game machine PY1 is powered on. As shown in the figure, in the main control main process, initial setting is first performed (step S001). In the initial settings, for example, stack setting, constant setting, interrupt time setting, game CPU 102 setting, SIO, PIO, CTC (circuit for managing interrupt time) setting, various flags, status and counters, etc. reset, etc. The initial value of the flag is "0" or "OFF", the initial value of the status is "1", and the initial value of the counter is "0". Note that the initial setting (S001) is executed only once after the power is turned on, and is not executed thereafter.

After the initial setting (S001), interrupts are prohibited (S002), and the normal design/special design main random number update process (S003) is executed. In this normal symbol/special symbol main random number update process (S003), various random number counter values shown in FIG. 18 are updated by adding one. When each random number counter value reaches the upper limit, it returns to "0" and is added again. The initial value of each random number counter may be a value other than "0", or may be changed randomly. Also, each random number may be a so-called hardware random number generated using a known random number generation circuit such as a counter IC.

When the normal design/special design main random number update process (S003) ends, the interrupt is permitted (S004). While interrupts are enabled, it is possible to execute main-side timer interrupt processing (S005). The main-side timer interrupt processing (S005) is executed based on an interrupt pulse that is repeatedly input to the game CPU 102 at a cycle of, for example, 4 msec. That is, it is executed, for example, at a 4 msec cycle. And, after the main side timer interrupt processing (S005) is completed, before the next main side timer interrupt processing (S005) is started, various counters by normal design / special design main random number update processing (S003) Value update processing is repeatedly executed. If an interrupt pulse is input to the game CPU 102 in the interrupt disabled state, the main timer interrupt processing (S005) is not started immediately, but is started after the interrupt is permitted (S004).

[Main Side Timer Interrupt Processing] Next, the main side timer interrupt processing (S005) will be described. As shown in FIG. 23, in the main side timer interrupt process (S005), first, the output process (S101) is executed. In the output process (S101), commands set in an output buffer provided in the game RAM 104 of the game control board 100 in each process described below are output to the effect control board 120, the payout control board 170, and the like.

In the input process (S102) that follows the output process (S101), various sensors (first start sensor 11a, second start sensor 12a, gate sensor 13a, big prize A detection signal detected by the mouth sensor 14a, general prize winning mouth sensor 10a, etc. (see FIG. 15) is read and stored (set) in the output buffer of the game RAM 104 as winning ball information. Also, a detection signal from the lower tray full switch for detecting the fullness of the lower tray 35 is taken in and stored in the output buffer of the game RAM 104 as lower tray full data.

The normal design/special design main random number update process (S103) performed next is the same as the normal design/special design main random number update process (S003) performed in the main control main process of FIG. That is, the update processing of various random number counter values (including the normal symbol random number counter value) shown in FIG. ) until the start of the next main-side timer interrupt process (S005)).

After normal symbol/special symbol main random number update process (S103), sensor detection process (S104), normal operation process (S105), special operation process (S106), specific area sensor detection process (S107) are executed. Thereafter, other processing (S108) is executed, and the main side timer interrupt processing (S005) ends. As other processing (S108), based on the number of special-figure 2 reserved balls described later, the second special-figure reservation display 83b is controlled to a display mode indicating the number, or based on the number of special-figure 1 reserved balls described later. It controls the display mode which shows the number of the 1st special figure reservation indicator 83a. Then, the processing of steps S002 to S004 of the main control main processing is repeatedly executed until the next interrupt pulse is input to the game CPU 102 (see FIG. 22), and when the interrupt pulse is input (after about 4 msec), The main side timer interrupt processing (S005) is executed again. In the output processing (S101) of the main-side timer interrupt processing (S005) executed again, the commands set in the output buffer of the game RAM 104 in the previous main-side timer interrupt processing (S005) are output.

[Sensor detection process] As shown in FIG. 24, in the sensor detection process (S104), first, it is determined whether or not the game ball has passed through the gate 13, that is, whether or not the game ball has been detected by the gate sensor 13a ( S201). If the game ball has passed through the gate 13 (YES in S201), a gate passage process, which will be described later, is performed (S202). On the other hand, if the game ball has not passed through the gate 13 (NO in S201), the process skips the gate passing process (S202) and proceeds to step S203.

In step S203, it is determined whether or not a game ball has entered the second start hole 12, that is, whether or not a game ball has been detected by the second start hole sensor 12a (S203). When the game ball has not won the second start port 12 (NO in S203), the process proceeds to step S207, but when the game ball has won the second start port 12 (YES in S203), the special figure 2 Whether the number of pending balls (the number of second special pending, specifically the number of the counter that counts the number of second special pending provided in the game RAM 104) has reached "4" (upper limit storage number) (S204). Then, if the number of special 2 pending balls has reached "4" (YES in S204), the process proceeds to step S207, but if the number of special 2 pending balls is less than "4" (in S204 NO), 1 is added to the number of reserved balls of special figure 2 (S205).

Then special figure 2 relation random number acquisition processing is done (S206). In the special figure 2 random number acquisition process (S206), the jackpot random number counter value (label-TRND-A), the hit type random number counter value (label-TRND-AS), the reach random number counter value (label-TRND-RC) and fluctuation Obtain the pattern random number counter value (label-TRND-T1) (that is, obtain the random value group shown in FIG. 18 (A)), the obtained random value of the second special figure reservation storage unit 105b of the current special figure 2 Stored in the storage area of the second special figure reservation storage unit 105b corresponding to the number of reservation balls.

Subsequently, in the sensor detection process (S104), it is determined whether or not the game ball has entered the first starting hole 11, that is, whether or not the game ball has been detected by the first starting hole sensor 11a (S207). When the game ball has not won the first start port 11 (NO in S207), the process is finished, but when the game ball has won the first start port 11 (YES in S207), the special figure 1 is reserved. Whether the number of balls (the number of the first special figure reservation, specifically the numerical value of the counter that counts the number of the first special figure reservation provided in the game RAM 104) has reached "4" (upper limit storage number) Judge (S208). Then, if the number of special-figure 1 reserved balls has reached "4" (YES in S208), the process ends, but if the number of special-figure 1 reserved balls is less than "4" (NO in S208) ), and add "1" to the number of special-figure 1 reserved balls (S209).

Subsequently, special figure 1 related random number acquisition processing (S210) is performed, and this processing ends. In the special figure 1 related random number acquisition process (S210), like the special figure 2 related random number acquisition process (S206), the jackpot random number counter value (label-TRND-A), the hit type random number counter value (label-TRND-AS) , Obtain the reach random number counter value (label-TRND-RC) and the fluctuation pattern random number counter value (label-TRND-T1) (that is, obtain the random value group shown in FIG. 18 (A)), and obtain the obtained random value It is stored in the storage area of the first special figure reservation storage unit 105a corresponding to the current number of special figure reservation balls among the first special figure reservation storage unit 105a.

[Gate Passing Process] As shown in FIG. 25, in the gate passing process (S202), the number of normal pattern reserved balls (the number of normal pattern reservations, specifically a counter that counts the number of normal pattern reservations provided in the game RAM 104 value) is 4 or more (S301), and if the number of normal design reserved balls is 4 or more (YES in S301), the process is terminated. On the other hand, if the number of normal design reserved balls is not 4 or more (NO in S301), "1" is added to the number of normal design reserved balls (S302), and normal design random number acquisition processing is performed (S303). In the normal symbol random number acquisition process (S303), the normal symbol random number counter value (label-TRND-H value, see FIG. 18(B)) is acquired, and the acquired random value is stored in the normal symbol reservation storage unit 106 of the game RAM 104. Among them, it is stored in a storage area according to the current number of normal design reserved balls.

[Normal Operation Processing] The game control microcomputer 101 performs sensor detection processing (S104) and then normal operation processing (S105) (see FIG. 23). As shown in FIG. 26, in the normal operation process (S105), first, it is determined whether or not the power chew 12D is in operation (S401). If the electric chew 12D is not in operation (NO in S401), then it is determined whether or not the normal symbol is stopped (S402). If the normal symbols are not being stopped and displayed (NO in S402), then it is determined whether or not the normal symbols are being displayed in a variable manner (S403). If the variable display of normal symbols is not in progress (NO in S403), then it is determined whether or not the number of reserved balls of normal symbols is "0" (S404). If the number of reserved balls in the normal design is "0" (YES in S404), this process ends.

In step S404, if the number of reserved balls of normal symbols is not "0" (NO in S404), hit determination processing is performed (S405). In the hit determination process (S405), the normal symbol random number counter value (label-TRND-H value) stored in the normal pattern reservation storage unit 106 is read, and based on the normal symbol hit determination table shown in FIG. 19 (C) It is determined whether it hits or not. Then, a pattern determination process is performed to set the normal pattern stop pattern data according to the result of the hit determination in a predetermined storage area of the game RAM 104 (S406). That is, in the symbol determination process (S406), if it is "losing", data corresponding to "general figure losing symbol" is set, and if "hitting", data corresponding to "normal winning symbol" is set.

Subsequently, the game control microcomputer 101 performs normal symbol variation time determination processing (S407). In normal design fluctuation time determination processing (S407), referring to the normal design fluctuation pattern selection table shown in FIG. Choose a pattern. On the other hand, if the game state is a non-time-saving state, a normal design variation pattern in which the normal design variation time is 30 seconds is selected.

Next, the game control microcomputer 101 decrements the number of normal symbol reserved balls by one (S408). Then, the storage location (storage area) of each general pattern reservation in the general pattern reservation storage unit 106 is shifted by one from the current position to the side to be read, and the memory corresponding to the fourth reservation in the general pattern reservation storage unit 106 Clear the area (storage area farthest from the read side) (S409). In this way, it is made to be digested in the order in which the general map reservation was reserved. After that, the game control microcomputer 101 starts variable display of normal symbols in the normal symbol variation pattern selected in step S407 (S410). Along with this, in order to inform the effect control board 120 of the start of normal symbol variation, a normal symbol variation start command is set.

If it is during the fluctuation display of the normal design in the above step S403 (YES in S403), then it is determined whether or not the fluctuation time of the normal design has passed (S411), and if it has not passed, the process is finished. On the other hand, if it has passed (YES in S411), the variable display of normal symbols is stopped with the display result (normal winning symbol or normal losing symbol) according to the determination result of the normal symbol random number (S412). Then, a normal symbol fluctuation stop command for informing the effect control board 120 of the normal symbol fluctuation stop is set (S413), and the normal symbol stop time is set (S414), and this process is finished.

Also, if the stop display of the normal design is in progress at step S402 described above (YES at S402), then it is determined whether or not the stop time of the normal design set at step S414 has passed (S415). If not, terminate the process. On the other hand, if it has passed (YES in S415), it is determined whether or not the normal pattern stop pattern data of the normal winning pattern is set (S416), and if it is not the data of the normal winning pattern (that is, if it is not a hit (NO in S416)), and this processing ends. On the other hand, if it is normal winning pattern data (that is, if it is winning (YES in S416)), the opening pattern of the electric chew 12D is set (S417). Specifically, if it is in the time saving state, the opening pattern during the time saving state (see the electric chew opening TBL2 in FIG. 21) is set as the opening pattern of the electric chew 12D. On the other hand, if it is in the non-time-saving state, the open pattern (see electric-tube open TBL1 in FIG. 21) during the non-time-saving state is set as the open pattern of the electric chew 12D. Then, according to the opening pattern set in step S417, the electric chew 12D is operated (S418).

Also, if the electric chew 12D is in operation in the above step S401 (YES in S401), then it is determined whether or not the operation time of the electric chew 12D has elapsed (S419). Finish processing. On the other hand, if it has passed (YES in S419), the operation of the electric chew 12D is terminated (S420).

[Special Action Processing] After the normal action processing (S105), the game control microcomputer 101 performs special action processing (S106) (see FIG. 23). As shown in FIG. 27, in the special operation process (S106), the processing relating to the special figure display 81 and the big winning device 14D is divided into four stages, and "special operation statuses 1, 2, 3, 4" are added to each stage. are assigned. Then, when the "special action status" is "1" (YES in S1301), the game control microcomputer 101 performs special symbol standby processing (S1302), and the "special action status" is "2". In case (NO in S1301, YES in S1303), special symbol fluctuation processing (S1304) is performed, and if "special operation status" is "3" (NO in S1301, S1303, YES in S1305) , Special symbol determination processing (S1306) is performed, and when the "special action status" is "4" (S1301, S1303, S1305 are all NO), special electric accessory processing (S1307) is performed. Note that the special operation status is "1" by default.

[Special Symbol Standby Processing] As shown in FIG. 28, in the special symbol standby processing (S1302), first, whether or not the number of reserved balls in the second starting port 12 (that is, the number of special figure 2 reserved balls) is "0". is determined (S1401). If the special figure 2 reserved ball number is "0" (YES in S1401), that is, if there is no memory of the random number counter value group acquired due to the winning of the second start port 12, the first start It is determined whether or not the number of reserved balls of mouth 11 (that is, the number of reserved balls of special figure 1) is "0" (S1407). And, if the number of special figure 1 reserved balls is also "0" (YES in S1407), that is, if there is no memory of the random number counter value group acquired due to the winning of the first start port 11, the customer It is determined whether or not the wait flag is ON (S1415). If it is ON (YES at S1415), this process is terminated, and if it is not ON (NO at S1415), the customer waiting command is set in the output buffer of the game RAM 104 (S1416), and the customer waiting flag is turned ON ( S1417), this process ends.

In step S1401, if the number of special figure 2 reserved balls is not "0" (NO in S1401), that is, the storage of the random number counter value group acquired due to the winning of the second start port 12 (special figure 2 reservation information ), if there is one or more, special figure 2 jackpot determination processing (S1402) and special figure 2 variation pattern selection processing (S1403) to be described later are performed. After that, the game control microcomputer 101 decrements the number of special figure 2 reserved balls by 1 (S1404). Then, the storage location (storage area) of various counter values in the second special figure reservation storage unit 105b is shifted by one to the side read from the current position, and the first reservation in the second special figure reservation storage unit 105b Clear the storage area corresponding to (S1405). Subsequently, the game control microcomputer 101 executes special figure 2 fluctuation start processing (S1406), and proceeds to step S1413. In the special figure 2 fluctuation start process (S1406), while setting the special operation status to "2", the fluctuation start command is set in the output buffer of the game RAM 104, and the fluctuation display of the second special symbol is started. In addition, the variation start command (also called the special figure 2 variation start command) set in the special figure 2 variation start process (S1406) includes the special figure stop design data set in the special figure 2 jackpot determination process (S1402) Information and information of the variation pattern set in the special figure 2 variation pattern selection process (S1403) (information including information on variation time) is included.

Also, if the number of special 2 reserved balls is "0" but the number of special 1 reserved balls is not "0" (YES in S1401 and NO in S1407), that is, there is no reservation information of special 2, If there is one or more memories of the random number counter value group acquired due to the winning of the 1 start port 11 (reservation information of special figure 1), special figure 1 jackpot determination processing (S1408) and special figure to be described later 1 fluctuation pattern selection processing (S1409) is performed. After that, the game control microcomputer 101 decrements the number of special figure 1 reserved balls by 1 (S1410). Then, the storage location (storage area) of various counter values in the first special figure reservation storage unit 105a is shifted by one to the side read from the current position, and the fourth reservation in the first special figure reservation storage unit 105a (S1411). In this way, the first special figure reservation is digested in the order in which it was reserved. Subsequently, the game control microcomputer 101 executes special figure 1 fluctuation start processing (S1412), and proceeds to step S1413. In the special figure 1 fluctuation start process (S1412), while setting the special operation status to "2", the fluctuation start command is set in the output buffer of the game RAM 104, and the fluctuation display of the first special symbol is started. In addition, the variation start command (also called the special figure 1 variation start command) set in the special figure 1 variation start process (S1412) is the special figure stop pattern data set in the special figure 1 jackpot determination process (S1408) Information and information (information including information on fluctuation time) of the fluctuation pattern set in the special figure 1 fluctuation pattern selection process (S1409) is included.

When proceeding to step S1413, it is determined whether or not the customer waiting flag is ON, and if it is ON, the customer waiting flag is turned OFF (S1414), and the process ends. As described above, in this embodiment, the variable display of the special symbols based on the first special figure reservation is performed only when the second special figure reservation is "0" (YES in S1401). That is, digestion of the second special figure reservation is executed with priority over digestion of the first special figure reservation.

[Special figure 2 jackpot determination process (special figure 1 jackpot determination process)] Special figure 2 jackpot determination process (S1402) and special figure 1 jackpot determination process (S1408) have the same processing flow, so based on FIG. will be explained together. As shown in FIG. 29, in the special figure 2 jackpot determination process (S1402) or the special figure 1 jackpot determination process (S1408), first, as the determination value, the jackpot random number counter value (label-TRND-A value) is read (S1501 ). Specifically, in the special figure 2 jackpot determination process (S1402), in the first storage area of the second special figure reservation storage unit 105b of the game RAM 104 (that is, the storage area corresponding to the first second special figure reservation) Read the stored jackpot random number counter value. Also, in the special figure 1 jackpot determination process (S1408), the first special figure reservation storage unit 105a of the game RAM 104 is stored in the first storage area (that is, the storage area corresponding to the first item of the first special figure reservation). Read the jackpot random number counter value.

Next, the jackpot determination table (FIG. 19A) is set (S1502). Next, it is determined whether or not the probability variation flag is ON, that is, whether or not the state is a high probability state (S1503). Then, if it is not a high probability state (NO in S1503), that is, if it is a normal probability state (non-high probability state), the table for the non-high probability state (jackpot judgment It is determined whether or not it is a big hit based on the value "0" to "204") (S1504). On the other hand, if it is in a high probability state (YES in S1503), whether it is a big hit based on the table for high probability state (jackpot judgment value is "0" to "655") out of the big hit judgment table (Fig. 19 (A)) It is determined whether or not (S1505).

If the result of the jackpot determination (S1504, S1505) is "jackpot", the hit type random number counter value (label-TRND-AS value) is read, and the hit type is determined based on the hit type determination table shown in FIG. (S1506). After determining the hit type (S1506), the jackpot flag is turned ON (S1507), and the special figure stop pattern data (see FIG. 17) corresponding to the hit type is set in the hit type buffer provided in the game RAM 104. (S1508) to finish the process. On the other hand, if the result of the big hit determination (S1504, S1505) is "losing", the special figure stop design data (01H) corresponding to the losing design is set (S1508) and the process ends.

[Special figure 2 variation pattern selection process (special figure 1 variation pattern selection process)] Special figure 2 variation pattern selection process (S1403) and special figure 1 variation pattern selection process (S1409) are the same because the flow of processing is the same A collective description will be given with reference to FIGS. 30 and 31. FIG. As shown in FIG. 30, in the special figure 2 variation pattern selection process (S1403) or special figure 1 variation pattern selection process (S1409), first, it is determined whether the gaming state is a time saving state (whether the time saving flag is ON) (S1601).

If it is not a time saving state (NO in S1601), that is, if it is a non time saving state, then it is determined whether or not the jackpot flag is ON (S1602). If it is ON (YES in S1602), with reference to the non-time-saving state jackpot normal table (part corresponding to the non-time-saving state and jackpot of the special figure fluctuation pattern determination table shown in FIG. 20), the fluctuation pattern random number counter value A variation pattern is selected based on (label-TRND-value of T1) (S1603). As shown in FIG. 20, when the variation pattern is determined, the variation time is also determined.

In the variable performance of the pachinko game machine PY1, SP (Super Reach) can be executed in addition to Do Not Disturb and Normal Reach. The misalignment is a variable effect in which the combination of the effect symbols EZ1, EZ2, and EZ3 is stopped and displayed in a separate pattern (for example, "458"). Normal ready-to-win is a variable effect in which the development effect is not executed after forming the above-described ready-to-win, and the remaining effect symbol that continues to be displayed in a variable manner is stopped and displayed. The SP reach is a variable effect in which the development effect is executed after forming the above-described reach, and the change time after the reach is longer than that of the normal reach. Thus, in this embodiment, a variation pattern is selected so that Dohazure, normal reach, and SP reach can be executed.

In SP reach, distribution ratios of various variation patterns are set so that the degree of winning expectation (degree of expectation for winning a jackpot) is higher than in normal reach (see FIG. 20). Therefore, when the player sees the SP reach with a long fluctuation time, it can be understood that the winning expectation is higher than that of the normal reach. Here, the SP reach includes types of weak SP reach A, weak SP reach B, and strong SP reach. Distribution ratios of various variation patterns are set in the order of weak SP reach A→weak SP reach B→strong SP reach so that the degree of expectation for winning the jackpot increases. Therefore, the player can understand that the winning expectation is very high by looking at the strong SP reach, and can understand that the winning expectation is somewhat high by looking at the weak SP reach B, and the weak SP reach. Looking at A, it can be understood that the expectation of winning is not very high.

In step S1602 shown in FIG. 30, if the jackpot flag is not ON, it is determined whether or not the reach random number counter value (label-TRND-RC value) is a reach establishment random value (S1604). In addition, as shown in FIG. 19(B), the reach establishment random number is "0" to "13" if it is a non-time saving state, and is "0" to "5" if it is a time saving state. That is, the time-saving state is less likely to reach when losing than the non-time-saving state. This is in order to speed up the digestion speed of the special figure pending by making it possible to select more short reach no loss with short fluctuation time in the time saving state.

If the reach random number counter value is a reach establishment random number value (YES in S1604), that is, in the case of reach loss, there is reach loss table during non-time saving state (non-out of the special figure fluctuation pattern determination table shown in FIG. 20 With reference to the time saving state and the part corresponding to the loss with reach), the variation pattern is selected based on the variation pattern random number counter value (S1605).

On the other hand, if the reach random number counter value is not a reach establishment random value (NO in S1604), that is, in the case of reach no loss, the reach no loss table during the non-time saving state (out of the special figure fluctuation pattern determination table shown in FIG. 20 The part corresponding to the non-time-saving state and reach-less loss) is referred to, and the variation pattern is selected based on the variation pattern random number counter value (S1606). At the time of loss without reach, the function of shortening variation according to the number of held balls works. That is, when the number of reserved balls in the special design is "3" or "4", a variation pattern with a shorter fluctuation time than when the number of reserved balls in the special design is "0" to "2" is selected. (See FIG. 20).

Also in step S1601, if it is determined that the gaming state is a time saving state (YES in S1601), as shown in FIG. The part corresponding to the time saving state among the special figure fluctuation pattern determination table) is performed in the same flow as the above steps S1602 to S1606 (S1607 to S1611).

That is, if it is a jackpot, a variation pattern is selected based on the variation pattern random number counter value by referring to the part corresponding to the jackpot in the time saving state of FIG. 20 (S1608). Also, if there is a reach loss, a variation pattern is selected based on the variation pattern random number counter value by referring to the part corresponding to the time saving state in FIG. 20 and the loss with reach (S1610). Moreover, if it is a reach-less loss, a variation pattern is selected based on the variation pattern random number counter value by referring to the portion corresponding to the reach-less loss in the time saving state of FIG. 20 (S1611).

In addition, in the special figure fluctuation pattern determination table in the time saving state (the part corresponding to the time saving state of the special figure fluctuation pattern decision table shown in FIG. 20), the function of shortening variation according to the number of pending balls when there is no reach It works when the number of held balls is "2" to "4". That is, shortening variation is more likely to be selected than during the non-time saving state. In addition, the fluctuation time as shortening fluctuation is shorter during the time saving state than during the non-working time saving state. That is, the special figure variation pattern determination table in the time saving state is a table such that the variation time is shorter than the special figure variation pattern determination table in the non time saving state.

After selecting the variation pattern as described above, as shown in FIG. 30, the selected variation pattern is set (S1612), and this process ends. Information on the variation pattern set in step S1612 is included in the variation start command set in step S1406 or S1412 in the special symbol standby process (S1302), and sent to the effect control board 120 by the output process (S101).

[Special symbol fluctuation process] As shown in FIG. 32, in the special symbol fluctuation process (S1304), first, the special symbol fluctuation time (variation time determined according to the fluctuation pattern selected in step S1403 or S1409, FIG. 20 See) has passed (S1801). If it has not elapsed (NO in S1801), this process is terminated immediately. As a result, the variable display of the special symbols is continued.

On the other hand, if the fluctuation time has elapsed (YES in S1801), a fluctuation stop command is set (S1802), and the special action status is set to "3" (S1803). Then, after performing other processing such as stopping the variable display of the special symbols with the symbols (jackpot symbols or losing symbols) corresponding to the set special symbol stop symbol data (S1804), this processing is finished.

[Special symbol determination process] As shown in FIG. 33, in the special symbol determination process (S1306), first, the special symbol stop time (stop time determined according to the variation pattern selected in step S1403 or S1409, see FIG. 20) (S1901). If it has not elapsed (NO in S1901), this process is terminated immediately. As a result, the stop display of the special symbols is continued. On the other hand, if the stop time has elapsed (YES in S1901), a game state management process, which will be described later, is performed (S1902).

Next, it is determined whether or not the jackpot flag is ON (S1903). If the jackpot flag is ON (YES in S1903), an opening pattern (see FIG. 17 for details) corresponding to the type of jackpot won is set (S1904). At this time, the value of a round counter that counts the number of unit open games (round games) executed during the jackpot game is set to the number of rounds corresponding to the type of jackpot won. Note that the setting of the release pattern (the set of data corresponding to the release pattern) may be performed for each round.

After step S1904, the game control microcomputer 101 performs game state reset processing (S1905). In the game state reset process (S1905), first, if the probability variation flag is ON, the probability variation flag is turned OFF, and if the time saving flag is ON, it is turned OFF. In other words, during execution of the jackpot game, it is controlled to a non-high probability state and a non-time saving state. After that, in order to start the jackpot game, a jackpot opening command is set (S1906), and the opening of the jackpot game is started (S1907). Then, the special action status is set to "4" (S1908), and this processing ends.

Also, if the jackpot flag is not ON in step S1903 (NO in S1903), the jackpot game is not started, so the special action status is set to "1" (S1909), and this process is finished.

[Playing State Management Processing] As shown in FIG. 34, in the playing state management processing (S1902), first, it is determined whether or not the variable probability flag is ON (S2001). If it is ON (YES in S2001), the value of the probability variation counter that counts the number of variations of the special symbol executed during the high probability state is decremented by 1 (S2002), and whether the value of the probability variation counter is "0" Judge (S2003). If it is "0" (YES in S2003), the variable probability flag is turned OFF (S2004), and the process proceeds to step S2005. If the determination result of step S2001 or S2003 is NO, the process immediately proceeds to step S2009.

In step S2005, it is determined whether or not the time saving flag is ON. If it is ON (YES in S2005), decrement the value of the time saving counter that counts the number of variations of the special symbols executed during the time saving state by 1 (S2006), and determine whether the value of the time saving counter is "0" (S2007). If it is "0" (YES in S2007), turn off the time saving flag (S2008) and proceed to step S2009. If the determination result of step S2005 or S2007 is NO, the process immediately proceeds to step S2009. In step S2009, a game state designation command including information on the current game state (information on whether the variable probability flag and the time saving flag are ON or OFF), information on the value of the variable probability counter and the value of the time saving counter, etc. The data is set in the output buffer of the RAM 104, and this processing ends.

[Special Electric Accessory Process (Jackpot Game)] The special electric accessory process is a process for executing a jackpot game. As shown in FIG. 35, in the special electric accessary product process (S1307), first, it is determined whether or not the jackpot end flag is ON (S2701). The jackpot end flag is a flag indicating that the opening of all the jackpot devices (big prize device 14D) in the jackpot game being executed has ended.

If the jackpot end flag is not ON (NO in S2701), it is determined whether or not the big winning port 14 is open (that is, whether or not the big winning device 14D is open) (S2702). If it is not open (NO in S2702), whether or not the time has come to open the big winning opening 14, that is, whether the time for opening the big winning opening has passed and the time has come to start opening the big winning opening 14, or , and whether or not it is time to start the next opening after the time interval between openings has elapsed (S2703).

If the determination result in step S2703 is NO, the process ends. On the other hand, if the determination result of step S2703 is YES, it is determined whether or not the jackpot game currently being executed is a jackpot game based on the probability variable jackpot (see FIG. 17) (S2704). If it is not a probability variable jackpot (NO in S2704), the process proceeds to step S2707, but if it is a probability variable jackpot (YES in S2704), it is determined whether it is the timing to start the 9th R that can pass through the specific area 16 (S2705). If it is not the timing to start the ninth round (NO in S2705), the process proceeds directly to step S2707. On the other hand, if it is the timing to start the ninth R (YES in S2705), V effective period setting processing is performed (S2706).

In the V effective period setting process (S2706), it is determined that the game ball detection by the specific area sensor 16a is effective during the opening of the big winning opening 14 and several seconds after closing the big winning opening 14 in the 9th round of the probability variable jackpot. Set to V validity period. In this embodiment, other periods (including when the jackpot game is not executed) are set as the V invalid period during which detection of the game ball by the specific area sensor 16a is determined to be invalid. Here, judging that the detection of the game ball by the specific area sensor 16a is effective means that the V flag is turned ON based on the detection of the game ball by the specific area sensor 16a (specific area sensor detection processing described later (see FIG. 37). ))That's what it means. Determining that the detection of the game ball by the specific area sensor 16a is invalid means that the V flag is not turned ON even if the game ball is detected by the specific area sensor 16a. The reason why the V effective period includes several seconds after closing the big winning hole 14 is that the game ball may enter the big winning hole 14 just before the closing of the big winning hole 14. be.

That is, in this embodiment, the V flag is turned ON only when the V passage (passage of the game ball to the specific area 16) during the V valid period is detected, and the V flag is turned on when the V passage is detected outside the V valid period (during the V invalid period). is not turned ON. When the V flag is ON, the variable probability flag is turned ON, that is, the game state after the jackpot game is set to a high probability state (game state setting process (see FIG. 36) described later). By doing so, the V flag is prevented from being turned on based on passing through the V due to fraud, that is, it is prevented from being set to a high-probability state.

In step S2707, the big winning opening (big winning opening 14) is opened according to the opening pattern (see FIG. 17) corresponding to the type of jackpot. In addition, the distribution member 16k always moves in a constant motion from the start of the round game of the first round. In the opening pattern (V long opening pattern) of the probability variable jackpot, in the ninth round, the AT opening/closing member 14k is opened so that the game ball that has won the big winning opening 14 can pass through the specific area 16 with a margin. On the other hand, in the normal jackpot opening pattern (V short opening pattern), in the ninth round, even if the game ball wins the big winning hole 14, the distribution member is arranged so that it cannot pass through the specific area 16. The opening timing of the AT opening/closing member 14k for the operation of 16k is set.

Subsequently, in step S2708, round designation command transmission determination processing is performed, and this processing ends. In the round designation command transmission determination process (S2708), it is determined whether or not the opening of the large winning opening 14 in step S2703 is the first opening in one round game. A round specifying command including information on the number of rounds is set in the output buffer of the game RAM 104 . It should be noted that, in this embodiment, the large winning opening 14 is not opened a plurality of times during one round game. Therefore, in this step S2708, the round designation command is always set.

In step S2702 of the special electric accessory processing (S1307), if the large winning opening 14 is open, it is determined whether or not the conditions for closing the large winning opening 14 are satisfied (S2709). In this form, the closing condition is that the number of prizes to be won into the big winning hole 14 in the round game reaches the specified maximum number of winnings (8 per 1R in this form), or the time to close the big winning hole 14 (that is, a predetermined opening time (see FIG. 17) has passed since the opening of the big winning opening 14) is satisfied. Then, if the conditions for closing the big winning opening 14 are not established (NO in S2709), the process is finished.

On the other hand, if the conditions for closing the big winning opening 14 are satisfied (YES in S2709), the big winning opening 14 is closed (blocked) (S2710). Then, it is determined whether one round game (round interval) has ended (S2711). If not finished (NO in S2711), the process ends. On the other hand, when the round game ends (YES in S2711), the value of the round counter is decremented by 1 (S2712), and it is determined whether or not the value of the round counter is "0" (S2713). If it is not "0" (NO at S2713), the process ends as it is to start the next round game.

On the other hand, if it is "0" (YES in S2713), as a jackpot ending process for ending the jackpot game, a jackpot ending command is set (S2714), and a jackpot ending is started (S2715). Then, the jackpot end flag is set (S2716), and the process ends.

If the jackpot end flag is ON in step S2701 (YES in S2701), the final round has ended, so it is determined whether or not the ending time of the jackpot game has passed (S2717), and the ending time has passed. If not (NO in S2717), this processing ends. On the other hand, if the ending time has passed (YES in S2717), the jackpot end flag is turned OFF (S2718). Then, a game state setting process, which will be described later, is performed (S2719). Subsequently, the jackpot flag is turned OFF (S2720). Subsequently, the special action status is set to "1" (S2721), and this processing ends.

[Game State Setting Processing] As shown in FIG. 36, in the game state setting processing (S2719), first, it is determined whether or not the V flag is ON (whether V has won during the V valid period) (S2801). If it is ON (YES in S2801), the probability variation flag is turned ON (S2802), and the time saving flag is turned ON (S2803). As a result, after the jackpot game, the game is controlled to the highly reliable time-saving state. Subsequently, "160" is set to the variable probability counter (S2804), "160" is set to the time saving counter (S2805), and the process proceeds to step S2808. As a result, the number of times of ST is 160 times and the number of times of time saving is 160 times.

On the other hand, if it is determined that the V flag is not ON in step S2801 (NO in S2801), the time saving flag is turned ON (S2806). That is, at this time, the probability variation flag is not turned ON. Thereby, it will be controlled to the low-probability short-time state after the jackpot game. Subsequently, "100" is set in the time saving counter (S2807), and the process proceeds to step S2808. That is, by this, the number of times of time saving is controlled to the low-probability time saving state of 100 times.

In step S2808, the game control microcomputer 101 specifies the game state including the information of the game state set now (ON or OFF of the probability variable flag, ON or OFF of the time saving flag, the value of the probability changing counter, the information of the value of the time saving counter) A command is set in the output buffer of the game RAM 104 . Thus, the game state setting process (S2719) ends.

[Specific Area Sensor Detection Process] As shown in FIG. 37, in the specific area sensor detection process (S107), first, it is determined whether or not a game ball has been detected by the specific area sensor 16a (S3001). In this embodiment, detection of game balls by the specific area sensor 16a is performed only when the distribution member 16k is controlled to the first state shown in FIG. 5(A). If there is no detection in step S3001 (NO in S3001), this process is terminated. If there is detection (YES in S3001), it is determined whether or not it is during the V valid period (S3002). If it is not during the V valid period (NO in S3002), this processing is finished. On the other hand, if it is during the V valid period (YES in S3002), the V flag is turned ON (S3003). Then, the V passage command is set in the output buffer of the game RAM 104 (S3004), and this process is finished. The V passage command is a command for causing the effect control board 120 to notify the V passage.

8. Operation of Effect Control Microcomputer 121 [Sub Control Main Processing] Next, the operation of the effect control microcomputer 121 will be described with reference to FIGS. Note that counters, timers, flags, statuses, buffers, etc. appearing in the description of the operation of the effect control microcomputer 121 are provided in the effect RAM 124 . The effect control microcomputer 121 provided in the effect control board 120 reads out and executes the sub-control main processing program shown in FIG. 38 from the effect ROM 123 when the pachinko game machine PY1 is powered on. As shown in the figure, in the sub-control main processing, CPU initialization processing is first performed (S4001). In CPU initialization processing (S4001), stack setting, constant setting, setting of CPU 122 for effect, setting of SIO, PIO, CTC (circuit for managing interrupt time), etc. are performed.

Subsequently, it is determined whether or not the power-off signal is ON and the contents of the performance RAM 124 are normal (S4002). If the determination result is NO, the effect RAM 124 is initialized (S4003), and the process proceeds to step S4004. On the other hand, if the determination result is YES (YES in S4002), the process proceeds to step S4004 without initializing the RAM 124 for effect. That is, if the power cutoff signal is not ON, or if the contents of the RAM 124 for effects are not normal even if the power cutoff signal is ON (NO in S4002), the RAM 124 for effects is initialized, but the power cutoff signal is generated due to a power failure or the like. is turned ON but the contents of the effect RAM 124 are maintained normally (YES in S4002), the effect RAM 124 is not initialized. Incidentally, if the effect RAM 124 is initialized, the values of various flags, statuses, counters and the like are reset. Also, these steps S4001 to S4003 are executed only once after the power is turned on, and are not executed thereafter.

In step S4004, interrupts are prohibited. Next, random number seed update processing is executed (S4005). In the random number seed update process (S4005), the values of various effect determination random number counters are updated. The random numbers for determining the effect include random numbers for determining the effect pattern for determining the effect pattern, random numbers for determining the variable effect pattern lottery for determining the variable effect pattern, random numbers for determining the previous effect for determining various advance effects, etc. There is The random number update method can be the same method as the random number update process performed by the game control board 100 described above. Instead of adding 1 to the random value at the time of updating, it is also possible to add 2 at a time. This also applies to the random number update process performed by the game control board 100 described above.

When the random number seed update process (S4005) ends, the command transmission process is executed (S4006). In the command transmission process ( S4006 ), various commands stored in the output buffer in the performance RAM 124 of the performance control board 120 are transmitted to the image control board 140 . The image control board 140 that has received the command executes various effects (variation effects, opening effects associated with jackpot games, round effects, ending effects, etc.) using the rear liquid crystal display device 50 and the transmissive liquid crystal display device 7 according to the commands. do. In addition, along with execution of various effects by the image control board 140, the effect control board 120 outputs sound from the speaker 610 via the sound control board 161, or outputs the board lamp 54 and the frame lamp via the sub-drive board 162. 212, the movable board lamp 53 is lighted and the movable board 55 is driven. The effect control microcomputer 121 subsequently permits an interrupt (S4007). Thereafter, steps S4004 to S4007 are looped. While interrupts are enabled, reception interrupt processing (S4008), 1 ms timer interrupt processing (S4009), and 10 ms timer interrupt processing (S4010) can be executed.

[Receiving interrupt processing] Receiving interrupt processing (S4008) is performed based on the strobe signal (STB signal) sent from the game control board 100 being input to the external INT input section of the effect control microcomputer 121. That is, unless the strobe signal is input to the external INT input section of the effect control microcomputer 121, the reception interrupt process (S4008) is not performed. As shown in FIG. 39, in the reception interrupt process (S4008), various commands transmitted from the game control board 100 are stored in the reception buffer of the effect RAM 124 (S4101). This reception interrupt process (S4008) is a process that is executed with priority over other interrupt processes (S4009, S4010).

[1 ms timer interrupt processing] 1 ms timer interrupt processing (S4009) is executed each time an interrupt pulse of 1 msec cycle is input to the effect control board 120. As shown in FIG. 40, in the 1 ms timer interrupt processing (S4009), first, input processing (S4201) is performed. In the input process (S4201), effect button detection sensor 40a (see FIG. 16), select button detection sensor 42a, upper initial position detection sensor 55Ua, upper drive position detection sensor 55Ub, lower initial position detection sensor 55Da, lower drive position Switch data (edge data and level data) is created based on the detection signal (detection signal) from the detection sensor 55Db.

Next, a lamp data output process, which will be described later, is executed (S4202). Subsequently, drive control processing, which will be described later, is executed (S4203). After the drive control process (S4203), the watchdog timer process (S4204) for resetting the watchdog timer is performed, and this process ends.

[Lamp Data Output Processing] The lamp data output processing (S4202) is for outputting lamp data to the sub-drive board 162 in order to cause the board lamp 54, frame lamp 212, and board movable body lamp 53 to emit light at a timing suitable for the presentation. processing. In the lamp data output process (S4202), first, as shown in FIG. 41, the effect control microcomputer 121 determines whether or not it is time to start the board movable body appearance effect (S4210). The start timing of the board movable body appearance effect is the timing of starting the display of the battle victory image WI shown in FIG. 13(B).

If it is the start timing of the appearance of the board movable body (YES in S4210), the performance control microcomputer 121 reads the board movable body lamp data from the performance ROM 123 and outputs the board movable body lamp data to the sub-drive board 162. (S4211). The movable board lamp data includes information such as at what timing the movable board lamp 53 emits light, in what color it emits light, at what luminance it emits light, and at what timing it turns off. ing. Therefore, the sub-drive board 162, to which the movable board lamp data is input, determines the timing at which the movable board 55 can be visually recognized behind the transmissive liquid crystal display device 7, as shown in FIG. 13C, based on the movable board lamp data. Then, the movable board lamp 53 is caused to emit light in a predetermined light emission mode (light emission color). Further, as shown in FIG. 13(D), the board movable body lamp 53 is extinguished at the timing when the production pattern EZ starts the stop display in the jackpot mode. On the other hand, if the production control microcomputer 121 does not start the movable board appearance production (NO in S4210), there is no need to control the light emission of the movable board lamp 53, so step S4211 is skipped and step S4212 is performed. proceed to

In step S4212, it is determined whether or not the upper initial position detection sensor 55Ua is ON. If it is ON (YES in S4212), then it is determined whether or not the lower initial position detection sensor 55Da is ON (S4213). If it is ON (YES in S4213), the upper board movable body 55U and the lower board movable body 55D are at their initial positions, and the process proceeds to step S4214. In step S4214, the effect control microcomputer 121 reads the board movable body extinguishing lamp data from the effect ROM 123, outputs the board movable body extinguishing lamp data to the sub-drive board 162, and proceeds to step S4215. As a result, the sub-drive board 162 to which the movable board lamp extinguishing data is inputted turns off the movable board lamp 53 . On the other hand, if the upper initial position detection sensor is not ON (NO at S4212) or the lower initial position detection sensor is not ON (NO at S4213), step S4214 is skipped and the process proceeds to step S4215. In other words, when both the upper board movable body 55U and the lower board movable body 55D are not at the initial positions, the process of step S4214 does not force the board movable body lamp 53 to go out.

Thus, if the movable board 55 is not at the initial position, the movable board lamp 53 is controlled in light emission mode based on the movable board lamp data, whereas if the movable board 55 is at the initial position, The movable board lamp 53 is forcibly turned off based on the movable board turn-off lamp data. Therefore, even if the contents of the movable board lamp data are wrong due to human error, the movable board lamp 53 can be turned off without fail if the movable board 55 is at the initial position.

In step S4215, as another lamp data output process, the lamp data is output to the sub-drive board 162 so as to cause the board lamp 54 and the frame lamp 212 to emit light at a timing suitable for the presentation, and this process ends.

[Drive Control Processing] Drive control processing (S4203) is processing for outputting drive data to the sub-drive board 162 in order to drive the board movable body 55 at a timing suitable for the performance. In the drive control process (S4203), first, as shown in FIG. 42, the effect control microcomputer 121 determines whether or not it is time to start the board movable body appearance effect (S4220). That is, it is determined whether or not it is time to start displaying the battle victory image WI shown in FIG. 13B. If it is not the start timing of the board movable body appearance effect (NO at S4220), the board movable body 55 does not need to be moved, so the process proceeds to step S4223.

On the other hand, if it is the start timing of the board movable body appearance effect (YES in S4220), the transmissive film 770 is controlled to the non-transmissive state (S4221). As a result, the rear of the transmissive liquid crystal display device 7 cannot be visually recognized. And the production control microcomputer 121 reads the board movable body appearance drive data from the production ROM 123, outputs the board movable body appearance drive data to the sub-drive board 162 (S4222), and proceeds to step S4223. The board movable body appearance drive data is drive data for moving the upper board movable body 55U and the lower board movable body 55D from the initial positions to the drive positions. The sub-drive board 162 to which the board movable body appearance driving data is input is arranged so that the upper board movable body 55U and the lower board movable body 55D move from the initial positions to the drive positions as the board movable body appearance effect starts. Then, the upper board movable body moving motor 55Um and the lower board movable body moving motor 55Dm are driven. In this way, as shown in FIG. 13B, by making the rear of the transmissive liquid crystal display device 7 invisible, the player can see the upper board movable body 55U and the lower board movable body 55D that are moving to the drive position. It is possible not to.

In step S4223, the effect control microcomputer 121 determines whether or not the board movable body appearance effect is being executed. If the board movable body appearance effect is not being executed (NO at S4223), the process proceeds to step S4228 shown in FIG. On the other hand, if the board movable body appearance effect is being executed (YES in S4223), it is determined whether or not the upper drive position detection sensor 55Ub is ON (S4224). If it is not ON (NO in S4224), the upper board movable body 55U has not yet moved to the drive position, so the process proceeds to step S4228 shown in FIG. On the other hand, if the upper driving position detection sensor 55Ub is ON (YES in S4224), then it is determined whether or not the lower driving position detection sensor 55Db is ON (S4225). If it is not ON (NO in S4225), the lower board movable body 55D has not yet moved to the drive position, so the process proceeds to step S4228 shown in FIG. On the other hand, if the lower drive position detection sensor 55Db is ON (S4225), it means that the board movable body 55 (upper board movable body 55U, lower board movable body 55D) has finished moving to the drive position. Proceed to S4226.

In step S4226, it is determined whether or not it is time to show the board movable body 55 at the driving position behind the transmissive liquid crystal display device 7 to appear (S4226). That is, it is determined whether or not it is time to hide the battle victory image WI displayed on the display screen 7a of the transmissive liquid crystal display device 7 (see FIGS. 13B and 13C). If it is not the timing to make the board movable body 55 appear (NO in S4226), the process proceeds to step S4228 shown in FIG. On the other hand, if it is time to make the disk movable body 55 appear (YES in S4226), the transmissive film 770 is switched from the non-transmissive state to the transmissive state (S4227), and the process proceeds to step S4228 shown in FIG. As a result, as shown in FIG. 13C, behind the display screen 7a of the transmissive liquid crystal display device 7, the face of the main character appears to suddenly appear due to the board movable body 55 in the drive position. In this way, the player suddenly sees the face of the main character, which is a three-dimensional structure, following the battle victory image WI shown in FIG. It is possible to give

As shown in FIG. 43, in step S4228, it is determined whether or not it is time to end the board movable body appearance effect. In this embodiment, the end timing of the appearance effect of the movable board body is the timing when two seconds have passed since the transmissive film 770 was switched from the non-transmissive state to the transmissive state in step S4227. That is, in the presentation of the movable board body of this embodiment, behind the transmissive liquid crystal display device 7, the movable board body 55 at the driving position is shown for only two seconds. If it is not the end timing of the board movable body appearance effect (NO at S4228), the process proceeds to step S4231. On the other hand, if it is the end timing of the board movable body appearance effect (YES in S4228), the transmissive film 770 is switched from the transmissive state to the non-transmissive state (S4229). As a result, the board movable body 55 behind the transmissive liquid crystal display device 7 becomes invisible. At this time, as shown in FIG. 13(D), the display screen 7a of the transmissive liquid crystal display device 7 stops and displays the performance symbol EZ in a jackpot mode.

After switching the transmissive film 770 to the non-transmissive state (S4229), the effect control microcomputer 121 reads the board movable body storage drive data from the effect ROM 123 and outputs the board movable body storage drive data to the sub-drive board 162. (S4230), and proceeds to step S4231. The board movable body storage drive data is drive data for moving the upper board movable body 55U and the lower board movable body 55D from the drive position to the initial position. The sub-drive board 162, to which the board movable body storage drive data is input, controls the upper board movable body 55U and the lower board movable body 55D to move from the drive position to the initial position when the board movable body appearance effect ends. Then, the upper board movable body moving motor 55Um and the lower board movable body moving motor 55Dm are driven. In this way, as shown in FIG. 13(D), the rear side of the transmissive liquid crystal display device 7 is hidden from view, so that the player can see the upper board movable body 55U and the lower board movable body 55D that are moving to the initial position. It is possible not to.

In step S4231, as other drive control processing, a processing for moving the board movable body 55 with an effect other than the board movable body appearance effect is performed, and this processing ends.

[10 ms timer interrupt processing] 10 ms timer interrupt processing (S4010) is executed each time an interrupt pulse with a period of 10 msec is input to the effect control board 120. As shown in FIG. 44, in the 10 ms timer interrupt processing (S4010), first, received command analysis processing, which will be described later, is performed (S4301).

Subsequently, switch state acquisition processing is performed to store the switch data created in the input processing (S4201) of the 1 ms timer interrupt processing (S4009) in the effect RAM 124 as switch data for the 10 ms timer interrupt processing (S4302). Then, based on the switch data stored in the switch state acquisition process (S4302), the switch process for setting the display contents of the display screen 50a is executed (S4303).

Subsequently, voice control processing (S4304) is performed. In the audio control process (S4304), audio data (data for controlling the output of audio from the speaker 610) is created, output to the audio control board 161, time management of audio production, and the like are performed. As a result, the speaker 610 outputs a sound that matches the performance to be executed. Then, other processing such as updating random numbers for various effects is executed (S4305), and this processing ends.

[Received Command Analysis Processing] As shown in FIG. 45, in the received command analysis processing (S4301), the effect control microcomputer 121 first determines whether or not a game state designation command is received from the game control board 100 (S4401). ), and if received, mode status setting processing is performed (S4402). In the mode status setting process (S4402), the received game state designation command is analyzed, and the value of the mode status is set based on the game state information included in the game state designation command. The value of the mode status is set to "1" if it is a normal game state, is set to "2" if it is a high-probability time-saving state, and is set to "3" if it is a low-probability time-saving state. In this way, the effect control microcomputer 121 can grasp the current game state.

Subsequently, the effect control microcomputer 121 determines whether or not a variation start command (special figure 1 variation start command or special figure 2 variation start command) is received from the game control board 100 (S4403), and if received Variation production start processing, which will be described later, is performed (S4404).

Subsequently, the effect control microcomputer 121 determines whether or not a fluctuation stop command (special figure 1 fluctuation stop command or special figure 2 fluctuation stop command) is received from the game control board 100 (S4405), and if received Fluctuation production end processing is performed (S4406). In the fluctuation production end processing (S4406), the fluctuation stop command is analyzed, and based on the analysis result, the fluctuation production end command for ending the fluctuation production is set in the output buffer of the production RAM124.

Subsequently, the effect control microcomputer 121 determines whether or not an opening command is received from the game control board 100 (S4407), and if received, performs an opening effect selection process (S4408). In the opening effect selection process (S4408), the opening command is analyzed, and based on the analysis result, the pattern (contents) of the opening effect to be executed during the opening of the jackpot game is selected. Then, an opening performance start command for starting the opening performance in the selected opening performance pattern is set in the output buffer of the RAM 124 for performance.

Subsequently, the effect control microcomputer 121 determines whether or not a round designation command is received from the game control board 100 (S4409), and if received, performs a round effect selection process (S4410). In the round effect selection process (S4410), the round designation command is analyzed, and based on the analysis result, the pattern (contents) of the round effect to be executed during the round game of the jackpot game is selected. Then, a round effect start command for starting the round effect in the selected round effect pattern is set in the output buffer of the RAM 124 for effect.

Subsequently, the effect control microcomputer 121 determines whether or not an ending command is received from the game control board 100 (S4411), and if received, performs ending effect selection processing (S4412). In the ending effect selection process (S4412), the ending command is analyzed, and based on the analysis result, the pattern (contents) of the ending effect to be executed during the ending of the jackpot game is selected. Then, an ending effect start command for starting the ending effect with the selected ending effect pattern is set in the output buffer of the RAM 124 for effect.

Subsequently, the effect control microcomputer 121 performs other processing (S4413) based on a received command other than the above commands (for example, a customer waiting effect indicating that the variable effect is not being executed based on the reception of the customer waiting command). Processing for performing, processing for performing V passing notification production indicating that there was V passing based on the reception of the V passing command, normal pattern fluctuation production based on the reception of the normal pattern fluctuation start command process), and the received command analysis process (S4301) ends.

[Variation Production Start Processing] As shown in FIG. 46, in the variation production start processing (S4404), the production control microcomputer 121 first analyzes the fluctuation start command (S4501). In the variation start command, the information of the special figure stop pattern data set in the special figure 1 jackpot determination process and the special figure 2 jackpot determination process (see FIG. 29), the special figure 1 variation pattern selection process and the special figure 2 variation pattern It contains information on the variation pattern set in the selection process (see FIGS. 30 and 31), information specifying the current game state, and the like. In addition, the information which the microcomputer 121 for production|presentation control acquired here can be suitably utilized also in the process performed after this.

Next, the effect control microcomputer 121 refers to the mode status value currently set (S4502). Subsequently, the performance symbols EZ1, EZ2, and EZ3 to be finally stopped and displayed in the variable performance are selected (S4503). Specifically, a random number for determining the performance symbol is acquired, and one table is selected from among a plurality of tables classified according to the presence or absence of reach based on the analysis result of the fluctuation start command. Then, a performance symbol is selected by determining the acquired performance symbol determination random number using the selected table. As a result, a combination (for example, "777", etc.) of the performance symbols EZ1, EZ2, and EZ3 that are finally stopped and displayed is determined.

Subsequently, the production control microcomputer 121 executes a variation production pattern selection process (S4504). In the variation effect pattern selection process (S4504), one of the tables classified according to the type of effect mode (mode status value) and the type of variation pattern is selected based on the analysis result of the start variation command. Select a table. Then, a variable performance pattern is selected by determining the acquired variable performance pattern lottery random number using the selected table. Once the variable production pattern is determined in this way, the time of the variable production, the variable display mode of the production pattern, the presence or absence of the reach production, the contents of the reach production, the presence or absence of the production button production (SW production), the contents of the production button production, the production development configuration, The details of the content of the variable production, such as the type of background of the production pattern, are determined.

In the present embodiment, in this fluctuation production pattern lottery process (S4504), a variable production pattern lottery random number is determined based on a table classified according to the fluctuation pattern that becomes the SP reach jackpot, and the board movable body appears. A variable effect pattern for executing the effect (see FIGS. 13B and 13C) may be selected. That is, the board movable body appearance effect of this embodiment is executed by lottery only when the variation patterns P1, P2, P3, P31, P32, and P33 (see FIG. 20) that result in the SP reach jackpot are selected. There is a production. Thus, in the present embodiment, the board movable body appearance effect can be executed only when the SP reach is executed and the jackpot is won.

After the fluctuation effect pattern selection process (S4504), the notice effect selection process is executed (S4505). In the notice effect selection process (S4505), along with obtaining a random number for deciding the notice effect, one table is selected from a plurality of tables classified according to the presence or absence of reach based on the analysis results of the fluctuation start command. select. Then, the selected table is used to determine the obtained random number for determining the announcement effect, thereby selecting the announcement effect. As a result, the content of the notice effect such as a so-called step-up notice effect or a chance-up notice effect is determined.

Thereafter, a variable performance start command based on the selected performance pattern, variable performance pattern, and advance notice performance is set in the output buffer of the performance RAM 124 (S4506), and this processing is finished. When the variable effect start command set in step S4606 is transmitted to the image control board 140 by the command transmission process (S4006), the variable effect synchronized with the variable display of the special symbol is started on the display screen 50a.

9. Effects of the present embodiment As described above in detail, according to the pachinko game machine PY1 of the present embodiment, as shown in FIG. Since the transmissive film 770 is in a non-transmissive state, the player cannot see the board movable body 55 moving behind the transmissive liquid crystal display device 7. - 特許庁Then, as shown in FIG. 13C, after the movable board body 55 moves to the drive position, the transparent film 770 is switched to the transparent state. As a result, the player suddenly sees the board movable body 55 at the driving position behind the display screen 7a of the transmissive liquid crystal display device 7.例文帳に追加In this way, by making the board movable body 55 appear suddenly to the player, it is possible to enhance the impact of the presentation by the board movable body 55.例文帳に追加

Further, according to the pachinko game machine PY1 of this embodiment, as shown in FIG. Instead of showing the battle victory image WI to be played, the moving board movable body 55 is not shown. Then, as shown in FIG. 13C, when the transmissive film 770 is switched to the transmissive state after the movable board 55 moves to the driving position, instead of showing the movable board 55 at the driving position, the display screen The battle victory image WI displayed in 7a is not shown. In this way, by instantaneously switching the object to be displayed from the battle victory image WI to the board movable body 55, it is possible to provide the player with novel game amusement.

Further, according to the pachinko game machine PY1 of this embodiment, as shown in FIG. Film 770 is in an opaque state. Therefore, both the upper panel movable body 55U and the lower panel movable body 55D moving behind the display screen 7a of the transmissive liquid crystal display device 7 cannot be seen. Then, after the upper board movable body 55U and the lower board movable body 55D move to the drive position, a board movable body appearance effect is executed in which the transparent film 770 is switched from the non-transmissive state to the transparent state. As a result, as shown in FIG. 13(C), the player can see the main character formed (completed) by the upper board movable body 55U and the lower board movable body 55D, which are respectively in the driving position behind the display screen 7a. suddenly sees the face of In this way, the upper board movable body 55U and the lower board movable body 55D make it appear as if the main character's face suddenly appears to the player, making it possible to provide a novel game interest.

Further, according to the pachinko game machine PY1 of this embodiment, when the upper board movable body 55U and the lower board movable body 55D are at their respective initial positions, the upper initial position detection sensor 55Ua and the lower initial position detection sensor 55Da detect , the movable board lamp 53 is turned off regardless of the movable board lamp data. Therefore, even if the movable board lamp data is incorrect due to human error, the movable board lamp 53 is always turned off when the upper board movable body 55U and the lower board movable body 55D are at their respective initial positions. It is possible to Therefore, depending on the position of the upper board movable body 55U and the position of the lower board movable body 55D, it is possible to turn the board movable body lamp 53 into the intended extinguishing mode (light emitting mode) without fail.

Further, according to the pachinko game machine PY1 of the present embodiment, when the upper board movable body 55U and the lower board movable body 55D are at the initial positions which are the initial positions, the upper initial position detection sensor 55Ua and the lower initial position detection sensor 55Ua Detection by the position detection sensor 55Da makes it possible to ensure that the board movable body lamp 53 does not emit light. Therefore, although the upper board movable body 55U and the lower board movable body 55D are in their respective initial positions, the board movable body lamp 53 is caused to emit light based on the wrong board movable body lamp data, which is useless. It is possible to prevent a situation in which power consumption increases.

Further, according to the pachinko game machine PY1 of this embodiment, even if the board movable body lamp data is incorrect due to human error, when the upper board movable body 55U and the lower board movable body 55D are at their respective initial positions, It is possible to ensure that the board movable body lamps 53 provided on the upper board movable body 55U and the lower board movable body 55D do not emit light. In this way, the lighting modes of the movable board lamps 53 provided on the upper board movable body 55U and the lower board movable body 55D are ensured according to the positions of the upper board movable body 55U and the lower board movable body 55D. It is possible to control In short, in this embodiment, as shown in FIG. 11A, when the upper board movable body 55U and the lower board movable body 55D are at their respective initial positions, the board movable body lamp 53 is hidden behind the game area 6. Visible or extremely difficult to see. Therefore, even if the board movable body lamp 53 emits light at this time, it is almost impossible to exhibit the presentation effect. Therefore, when the upper board movable body 55U and the lower board movable body 55D are at their respective initial positions, the upper initial position detection sensor 55Ua and the upper initial position detection sensor 55Ua are used to reliably prevent the board movable body lamp 53 from unintentionally and wastefully emitting light. The detection by the lower initial position detection sensor 55Da forces the board movable body lamp 53 not to emit light.

10. Modifications Modifications will be described below. In the description of the modified example, the same reference numerals are assigned to the same configurations as those of the pachinko game machine PY1 of the above configuration, and the description thereof is omitted. Of course, the configurations according to the modified examples may be combined as appropriate. Moreover, technical features in the above embodiments and modifications below can be deleted as appropriate unless they are described as essential in this specification.

In the above embodiment, as shown in FIG. 14, when at least one of the upper initial position detection sensor 55Ua and the lower initial position detection sensor 55Da is OFF, the movable board lamp 53 emits light based on the movable board lamp data. I tried to make it a mode. When both the upper initial position detection sensor 55Ua (specific position detection means) and the lower initial position detection sensor 55Da (specific position detection means) are ON, the board movable body lamp 53 is turned off (in a specific light emission mode). ). However, as shown in FIG. 47, if at least one of the upper driving position detection sensor 55Ub and the lower driving position detection sensor 55Db is OFF, the movable board lamp 53 is set to emit light based on the movable board lamp data. In this way, when both the upper drive position detection sensor 55Ub (specific position detection means) and the lower drive position detection sensor 55Db (specific position detection means) are ON, the board movable body lamp 53 is set to the predetermined position. A lighting mode (a specific light emission mode) may be used.

In the case of the modified example described above, when the upper board movable body 55U and the lower board movable body 55D are in the driving position, the board movable body lamp 53 is always set in advance regardless of the board movable body lamp data. A lighting mode is possible. Therefore, even if the movable board lamp data is incorrect due to human error, the movable board lamp 53 is always lit as intended when the upper board movable body 55U and the lower board movable body 55D are in their respective drive positions. It is possible to emit light in various ways. That is, it is possible to reliably prevent a situation in which the movable board lamp 53 is unintentionally turned off even though the movable board 55 appears at the driving position.

In the above embodiment, according to the position of the movable board body 55 (movable body) arranged behind the transmissive liquid crystal display device 7 (display means), the board movable body lamp 53 provided on the board movable body 55 is turned on. The light emission mode of (light emitting means) is compulsorily determined. However, the light emitting mode of the light emitting means provided on the movable board may be forcibly determined according to the position of the movable board arranged in front of the display means.

In the above embodiment, the lighting mode of the movable board lamp 53 (light emitting means) provided on the movable board body 55 is forcibly determined according to the position of the movable board body 55 (movable body). However, the light-emitting means whose light-emitting mode is forcibly determined does not necessarily have to be provided on the movable body. For example, the lighting mode of at least a part of the frame lamp 212 or the board lamp 54 may be forcibly determined according to the position of the board movable body 55 . For example, when the board movable body 55 is at the initial position (when both the upper initial position detection sensor 55Ua and the lower initial position detection sensor 55Da are detected), at least part of the frame lamp 212 or the board lamp 54 is forcibly turned off. It is also possible to turn off the light at the same time. This is because the power consumption by the frame lamp 212 or the board lamp 54 can be reliably suppressed. Further, when the board movable body 55 is in the drive position (when both the upper drive position detection sensor 55Ub and the lower drive position detection sensor 55Db are detected), at least part of the frame lamp 212 or the board lamp 54 is forcibly turned off. A predetermined lighting mode may be used. This is because when the board movable body 55 appears, the frame lamp 212 or the board lamp 54 can be always illuminated in a lighting mode, and the production effect can be surely enhanced.

In the above embodiment, the light emission mode of the light emitting means (board movable body lamp 53) is forcibly determined according to the position of the board movable body 55 (movable body) provided on the game board 1. FIG. However, the light emitting mode of the light emitting means may be forcibly determined according to the position of the frame movable body (movable body) provided in the game machine frame 2 . In this case, the frame lamp 212 provided in the game machine frame 2 may be the light emitting means for which the light emitting mode of the light emitting means is forcibly determined. By determining the light emission mode of the frame lamp 212 provided in the game machine frame 2 according to the position of the frame movable body, the interlocking effect of the movable body provided in the game machine frame 2 and the light emitting means can be improved. This is because they can be reliably matched. The movable body is not limited to the board movable body 55 and the frame movable body. It may be an AT opening/closing member 14k or the like.

In the above embodiment, the upper initial position detection sensor 55Ua and the lower initial position detection sensor 55Da (specific position detection means) for detecting the initial position (specific position) when the plate movable body 55 is stopped are used to detect the movable plate. The light emission mode of the body lamp 53 is controlled. However, the position of the movable board body 55 (movable body) that serves as a trigger when controlling the light emission mode of the movable board body lamp 53 (light emitting means) is not limited to the position where the movable board body 55 is stopped. do not have. For example, by providing an intermediate position detection sensor capable of detecting that the movable board 55 passes through an intermediate position between the initial position and the drive position, detection by the intermediate position detection sensor causes the movable board lamp 53 (light emission) to be detected. means) may be controlled. Alternatively, the light emission mode of the movable board lamp 53 (light emitting means) may be controlled according to the number of steps of the stepping motor for moving the movable board 55 .

In the above embodiment, the effect control microcomputer 121 (light emission control means) turns off the board movable body lamp 53 when there is detection by the upper initial position detection sensor 55Ua and the lower initial position detection sensor 55Da. However, the light emission control means is not limited to the effect control microcomputer 121 . For example, the detection signal of the upper initial position detection sensor 55Ua and the detection signal of the lower initial position detection sensor 55Da are input to the sub-drive board 162 . Then, the CPU (light emission control means) provided on the sub-drive board 162 turns off the board movable body lamp 53 when there is detection by the upper initial position detection sensor 55Ua and the lower initial position detection sensor 55Da. can be

In the above mode, the board movable body appearance effect (transparent appearance effect) is executed when the battle victory image WI (see FIG. 13B) indicating that the jackpot has been won is started. That is, the board movable body appearance performance can be executed only when a big win is won in the SP reach. However, the transparent appearance effect may be executed except when a big win is won in the SP reach. For example, when it is a winning branch point in SP reach, when it develops into SP reach, a pseudo-continuous effect (a cycle with variable display of the effect symbol EZ between the start of the variable display of the special symbol and the stop display) Even if it is executed when the production pattern EZ is temporarily stopped and displayed in the production that has multiple times, or when the continuous notice (the notice production that is executed over the variable display of the special pattern multiple times) is executed. good.

In the above embodiment, while the upper board movable body 55U and the lower board movable body 55D are respectively moving from the initial position to the drive position, the display screen 7a of the transmissive liquid crystal display device 7 displays the battle victory shown in FIG. 13(B). An image WI (specific effect image) was displayed. However, the specific effect image displayed on the display screen 7a while the upper board movable body 55U and the lower board movable body 55D are respectively moving from the initial position to the driving position is not limited to the battle victory image WI. , can be changed as appropriate. For example, as a specific effect image, it is possible to appropriately change a battle image in SP reach, a character introduction image, or the like.

In the above form, if the board movable body appearance effect (transparent appearance effect) is executed, the winning of the jackpot is confirmed. However, by executing the transparent appearance effect, it may be possible to suggest that the degree of expectation for winning the jackpot is increased as the advance notice effect. In this case, for example, when the movable board body 55 at the driving position is visible, the color of the light emitted from the movable board body lamp 53 may be used to indicate the degree of expectation for winning the jackpot. . That is, the luminescent color of the board movable body lamp 53 may indicate that the winning expectation for the big win is high in the order of, for example, blue, green, red, gold, and rainbow.

In the above-described form, in the board movable body appearance effect (transparent appearance effect), two movable bodies, the upper board movable body 55U and the lower board movable body 55D at the drive position, seemed to appear. However, in the transparent appearance effect, it may be shown that three or more movable bodies appear. Alternatively, it may be shown that one movable body appears.

In the above-described mode, in the board movable body appearance effect (transparent appearance effect), the upper board movable body 55U and the lower board movable body 55D (movable body) at the drive position (operating position) move the main body of the pachinko game machine PY1. The character's face (specific motif) is formed (completed). However, the specific motif formed by the movable body in the action position may be anything other than the face of the main character, and can be changed as appropriate as long as it gives rise to a specific idea. Therefore, numbers, graphics, characters, patterns, items, and the like may be used.

In the above embodiment, the transparent film 770 (transparency switching means) can be switched between a transparent state (first state) in which the rear is visible and a non-transmissive state (second state) in which the rear is invisible. there were. However, the transparency switching means does not have to switch to the non-transmissive state in which the rear is invisible as the second state. That is, the transparency switching means may be capable of switching between a transparent state (first state) in which the rear is visible and a difficult-to-transmit state (second state) in which visibility is more difficult than in the transparent state.

In the above embodiment, when the upper board movable body 55U and the lower board movable body 55D (movable bodies) are at the initial positions (standby positions) as shown in FIG. It did not overlap in the front-rear direction with respect to Further, as shown in FIG. 11(C), when it is in the driving position (operating position), the entirety overlaps the display screen 7a of the transmissive liquid crystal display device 7 in the front-rear direction. However, the movable body may partially overlap the display screen 7a of the transmissive liquid crystal display device 7 in the front-rear direction as a standby position. As for the operating position, the display screen 7a of the transmissive liquid crystal display device 7 does not have to be partially overlapped in the front-rear direction. That is, the movable body has an initial position (standby position) where it does not overlap or partially overlaps the display screen 7a of the transmissive liquid crystal display device 7 in the front-rear direction, and the display screen 7a of the transmissive liquid crystal display device 7 is shifted from the initial position. It is sufficient if it can move to a drive position (operating position) where there are many overlapping portions in the front-rear direction.

In the above embodiment, only one big winning opening 14 is provided. However, it is also possible to provide two big prize openings, namely the first big prize opening and the second big prize opening. In this case, the first big winning hole may be opened by the big winning game, and the second big winning hole may be opened by the small winning game. Alternatively, in the jackpot game, the opening of the first big winning opening and the opening of the second big winning opening may be switched depending on the round. Further, when providing the first big prize opening and the second big prize opening, the specific area 16 may be provided in one of them.

In the above embodiment, it is configured as a game machine (so-called V probability machine) which is controlled to a high probability state based on passing through the specific area 16 into the big winning hole 14 . However, the gaming machine may be constructed such that the transition to the high-probability state is determined only by the type of the winning jackpot (jackpot pattern), or the transition to the high-probability state may be determined based on the type of the winning jackpot and the game state at the time of winning. It may be configured as a gaming machine in which transition is determined. In addition, it is configured as other types of game machines, such as so-called 1 type 2 type mixing machine, 2 type game machine (feather type game machine), and a falling machine that falls from a high probability state to a normal probability state by lottery. can be

In the above mode, as shown in FIG. 17, types of jackpots (types of jackpot symbols) are provided. However, the types of jackpots shown in FIG. 17 are only examples, and can be changed as appropriate.

In the above form, it was set so as not to win a small hit in the lottery of special symbols. However, a small winning game may be executed in which a small winning game may be won and the big winning opening 14 may be opened. In the small winning game, the opening time of the big winning opening 14 can be appropriately changed as long as it is possible to win at least one ball. However, it is desirable to set the total opening time of the big winning opening 14 to 1.8 seconds or less so that an unintended amount of prize balls is not played.

In the above embodiment, four random numbers such as a jackpot random number are obtained as random numbers (determination information) obtained based on the ball entering the first starting port 11 or the second starting port 12. Based on the obtained random number, whether or not the jackpot is won, the type of the jackpot, the presence or absence of reach, and the type of variation pattern may be determined. That is, it is possible to arbitrarily set the number of random numbers to be obtained based on the starting prize and what is determined in each random number.

Further, in the above embodiment, the pachinko game machine PY1 is configured, but it may be configured as a slot machine (rotating drum type game machine, pachislot game machine). In the case of a slot machine here, it may be of any type. In the case of a so-called normal machine (type A slot machine) that increases the number of medals obtained by winning a big bonus or regular bonus, the state in which the big bonus or regular bonus is executed corresponds to the special game state. In addition, if it is a so-called ART machine or AT machine that increases the medals acquired during a special game period such as ART (Assist Replay Time) or AT (Assist Time) that can frequently win small roles, the state during ART or AT corresponds to the special game state. In addition, in normal machines, the control condition for the special game state is that after winning the big bonus or regular bonus, each combination of symbols that triggers the transition to the big bonus or regular bonus is placed on the activated pay line. It is to be derived and displayed as a reel display result. Also, in the ART machine and AT machine, the control condition for the special game state is, for example, after winning the execution lottery of ART or AT, reaching the activation timing of ART or AT by digesting the prescribed number of games. be.

In the present embodiment, the light emitting mode of the light emitting means does not only mean the mode in which the light emitting means emits light, but also includes the mode in which the light emitting means is extinguished (non-light emitting mode in which light is not emitted, extinguished mode). is.

11. Inventions Shown in the Above-described Embodiments The above-described embodiments show inventions of the following means. In the description of the means described below, the corresponding structural names and expressions in the above-described embodiments and the reference numerals used in the drawings are added in parentheses for reference. However, the constituent elements of each invention are not limited to this appendix.

<Means A>
The invention according to means A1 is
In a game machine (pachinko game machine PY1) equipped with a production control means (production control microcomputer 121) capable of controlling production,
an image display means (transmissive liquid crystal display device 7) capable of visually recognizing the rear side of the display screen (7a);
A first state (transmissive state) in which the area behind the display screen is visible, and a second state (non-transmissive state) in which the area behind the display screen is invisible or more difficult to see than the first state. a transparency switching means (transmissive film 770) switchable to
a standby position (initial position shown in FIG. 11A) disposed behind the transparency switching means and not overlapping the display screen in the front-back direction or partially overlapping the display screen in the front-back direction; Movable bodies (upper board movable body 55U, lower board movable body 55D) that can move to an operation position (driving position shown in FIG. 11(C)) where there are more portions overlapping the display screen in the front-rear direction than positions. and
The production control means is
The transparency switching means is set to the second state while the movable body is moving from the standby position to the operating position, and the transparency switching means is switched to the second state after the movable body moves to the operating position. This game machine is characterized in that it is possible to execute a transparent appearance effect (a movable board appearance effect, FIG. 13(B)→FIG. 13(C)) for switching from the second state to the first state.

According to the gaming machine with this configuration, the transparency switching means is in the second state while the movable body is moving from the standby position to the operating position. I can't see my body After the movable body moves to the operating position, the transparent appearance effect is executed in which the transparency switching means is switched to the first state. appear. In this way, by making the movable body appear to the player as if it suddenly appeared, it is possible to enhance the impact of the presentation by the movable body.

The invention according to means A2 is
In the gaming machine according to means A1,
The production control means is
While the movable body is moving from the standby position to the operating position, a specific effect image (battle victory image WI shown in FIG. 13B) is displayed on the display screen so that the movable body performs the motion. The specific effect image is not displayed on the display screen when the transparency switching means is switched from the second state to the first state after moving to the position (see FIG. 13(B) ⇒ FIG. 13(C) ) is a gaming machine characterized by

According to the gaming machine with this configuration, while the movable body is moving from the standby position to the operating position, instead of showing the player a specific effect image displayed on the display screen, the player can see the moving movable body. I can't show you Then, when the transparency switching means is switched to the first state after the movable body moves to the operating position, instead of showing the movable body at the operating position, the specific effect image displayed on the display screen is not shown. . In this way, by instantaneously switching the object to be shown from the specific effect image to the movable body, it is possible to provide the player with a novel game interest.

The invention according to means A3 is
In the gaming machine according to means A1 or means A2,
The movable body is composed of a plurality of movable bodies (upper board movable body 55U, lower board movable body 55D),
While each of the plurality of movable bodies does not form a specific motif (the face of the main character of the pachinko game machine PY1) (see FIG. 11A) when each of the plurality of movable bodies is at the standby position, each of the plurality of movable bodies When in the operating position, it forms the specific motif (see FIG. 11(C)),
The production control means is
While each of the plurality of movable bodies is moving from the standby position to the operating position, the transparency switching means is set to the second state, and after each of the plurality of movable bodies has moved to the operating position, the A game characterized in that it is possible to execute a transparent appearance effect (a movable board appearance effect, see FIG. 13(B) ⇒ FIG. 13(C)) for switching the transparency switching means from the second state to the first state. machine.

According to the gaming machine with this configuration, the transparency switching means is in the second state while each of the plurality of movable bodies is moving from the standby position to the operating position, so the player can move behind the display screen. You cannot see multiple moving bodies that are After the plurality of movable bodies move to the operating positions, the transparent appearance effect is executed in which the transparency switching means is switched to the first state. A particular motif formed by movable bodies suddenly becomes visible. In this way, it is possible to provide the player with a novel game amusement by making it appear that a specific motif suddenly appears with a plurality of movable bodies.

By the way, the gaming machine described in Japanese Patent Laying-Open No. 2015-092893 includes image display means and a movable body that can move in front of the display screen of the image display means. In this gaming machine, when it is suggested that the probability of winning a big win is high, the movement of the movable body can give the player a sense of exhilaration. However, since the movable member moves in front of the display screen of the image display means, the moving movable body can be seen. Therefore, from the player's point of view, it does not appear that the movable body suddenly appears after movement. That is, since the player can grasp the existence of the movable body at the moment when the movable body starts to move, there is room for improvement in the impact of the presentation by the movable body. Therefore, the invention according to the means A1 to A3 described above provides a first state in which the back of the display screen is visible and the back of the display screen is visible in the gaming machine described in Japanese Patent Laid-Open No. 2015-092893. a transparency switching means capable of switching between a second state that makes it impossible or less visible than the first state; and a transparency switching means that is arranged behind the transparency switching means and does not overlap the display screen in the front-rear direction. or a movable body capable of moving between a standby position partially overlapping in the front-rear direction and an operating position in which more parts overlap in the front-rear direction with respect to the display screen than in the standby position; transparent appearance in which the transparency switching means is in the second state while the movable body is moving from the standby position to the operating position, and the transparency switching means is switched from the second state to the first state after the movable body moves to the operating position. The difference is that production can be executed. As a result, it is possible to solve the problem of increasing the impact of the presentation by the movable body (to produce an effect).

<Means B>
The invention according to means B1 is
light-emitting means capable of emitting light (plate movable body lamp 53);
A game machine (pachinko game machine PY1) comprising light emission control means (effect control microcomputer 121) capable of controlling the light emission mode of the light emission means based on light emission data (board movable body lamp data),
Movable bodies (upper board movable body 55U, lower board movable body 55D),
Specific position detection means (upper initial position detection sensor 55Ua, lower initial position detection sensor 55Da) capable of detecting that the movable body is at a specific position (initial position),
The light emission control means is
The gaming machine is characterized in that when there is detection by the specific position detection means, the light emission means is controlled to a specific light emission mode (extinguishing mode) regardless of the light emission data (see FIG. 14).

According to the game machine of this configuration, when the movable body is at the specific position, the light emitting means is in a specific light emitting mode regardless of the light emission data as a result of detection by the specific position detecting means. Therefore, even if the light emission data is erroneous due to human error, the light emission means can always be in the specific light emission mode when the movable body is at the specific position. Therefore, it is possible to make the light emitting means intended to emit light according to the position of the movable body.

The invention according to means B2 is
In the gaming machine according to means B1,
An image display means (transmissive liquid crystal display device 7) having a display screen (7a) is provided,
The movable body has a standby position (initial position shown in FIG. 11A) that does not overlap the display screen in the front-rear direction or partially overlaps the display screen in the front-rear direction. It is possible to move to an operating position (driving position shown in FIG. 11C) where there are many overlapping parts in the front-rear direction,
The specific position detection means is standby position detection means (upper initial position detection sensor 55Ua, lower initial position detection sensor 55Da) capable of detecting that the movable body is at the standby position as the specific position,
The light emission control means is
The game machine is characterized in that when there is detection by the standby position detection means, the specific light emission mode is controlled to a non-light emission mode (extinguishing mode) in which the light emission means does not emit light regardless of the light emission data.

According to the game machine having this configuration, when the movable body is at the standby position, the light emitting means can always be set to the non-light emitting mode by detection by the standby position detecting means. Therefore, it is possible to prevent a situation in which the light emitting means is caused to emit light based on erroneous light emission data even though the movable body is in the standby position, resulting in a wasteful increase in power consumption.

The invention according to means B3 is
In the gaming machine according to means B1 or means B2,
The game machine is characterized in that the light emitting means is provided on the movable body (see FIG. 11(A)).

According to the game machine with this configuration, even if the light emission data is wrong due to human error, the light emitting means provided on the movable body is always set to the specific light emission mode when the movable body is at the specific position. is possible. In this way, it is possible to reliably control the light emission mode of the light emitting means provided on the movable body according to the position of the movable body.

By the way, in the gaming machine described in Japanese Patent Application Laid-Open No. 2015-092893, various light-emitting means such as a frame lamp and a board lamp are provided. The light emission mode of the light emitting means is controlled based on the light emission data by an effect control microcomputer (light emission control means) capable of controlling the effect. However, the luminescence data is prepared in advance by the designer, and the information contained in the luminescence data is not always correct. That is, it cannot be completely denied that the light emission data may contain erroneous information due to human error. Therefore, when the light emitting means is controlled based on the light emission data, it is possible that the light emitting means does not emit light as intended. Therefore, the invention according to the above-described means B1 to B3 is provided with a specific position detection means capable of detecting that the movable body is at a specific position in the game machine described in JP 2015-092893 A, light emission control means is different in that when there is detection by the specific position detecting means, the light emitting means is controlled to a specific light emitting mode regardless of the light emission data. Thereby, it is possible to solve the problem of making the light-emitting means to have an intended light-emitting mode (to produce a function and effect).

PY1 Pachinko machine 7 Transmissive liquid crystal display device 7a Display screen 53 Movable board lamp 55 Movable board 55U Movable upper board 55Ua Upper initial position detection sensor 55D Lower movable body 55Da Lower side Initial position detection sensor 121...Production control microcomputer 770...Transparent film

Claims (2)

a light emitting means capable of emitting light;
A gaming machine comprising light emission control means capable of controlling the light emission mode of the light emission means based on light emission data,
a movable body; and
a specific position detection means capable of detecting that the movable body is at a specific position;
The light emission control means is
a detection signal indicating that the movable body is at the specific position can be input from the specific position detection means;
When the detection signal is not input, the light emission mode of the light emission means can be controlled based on the light emission data. A gaming machine characterized by controlling in a manner . In the gaming machine according to claim 1,
the specific position is an initial position when the movable body is in an initial state;
The light emission control means is
a detection signal indicating that the movable body is at the initial position can be input from the specific position detection means;
When the detection signal is not input, the light emission mode of the light emission means can be controlled based on the light emission data. A game machine characterized in that it is controlled in a non-light-emitting mode as a light-emitting mode .

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