JP2014128598A - Game machine - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a game machine having a movable accessory capable enhancing a decorative effect while retaining sufficiently a flow-down area, in which a game ball flows.SOLUTION: A game machine comprises: a flow-down area 16 forming a portion of a game area 3 partitioned and formed on a game board 2 and allowing a game ball to flow down on the front; a center case 4 constituting a portion of the flow-down area and having an opening formed in the front face of the game board; a display device for performing a performance display; and a decorative member decorating the game board. The decorative member includes: a first decorative member mounted on the front face of the center case; a second decorative member defining a portion of the flow-down area; and a third decorative member mounted on the front face of the movable accessory. The movable accessory can be converted into a first state, which is stored on the edge of the opening of the center case, and a second state, which covers a portion of the front face of the display in the inside of the opening. In the second state, the first decorative member, the second decorative member and the third decorative member are connected to form one aggregated decorative body.

Description

  The present invention relates to a gaming machine such as a pachinko gaming machine provided with a decorative member in a gaming area.

  In a conventional gaming machine, for example, a pachinko gaming machine, a variable display device is provided in the approximate center of the gaming area, and a center case is provided around the display. The variable display device displays a plurality of identification information in a variable manner corresponding to the progress of the game. Among such pachinko gaming machines, there is a game board in which a plurality of movable accessories configured to be movable in front of the variable display device are provided (for example, see Patent Document 1). This movable accessory moves in front of the variable display device as a decorative member under a predetermined condition, thereby enhancing the decorative effect of the gaming machine.

JP 2007-222515 A

  By the way, in the gaming machine as described above, since a plurality of movable accessories only move independently in front of the variable display device as decoration members, they lack power. For this reason, in order to further enhance the decoration effect of the gaming machine, it is necessary to increase the moving range of the movable accessory, and as a result, it is necessary to increase the size of the center case. However, if the center case is enlarged, the flow area where the game ball flows down is eroded, so that a sufficient flow area cannot be ensured, and the interest of the game is reduced.

  The present invention has been made in view of the above circumstances, and an object of the present invention is to provide a gaming machine equipped with a movable accessory capable of enhancing a decoration effect while sufficiently securing a flow-down area where game balls flow down. It is something to be offered.

The present invention has been proposed in order to achieve the above-described object, and according to the first aspect of the present invention, a part of the game area defined on the game board is formed, and the game ball flows down the front surface. Possible flow area,
A center case of a frame structure that forms part of the gaming area and forms an opening on the front surface of the gaming board;
A display device that exposes the display unit from the opening of the center case and displays the effect on the display unit;
In a gaming machine comprising a decorative member for decorating the gaming board,
The decorative member is
A first decorative member provided on the front surface of the center case;
A second decorative member that defines a part of the flow-down region;
A third decorative member provided on the front surface of the movable accessory moving in the game area,
The movable accessory can be converted into a first state stored at an edge of the opening of the center case and a second state covering a part of the front surface of the display unit inside the opening. And
In the second state, the first decorative member, the second decorative member, and the third decorative member are connected to form a collective decorative body.

  According to a second aspect of the present invention, the first decorative member, the second decorative member, and the third decorative member are provided with a linear decorative body that represents an outline of the collective decorative body. The gaming machine according to claim 1.

  According to a third aspect of the present invention, the second decorative member includes a light transmission region capable of transmitting light at least in part, and a surface treatment layer is formed on a back surface side of the light transmission region. A gaming machine according to claim 1 or 2, characterized in that.

The thing of Claim 4 is comprised by the several movable member which the said movable accessory can move to a predetermined position, and each can connect,
A protrusion is provided on the connection surface of one movable member in the movable members that are connected to each other among the plurality of movable members,
4. The gaming machine according to claim 1, wherein the connecting surface of the other movable member that is connected to the one movable member is provided with a concave portion that fits into the protruding portion. 5.

According to a fifth aspect of the present invention, the protruding portion has a shape that tapers toward a connection surface of the other movable member,
5. The projection according to claim 4, wherein when the one movable member and the other movable member move to a predetermined position, the tip of the projection is slid into the recess from the edge of the recess. It is a gaming machine described.

According to the present invention, the following excellent effects can be obtained.
That is, according to the first aspect of the present invention, a part of the game area defined on the game board is formed, a flow area where the game ball can flow down the front surface, and a part of the game area. A frame-structured center case that forms an opening in the front surface of the game board, a display device that exposes the display unit from the opening of the center case and displays an effect on the display unit, and a decoration that decorates the game board In the gaming machine including the member, the decoration member moves in the game area, the first decoration member provided on the front surface of the center case, the second decoration member that defines a part of the flow-down area, and A third decorative member provided on the front surface of the movable accessory, wherein the movable accessory is in a first state stored at the edge of the opening of the center case, and on the inside of the opening, In the second state, it can be converted to the second state covering a part of the front surface. Since the first decorative member, the second decorative member, and the third decorative member are connected to form one collective decorative body, not only the decorative effect of the movable accessory alone, but also the center case and the flow-down region Since a decoration effect by a large collective ornament using a part of the front surface can be obtained, the decoration effect of the game board can be enhanced while securing a flow-down area. Note that the collective decorative body is a single character, symbol, design, or the like formed by a collection of a plurality of decorative members, or a combination thereof, which is recognized as a single decorative body through vision.

  According to the second aspect of the present invention, the first decorative member, the second decorative member, and the third decorative member are provided with the linear decorative body that represents the outline of the collective decorative body. By emphasizing the outline of the decorative body, it is possible to form a collective decorative body with a sense of unity. As a result, the decoration effect of the game board can be further enhanced.

  According to the invention described in claim 3, the second decorative member includes a light transmission region capable of transmitting light at least in part, and a surface treatment layer is formed on the back side of the light transmission region. Therefore, the surface treatment layer can be recognized through the light transmission region from the front of the second decorative member, and the flow-down region can be decorated. Further, even if the game ball flows down the front surface of the second decorative member, the surface treatment layer is not soiled or peeled off.

  According to the fourth aspect of the present invention, the movable accessory is constituted by a plurality of movable members that can be connected to each other by moving to a predetermined position, and one of the movable members that are connected to each other among the plurality of movable members. Since the projecting portion is provided on the connection surface of the movable member, and the recess surface that fits the projection portion is provided on the connection surface of the other movable member that is connected to the one movable member, a plurality of movable members are attached to the predetermined surface. It is possible to firmly connect at the position, and it is possible to prevent a shift of the connection portion due to external vibration or the like. In addition, since a plurality of movable members can be connected with a simple configuration without using a magnet or the like, the manufacturing cost can be reduced.

  According to the fifth aspect of the present invention, the protrusion has a shape that tapers toward the connecting surface of the other movable member, and when the one movable member and the other movable member move to a predetermined position. In addition, since the tip of the protrusion is fitted into the recess by sliding from the edge of the recess, even if one movable member is not accurately waiting at a predetermined position, it can be connected to the other movable member, Connection failure can be suppressed.

It is a front view of a game board. It is a perspective view of a game board. It is a disassembled perspective view when the game board is viewed from the front. It is a disassembled perspective view when a game board is seen from back. (A) is an enlarged front view in a state in which the first start prize opening decoration member is provided in the game board, and (b) is an enlarged cross-sectional view in a state in which the first start prize opening decoration member is provided in the game board. (A) is a front view of an upper decorative member, (b) is an AA cross-sectional view, and (c) is a region B enlarged view. (A) is a front view in a state where the upper movable accessory and the lower movable accessory are separated from each other, (b) is an enlarged front view of the lower movable accessory, and (c) is a connecting portion between the upper movable accessory and the lower movable accessory. (D) is an enlarged view of the region C illustrating the connection between the upper movable accessory and the lower movable accessory. (A) is a front view of the upper movable accessory, (b) is a perspective view in which the upper movable accessory is partially cut away along the DD section, and (c) is a DD sectional view. (A) is a front view of a 1st light emission movable accessory, (b) is EE sectional drawing, (c) is a schematic diagram in EE sectional drawing explaining light emission of the light emission source. It is a front view of the game board in the state where the upper movable combination and the lower movable combination are connected. It is a front view of the game board in the state in which the 1st light emission movable combination and the 2nd light emission movable combination are driving. (A) is a front view of the game board, (b) is an enlarged view of a main part explaining the attachment of the control base to the game board, and (c) is a main part explaining the attachment of the control base to the game board in other embodiments. It is an enlarged view. It is a perspective view of the game board in 2nd Embodiment. It is a perspective view of the state where the armor decoration member was removed from the center case in a 2nd embodiment. It is a figure explaining the armor member in 2nd Embodiment, (a) is a principal part enlarged view when the armor member is seen from the outside, (b) is a principal part enlarged view when the armor member is seen from the inside. (C) is a principal part enlarged view explaining attachment of the armor decoration member with respect to a center case, (d) is principal part sectional drawing explaining attachment of the armor decoration member with respect to a center case. It is a block diagram of a game board. It is a block diagram of the arithmetic processing unit (amuse chip) for games. It is a block diagram around the arithmetic processing unit (amuse chip) for games provided in the game control device. It is explanatory drawing of user work RAM. It is explanatory drawing of a stack area | region. It is a flowchart of the process at the time of power-on of a game control device, a payout control device, and an effect control device. It is a flowchart of the first half of a game control apparatus main process. It is a flowchart of the latter half part of a game control apparatus main process. It is explanatory drawing of a delay process. It is explanatory drawing of the delay process in other embodiment. It is a flowchart which shows a timer interruption process. It is the timing chart of the state of the communication port with which the game control apparatus at the time of power activation, the payout control apparatus, and the production | presentation control apparatus performs, and the game control apparatus. It is a flowchart for demonstrating the procedure in the case of transmitting instruction | command from a game control apparatus to an effect control apparatus and a payout control apparatus. It is explanatory drawing of the command signal transmitted to a payout control apparatus and an effect control apparatus from a game control apparatus. It is explanatory drawing of the signal transmitted to a payout control apparatus. It is explanatory drawing of the signal transmitted to an effect control apparatus. It is a figure explaining the specification of a gaming machine. It is explanatory drawing of the display content of a display apparatus. It is a flowchart of the second half part of the production control device main process.

  Hereinafter, the best mode for carrying out the present invention will be described with reference to the drawings, taking a pachinko gaming machine 1 as a typical gaming machine as an example. FIG. 1 is a front view of the game board 2 of the pachinko gaming machine 1, and FIG. 2 is a perspective view of the game board 2 of the pachinko gaming machine 1. 3 and 4 are exploded perspective views of the game board 2 when viewed from the front and rear, respectively. In FIGS. 3 and 4, members attached to the front surface of the game board 5 such as a display device and a winning opening and a guide rail are omitted.

  The game board 2 of the pachinko gaming machine 1 has a frame structure in which a game area 3 is partitioned and formed on the front surface thereof, forms a part of the game area 3, and forms an opening 7 on the front surface of the game board 2. A center case 4, a game board 5 to which the center case 4 is attached on the front side and serving as a base of the game board 2, a control base 6 attached to the rear side (back side) of the game board 5, and the control base 6, and is schematically configured to include a display device 8 that displays the display 9 by exposing the display 9 from the opening 7 of the center case 4, and a decorative member that decorates the game board 2. Specifically, as shown in FIG. 1, the front surface of the game board 5 is fixed to a substantially C-shaped first guide rail 10 made of a metal strip on the left side of the surface, and the inner side of the first guide rail 10. The arc-shaped second guide rail 12 is fixed at a predetermined interval to become the hitting ball passage 11. In addition, a horizontally long upper side case 13 is provided on the upper side of the game board 5, and an arc surface that is continuous with the upper end portion of the first guide rail 10 is formed in the lower portion of the upper side case 13. A vertically long right side case 14 is provided on the right side of the game board 5, and an arc surface continuous with the arc surface of the upper side case 13 is formed on the upper left side of the right side case 14. Thus, the area formed in a substantially circular shape by the first guide rail 10, the second guide rail 12, the arc surface of the upper side case 13, and the arc surface of the right side case 14, forms the game area 3 of the game board 2. Forming. In the present embodiment, a center case mounting hole 15 (see FIGS. 3 and 4) is opened in the center portion of the game board 5 (game area 3) in the thickness direction, and the center case mounting hole 15 is opened. The center case 4 is fitted and attached to the front. A plurality of obstacle nails 22 are provided on the front surface of the game board 5 around the center case 4 inside the game area 3 to guide the game balls flowing down and adjust the flow force of the game balls. This region constitutes most of the flow-down region 16 where the game ball can flow down.

  Further, as shown in FIG. 1, a stepped portion 17 in which a part of the right side case 14 protrudes toward the center case 4 side is formed on the side portion facing the tip of the hitting ball passage 11 in the right flowing region 16. In addition, a buffer member that constitutes a part of the surface of the stepped portion 17 (a location where a game ball that has traveled along the arc surface of the upper side case 13 collides) is formed on a part of the stepped portion 17. 18 is disposed. The buffer member 18 is formed of an impact-resistant resin or the like so that the game ball that has been vigorously advanced toward the right-side down area 16 collides and changes the down-flow direction. An armor member 19 of the center case 4 to be described later is disposed at a certain distance from the right side case 14, and a part of the armor member 19 is aligned with the stepped portion 17 of the right side case 14. An armor step 20 that is recessed is formed. Thereby, a ball flow down passage 21 through which a game ball can pass is formed between the right side case 14 and the armor member 19. Further, on the side surface of the armor member 19 facing the buffer member 18, a failure nail row 23 including a plurality of failure nails 22 arranged in a row is provided.

  Moreover, the cell sheet 24 (a kind of surface treatment layer in this invention) which printed patterns, such as a picture and a character, is affixed on the surface of the game board | substrate 5 (refer FIG. 5). Further, below the center case 4, there is a first start winning port decoration member 26 (corresponding to one of the second decorative members of the present invention, which will be described later) having a first start winning port 25 for starting a variable display game. Below the first start winning opening decoration member 26, there is a large winning opening (special variable winning apparatus) 27 that can be converted into a state in which a game ball is not accepted and a state in which it is easy to accept as the game progresses. Below the winning opening 27 and at the lower edge of the gaming area 3, an out opening 28 is provided for collecting the game balls that have flowed down without winning. Further, on the side of the left side of the first start winning opening 25 (second guide rail 12 side), a general winning opening 32 through which a game ball can win along the side surface of the second guide rail 12 has an arc shape. The second start winning opening 30 is provided on the right side of the first starting winning opening 25 (on the side opposite to the second guide rail 12). Further, an ordinary symbol start gate 31 is provided above the second start winning opening 30 (to the right side of the center case 4), and below the second starting winning opening 30 is a special figure indicator 120 and a general purpose display. A symbol display unit 29 in which a figure display 121 (see FIG. 16) is integrated is provided. Then, the game balls of the pachinko gaming machine 1 are advanced by winning the game balls in the first start winning opening 25, the second starting winning opening 30, and the normal symbol starting gate 31. Specifically, when the game ball wins (passes) the normal symbol start gate 31, the symbol display unit 29 displays the normal variation display game, and the result mode of the general variation display game indicates “winning”. In this case, the normal variation winning device 33 of the second start winning opening 30 is opened, and the game ball is converted into a state where it is easy to win the second starting winning opening 30. When the game ball wins the first start winning opening 25 or the second start winning opening 30, the symbol display unit 29 plays a special figure variation display game (first special figure variation display game or second special figure variation display game). Go and change the display. The winning of the game ball to the general winning opening 32 is detected by the winning openings SW (switches) 32A to 32N (see FIG. 16) provided in the general winning opening 32, and the game balls to the normal symbol starting gate 31 are detected. The passage is detected by a normal start SW (switch) 31A (see FIG. 16). In addition, the winning of the game ball to the first start winning opening 25 and the second start winning opening 30 is detected by the special start SW (switch) 25A, 30A (see FIG. 16), the game ball to the big winning opening 27 The winning is detected by a count SW (switch) 27A (see FIG. 16) provided in the special winning opening 27. Further, the opening / closing of the normal variation winning device 33 is performed by energizing a general electric solenoid (general power SOL) 95 (see FIG. 16), and the state conversion of the big winning port 27 is performed by the large winning port solenoid (large winning port SOL). ) 96 (see FIG. 16).

  On the other hand, on the rear surface (back surface) of the game board 5, when a control base 6 to be described later is attached, a guide hole 35 serving as a guide for the attachment position of the control base 6 is opened without penetrating in the thickness direction. (See FIG. 4). In the present embodiment, two game boards 5 are provided on the upper left side and the lower right side when the game board 5 is viewed from the rear in correspondence with a reference convex part 36 (described later) provided on the front surface of the control base 6. The attachment of the control base 6 and the center case 4 will be described later. The guide hole 35 is formed in the game board 5 by a router or the like.

  Next, the first start winning opening decoration member 26 attached to the game board 5 will be described. As shown in FIG. 5, the first start winning opening decoration member 26 is one of decoration members that decorate the game board 2, and is a crescent-shaped plate member that curves downward. The front face of the first start winning opening decoration member 26 constitutes a part of the flow-down area 16 where the game ball flows down, and the back face is decorated. Further, at the center of the first start winning opening decoration member 26, a first start winning opening 25 for winning a game ball, and a flow direction change projecting forward at the left and right sides of the first starting winning opening 25 are shown. Each member 37 is provided. The first start winning port 25 is one of the winning ports through which game balls win as described above, and a ball channel is formed in the interior thereof toward the back of the game board 2. The winning game ball is sent to the rear side of the game board 2 by this ball flow path. The flow direction changing member 37 is a member that prevents the game ball from winning from above the central portion of the big prize opening 27, and collides with the game ball flowing down toward the upper part of the central portion of the big prize opening 27. , The flow direction is changed. Here, the game ball whose flow direction has changed is won from the end of the big prize opening 27 to the big prize opening 27 or is removed from the big prize opening 27 and collected from the out opening 28. That is, it is possible to adjust the winning rate for winning the big winning opening 27 by the flow direction changing member 37. Further, a first start winning opening linear ornament 38 formed by dividing the first start winning opening decoration member 26 is provided on the edge of the lower arc of the first start winning opening decoration member 26. The first start prize opening decoration member 26 is integrally formed of a transparent (or translucent) resin member together with the flow direction changing member 37 and the first start prize opening linear decoration body 38. For this reason, the decorative member applied to the rear of the first start prize opening decorative member 26 can be visually recognized from the front, and light from a light source such as an LED (light emitting device 92a in FIG. 16) provided at the rear can be seen. Can be transmitted. Moreover, since the 1st start winning opening linear decoration body 38 is also formed of the transparent (or translucent) resin member, the decoration on the back side can be visually recognized. In the present embodiment, the cell sheet 24 of the game board 5 is arranged on the back side of the first start winning opening linear ornament 38, and a metallic glossy portion 24a having metallic luster is formed in that portion (see FIG. 5). ). Thereby, the decoration with metallic luster can be visually recognized from the front of the first start winning opening linear ornament 38.

  Next, the center case 4 will be described. The center case 4 is a frame-like member that forms an opening 7 on the front surface of the game board 2, and a case decoration that extends from the left and right of the upper edge of the opening 7 on the front surface of the center case 4. A member 39 (corresponding to the first decorative member of the present invention) and an armor for preventing the game ball from flowing into the center case 4 from above the case decorative member 39 to the right side of the center case 4 A member 19, an armor decoration member 40 for decorating the inside (opening 7 side) of the armor member 19, and an upper decoration member 41 provided along the upper edge of the case decoration member 39 (second embodiment of the present invention) 1), a character decoration member 42 provided on the right edge of the opening 7, and a lower edge of the opening 7. The game ball flowing in from a warp opening (not shown) A rolling surface (stage) 43 that rolls in the left-right direction; A stage lower decorative member 44 for decorating the lower sliding surface 43 (corresponding to one of the second decorative member of the present invention) is provided. A display device 8 that displays a plurality of pieces of identification information variably in response to the progress of the game faces the opening 7 from behind, and a game ball that has entered the rolling surface 43 is on the surface of the opening 7. A clear case is provided so as not to enter the display device 8 side. Further, on the rolling surface 43, there are provided a sphere inlet 45 opened at the center and a sphere guide 46 recessed in a groove shape on both the left and right sides (see FIG. 2). The ball inflow port 45 communicates with a ball outflow port 47 opened in the stage lower decoration member 44 via an internal ball flow path, and the game ball flowing into the ball inflow port 45 from the rolling surface 43 is passed through the ball outflow port. 47. The ball guide portion 46 is formed by a curved surface having a bottom surface recessed in the center in the left-right direction, and the game ball swings the ball guide portion 46 left and right by inclining the curved surface downward. However, it is configured to roll forward.

  The case decoration member 39 is one of decoration members for decorating the game board 2 and is formed so as to protrude forward so that the game ball can be prevented from flowing into the center case 4 together with the upper armor member 19. Has been. The case decoration member 39 is formed of a transparent (or translucent) resin member with a decoration on the front side, and can transmit light from a light emitting source such as an LED (light emitting device 92b in FIG. 16) provided at the rear. Is formed. In addition, a case line-shaped decorative body 49 is formed along the outer shape of the case decorative member 39 at the inner edge (in the display unit 9 side) of the case decorative member 39 and the edge facing the armor decorative member 40. Yes. A metal layer formed by metal plating is formed on the surface of the case linear decorative body 49.

  The armor member 19 is a bowl-shaped member that protrudes forward from the upper side to the right side of the case decoration member 39, and is formed in a substantially arc shape along the arc surfaces of the upper side case 13 and the right side case 14. ing. In addition, as described above, the armor member 19 is formed with the armor step 20 that is recessed toward the opening 7 in accordance with the step of the right side case 14. A game ball that has flowed down the rightward flow area 16 collides with the armor step portion 20 to change the flow direction. An armor decoration member 40 is provided on the inner side (opening 7 side) of the armor member 19 from the upper side to the right side of the armor member 19.

  The armor decoration member 40 is a member that decorates the inside of the armor member 19, a horizontally long upper armor decoration member 50 that is positioned inside the upper armor member 19, and the armor member 19 that extends from the armor step 20 to the right end. And a vertically long side armor decoration member 51 located inside. That is, the upper armor decoration member 50 is formed by being sandwiched between the upper armor member 19 and the case decoration member 39, and the side armor decoration member 51 is formed of the right armor member 19, the case decoration member 39 and the later-described armor decoration member 39. It is formed by being sandwiched between character decoration parts.

  The upper decorative member 41 is a plate-shaped member whose upper side on the case decorative member 39 side is aligned with the upper side of the case decorative member 39 and whose lower side is formed along the outer left edge of the case decorative member 39. The upper decorative member 41 of the present embodiment is formed of a transparent (or translucent) resin member, and the rear surface is decorated. For this reason, the decoration can be visually recognized from the front. Further, a light source (such as a light emitting device 92c in FIG. 16) such as an LED is provided behind the upper decorative member 41, and light from this light source can be transmitted. The front surface of the upper decorative member 41 is located behind the front surface of the case decorative member 39, and is aligned so that the front surface of the game board 5 is substantially flush with the front and rear direction. That is, the case decoration member 39 constitutes one of the decoration members that decorate the game board 2, and its front surface defines a part of the flow-down area 16. Further, the upper linear decoration aligned with the same width as the case linear decorative body 49 is provided on the upper side (opposite side of the case decorative member 39) of the periphery (edge) of the case decorative member 39. A body 52 is provided. The upper linear decorative body 52 is integrally formed of a transparent (or translucent) resin member. As shown in FIG. 6, a metal layer 53 (in the present invention) is formed on the surface on the back side thereof. A kind of surface treatment layer) is formed. For this reason, the decoration by the metal layer 53 can be visually recognized from the front.

  The character decoration member 42 is a transparent (or translucent) resin member that represents a continuous character (logo) made up of characters, symbols, and the like on the surface. The character decoration member 42 is configured to cover a part of the upper movable accessory 58 on the front side in a state where the upper movable accessory 58 described later is stored in the edge of the opening 7 of the center case 4. The light from the upper movable member 58 can be transmitted. Accordingly, if the upper movable accessory 58 is stored in the edge of the opening 7, if the light is emitted, the character decoration member 42 can be seen to emit light.

  The stage lower decoration member 44 is a transparent (or translucent) resin member with a decoration on the surface, and can transmit light from a light emitting source such as an LED (light emitting device 92d in FIG. 16) provided behind the stage. Forming. In addition, a ball outlet 47 is opened at the center of the surface of the stage lower decorative member 44. As described above, the game ball that has flowed into the ball inlet 45 flows down the ball channel and flows into the ball outlet 47. It is formed so that it can flow out of. Then, the game ball that has flowed out from the ball outlet 47 and the game ball that has rolled forward from the ball guide portion 46 of the rolling surface 43 flow down the front surface of the stage lower decoration member 44. That is, the stage lower decoration member 44 constitutes one of the decoration members that decorate the game board 2, and the front surface thereof constitutes a part of the flow-down area 16 where the game ball can flow down. The stage lower decoration member 44 has a lower end width that is the same as the first start prize opening decoration member 26 when viewed from the front, and an upper end width that is the same as the lower end width of the lower movable accessory 59 described later. ing. In this embodiment, it is formed in a slightly tapered shape from the lower end side toward the upper end side. A case linear ornament 49 (or a first start winning opening linear ornament 38 or a lower movable accessory linear ornament 74 to be described later) is provided at the left and right edges of the front surface of the stage lower ornament member 44. The stage lower line-shaped decorative body 48 having the same width as that of the first stage is provided. The stage lower linear decorative body 48 is integrally formed of a transparent (or translucent) resin member, and a metal layer (a kind of surface treatment layer in the present invention) by metal plating is formed on the back side surface thereof. Is formed. For this reason, the decoration by a metal layer can be visually recognized from the front.

  On the other hand, on the rear surface of the center case 4, as shown in FIG. The alignment convex portion 55 is a protrusion protruding rearward from the rear surface of the center case 4 and is formed in a tapered shape in the present embodiment (see FIG. 12B). In the present embodiment, as shown in FIG. 12B, the length of the alignment convex portion 55 (the distance between the rear surface of the center case 4 and the rear end surface of the alignment convex portion 55) is the length of the reference convex portion 36 ( The distance between the front surface of the control base 6 and the front end surface of the reference convex portion 36 is longer than the distance. Furthermore, in the present embodiment, two center guides 4 are provided at an upper left position and a lower right position when the center case 4 is viewed from the rear, corresponding to the alignment recesses 54 provided on the front surface of the control base 6. The length of the alignment protrusion 55 may be any length as long as it can be engaged with the alignment recess 54 when the control base 6 and the center case 4 are brought into contact with each other. It can also be formed to have the same length as the length of the convex portion 36 (the distance between the front surface of the control base 6 and the front end surface of the reference convex portion 36) (see FIG. 12C). The attachment of the control base 6 and the center case 4 will be described later.

  Next, the control base 6 will be described. As shown in FIGS. 3 and 4, the control base 6 is formed in a frame structure having a display opening 56 and exposes the display unit 9 of the display device 8 attached to the rear surface side to the display opening 56. ing. That is, the display unit 9 of the display device 8 is exposed through the display opening 56 of the control base 6 and the opening 7 of the center case 4. Further, the control base 6 of the present embodiment is formed of a transparent resin or the like. Further, on the front surface of the outer periphery of the control base 6, a control base mounting portion 57 that is in contact with the rear surface of the game board 5 and is screwed is formed in a bowl shape. Then, at the edge of the display opening 56 behind the control base mounting portion 57, as viewed from the front, the upper movable accessory 58 is on the right side, the lower movable accessory 59 is on the lower side, and the first light emitting movable accessory 60 is on the left side. The second light emitting movable accessory 61 is provided on the upper side, and these are stored in the edge of the opening 7 of the center case 4 in a state where they are not driven. It should be noted that the upper movable accessory 58 and the lower movable accessory 59 are each a connected movable accessory 62 (corresponding to the movable accessory of the present invention) that moves to a predetermined position and is connected to each other (FIGS. 3 and 7). Etc.). Further, a small symbol display unit 64 for displaying information related to the progress of the game is separately provided on the lower edge of the display opening 56 (the lower side of the control base 6). The symbol display unit 64 of the present embodiment is configured so that when any one of the connected movable accessory 62, the first light emitting movable accessory 60, and the second light emitting movable accessory 61 moves into the display unit, it does not interfere with them. It is formed at the edge of the display opening 56 on the left side of the lower movable accessory 59 (see FIG. 1 and the like).

  In addition, on the front surface of the control base 6, a guide convex portion 36 that faces the guide hole 35 of the game board 5 and an alignment recess 54 that engages with the alignment convex portion 55 of the center case 4 are provided. The guide protrusion 36 is formed on the outer periphery of the control base 6 so that the control base 6 can be easily aligned with the guide hole 35 when the control base 6 is attached to the game board 5. The reference convex portion 36 of the present embodiment is formed by projecting a circumferential edge of a hole opened in the control base mounting portion 57 toward the front. Further, the tip is formed to a height that does not contact the bottom of the guide hole 35 when the control base 6 is attached to the game board 5. Furthermore, the diameter of the reference convex portion 36 is formed to be smaller than the diameter of the reference hole 35. Then, two guide protrusions 36 of the present embodiment are provided on the lower left side and the upper right side when viewed from the front of the control base 6 so as to correspond to the guide holes 35 of the game board 5. The alignment recess 54 is a hole whose front side is open inside the reference hole 35 (on the display opening 56 side). The alignment recess 54 is reduced in diameter toward the rear so as to be engageable with the alignment protrusion 55 in accordance with the shape of the alignment protrusion 55. Further, in the present embodiment, two control bases 6 are provided at an upper right position and a lower left position when viewed from the front so as to correspond to the alignment convex portion 55 of the center case 4.

  The upper movable accessory 58 is a hollow box-like vertically long member, and its front surface constitutes one of the decorative members. More specifically, as shown in FIG. 8, the upper movable accessory 58 has a box-shaped upper movable accessory base member 65 containing a light emitting source such as an LED (the light emitting device 92e in FIG. 16), and a front thereof. The upper movable member decoration member 66 that forms the front surface of the upper movable member 58 by being covered, and the light diffusion plate 67 disposed between them and in front of the light emitting source are configured. The upper movable accessory base member 65 is a member that forms a side wall surrounding the periphery of the upper movable accessory 58 (the rear surface of the upper movable accessory 58) and its periphery. The light diffusing plate 67 is a member that diffuses light from the light source, and is a transparent resin member in which a groove that diffuses light is formed on the surface. The upper movable accessory decoration member 66 is a transparent (or translucent) resin member with a decoration on the front surface, and is formed so as to transmit diffused light transmitted through the light diffusion plate 67. In addition, on both the left and right sides of the upper movable accessory decoration member 66, an elongated movable movable accessory linear ornament body 68 is provided (the upper movable accessory decoration member 66 and the upper movable accessory linear ornament body). 68 (that is, the member constituting the front surface of the upper movable accessory 58 corresponds to the upper portion of the third decorative member of the present invention). The upper movable accessory linear decorative body 68 has a metal layer 53 formed by metal plating on the front side surface, and the width thereof is the width of the lower movable accessory linear decorative body 74 and the case linear decorative body 49. The width is aligned to the same level. The upper movable accessory linear decorative body 68 of the present embodiment is formed in a bowl shape at the front end of the side wall (the standing wall standing up from the bottom portion) located on the left and right of the upper movable accessory base member 65. Yes. Further, on the upper part of the upper movable accessory base member 65, there is a swing shaft 71 that swings by transmitting power from a drive source such as a motor (drive source 93a in FIG. 16) via a gear or the like. The swing shaft 71 is pivotally attached to the upper end of the right side of the control base 6. As a result, when the drive source is driven, the upper movable accessory 58 can be swung around the swinging shaft 71, and the display device 8 displays from the state of waiting on the right edge of the opening 7 of the center case 4. It can convert into the state which coat | covers the center part of the part 9. FIG. The upper movable accessory 58 is partially exposed from the opening 7 (see FIG. 1) in a state where it waits at the right edge of the opening 7 of the center case 4. It constitutes part of the edge. In addition, a protrusion 69 having a shape that tapers in a downward direction on a lower side (lower movable accessory 59 side) surface (a connection surface with the lower movable accessory 59) of the upper movable accessory base member 65. Is provided. Two protrusions 69 are provided at positions corresponding to the recesses 70 of the lower movable accessory 59 so that the projections 69 can be fitted into the recesses 70 of the lower movable accessory 59 described later.

  Similar to the upper movable accessory 58, the lower movable accessory 59 is a hollow box-like vertically long member, and its front surface constitutes one of the decorative members. More specifically, the lower movable combination 59 is a box-shaped lower movable combination base member 72 that houses a light emitting source such as an LED (light emitting device 92f in FIG. 16), and a lower movable combination by covering the front thereof. The lower movable accessory decoration member 73 that forms the front surface of the object 59, and a light diffusing plate disposed between them and in front of the light source. The lower movable accessory base member 72 is a member constituting a bottom portion of the lower movable accessory 59 (a rear surface of the lower movable accessory 59) and a side wall surrounding the periphery thereof. The light diffusing plate is a member that diffuses light from the light emitting source, and is a transparent resin member in which a groove that diffuses light is formed on the surface. The lower movable accessory decoration member 73 is a transparent (or translucent) resin member having a decoration on the front surface, and is formed so as to transmit the diffused light transmitted through the light diffusion plate. In addition, on both the left and right sides of the lower movable accessory decoration member 73, elongated lower movable accessory linear ornaments 74 are provided (the lower movable accessory decoration member 73 and the lower movable accessory linear ornaments). 74 (that is, the member constituting the front surface of the lower movable accessory 59 corresponds to the lower portion of the third decorative member of the present invention). The lower movable accessory linear decorative body 74 has a metal layer 53 formed by metal plating on the surface on the front side, and the width of the lower movable accessory linear decorative body 68 and the stage lower linear decorative body 48 is the same. It is aligned to the same width as the width. The lower movable accessory linear decorative body 74 of the present embodiment is formed in a bowl shape at the front ends of the side walls (standing walls standing up from the bottom portion) located on the left and right of the lower movable accessory base member 72. Yes. A rack gear (not shown) that transmits power from a drive source such as a motor (drive source 93b in FIG. 16) via a gear or the like is provided at the bottom of the lower movable accessory base member 72. It arrange | positions along the linear decoration body 74 (up-down direction). Thereby, if the drive source is driven, the lower movable accessory 59 can be moved up and down, and the center lower portion of the display unit 9 of the display device 8 from the state of waiting at the lower edge of the opening 7 of the center case 4. Can be converted into a covering state. In addition, a concave portion 70 that fits with the protrusion 69 is provided on the surface (connecting surface) on the upper side (upper movable accessory 58 side) of the lower movable accessory base member 72. The recess 70 opens in a V-shaped cross section in accordance with the tapered shape of the protrusion 69. For this reason, when the upper movable accessory 58 and the lower movable accessory 59 move to a predetermined position, the tips of the protrusions 69 slide into the recesses 70 from the edges of the recesses 70, and the connecting surfaces of both members Can be connected together.

  As shown in FIG. 9, the first light-emitting movable accessory 60 is an accessory that is decorated with light and swings at a predetermined timing, and is decorated on the surface. The center case 4 is not driven. Is stored in the left edge of the opening 7. The first light-emitting movable accessory 60 is connected to an intermittent gear 75 pivotally attached to the upper end of the left side of the control base 6 and one end (the upper side of FIG. 9A) on the toothless side of the intermittent gear 75. The first light-emitting movable accessory body 76 is made. The intermittent gear 75 is connected to a drive source such as a motor (a drive source 93c in FIG. 16) via a gear or the like, and transmits power from the drive source. For this reason, when the drive source is driven, the first light-emitting movable accessory 60 (first light-emitting movable accessory body 76) is moved from the left edge of the opening 7 of the center case 4 to the center of the display unit 9 of the display device 8. Can be swung toward. The first light-emitting movable accessory body 76 is a half on the left side in a state where it is stored on the front side (on the left edge of the opening 7 of the center case 4) by a non-translucent member that does not transmit light (colored resin or the like) ), And the other side of the front surface (transparent or translucent resin, etc.) adjacent to the non-translucent portion 77 and transmitting light (half of the right side in the above state). The light-transmitting part 78 formed with the light-transmitting part 78 and the light-transmitting part 78 and the non-light-transmitting part 77, and the LED board 79 (the light-emitting device 92g in FIG. 16) mounted thereon, And a reflecting member 81 that reflects light provided between the light transmitting portion 77 and the light transmitting portion 77. The LED 79 is mounted at a position facing the reflecting member 81 on the front surface of the electric decoration board 80, and can emit light at a predetermined timing. The reflection member 81 is formed so that the portion facing the LED 79 is inclined with respect to the electric decoration substrate 80 so that the light from the LED 79 can be reflected to the light transmitting portion 78 side. A layer that reflects light, such as resin, is formed. The electrical decoration board 80 is formed so that at least a portion facing the light-transmitting portion 78 on the front surface can reflect light so that the light reflected by the reflecting member 81 can be easily reflected. Such an electrical decoration board | substrate 80 can be formed by coating the surface of the front side with the paint which has metallic luster, or a white paint, for example. The translucent part 78 has a partition wall part 78a that partitions the boundary with the non-translucent part 77, and a front curve that forms a front surface of the translucent part 78 that is curved while being inclined downward to the opposite side of the non-translucent part 77. 78b, and a plurality of fine grooves 82 are formed on the inner surface thereof. The groove 82 can diffuse light transmitted through the front curved portion 78b and the partition wall portion 78a. Note that a pigment having a large particle diameter or the like may be applied to the surfaces of the reflecting member 81 and the electric decoration substrate 80 so that light is easily diffusely reflected. Further, the reflecting member 81 itself may be formed of a metal or a white resin or the like, and the electric decoration substrate 80 itself may be formed of a white resin or the like.

  Thus, since the 1st light emission movable accessory main body 76 was comprised, the light from LED79 can be reflected in the translucent part 78 side by the reflection member 81, and this reflected light can be reflected by the front surface of the electrical decoration board | substrate 80. . For this reason, the light of LED79 can be visually recognized from the exterior of the translucent part 78 indirectly. The reflected light is diffused when passing through the front curved portion 78b (translucent portion 78), and the light can be viewed from outside the front curved portion 78b (translucent portion 78) ( Solid line arrow in FIG. 9C). The light visible from the outside of the translucent part 78 is not limited to the above-described reflected light (indirect light), but also the direct light of the LED 79 that does not reflect and passes through the partition wall part 78a and the front curved part 78b. Slightly included (dashed arrow in FIG. 9C). This direct light is diffused twice by the groove 82 formed in the partition 78a and the front curved portion 78b when transmitted. In addition, the groove | channel 82 formed in the partition part 78a and the front curved part 78b may be formed not only in an inner surface but in an outer surface or both an inner surface and an outer surface.

  The second light-emitting movable accessory 61 is the same accessory as the first light-emitting movable accessory 60 that can be decorated and oscillated with LEDs (light-emitting device 92h in FIG. 16), but is intermittent gear (not shown). ) (The number of teeth) and the decorative shape of the surface are different from the first light-emitting movable accessory 60. More specifically, the second light emitting movable member 61 is formed so that the diameter of the intermittent gear is larger (the number of teeth) than that of the first light emitting movable member 60, and a drive source such as a motor (FIG. 16). In this case, the reduction ratio is set lower than that of the first light-emitting movable accessory 60. For this reason, in the state which is not driven, it can suppress that the 2nd light emission movable accessory 61 rock | fluctuates below by the vibration of the game board 2, etc. Further, the second light-emitting movable accessory 61 has an intermittent gear axially attached to the right end portion of the upper side of the control base 6 and is not driven. It is stored in the upper edge of the opening 7 of the center case 4 in a state in which ′ is directed. In addition, about another structure, although the decoration differs from the 1st light emission movable combination 60, since it is the same as the 1st light emission movable combination 60 about a technical feature, description is abbreviate | omitted.

  Next, the driving of the above-described connected movable combination 62 (upper movable combination 58 and lower movable combination 59), first light emission movable combination 60 and second light emission movable combination 61 will be described. Each of these movable accessories is driven based on a signal input from the game control device 100 according to a reach variation pattern (game progress) or the like. In the game, the linked movable combination 62, the first light emitting movable combination 60 and the second light emitting movable combination 61 are not driven at the same time. Each appears separately.

  First, driving of the connected movable accessory 62 will be described. The connected movable accessory 62 is stored at the edge of the opening 7 of the center case 4 when no signal is input from the game control device 100 (see FIG. 16) (first state). Thereafter, when a control signal for the connected movable accessory 62 is input from the game control device 100 to the effect control device 150 (see FIG. 16) in accordance with the reach variation pattern, the drive source of the upper movable accessory 58 is first driven. And the light source of the upper movable accessory 58 is caused to emit light. As a result, the upper movable accessory 58 swings toward the center of the display unit 9 around the swing shaft 71. When the lower end portion of the upper movable accessory 58 moves to the center portion of the display unit 9, the driving of the drive source is stopped and the upper movable accessory 58 is made stationary. Thereafter, the drive source of the lower movable accessory 59 is driven, and the light source of the upper movable accessory 58 is caused to emit light. As a result, the lower movable accessory 59 moves from the lower edge of the opening 7 of the center case 4 toward the upper side (upper movable accessory 58 side), and is movable downward to the protrusion 69 of the upper movable accessory 58. The concave portion 70 of the accessory 59 is fitted, and the upper end of the lower movable accessory 59 is brought into contact with the lower end of the upper movable accessory 58. At this time, for example, when the position of the protrusion 69 of the upper movable accessory 58 and the recess 70 of the lower movable accessory 59 is shifted due to a drive error or a manufacturing error, the edge of the recess 70 is tapered. By abutting and pushing up the inclined surface (white arrow in FIG. 7D), a force can be applied in the horizontal direction (direction perpendicular to the moving direction of the lower movable accessory 59) (in FIG. 7D). Thus, the upper movable accessory 58 can be moved to a predetermined position, and the upper movable accessory 58 and the lower movable accessory 59 can be connected without deviation.

  Then, when the upper movable combination 58 and the lower movable combination 59 are connected and converted into a state (second state) in which a part of the front surface of the display unit 9 is covered inside the opening 7, each drive source Is stopped and this state is maintained for a predetermined period. At this time, the upper decorative member 41, the case decorative member 39, the front surface of the upper movable accessory 58, the front surface of the lower movable accessory 59, the lower stage decorative member 44, and the first start winning opening decorative member 26 are connected. Two collective ornaments are formed. In the present embodiment, a decorative body representing the Arabic numeral “7” can be formed on the front surface of the game board 2 (see FIG. 10). More specifically, the upper decorative member 41 and the case decorative member 39 are connected to form the upper horizontal line of the decorative body “7”, and the front of the upper movable accessory 58, the front of the lower movable accessory 59, and the lower stage decoration. The member 44 and the first start winning opening decoration member 26 are connected to form a vertical line of the decoration “7”. At this time, the upper linear ornament 52, the case linear ornament 49, the upper movable accessory linear ornament 68, the lower movable accessory linear ornament 74, the stage lower linear ornament 48, and the first start prize. The mouth-line-shaped decorative body 38 represents a contour of the decorative body “7” in a series, and the sense of unity can be further increased. In particular, in this embodiment, since each linear decorative body representing the outline of the decorative body “7” is unified so as to have a metallic luster when viewed from the front, a sense of unity can be further increased. Further, the upper decorative member 41, the case decorative member 39, the upper movable accessory decorative member 66, the lower movable accessory decorative member 73, the lower stage decorative member 44, and the first start prize opening decorative member 26 are caused to emit light all at once. In addition, a sense of unity can be increased. In the first state, each member can also emit light separately as the game progresses. Further, in the first state, the upper movable accessory 58 is located on the rear surface side of the character decoration member 42. By emitting light in this state, it can be seen that the character decoration member 42 emits light. . The case decorative member 39 corresponds to the first decorative member of the present invention, and the upper decorative member 41, the lower stage decorative member 44, and the first start prize opening decorative member 26 correspond to the second decorative member of the present invention. The members constituting the front surfaces of the upper movable accessory 58 and the lower movable accessory 59 (upper movable accessory decoration member 66, upper movable accessory linear ornament 68, lower movable accessory decoration member 73, and lower movable accessory) The linear decorative body 74) corresponds to the third decorative member of the present invention. Further, the upper linear ornament 52, the case linear ornament 49, the upper movable accessory linear ornament 68, the lower movable accessory linear ornament 74, the lower stage linear ornament 48, and the first start prize opening. The linear decorative body 38 corresponds to the linear decorative body of the present invention.

  Next, driving of the first light-emitting movable accessory 60 and the second light-emitting movable accessory 61 will be described. Each light-emitting movable accessory is stored behind the edge of the opening 7 of the center case 4 when no signal is input from the game control device 100, and is hidden from view by the player. Thereafter, when a control signal for each light-emitting movable accessory is input from the game control device 100 to the effect control device 150 in accordance with a reach variation pattern different from the case where the linked movable accessory 62 is driven, each drive source is turned on. Drive. As a result, the first light-emitting movable accessory 60 is swung with the upper left corner of the display unit 9 as an axis and the lower end toward the center, and the second light-emitting movable accessory 61 is centered on the upper right corner of the display unit 9. The lower end is swung toward the center, and appears at a position visible to the player. Thereafter, when each light-emitting movable accessory moves to a predetermined position, driving of the drive source is stopped, and each light-emitting movable accessory is stopped. In the present embodiment, each light-emitting movable accessory is moved on the diagonal line of the display unit 9, and the second light-emitting movable accessory 61 is stationary in a state where it intersects in front of the first light-emitting movable accessory 60 (FIG. 11). reference). At this time, each light-emitting movable combination causes the LED 79 to emit light so that the translucent portions 78 and 78 ′ (in FIG. 9, above the first light-emitting movable combination 60 and below the second light-emitting movable combination 61). Shining.

  Next, the manufacturing process of the game board 2 as described above will be described. First, a plurality of obstacle nails 22 are planted at predetermined positions on the game board 5, and the center case 4 is fitted into the center case mounting hole 15 of the game board 5 from the front and positioned. In this state, the center case 4 and the game board 5 are firmly fixed using screws or the like. Thereafter, the first guide rail 10, the second guide rail 12, the upper side case 13, the right side case 14, the first start winning port decoration member 26, the big winning port 27, the out port 28, the general winning port 32, the second start. In addition to the winning opening 30, members installed on the game board 5 are positioned and fixed at predetermined positions with screws or the like. Next, the control base 6 is brought closer from the rear of the game board 5 while visually confirming the positions of the guide holes 35 of the game board 5 and the guide protrusions 36 of the control base 6. In this embodiment, since the control base 6 is formed of a transparent resin or the like, the position of the guide hole 35 can be confirmed from the rear through the control base 6. For this reason, the reference convex portion 36 can easily face the reference hole 35. Even when the position of the reference hole 35 cannot be confirmed through the control base 6, the reference protrusion 35 is provided on the outer peripheral portion of the control base 6, so that the reference hole 35 and the reference protrusion are formed from the outside of the control base 6. The position of the part 36 can be easily confirmed. When the reference convex portion 36 approaches the reference hole 35, the alignment convex portion 55 of the center case 4 is inserted into the alignment concave portion 54 of the control base 6. At this time, since the alignment convex portion 55 is formed in a tapered shape, a positional deviation with respect to the alignment convex portion 55 is allowed to some extent, and the alignment convex portion 55 can be inserted into the alignment concave portion 54. Thereafter, when the control base 6 is brought into contact with the game board 5 with the reference convex portion 36 facing the reference hole 35, the alignment convex portion 55 and the alignment concave portion 54 are engaged. Thereby, positioning of the control base 6 with respect to the center case 4 can be performed. In this state, the game board 2 can be manufactured by fixing the control base mounting portion 57 to the game board 5 with screws or the like.

  As described above, in the above embodiment, the case decoration member 39 provided on the front surface of the center case 4, the upper decoration member 41 that defines a part of the flow-down region 16, the stage lower decoration member 44, and the first start prize opening The decorative member 26, the upper movable accessory decorative member 66 and the upper movable accessory linear decorative body 68 provided on the coupled movable accessory 62 moving in the game area 3, and the lower movable accessory decorative member 73 and the lower movable member. The accessory movable linear ornament 74 is provided, and the connected movable accessory 62 is displayed in the first state stored on the back side of the edge of the opening 7 of the center case 4 and on the inner side of the opening 7. The second state covering a part of the front surface of the portion 9 can be converted to the second state. In the second state, the above-mentioned decorative members are connected to form a decorative body representing the Arabic numeral “7”. Therefore, the upper movable part 58 and the lower part are possible. Not only the decorative effect of the accessory 59 but also the decorative effect by the large decorative body “7” using a part of the front surface of the center case 4 and the flow-down area 16 can be obtained, so that the flow-down area 16 is secured. The decoration effect of the game board 2 can be enhanced. In addition, each of the above-described decorative members includes an upper linear decorative body 52, a case linear decorative body 49, an upper movable accessory linear decorative body 68, and a lower movable accessory linear ornament that represent the contour of the decorative body “7”. Since the body 74, the stage lower linear decorative body 48, and the first start winning opening linear decorative body 38 are provided, the contour can be emphasized to form the decorative body “7” having a more integrated feeling. . As a result, the decoration effect of the game board 2 can be further enhanced. Furthermore, the upper decorative member 41 includes a light transmission region (in this embodiment, in particular, the upper linear decorative body 52) that can transmit light at least in part, and a game board is provided on the back side of the light transmission region. 2 is formed, the pattern of the cell sheet 24 can be recognized from the front of the upper decorative member 41, and the flow-down region 16 can be decorated. Further, even if the game ball flows down the front surface of the upper decorative member 41, the cell sheet 24 is not soiled or peeled off. Similarly, the stage lower decoration member 44 and the first start prize opening decoration member 26 are light transmissive regions capable of transmitting light at least partially (in this embodiment, in particular, the stage lower linear decoration body 48 and the first Since a metal layer for decorating the game board 2 is formed on the back side of the light transmission area, the stage lower decoration member 44 and the first start prize opening decoration member 26 are provided. The metal layer can be recognized from the front of the flow area, and the flow-down area 16 can be decorated. Further, even if the game balls flow down the front surfaces of the stage lower decoration member 44 and the first start prize opening decoration member 26, the metal layer is not soiled or peeled off.

  The connected movable accessory 62 includes an upper movable accessory 58 and a lower movable accessory 59 that can be connected to each other by moving to a predetermined position, and the upper movable accessory 58 is provided with a protrusion 69. Since the lower movable combination 59 is provided with a recess 70 that fits into the protrusion 69, the upper movable combination 58 and the lower movable combination 59 can be firmly connected at a predetermined position. It is possible to prevent misalignment of the connected portion due to vibration or the like. Further, since the upper movable accessory 58 and the lower movable accessory 59 can be connected with a simple configuration without using a magnet or the like, the manufacturing cost can be reduced. Furthermore, the protrusion 69 has a shape that tapers toward the lower movable accessory 59, and when the upper movable accessory 58 and the lower movable accessory 59 move to a predetermined position, the tip of the protrusion 69 is Since it slides into the recess 70 from the edge of the recess 70 and fits, even if one of the movable members is not accurately waiting at a predetermined position, it can be connected to the other movable member, thereby suppressing poor connection. be able to.

  The game board 2 includes a game board 5 with a center case 4 attached to the front side, and a control base 6 attached to the rear side of the game board 5. A guide hole 35 serving as a guide for the mounting position of the base 6 is provided. A rear surface of the center case 4 is provided with an alignment convex portion 55 that engages with the control base 6, and a front surface of the control base 6 faces the guide hole 35. The guide protrusion 36 and the alignment recess 54 that engages with the alignment protrusion 55 are provided. When the guide protrusion 36 faces the reference hole 35, the alignment recess 54 engages with the alignment protrusion 55, Since the control base 6 and the center case 4 are configured to be positioned, when the control base 6 is attached to the game board 5 to which the center case 4 is attached, rough positioning is performed using the guide holes 35 and the guide protrusions 36. As a guide Can be, by attaching while facing the guide protrusion 36 to guide hole 35, by engaging the matching protrusion 55 to a matching recess 54, it is possible to position the control base 6 against the center case 4 easily. As a result, the game board 2 can be easily manufactured.

  Furthermore, the control base 6 has a first light-emitting movable accessory 60 and a second light-emitting movable accessory 61 that perform decoration with light, and these light-emitting movable agents are front surfaces by a non-translucent member that does not transmit light. A non-translucent portion 77 formed on one side, a translucent portion 78 formed adjacent to the non-translucent portion 77 on the other side of the front surface by a translucent member capable of transmitting light, the translucent portion 78 and the non-transparent portion An electrical decoration board 80 located behind the translucent part 77 and a reflection member 81 that reflects light provided between the electrical decoration board 80 and the non-translucent part 77 are provided. The LED 79 is mounted on the front surface of the electrical decoration substrate 80 at a position facing the reflecting member 81, and the light from the LED 79 is reflected by the reflecting member 81 toward the translucent portion 78, and the reflected light is Reflected by the front surface of the decorative substrate 80, the light is visible from the outside of the translucent part 78. Since the direct light from the LED 79 can be shielded by the non-translucent portion 77 when viewed from the front, the reflected light (indirect light) from the LED 79 can be transmitted by the translucent portion 77. The light can be visually recognized from the outside, and unevenness of the light due to the arrangement of the LED 79 visually recognized at this time can be suppressed. Further, since the light transmitting portion 78 has a plurality of fine grooves 82 for diffusing light on at least one surface, the light from the LED 79 can be diffused and is visually recognized from the outside of each light emitting movable accessory. Light unevenness due to the arrangement of the LEDs 79 can be further suppressed.

  By the way, although the connection movable object 62 of the said embodiment provided the projection part 69 in the upper movable object 58 and the recessed part 70 in the lower movable object 59 2 each, it is not restricted to this. For example, a concave portion may be provided in the upper movable accessory, and three protrusions may be provided in the lower movable accessory. In short, it is only necessary to provide one or more protrusions corresponding to one of the upper movable accessory and the lower movable accessory, and a recess corresponding to the other. Further, the above-described coupled movable combination is not limited to two, the upper movable combination and the lower movable combination. For example, it is also possible to provide a plurality of movable members that can be moved and to connect them together. In this case, a protrusion is provided on the connection surface of one movable member of the plurality of movable members that are connected to each other, and the protrusion is fitted to the connection surface of another movable member that is connected to one movable member. By providing the concave portions to be connected, they can be connected to each other.

  Furthermore, in the above-described embodiment, two guide holes 35 are provided in the game board 5 and two guide protrusions 36 are provided in the control base 6, respectively, but this is not restrictive. For example, three guide protrusions may be provided on the game board, and three reference holes may be provided on the control base. In short, it is only necessary to provide one or more guide holes corresponding to one of the game board and the control base and the reference protrusion to the other. Similarly, two alignment protrusions are provided in the center case, and two alignment recesses are provided in the control base. However, the present invention is not limited to this. For example, three alignment concave portions may be provided in the center case, and three alignment convex portions may be provided in the control base. In short, it is only necessary to provide one or more matching protrusions on one of the center case and the control base, and one or more matching recesses on the other.

  Further, the decorative body formed by connecting the decorative members described above is not limited to the Arabic numeral “7”. For example, symbols such as kanji, alphabets, circles and triangles can be formed. In short, it is a single character, symbol, design, or the like formed by a plurality of decorative members formed together, or a combination thereof, as long as it is a collective decorative body that is recognized as a single decorative body through vision.

  Further, in the above embodiment, the metal layer is provided on the back surface of the upper linear decorative body 52 and the lower stage linear decorative body 48, and the cell located on the back surface side of the first start winning opening linear decorative body 38 is provided. The sheet is provided with a metallic glossy portion 24a having a metallic gloss and can be viewed from the front, but is not limited thereto. For example, a cell sheet may be disposed on the back side of the upper linear decorative body and the stage lower linear decorative body, and a metallic luster part having metallic luster may be provided there. Moreover, you may provide the metal layer by a metal plating process in the back surface of a 1st start winning opening linear ornament. Furthermore, the metal layer can be formed by a method such as electroplating, melting plating, or vacuum deposition. In addition, a metallic gloss paint can be applied to the back of each decorative body, or a metallic gloss seal can be applied to the back of each decorative body. Further, not only a layer having metallic luster, but also a colored layer such as red or blue may be formed by the method described above. In short, a surface treatment layer may be provided on the back side of the upper linear decorative body, the lower stage linear decorative body, and the first start winning opening linear decorative body. Furthermore, the surface treatment layer is not limited to the back side of the upper linear decorative body, the stage lower linear decorative body, and the first start winning opening linear decorative body, but the upper decorative member, the stage lower decorative member, and the first It can also be provided on the back side of the starting prize opening decoration member.

  Next, a second embodiment will be described with reference to the drawings. FIG. 13 is a perspective view of the game board 2 in the second embodiment, and FIG. 14 is a perspective view of the state in which the side armor decoration member 51 is removed from the center case 4 in the second embodiment. FIG. 15 is a diagram for explaining the armor member 19 in the second embodiment. FIG. 15A is an enlarged view of a main part when the armor member 19 is viewed from the outside, and FIG. The main part enlarged view when the member 19 is seen from the inside, FIG.15 (c) is the principal part enlarged view explaining attachment of the side armor decoration member 51 with respect to the center case 4, FIG.15 (d) is with respect to the center case 4. FIG. It is principal part sectional drawing explaining attachment of the side part armor decoration member 51. FIG. The second embodiment is different from the first embodiment in that the adjustment notch 86 is formed in the armor member 19 and the buffer 84 is formed in the armor decoration member.

  More specifically, in the second embodiment, as in the first embodiment, a part of the right side case 14 is placed in the center case 4 on the side facing the tip of the hitting ball passage 11 in the right flowing region 16. A stepped portion 17 projecting to the side is formed, and a buffer member 18 formed of a shock-resistant resin or the like is disposed on a part of the surface (a portion facing the center case 4). . The armor member 19 is formed from the upper side to the right side of the center case 4, and a part of the armor member 19 is recessed to the opening 7 side in accordance with the stepped portion 17 of the right side case 14. 20 is formed. The armor step portion 20 is formed to be inclined downward from the left side (upstream side in the downflow direction) to the right side (downstream side in the downflow direction). Further, an armor decoration member 40 is formed inside the armor member 19. The armor decoration member 40 of the present embodiment includes a horizontally long upper armor decoration member 50 located inside the upper armor member 19 and a vertically long side located inside the armor member 19 extending from the armor step 20 to the right end. The armor decoration member 51 is formed separately and assembled to the center case 4 (the armor member 19) (see FIG. 14). In the present embodiment, the armor member 19 is made of ABS resin (acrylonitrile butadiene styrene copolymer synthetic resin) that is difficult to remove the paint, and the side armor decoration member 51 is made of high impact resistance PC (polycarbonate resin). ing. Then, a cutout portion 83 is formed in a part of the armor member 19 (armor step portion 20) located at a portion facing the flow-down region 16 (ball flow-down passage 21), and the side armor decoration member 51 is fitted into the cutout portion 83. The buffer part 84 exposed to the flow-down area 16 is formed together, and the game ball flowing down the flow-down area 16 is caused to collide with the buffer part 84 so that the impact generated when the game ball collides can be buffered.

  More specifically, the notch 83 is in a state in which the front end portion of the armor step portion 20 is left on the upper surface of the armor step portion 20 (surface on the flow-down region 16 side) without penetrating forward from the rear end to the front end portion. The cross section is notched so as to have a step. In other words, the notch 83 is formed by notching a state in which the front end surface of the armor step 20 is left open toward the rear of the center case 4 (see FIGS. 14 and 15). The buffer portion 84 is a thin plate that can be fitted into the notch portion 83, and is formed integrally with the upper end portion of the side armor decoration member 51. More specifically, the buffer portion 84 extends in a bowl shape toward the front side with a gap left above the armor member contact portion 85 of the side armor decoration member 51 that contacts the inside of the armor step portion 20. ing. For this reason, the side armor decoration member 51 is assembled from the rear of the center case 4 so as to sandwich the step bottom of the notch 83 between the armor member contact portion 85 and the buffer portion 84 (see FIG. 15D). The buffer portion 84 fits into the notch portion 83 and constitutes a part of the ball flow down passage 21 together with the armor step portion 20. Further, the buffer portion 84 is formed so that the upper surface on the upstream side is aligned with the inclination of the armor step portion 20 so that the upper surface on the upstream side from the center portion is aligned with the upper surface of the armor step portion 20 when viewed from the front. The upper surface on the downstream side is gentler than the inclination of the armor step portion 20 so that the upper surface on the downstream side from the central portion is positioned slightly above the upper surface of the armor step portion 20 at the boundary with the armor step portion 20 on the downstream end side. It is formed with a gentle slope. As a result, it is possible to prevent reverse rotation at the downstream boundary between the buffer portion 84 and the armor step portion 20 and to recover the momentum of the game ball that has collided with the buffer portion 84 and has been reduced. Smooth flow to the downstream side.

  Next, the adjustment notch 86 of the armor member 19 will be described. As in the first embodiment, in the ball lowering passage 21 through which the game ball formed between the right side case 14 and the armor member 19 can pass, on the side surface of the armor member 19 facing the buffer member 18, A failure nail row 23 is arranged in which the failure nails 22 are arranged in a plurality of rows. Here, the obstacle nail 22 constituting the obstacle nail row 23 guides the game ball flowing down the ball flow down passage 21 and changes its length and inclination, so that the ball flow down passage 21 (flow down region 16 of the game ball) is changed. ) Can be changed to adjust the downward force of the game ball. For this reason, after the game board 2 is formed, the inclination of the obstacle nail 22 constituting the obstacle nail row 23 may be adjusted using an adjustment tool such as pliers. In the second embodiment, in order to prevent the armor member 19 from interfering with the adjustment of the obstacle nail 22, the adjustment notch in which a part of the armor member 19 facing the obstacle nail row 23 is cut out in an arc shape toward the rear. A portion 86 is formed (see FIG. 15B and the like). The shape of the adjustment notch 86 is not limited to the arc shape, and may be formed in a square shape. In short, any shape may be used as long as it is a notch that does not interfere with the adjustment tool when adjusting the obstacle nail 22. Since other configurations are the same as those in the first embodiment, description thereof is omitted.

  As described above, in the second embodiment, a part of the game area 3 partitioned on the game board 2 is configured, and a flow-down area 16 in which a game ball can flow down the front surface and a part of the game area 3 are formed. In the pachinko gaming machine 1 including the center case 4 that constitutes the center case 4, the center case 4 includes an armor member 19 that prevents a game ball from flowing into the center case 4, and a side that decorates the armor member 19. A cutout portion 83 is formed in the armor member 19 at a position facing the flow-down region 16, and the cut-out portion 83 is fitted into the cut-out portion 83 in the side-armor decoration member 51. Since the shock absorber 84 exposed to the shock absorber 84 is formed and the game ball flowing down the flow-down area 16 collides with the shock absorber 84 so that the impact generated when the game ball collides can be buffered, the armor member 19 is destroyed by the game ball. Can be prevented. Further, there is no need to separately prepare the buffer portion 84, and the center case 4 provided with the buffer portion 84 can be easily manufactured. Furthermore, since the buffer part 84 fitted to the notch part 83 is formed in the side armor decoration member 51, it is possible to prevent the appearance from being impaired.

  In addition, since the armor member 19 and the side armor decoration member 51 are formed of resins having different characteristics, the resin forming the armor member 19 and the side armor decoration member 51 is selected according to their use. be able to. In the present embodiment, the armor member 19 is formed of ABS resin that is difficult to remove the paint, and the side armor decoration member 51 is formed of high impact resistance PC, so that the buffering effect by the buffering portion 84 is ensured, The decoration effect can be enhanced by decoration by painting the armor member 19. Further, the armor member 19 is formed by cutting out the notch 83 so that the notch 83 is opened toward the rear of the center case 4, and the side armor decoration member 51 is assembled to the center case 4 from the rear, thereby Since it is configured to fit into the notch 83, the buffer portion 84 can be formed simply by assembling the side armor decoration member 51 to the center case 4, and the center case 4 having the buffer portion 84 can be easily manufactured. it can.

  A plurality of obstacle nails 22 for guiding the flow of the game ball are planted along a part of the armor member 19 in the flow area 16. Since the adjustment notch 86 is formed by notching, the armor member 19 does not get in the way when the angle of the obstacle nail 22 is adjusted using the adjustment tool, and the angle of the obstacle nail 22 is easily adjusted. be able to.

  In the above-described embodiment, the pachinko gaming machine 1 is taken as an example. However, the present invention is not limited to this, and any gaming machine using a gaming ball such as a sparrow ball gaming machine or an arrangement ball gaming machine may be used.

Next, a control method of the gaming machine (pachinko gaming machine) 1 provided with the gaming board 2 of each embodiment described above will be described.
FIG. 16 is a block diagram of the gaming machine 1 of the present embodiment.

  The game control device 100 includes a game microcomputer (game calculation processing device 600) 101, an input I / F (Interface) 105, an output I / F (Interface) 106, and an inspection device connection terminal 107.

  The gaming microcomputer 101 includes a CPU 102, a ROM (Read Only Memory) 103, and a RAM (Random Access Memory) 104.

  The CPU 102 is a main control device that controls the game in an integrated manner, and controls the game. The ROM 103 stores invariant information (programs, data, etc.) for game control. The RAM 104 is used as a work area during game control.

  The game control device 100 is provided with an inspection device connection terminal 107, and an identification number uniquely set in the gaming microcomputer 101 can be output from the inspection device connection terminal 107. Thus, when an inspection device (not shown) is connected to the inspection device connection terminal 107, the inspection device can identify the gaming machine 1.

  The CPU 102 receives various inspection devices (special drawing start SW25A, 30A, universal drawing start SW31A, count SW27A, winning opening SWa32A to winning opening SWn32N, overflow SW (switch) 109, out of ball SW (switch) via the input I / F 105. ) 110 and a detection signal from the frame opening SW (switch) 111), various processes such as a big hit lottery are performed.

  The overflow switch 109 detects that a predetermined number or more of game balls are stored in a lower tray having a mechanism for storing and discharging game balls. The ball break switch 110 is disposed in the ball storage unit 320 and detects that the number of game balls stored in the ball storage unit 320 is less than or equal to a predetermined number. The frame opening switch 111 detects that the front frame assembled to the front surface of the gaming machine 1 so as to be capable of opening and closing is opened.

  In addition, the CPU 102, via the output I / F 106, displays a general-purpose indicator 121, a special-purpose indicator 120, a general electric power SOL (solenoid) 95, a special winning opening SOL (solenoid) 96, a payout control device 210, and an effect control device. A command signal is transmitted to 150 to control the game in an integrated manner.

  The universal symbol display 121 displays a variable display game that is performed when a game ball wins the normal symbol starting gate 31. The special figure display 120 displays a variable display game that is performed when a game ball wins the first start winning opening 25 or the second starting winning opening 30.

  The general electric power SOL 95 opens the normal variation winning device 33 provided in the second start winning opening 30 and opens the entrance to the second starting winning opening 30 for a predetermined time.

  The special winning opening SOL96 is in an open state (advantageous to the player) from the closed state (a disadvantageous state for the player) in which the special variable winning device (large winning port) 27 does not accept the game ball for a predetermined time. ).

  In addition, the game control device 100 outputs information related to the gaming machine 1 to an information collection terminal or a game hall internal management device (not shown) installed in the game store via the external information terminal 108.

  The game control device 100 transmits a change start command, a customer waiting demo command, a fanfare command, a probability information command, an error designation command, and the like to the effect control device 150 as an effect control command signal.

  Next, the payout control device 210 and the effect control device 150 will be described.

  The effect control device (display control device) 150 controls the speaker 94 and the display device 8 based on various signals input from the game control device 100, and also the light-emitting device 29 that performs the game effect by light emission, as described above. The driving sources 93a to 93d provided for driving the animals (the first light-emitting movable accessory 60, the second light-emitting movable accessory 61, and the connected movable accessory 62) are controlled. The effect control device 150 also receives signals from position detection sensors (not shown) for detecting the positions of these movable objects 60 to 62.

  The effect control device 150 includes a gaming microcomputer (game arithmetic processing device 600) 151, a driver 155, a sound circuit 156, a VDP 157, and a monitoring circuit 158.

  The gaming microcomputer 151 includes a CPU 152, a ROM 153, and a RAM 154.

  The CPU 152 is a control device that comprehensively controls effect control. The ROM 154 stores invariant information (programs, data, etc.) for effect control. The RAM 154 is used as a work area during production control.

  The driver 155 controls the light emitting devices 92a to 92h and the drive sources 93a to 93d according to a command from the CPU 152. The sound circuit 156 generates a sound effect according to a command from the CPU 152 and outputs the sound effect from the speaker 94.

  In response to a command from the CPU 152, the VDP 157 reads font data from a character ROM (not shown), generates image data, and outputs the image data to the display device 8. The monitoring circuit 158 has a function of monitoring the operation of the CPU 152 and resetting the CPU 152 when an abnormality (such as program runaway) occurs.

  The payout control device 210 is a device that drives the payout motor 220 of the payout device based on the prize ball command signal from the game control device 100 and performs control for paying out the prize ball. Also, the payout control device 210 drives the payout motor 220 of the payout device based on the payout command signal transmitted from the game control device 100 based on the loan request signal from the card unit 97 to pay out the rental money. It is an apparatus which performs control for making it happen.

  The payout control device 210 includes a game microcomputer (game operation processing device 600) 211, an input I / F (Interface) 215, an input / output I / F (Interface) 216, and an inspection device connection terminal 217.

  The gaming microcomputer 211 includes a CPU 212, a ROM 213, and a RAM 214.

  The CPU 212 is a control device that comprehensively controls the payout and controls the payout control. The ROM 213 stores invariant information (program, data, etc.) for payout control. The RAM 214 is used as a work area during payout control.

  The CPU 212 receives inputs from the payout ball detection sensor 112, the overflow switch 109, the ball break switch 110, the error release switch 223, the tax rate setting switch 226, and the lending fee setting switch 227 via the input I / F 215.

  The error release switch 223 is operated by the store clerk of the amusement store when the cause of the error generated by the store clerk at the amusement store is canceled when an error occurs in the payout control device 210, and cancels the error state. It is a switch.

  The tax rate setting switch 226 is a switch for setting a tax rate of indirect tax imposed on the rental of game balls. The rental fee setting switch 227 is a switch for setting the valuable value of the game balls to be lent.

  Further, the CPU 212 transmits a command signal to the payout motor 220, the launch control device 221, the error number display 222, the tax rate display 224, and the rental charge display 225 via the input / output I / F 216. In addition, the CPU 212 receives various signals from the game control apparatus 100 via the input / output I / F 216.

  The payout motor 220 is a motor that is actually driven to pay out the game ball by the payout device. Specifically, the payout motor 220 pays out the game ball by rotating a sprocket having a predetermined number of recesses capable of storing one game ball.

  The launch control device 221 controls a launch device for launching a game ball onto the game board 2. The error number display 222 is disposed on the back side of the payout control device 210 and displays the type of error that has occurred in the payout control device 210 so that it can be specified.

  The tax rate indicator 224 is disposed on the back side of the payout control device 210 and displays the tax rate of the indirect tax set by the tax rate setting switch 226. The rental charge indicator 225 is disposed on the back side of the payout control device 210 and displays the valuable value of the game balls to be lent set by the rental charge setting switch 227.

  The game control device 100, the effect control device 150, and the payout control device 210 are connected to the power supply device 160.

  The power supply device 160 includes a backup power supply 161 and a RAM clear switch 162.

  The backup power supply 161 supplies power to the game control device 100, the effect control device 150, and the payout control device 210 even in the event of a power failure (it may not be supplied to the effect control device 150).

  The RAM clear switch 162 is a switch that initializes information stored in the RAM 104 provided in the game control device 100 and the RAM 214 provided in the payout control device 210.

  Further, when the ball lending button 89 provided in the gaming machine 1 is operated, the card unit 97 subtracts the valuable value for the gaming ball to be lent from the valuable value stored in the card such as the prepaid card or the membership card. The value of the subtracted value is displayed on the balance display unit 91 of the gaming machine 1. Further, when the discharge button 90 provided in the gaming machine 1 is operated, the card unit 97 discharges the card inserted into the card insertion slot 71.

  The game microcomputer 101 provided in the game control device 100 and the game microcomputer 211 provided in the payout control device 210 are connected by SIO connection and encrypted signal connection.

  An unencrypted signal (plaintext data) that is not encrypted is communicated in the SIO connection, and an encrypted signal (encrypted data) that is encrypted is communicated in the encrypted signal connection.

  The game microcomputer 101 provided in the game control device 100 and the game microcomputer 211 provided in the payout control device 210 include ports for SIO connection and encrypted signal connection.

  Next, the game microcomputer 101 provided in the game control device 100 and the game microcomputer 211 provided in the payout control device 210 (hereinafter collectively referred to as the game arithmetic processing device 600) will be described in detail with reference to FIG.

  FIG. 17 is a block diagram of the game arithmetic processing device (amuse chip) 600 of this embodiment.

  The game processing unit 600 is manufactured as an IC for a so-called amuse chip, and is divided into a game area unit 600A for performing game control and an information area unit 600B for managing information.

  First, the game area 600A is a collective term for a CPU core 601 (corresponding to the CPU 102 or CPU 212 in FIG. 16), a user program ROM 602 (corresponding to the ROM 103 or ROM 213 in FIG. 16), and an HW parameter ROM 603 (user program ROM 602 and HW parameter ROM 603). ROM (non-volatile storage means), user work RAM 604 (corresponding to RAM 104 or RAM 214 in FIG. 16), mirrored RAM 605 (user work RAM 604 and mirrored RAM 605 are collectively referred to as RAM (volatile storage means)), external Bus interface (I / F) 606, bus switching circuit 607, random number generation circuit 608, clock generator 609, reset / interrupt control circuit 610, address decoder 611, output control Road 612, the boot block 613, decoding · ROM write circuit 614, a serial transceiver circuit 615, the encryption reception circuit 616, and configured by a bus 617.

  The CPU core 601 functions as arithmetic processing means for performing arithmetic processing for game control. The user program ROM 602 stores a control program. The control program is a game control program for controlling a game when the game arithmetic processing device 600 is the game microcomputer 101 provided in the game control device 100, and the game arithmetic processing device 600 is a payout control device. 210 is a payout control program for paying out game balls in the case of the game microcomputer 211 provided in 210, and in the case where the game arithmetic processing device 600 is the game microcomputer 151 provided in the effect control device 150, This is an effect control program for effect control.

  The HW parameter ROM 603 stores validity confirmation information. The legitimacy confirmation information is information in the case of performing a simple check of the legitimacy of the gaming arithmetic processing device 600. For example, a unique ID indicating a unique identifier of the gaming machine 1, a manufacturer code (manufacturer of the gaming machine 1) A unique identifier assigned to each manufacturer), a rank code indicating the rank (1 type, 2 type, etc.) of the gaming machine 1, a model code set by the manufacturer for the type of the gaming machine 1, and an inspection number. An inspection code to be displayed, a RAM backup code indicating whether or not to back up the RAM when the power is turned on, a tax rate set by the tax rate setting switch 226, a lending fee set by the lending fee setting switch 227, and the like. Further, the HW parameter ROM 603 stores only one unique ID that is a unique identifier of the inspection apparatus that first transmitted the lending information request.

  When the third party organization or the manufacturer of the gaming machine 1 writes the program in the user program ROM 602, the validity confirmation information is written in the HW parameter ROM 603.

  When performing a simple check of the gaming arithmetic processing device 600, when the gaming arithmetic processing device 600 is powered on, the arithmetic value calculated by the gaming arithmetic processing device 600 itself and the validity confirmation information (that is, a third party organization, etc.) And a result value set in advance by the above-described (3), the game processing unit 600 can be easily checked.

  The user work RAM 604 is used as a work area (work area) when executing processing based on a program in the game area 600A. Since this user work RAM 604 is supplied with the backup power from the backup power supply 161 (FIG. 16), the stored data is held even if the power supply to the gaming machine 1 is interrupted.

  The mirrored RAM 605 duplicates the information stored in the user work area at the fall of the clock and stores the duplicated information (if the CPU core is Z80, the process is executed at the rise of the clock. To prevent it from moving.)

  The external bus interface 606 is an interface such as a memory request signal MREQ, an input / output request signal IORQ, a memory write signal WR, a memory read signal RD, and a mode signal MODE, and the bus switching circuit 607 is a 16-bit address signal A0. ˜A15 and 8-bit data signals D0 to D7.

  For example, when the data signals D0 to D7 are added while the address signals A0 to A15 are sequentially incremented while the MODE signal is at a high level, the writing mode to the user program ROM 602 is set, or the gaming machine 1 manufacturer or The program can be written by a third party.

  Note that the write mode allows a program to be written, and does not allow a boot program stored in the boot block 613 to be written.

  Further, when the writing of the program to the user program ROM 602 is completed, a writing end code is recorded in a predetermined area of the HW parameter ROM 603 (for example, recorded by physically cutting a predetermined code or a predetermined bit). Thus, when a write end code is recorded in the HW parameter ROM 603, a new program cannot be written in the user program ROM 602.

  The random number generation circuit 608 generates a random number related to whether or not to add a game value (for example, jackpot) in the game execution process (the random number is used for determining a jackpot or determining a symbol at a stop). A mathematical method (for example, a congruent method or an M-sequence method) for generating a uniform random number is used. Note that when the gaming arithmetic processing device 600 is the gaming microcomputer 211 provided in the payout control device 210, the random number generation circuit 608 may not be provided.

  The clock generator 609 generates a timer interrupt signal generated at a predetermined cycle (for example, 4 milliseconds) and a clock signal. The timer interrupt signal and clock signal generated by the clock generator 609 are input to the CPU core 102. When a timer interrupt signal is input, the CPU core 102 executes a timer interrupt process shown in FIG.

  When the reset / interrupt control circuit 610 detects an externally input reset signal (RST), the reset / interrupt control circuit 610 transmits the reset signal to each circuit provided in the gaming arithmetic processing device 600. When the occurrence of a predetermined interrupt condition is detected, the CPU core 601 is notified of the occurrence of the interrupt.

  The address decoder 611 decodes the location of the built-in device and the built-in control / status register group by the memory mapped I / O method and the I / O mapped I / O method.

  The output control circuit 612 controls the signal from the address decoder 611, outputs an 8-bit chip select signal (CS0 to CS7) from the external terminal to the outside, and selects a circuit provided inside the game processing unit 600 A function of generating a chip select signal. The boot block 613 stores a boot program and performs processing related to initialization of the gaming arithmetic processing device 600 when the power is turned on.

  The decryption / ROM writing circuit 614 is used in the writing mode to the user program ROM 602 and the HW parameter ROM 603, and passes through the bus switching circuit 607 while the mode signal MODE is at the [H] level. The address signals A0 to A15 and the data signals D0 to D7 are fetched and the information (encrypted program and encrypted unique ID after change) included in the data signals D0 to D7 is decrypted, and then the bus The data is output (written) to the user program ROM 602 and the HW parameter ROM 603 via 617.

  The serial transmission / reception circuit 615 is a circuit for transmitting / receiving plaintext data not encrypted by SIO connection.

  The encrypted transmission / reception circuit 616 is a circuit that transmits / receives encrypted data encrypted by encrypted signal connection. A signal line for encrypted data is connected to the encrypted transmission / reception circuit 616. The encrypted transmission / reception circuit 616 transmits / receives data via a signal line of encrypted data.

  The bus 617 includes a data bus (data bus 660 in FIG. 18), an address bus (address bus 650 in FIG. 18), and a control bus, and extends to the information area portion 600B.

  Next, an information area unit 600B for managing information in the game processing unit 600 includes an HPG program ROM 618, an ID property memory 619, a bus monitor circuit 620, an HPG work RAM 621, a control circuit 622, an external communication control circuit 623, and a bus 624. , And a part of the bus 617 extending from the game area 600A.

  The HPG program ROM 618 stores an HPG program for performing various inspection operations.

  In the ID property memory 619, the information stored in the HW parameter ROM 603 can be immediately output to the inspection device (not shown) based on the request received from the inspection device (not shown) via the external communication control circuit 623. The information stored in the HW parameter is duplicated and stored when the computer processing unit 600 is powered on (system reset). The ID property memory 619 can be accessed from both the game area 600A side and the information area 600B side.

  The bus monitor circuit 620 monitors and controls the state of the bus 617 on the game area 600A side from the information area 600B side. The control here refers to timing control when the contents of the HW parameter ROM 603 are copied to the ID property memory 619, or when the program stored in the user program ROM 602 is output to the outside (the bus 617 on the game area 600A side is connected). Timing control at the time of opening and reading a program from the user program ROM 602 and outputting it to the outside from the information area 600B side. The program is output after being encrypted by the external communication control circuit 623.

  The HPG work RAM 621 is used as a work area (work area) when executing processing based on a program in the information area unit 600B.

  The control circuit 622 controls the information area 600B side and has a buffer memory. For example, the control circuit 622 monitors the operation of the CPU core 102 via the bus monitor circuit 620 and copies the contents stored in the user work RAM 604 of the game area unit 600A to the mirrored RAM 605 during non-operation.

  Further, the contents of the ID property memory 619 of the information area unit 600B are transferred to the outside in response to a request from an inspection apparatus (not shown), or the program in the user program ROM 602 is received via the bus monitor circuit 620 in response to a program request. To the outside. The memory of the control circuit 622 is used for timing adjustment at the time of transfer.

  The external communication control circuit 623 communicates with an inspection device (not shown). For example, information (for example, a unique ID, a program, an actual payout) stored in the game processing device 600 based on a command from the outside. The number is encrypted, and then transferred to the outside.

  In the game processing unit 600, the game area unit 600A and the information area unit 600B operate independently via the bus monitor circuit 620. That is, the information area 600B side can operate regardless of the operation of the CPU core 102 in the game area 600A (regardless of the program execution).

  Although not shown in FIG. 17, the gaming arithmetic processing device 600 includes a security circuit 630 and a RAM access restriction circuit 640 described later in FIG. 18.

  FIG. 18 is a block diagram of a game arithmetic processing device (amuse chip) 600 provided in the game control device 100 of the present embodiment and its surroundings.

  The gaming arithmetic processing device 600 includes a security circuit 630, a CPU core 102 (601 in FIG. 17), a RAM access restriction circuit 640, a user work RAM 104 (604 in FIG. 17), a bus switching circuit 607, an address decoder 611, and an output control circuit. 612 and a user program ROM 103 (603 in FIG. 17).

  Note that these circuits and the like included in the gaming arithmetic processing device 600 are connected via an address bus 650 and a data bus 660.

  Further, the game control device 100 includes an effect control communication port 670 connected to the effect control device 150 and a payout control communication port 680 connected to the payout control device 210 outside the game arithmetic processing device 600. .

  Hereinafter, the effect control communication port 670 and the payout control communication port 680 are collectively referred to as communication ports 670 and 680. The communication ports 670 and 680 function as communication ports (command output means) in this embodiment, and are included in the output I / F 106 shown in FIG.

  The communication ports 670 and 680 are connected to the gaming arithmetic processing device 600 via a data bus 690 external to the gaming arithmetic processing device 600.

  The data buses 660 and 690 are configured by 8-bit signal lines D0 to D7.

  When power is supplied to the gaming arithmetic processing device 600, a reset signal (start signal) is input from the power supply device 160 via the RST terminal (FIG. 17), and the reset interrupt control circuit 610 (FIG. 17) is activated. Operate.

  When this reset signal is input, the security circuit 630 executes security check processing using the validity confirmation information stored in the HW parameter ROM 602. This security check process is a process for determining the validity of the program stored in the user program ROM 103.

  While this security check process is being executed, the security circuit 630 continuously outputs a reset signal to the reset terminal (RES (negative logic)) of the CPU core 102, thereby waiting for the CPU core 102 to start up. .

  The CPU core 102 includes the aforementioned reset terminal (RES (negative logic)), a write command output terminal (WR (negative logic)), and a read command output terminal (RD (negative logic)). The reset terminal is connected to the security circuit 630, and when a reset signal is input to the gaming arithmetic processing device 600, as described above, the reset to the CPU core 102 is performed during the security check process. A signal is input to the reset terminal.

  When a reset signal is input to the reset terminal of the CPU core 102, the CPU core 102 initializes a register (REG) provided in the CPU core 102.

  When the CPU core 102 outputs a write command for instructing the user work RAM 104 to write data, a low level signal having a voltage lower than a predetermined value is output from the write command output terminal of the CPU core 1021. Is done.

  Similarly, when the CPU core 102 outputs a read command for instructing data read from the user work RAM 104, a low level signal having a voltage lower than a predetermined value is output from the read command output terminal of the CPU core 102. The

  That is, the normal voltage is maintained at a high level at the write command output terminal and the read command output terminal, and the voltage is at a low level only when reading / writing to the user work RAM 104 is performed.

First, reading of data from the user work RAM 104 will be described.
When a read command is input from the CPU core 102 to a read command input terminal (RD (negative logic)) of the user work RAM 104, read data is output to the CPU core 102 via the address bus 650 and the data bus 660.

  At this time, the address of the user work RAM 104 is output from the CPU core 102 to the address bus 650, and a selection signal is input from the address decoder 611 to a chip selection terminal (corresponding to a so-called CS terminal, not shown) of the user work RAM 104. As a result, the user work RAM 104 is selected.

  Next, the selected user work RAM 104 outputs the data in the storage area designated by the address bus 650 to the data bus 660. Next, the CPU core 102 takes in the data output to the data bus 660. By such a procedure, the CPU core 102 reads data from the user work RAM 104.

  Next, data writing to the user work RAM 104 will be described.

  The write command output terminal provided in the CPU core 102 is connected to one input terminal of the two input terminals provided in the OR gate circuit 642 of the RAM access restriction circuit 640.

  The other input terminal of the OR gate circuit 642 is connected to the output terminal (Q (negative logic)) of the flip-flop circuit 641 of the RAM access restriction circuit 640, and the output terminal of the OR gate circuit 642 is the write of the user work RAM 104. It is connected to the command input terminal (WR (negative logic)).

  When a low level signal having a voltage equal to or lower than a predetermined value is input to the write command input terminal of the user work RAM 104, writing to the user work RAM 104 is permitted.

  Therefore, writing to the user work RAM 104 is not permitted unless low level signals are input to the two input terminals of the OR gate circuit 642, respectively. In other words, when a high level signal is input to at least one input terminal of the OR gate circuit 642, writing to the user work RAM 104 is restricted (prohibited).

  Here, the flip-flop circuit 641 of the RAM access restriction circuit 640 will be described.

  The flip-flop circuit 641 uses, for example, a logic IC whose model number is 74HC74. The flip-flop circuit 641 is a D-type flip-flop circuit. As input terminals, a data terminal (D), a clear terminal (CLR (negative logic)), a clock terminal (CK (positive logic)), and a preset terminal ( PR (negative logic)) and output terminals (Q (positive logic), Q (negative logic)).

  One predetermined signal line (for example, D0) among the signal lines D0 to D7 constituting the data bus 660 is connected to the data terminal.

  A reset signal line is connected to the clear terminal from the power supply device 160, and when the reset signal is input, the clear terminal becomes low level. At this time, the flip-flop circuit 641 outputs a low level signal from the output terminal Q (positive logic) and outputs a high level signal from the output terminal Q (negative logic). The output from the output terminal Q (positive logic) and the output from the output terminal Q (negative logic) are at levels that are mutually inverted.

  The clock terminal is connected to the output control circuit 612 and is normally maintained at a low level.

  The signal level from the output terminal Q (negative logic) provided in the flip-flop circuit 641 can be freely set by the CPU core 102. This setting is realized by the CPU core 102 writing predetermined data in the storage area of the address assigned to the flip-flop circuit 641.

  Specifically, when the CPU core 102 performs processing for writing data to the storage area of the address assigned to the flip-flop circuit 641, the address of the flip-flop circuit 641 is output from the CPU core 102 to the address bus 650. The Next, a clock signal is input from the address decoder 611 to the clock terminal of the flip-flop circuit 641 via the output control circuit 612, and the voltage level of the clock terminal rises to a high level.

  At this time, the flip-flop circuit 641 captures the signal input to the data terminal, outputs the captured signal from the output terminal Q (positive logic), and outputs the inverted value of the captured signal from the output terminal Q (negative logic). Output.

  Further, in the flip-flop circuit 641, when the output control circuit 612 finishes inputting the clock signal, the voltage level of the clock terminal falls and becomes a low level, and the output terminal Q (positive logic) and the output terminal Q (negative logic). ) Voltage level.

  The preset terminal is connected to a pull-up resistor (not shown), and the voltage level of the preset terminal is always high.

  The output terminal Q (negative logic) outputs a signal to the input terminal of the OR gate circuit 652. Nothing is connected to the output terminal Q (positive logic).

  Next, various operations according to the input state of the flip-flop circuit 641 will be described.

  As described above, the flip-flop circuit 641 reads the voltage level of the data terminal at the rise of the voltage level of the clock terminal, that is, when the input of the clock signal starts, and outputs the inverted value of the read voltage level to the output terminal Q (negative logic). Output from.

  On the other hand, the flip-flop circuit 641 holds the output from the output terminal Q (negative logic) at the fall of the voltage level of the clock terminal, that is, at the end of the input of the clock signal, at the rise of the power level of the clock terminal.

  When a high level signal is output from the output terminal Q (negative logic) to the input terminal of the OR gate circuit 642, either the low level signal or the high level signal is input to the other input terminal of the OR gate circuit 642. Also, a high level signal is output from the output terminal of the OR gate circuit 642.

  Therefore, if a high-level signal is output from the output terminal Q (negative logic) of the flip-flop circuit 641, even if a write command signal is input to the other input terminal of the OR gate circuit 642 (the other Even if a low level signal is input to the input terminal), the low level is not input to the write command input terminal of the user work RAM 104, and a RAM write inhibit state occurs.

  The voltage level input to the data terminal of the flip-flop circuit 641 when the clock signal is input to the flip-flop circuit 641 depends on whether the RAM access restriction circuit 640 is in the RAM write prohibition state or the RAM write permission state. Or based on the presence or absence of a reset signal input.

  As described above, the CPU core 102 can control the output control circuit 612 to control the output of the clock signal, and can also control the output of the signal line of the data bus 660, so that the output terminal Q (negative logic) of the flip-flop circuit 641. The signal output from can be controlled by the CPU core 102. In other words, the CPU core 102 can control the write state of the RAM access restriction circuit 640 by controlling the signal level of the data bus 660.

  Further, as described above, when the reset signal is input to the clear terminal of the flip-flop circuit 641, the flip-flop circuit 641 sets the voltage level of the output terminal Q to low, and therefore the output terminal Q (negative logic) The voltage level goes high. Therefore, when a reset signal is input to the flip-flop circuit 641, the RAM access restriction circuit 640 causes a RAM write prohibition state.

  Next, the communication ports 670 and 680 will be described.

  Communication ports 670 and 680 are configured by D-type flip-flop circuits. For example, a logic IC having a model number of 74HC273 is used for the flip-flop circuit, for example.

  This flip-flop circuit includes D0 to D7 terminals (D0_D7 in the figure), a clock terminal (CK), a clear terminal (CLR (negative logic)), and output terminals Q0 to Q7 (Q0_Q7 in the figure).

  DO to D7 terminals are terminals connected to the data bus 690 to acquire data to be transmitted to the effect control device 150 or the payout control device 210 from the data bus 690.

  A reset signal line is connected to the clear terminal from the power supply device 160. When a reset signal is input, the voltage level of the reset terminal becomes a low level. At this time, the communication ports 670 and 680 output low level signals from all of the output terminals Q0 to Q7.

  The signal levels from the output terminals Q0 to Q7 provided in the communication ports 670 and 680 can be freely set by the CPU core 102. This setting is realized by the CPU core 102 writing predetermined data in the storage area of the address assigned to the communication port 670 or the communication port 680.

  Specifically, when the CPU core 102 performs a process of writing data to the storage area of the address assigned to the communication port 670 (or communication port 680), the CPU core 102 transfers the communication port 670 ( Alternatively, the address of the communication port 680) is output.

  Next, a clock signal is input from the address decoder 611 to the clock terminal of the communication port 670 (or communication port 680) via the output control circuit 612, and the voltage level of the clock terminal rises to a high level.

  The communication ports 670 and 680 read data from the data bus 690 via the D0 to D7 terminals and output the read data from the Q0 to Q7 terminals when the voltage level of the clock terminal rises, that is, when the input of the clock signal starts.

  The communication ports 670 and 680 hold the voltage levels of the Q0 to Q7 terminals when the voltage level of the clock terminal falls, that is, when the input of the clock signal is completed.

  As described above, when the output control circuit 612 inputs a clock signal to the communication port 680 connected to the payout control device 210, the communication port 680 reads data from the data bus 690 at the timing when the clock signal is input, The read data is output to the dispensing control device 210.

  As described above, when a reset signal is input to the communication ports 670 and 680, the communication ports 670 and 680 are initialized. Specifically, when a reset signal is input, regardless of the voltage levels of the D0 to D7 terminals, the voltage levels of the Q0 to Q7 terminals are low, and the communication ports 670 and 680 are in the initial state.

  It should be noted that the activation (reset) of the security circuit 630, the RAM access restriction circuit 640, and the communication ports 670 and 680 described above is performed by sending a reset signal from the power supply device 160 via the reset interrupt control circuit 610 (FIG. 17). Will be executed if accepted.

  However, the reset signal from the power supply device 160 does not necessarily have to be input to each circuit via the reset interrupt control circuit 610, but to each circuit via a separate signal line that does not pass through the reset interrupt control circuit 610. It may be configured to be input.

  The payout control apparatus 210 does not include the communication ports 670 and 680, but includes a reception port (command input means) (not shown) that receives an output signal from the communication port 680 as shown in FIG. This is different from the game control device 100. The other configuration is the same as that of the game control device 100 shown in FIG.

  Also, the effect control device 150 does not include the communication ports 670 and 680, but includes a reception port (command input means) (not shown) that receives an output signal from the communication port 670 as shown in FIG. This is different from the game control device 100.

  Further, the gaming arithmetic processing device 600 does not include the RAM access restriction circuit 640. The other configuration is the same as that of the game control device 100 shown in FIG.

  Note that the reception port provided in the payout control device 210 and the effect control device 150 uses a logic IC whose model number is 74HC244. 74HC244 is a three-state buffer, and signals from the communication ports 670 and 680 of the game control device 100 are connected to the data input side of the three-state buffer, and the data output side of the three-state buffer is connected to the payout control device 210 (or effect). The data bus 690 formed in the control device 150) is connected.

  FIG. 19 is an explanatory diagram of the user work RAM 104 of the present embodiment.

  The user work RAM 104 includes a first power failure recovery area 701, a work area 702, a checksum area 703, a second power failure recovery area 704, a use prohibition area 705, and a stack area 706.

  Addresses “2800H” to “29FFH” are assigned to the user work RAM 104, addresses “2800H” are assigned to the first power failure recovery area 701, and addresses “2801H” to “2917H” are assigned to the work area 702. The address “2918H” is allocated to the checksum area 703, the address “2919H” is allocated to the second power failure recovery area 704, and the addresses “291AH” to “297FH” are allocated to the prohibited area 705. The stack area 706 is assigned addresses “2980H” to “29FFH”.

  Each area of the user work RAM 104 will be described.

  The first power failure recovery area 701 and the second power failure recovery area 704 store information that is referred to when power supply to the gaming machine 1 is started. Information (power cutoff confirmation flag) indicating whether or not the power cutoff processing has been executed correctly when the power switch 1 is turned off) is stored.

  The work area 702 stores variables and the like necessary for game control, and these variables are updated by the game control device main process shown in FIGS. 22 and 23 and the timer interrupt process shown in FIG. The checksum area 703 stores the checksums of the first power failure recovery area 701, the work area 702, the checksum area 703, and the second power failure recovery area 704 of the user work RAM 104 that are calculated when a power failure occurs.

  The use-prohibited area 705 is a storage area that is not used, and the CPU core 102 is reset when the area is accessed.

  The stack area 706 stores saved data when part of the data calculated by the CPU core 102 is temporarily saved. In addition, a return address when an interrupt occurs and a return address when a subroutine or function is called are also stored.

  FIG. 20 is an explanatory diagram of the stack area 706 of this embodiment.

  In FIG. 20, a case where the return address is stored in the stack area 706 will be described.

  First, in a state where no data is stored in the stack area 706, the stack pointer (SP) indicates the area (2A00H) adjacent to the last area (29FFH) of the stack area as the stack pointer initial value.

  Note that the area indicated by the stack pointer initial value is an area that is not included in the stack area (in this embodiment, an area that is not included in the storage area of the user work RAM 104).

  Next, when saved data is stored in the stack area 706, or when a return address is stored in the stack area 706 due to an interrupt or a subroutine call, the area where the data (or address) is stored last is stored by the stack pointer. Will show.

  When the saved data is restored from the stack area 706 or when the return address is extracted (when the interrupt process or the subroutine process ends and the process returns to the caller), the data (indicated by the stack pointer at that time) (Or address) is fetched, and the storage area from which data is to be fetched next is indicated by the stack pointer.

  In this way, the return address stored in the stack area 706 is read first from the return address stored later.

  FIG. 20 shows a state where a new interrupt or subroutine call occurs and the return address is stored as the fourth return address when the stack pointer points to the third return address. Thereafter, the storage area (29F8H) of the fourth return address is indicated by the stack pointer.

  FIG. 21 is a flowchart of the power-on process of each device (game control device 100, payout control device 210, and effect control device 150) of the present embodiment.

  Specifically, FIG. 21A is a flowchart of the power-on process of the game control apparatus 100, FIG. 21B is a flowchart of the power-on process of the payout control apparatus 210, and FIG. C) is a flowchart of the power-on process of the effect control device 150.

  The processing will be described from the power-on processing (FIG. 21A) of the game control device 100. This power-on process is not a process executed by the CPU 102 from the beginning, but is a process executed first by various hardware provided in the game control device 100 and later executed by the CPU 102.

  First, a reset signal is transmitted from the power supply device 160 to the game control device 100 (901).

  This reset signal is input from the power supply device 160 to the security circuit 630 (see FIG. 18), the clear terminal (see FIG. 18) of the flip-flop circuit 641 of the RAM access restriction circuit 640, and the clear terminals of the communication ports 670 and 680. The

  Specifically, when the power is turned on, a voltage equal to or lower than a predetermined voltage (for example, 5V) is applied to these clear terminals for a predetermined time, and a reset signal is input. As a result, the reset signal is not input.

  When the reset signal is input from the power supply device 160, the security circuit 630 continues to output the reset signal to the reset terminal of the CPU core 102 until the security check process described later is completed, and waits for the CPU core 102 to start up. Let

  Since the reset signal is input to the clear terminals of the communication ports 670 and 680, the voltage levels of the D0 to D7 terminals and the Q0 to Q7 terminals of the communication ports 670 and 680 are controlled to be low, and various devices (general power SOL95, The communication ports 670 and 680 and the output I / F 106 are initialized by hardware by setting all the ports of the output I / F 106 connected to the big prize opening SOL96 and the like to 0 (902).

  Next, the RAM access restriction circuit 640 generates a RAM write prohibited state in which writing to the user work RAM 104 is restricted (903).

  Specifically, as described in FIG. 18, since the reset signal is input to the clear terminal of the flip-flop circuit 641, a high-level signal is output from the output terminal Q (negative logic) of the flip-flop circuit 641. It becomes a state.

  As a result, whether a high level signal is input to the other input terminal of the OR gate circuit 642 or a low level signal is input, a high level signal is input to the write command input terminal of the user work RAM 104. As a result, a RAM write prohibition state occurs.

  Next, the security circuit 630 shown in FIG. 18 to which the reset signal is input executes self-diagnosis processing (904). The self-diagnosis process is a process for determining whether or not the security circuit 630 has been initialized.

  If it is determined by the self-diagnosis process that the security circuit 630 has been initialized, the security circuit 630 executes a security check process (905).

  As described with reference to FIG. 18, the security check process uses the validity check information stored in the HW parameter ROM 603 (see FIG. 17) to check the validity of the program stored in the user program ROM 602 (see FIG. 17). This is a process for making a determination.

  When the security check process is executed in the process of step 905, the process proceeds to the main process of the game control apparatus 100. At this time, the security circuit 630 stops the reset signal output to the reset terminal of the CPU core 102, whereby the CPU core 102 is activated. For this reason, the main process of the game control device 100 is executed by the CPU core 102. The main process of the game control apparatus 100 will be described with reference to FIG.

  Next, the power-on process (FIG. 21B) of the payout control device 210 will be described. As described above, the payout control device 210 is different from the communication ports 670 and 680 in that it includes a receiving port (not shown) (included in the input / output I / F 216 input in FIG. 16). It is the same structure as the game control apparatus 100 shown. The same components as those of the game control device 100 shown in FIG.

  First, a reset signal is transmitted from the power supply device 160 to the payout control device 210 (911). Note that the specific description of the process in step 911 is the same as the process in step 901.

  Since the reset signal is input to the payout control device 210, the voltage level of the output port (included in the input / output I / F 216 in FIG. 16) of the payout control device 210 is set to 0, and various devices (the payout motor 220). And the ports of the input / output I / F 216 connected to the launch control device 221 and the like are all set to 0, and the input / output I / F 216 is initialized by hardware (912).

  Next, a RAM write inhibition state in which writing to the RAM 214 is restricted by the RAM access restriction circuit 640 of the payout control device 210 occurs (913). Note that the specific description of the process of step 913 is the same as the process of step 903.

  Next, the security circuit 630 of the payout control device 210 to which the reset signal is input executes self-diagnosis processing (914). Note that the specific description of the process of step 914 is the same as the process of step 904.

  If it is determined by the self-diagnosis process that the security circuit 630 has been initialized, the security circuit 630 executes a security check process (915). Note that the specific description of the process in step 915 is the same as the process in step 905.

  Then, the payout control device 210 executes initialization processing at power-on (916). The initialization process at power-on is a process for initializing the RAM 214 and the like, and is executed by the CPU 212. Further, before the RAM 214 is initialized, the RAM write prohibition state generated in the process of step 913 is canceled, and the RAM 214 becomes a RAM writable state.

  Next, the payout control device 210 allows the game control device 100 to accept data from a reception port (not shown) (connected to the discharge control communication port 670 of the game control device 100 in FIG. 18). A state is generated in which a command from can be received (917).

  Then, the payout control device 210 takes in the data transmitted from the game control device 100 from the reception port (918).

  Regarding the processing of step 918, the configuration of the payout control device 210 is almost the same as the configuration of the game control device 100, and will be described with reference to FIG. 18. This output port (game) is output by the output selection circuit 612 of the payout control device 210. When connected to the discharge control communication port 670 of the control device 100 is selected, the data of Q0 to Q7 output from the discharge control communication port 670 of the game control device 100 is fetched, and the fetched data is paid out. The data is output to the data bus 690 of the device 210.

  Then, the CPU 212 of the payout control device 210 determines whether or not the data fetched by the reception port is an initialization command (919). Here, first, the timing of the rise of the Q7 signal (corresponding to STB described later in FIG. 29A) output from the discharge control communication port 670 is waited.

  Then, at the timing when the signal of Q7 rises, the signals of Q0 to Q6 (corresponding to DATA described later in FIG. 29A) output from the discharge control communication port 670 are defined in advance as initialization commands. (It will be described later in detail with reference to FIG. 30).

  If it is determined in step 919 that the data captured by the communication port is not an initialization command, the process returns to step 918, and the processing in step 918 is executed until the initialization command is captured.

  On the other hand, if it is determined in step 918 that the data fetched by the reception port is an initialization command, step 918 is performed until all initialization commands necessary for initialization of the dispensing control device 210 are received. After repeating the processes of -919, the initialization process at the start of communication is executed (920), and the process proceeds to the payout control apparatus main process.

  Next, the power-on process (FIG. 21C) of the effect control device 150 will be described.

  As described above, the effect control device 150 includes a reception port (not shown) instead of the communication ports 670 and 680, and the game arithmetic processing device 600 does not include the RAM access restriction circuit 640. Is the same configuration as the game control apparatus 100 shown in FIG. The same components as those of the game control device 100 shown in FIG.

  First, a reset signal is transmitted from the power supply device 160 to the effect control device 150 (921). Note that the specific description of the process of step 921 is the same as the process of step 901.

  Since the reset signal is input to the effect control device 150, the reception port of the effect control device 150 is initialized by hardware (922).

  Then, the effect control device 150 executes an initialization process when the power is turned on (923). The initialization process at power-on is a process for initializing the RAM 154 and the like, and is executed by the CPU 152. At this time, the CPU 152 controls the drive sources 93a to 93d (drive sources that drive the movable objects 60 to 62 described above) while monitoring the signal input from the position detection sensor (not shown). Control for returning the movable objects 60 to 62 to the initial position is started.

  Next, the effect control device 150 generates a state in which a command from the game control device 100 can be received by permitting the reception port to take in data (924).

  Then, the effect control device 150 takes in the data transmitted from the game control device 100 from the reception port (925).

  About the process of step 925, since the structure of the production | presentation control apparatus 150 is as substantially the same as the structure of the game control apparatus 100, if it demonstrates using FIG. When connected to the effect control communication port 680 of the control device 100 is selected, the data of Q0 to Q7 output from the effect control communication port 680 of the game control device 100 is taken in, and the fetched data is effect controlled. The data is output to the data bus 690 of the device 150.

  Then, the CPU 152 of the effect control device 150 determines whether or not the data captured by the reception port is an initialization command (926). Here, first, the timing of the rise of the Q7 signal (corresponding to STB described later in FIG. 29A) output from the effect control communication port 680 is waited for.

  Then, at the timing when the signal of Q7 rises, the signals of Q0 to Q6 (corresponding to DATA described later in FIG. 29A) output from the effect control communication port 680 are defined in advance as an initialization command. It is determined by whether or not (details will be described later with reference to FIG. 31).

  If it is determined in step 926 that the data fetched by the receiving port is not an initialization command, the process returns to step 925, and the processing in step 925 is executed until the initialization command is fetched.

  However, when the data pattern (Q0 to Q7 pattern) taken in by the receiving port is a specification specifying signal which will be described later with reference to FIG. 34, the process proceeds to the specification determination process in step 2212 in FIG. However, this will be described later.

  On the other hand, if it is determined in the process of step 926 that the data captured by the reception port is an initialization command, step 925 is performed until all initialization commands necessary for initialization of the effect control device 150 are received. After the processes of ˜926 are repeated, an initialization process at the start of communication is executed (927).

Here, the effect control device 150 determines the specification of the gaming machine 1 based on a command including information (specification specification information at initialization) that specifies the specification of the gaming machine in the initialization command. . Then, the CPU 152 of the effect control device 150 stores information (game specification information) as a result of determining the specifications of the gaming machine 1 in the RAM 154. Furthermore, the process which changes the position of the above-mentioned movable bodies 60-62 is performed corresponding to the information on the probability state included in the initialization command.
Note that when the initialization process at the start of communication in Step 927 is started, that is, when the initialization command is received, the process of returning the movable objects 60 to 62 started in Step 923 to the initial position is completed. If not, it is confirmed by the signal input from the position detection sensor that the movable objects 60 to 62 have returned to the initial position, and the initialization process at the start of communication is executed.

  When the process of step 927 is completed, the process proceeds to an effect control apparatus main process (described later in FIG. 34).

  Next, game control device main processing executed by the CPU 102 of the game control device 100 will be described with reference to FIGS.

  FIG. 22 is a flowchart of the first half of the game control device main process of the present embodiment, and FIG. 23 is a flowchart of the second half of the game control device main process of the present embodiment.

  First, the game control device 100 prohibits interruption to the CPU 102 (1001).

  Then, the game control device 100 sets a stack pointer at a predetermined address (stack pointer initial value described above with reference to FIG. 20) in the stack area 706 shown in FIG. 20 (1002), and sets an interrupt mode. (1003).

  The interrupt mode allows the CPU 102 to process an interrupt request from a built-in device and to set a position for executing the interrupt request process in a program.

  Next, the game control apparatus 100 takes in the state of the RAM clear SW signal from the input I / F 105 and stores the state of the fetched RAM clear SW signal in the register of the CPU 102 (1004).

  And the game control apparatus 100 performs the delay process which does not use RAM104 (1005). This delay process is a process that waits for a predetermined time, and specifically, is a process that continues to decrement until a predetermined number becomes zero in a storage area where a checksum is not calculated. Details of the delay processing will be described with reference to FIGS.

  Next, the game control device 100 takes in the state of the RAM clear SW signal again from the input I / F 105 and stores the state of the fetched RAM clear SW signal in the register of the CPU 102 (1006).

  Note that the CPU 102 stores the RAM clear SW signal state in step 1004 and the register clear area that stores the RAM clear SW signal state in step 1004 so that the CPU 102 can compare the states of the two RAM clear signals. The register areas to be used are different areas.

  Next, the game control device 100 sets the RAM write prohibition state generated in the process of step 903 to a RAM writable state (1007).

  Specifically, a clock signal is input from the output control circuit 612 to the clock terminal of the flip-flop circuit 641 in accordance with a command from the CPU 102, and the signal level of the signal line connected to the data terminal of the flip-flop circuit 641 is set to a high level. To.

  As a result, a high level signal is output from the output terminal Q (positive logic) of the flip-flop circuit 641, and a low level signal is output from the output terminal Q (negative logic). When a low level signal is input, the RAM becomes writable.

  Next, the game control device 100 executes various setting processes using the stack area 706 (1008). This setting process is, for example, a process of setting initial data in various storage areas necessary for game control by calling a subroutine or a function.

  These subroutines and functions are called from a plurality of locations described in the game control program, and contribute to reducing the capacity of the game control program. On the other hand, when a subroutine or function is called, processing for saving the return address in the stack area 706 is required as described above.

  Then, the game control apparatus 100 compares the state of the RAM clear SW signal stored in the register in the process of Step 1004 with the state of the RAM clear SW signal stored in the register in the process of Step 1008, and determines which RAM It is determined whether the state of the clear SW signal also indicates that the RAM clear SW 162 has been operated (1009).

  In the processing of step 1009, since it is determined whether or not the RAM clear SW 162 has been operated based on the state of the RAM clear signal acquired at different timings, erroneous determination due to noise or the like can be prevented.

  If it is determined in step 1009 that the RAM clear SW 162 has been operated, the game control device 100 initializes all storage areas of the user work RAM 104 (1010).

  Then, the game control device 100 transmits an initialization command signal to the payout control device 210 and the effect control device 150 (1011). Here, all initialization command signals (described later in FIG. 30) necessary to initialize the payout control device 210 are transmitted. In addition, all initialization command signals (described later in FIG. 31) necessary for initializing the production control device 150 are transmitted.

  When this initialization command signal is transmitted, it is transmitted including information for specifying the specifications of the gaming machine (specification specification specification information). The specifications of the gaming machine are stored in advance in the ROM 103 of the gaming control device 100.

  When step 1011 is completed, the process proceeds to step 1017 shown in FIG.

  On the other hand, when it is determined in step 1009 that the RAM clear SW 162 has not been operated, the game control device 100 confirms that the power is shut down in the first power failure recovery area 701 and the second power failure recovery area 704 of the user work RAM 104. It is confirmed whether the flag is stored (more precisely, whether the power shutoff confirmation flag is on) (1012).

  Then, the game control device 100 determines whether or not the power-off process has been executed correctly when the power supply was stopped immediately before (1013).

  Specifically, in the game control device 100, when the power shutdown confirmation flag is stored in both the first power failure recovery area 701 and the second power failure recovery area 704, the power shutdown process is correctly executed. On the other hand, when the power shutdown confirmation flag is not stored in at least one of the first power failure recovery area 701 and the second power failure restoration area 704 (when at least one power interruption confirmation flag is OFF). Determines that the power-off process is not correctly executed.

  If it is determined in step 1013 that the power-off process has been executed correctly, the game control apparatus 100 determines that the first workout recovery area 701, work area 702, checksum area 703, and 2 Checksum is calculated using the power failure recovery area 704, and it is verified whether or not the calculated checksum matches the checksum stored in the checksum area 703 (1014).

  The checksum stored in the checksum area 703 is checked using the first power failure recovery area 701, work area 702, checksum area 703, and second power failure recovery area 704 of the user work RAM 104 when a power failure is detected. The sum is calculated and stored.

  That is, the process of step 1014 is a process of collating whether the information stored in the user work RAM 104 at the time of power failure detection matches the information stored in the user work RAM 104 at the time of power-on.

  Then, it is determined whether or not the collation result of the processing in step 1014 matches the calculated checksum and the checksum stored in the checksum area 703 (1015).

  If it is determined in step 1015 that the checksum calculated in step 1014 does not match the checksum stored in checksum area 703, that is, the information stored in user work RAM 104 when a power failure is detected If the information stored in the user work RAM 104 at the time of power-on does not match, the game control device 100 proceeds to the process of step 1010, initializes all areas of the user work RAM 104, and in the process of step 1011 An initialization command is transmitted to the payout control device 210 and the effect control device 150.

  On the other hand, if it is determined in step 1015 that the checksum calculated in step 1014 matches the checksum stored in the checksum area 703 in step 1014, that is, the user work at the time of power failure detection. When the information stored in the RAM 104 matches the information stored in the user work RAM 104 at the time of power-on, the game control device 100 determines the area necessary for starting the game control device 100 (part of the user work RAM 104). Is initialized (1016).

  At this time, the power shutdown confirmation flag is erased in each of the first power failure restoration area 701 and the second power interruption restoration area 704 of the user work RAM 104 (more precisely, the power interruption confirmation flag is turned off in each area).

  Then, the game control device 100 transmits an initialization command to the payout control device 210 and the effect control device 150 (1011).

  When these processes are completed, the initialization process related to the game control device 100 is completed. Next, the processing proceeds to step 1017 shown in FIG.

  Next, after the initialization command is transmitted to the payout control device 210 and the effect control device 150 in the process of step 1011, the game control device 100 measures CTC (Counter Timer Circuit) for measuring various times and performing timer interrupts. Is started (1017), and a random number circuit for generating random numbers related to game control is initialized (1018). Then, the game control device 100 permits an interrupt to the CPU 102 that is prohibited in the process of Step 1001 (1019).

  Next, the game control device 100 executes an initial value random number update process for updating the initial value random number (1020). The initial value random number is an initial value when a random number counter relating to game control (for example, a random number counter acquired at the timing of winning the first start winning opening 25 or the second starting winning opening 30) reaches an upper limit value. Returning to, it is a random number for determining the initial value.

  Then, the game control device 100 confirms whether or not a power failure detection signal has been input (1021), and determines whether or not the confirmation result in the processing of step 1021 indicates that a power failure detection signal has been input. (1022).

  If it is determined in step 1022 that the power failure detection signal has not been input, no power failure has occurred, and the process returns to step 1020.

  On the other hand, if it is determined in step 1022 that a power failure detection signal has been input, the game control device 100 prohibits interruption to the CPU 102 (1023), and lowers the voltage level of the output port of the output I / F 106. The level is set (1024).

  Next, the game control device 100 stores the power shutdown confirmation flag in the first power failure recovery area 701 and the second power failure restoration area 704 of the user work RAM 104 (more precisely, the power interruption confirmation flag is turned on in each area). (1025), the checksum is calculated using the first power failure recovery area 701, the work area 702, the checksum area 703, and the second power failure recovery area 704 of the user work RAM 104, and the calculated checksum is used as the checksum area. It is stored in 703 (1026).

  Next, the game control device 100 puts the user work RAM 104 into the RAM write prohibited state by the RAM access restriction circuit 640 (1027).

  Specifically, a clock signal is input from the output control circuit 612 to the clock terminal of the flip-flop circuit 641 in accordance with a command from the CPU 102, and the signal level of the signal line connected to the data terminal of the flip-flop circuit 641 is set to a low level. To.

  As a result, a low level signal is output from the output terminal Q (positive logic) of the flip-flop circuit 641, and a high level signal is output from the output terminal Q (negative logic). When a high level signal is input, the RAM write inhibit state is entered.

  Then, the game control device 100 stands by until the gaming machine 1 is turned off (1028). In addition, since the backup power supply is connected to the game control apparatus 100, even if a power failure occurs, the power supply is not immediately turned off.

  In the present embodiment, in the process of step 1014, the RAM is writable in the process of step 1007 before determining the validity of the user work RAM 104 at the time of power-off and the user work RAM 104 at the time of power-on. The timing for making the RAM writable state may be immediately before the initialization process of the user work RAM 104 in the process of step 1010 or 1016 performed according to the legitimacy of the process of step 1014 at the latest.

  As described above, when the power supply is cut off in the gaming machine 1, the user work RAM 104 is set to the RAM writing prohibited state after the necessary power-off process is executed, and the game machine 1 supplies power again. Even if the process returns, the user work RAM 104 is not immediately brought into the RAM writable state, the hardware initialization process is executed for a certain period of time, and the process of step 1010 or 1016 is performed according to the validity of the process of step 1014. Immediately before executing the initialization process of the user work RAM 104 in the process, by finally making the RAM writable state, it is possible to prevent inadvertent writing of the user work RAM 104 until the user work RAM 104 is initialized.

  Therefore, immediately before the validity determination in the process of step 1014 is performed, the RAM writing is in a prohibited state. Therefore, erroneous writing is performed in the user work RAM 104 after power-on, and an erroneous determination is made in the process of step 1014. Can be prevented.

  In the present embodiment, in order to execute various setting processes using the stack area 706 in the process of step 1008, the RAM write enabled state is set in the process of step 1007 before the validity determination process in the process of step 1014. ing.

  As a result, various setting processes using the stack area 706 that is not the target of the validity determination can be performed before the validity determination is performed, so that various settings of the game control device 100 can be performed at an early stage. Therefore, the game control apparatus 100 can be started up at high speed, and the stack area 706 can be used, so that the processing program can be shared and the program capacity can be reduced.

  In FIG. 22, after initializing the user work RAM 104 in the process of step 1010 or 1016, the initialization command signal is transmitted in the process of step 1015, but step 1008 before executing the validity determination in step 1014. An initialization command signal may be transmitted after execution of the process.

  In this case, since the validity determination in the process of step 1014 is not performed, the initialization command signal is transmitted using the stack area 706 that does not contribute to the validity determination or the register provided in the CPU 102.

  In the process of step 1010 or 1016, the process of step 1016, which is a process for initializing a partial area of the RAM 104, takes longer than the process of step 1010, which is a process for initializing the entire area of the RAM 104. The time for which the initialization command signal is transmitted differs depending on whether the processing of 1010 or the processing of step 1016 is performed.

  By transmitting the initialization command signal before executing the validity determination in the process of step 1014, the initialization command signal can be transmitted earlier than transmitting the initialization command signal in the process of step 1011. In addition, the initialization command signal can be transmitted in a certain time after the power is turned on.

  FIG. 24 is an explanatory diagram of the delay processing of this embodiment.

  This delay processing is executed in step 1005 of FIG. 22, but at the time when the delay processing is executed, the RAM writing is prohibited so that the value of the user work RAM 104 cannot be updated. This is to check the checksum stored at the time of the previous power failure and the current checksum immediately after the power is turned on.

  For this reason, in the delay processing of step 1005 shown in FIG. 22, the user work RAM 104 including the storage area where the validity is determined is not used, and other storage areas (determination targets that are not subject to the validity determination are included. The delay processing must be executed using the (external storage area). Therefore, the delay processing of this embodiment is executed using a register (general-purpose register) provided in the CPU core 102.

  Hereinafter, delay processing using a register will be described. Since a Z80 CPU is used as the CPU core 102, description will be made using the registers and assembly language used in the Z80 CPU.

  First, the row 1201 corresponds to the first processing of the delay processing, and “0400H” is loaded into the HL register in which the H register and the L register of the CPU core 102 register (see FIG. 18) are configured as one pair. . Specifically, “04H” is loaded into the H register, and “00H” is loaded into the L register.

  Next, proceeding to line 1203, where the value of the HL register is decremented. When the row 1203 is executed for the first time, the value of the HL register is “03FFH”.

  The process then proceeds to line 1204, where the value stored in the H register is loaded into the A register.

  Then, proceeding to a row 1205, a logical sum of the A register and the L register is calculated. In line 1206, if the logical sum calculated in line 1205 is not zero, the process returns to line 1202. Accordingly, the processing in rows 1203 to 1206 is repeated until both the H register and the L register become “00H”.

  That is, in FIG. 24, “0400H” stored in the H register and L register used as the maintenance timer is decremented until “0000H”, and the decrement is performed 1024 times in total. During this time, the game control device main process shown in FIG. 22 waits in the process of step 1005, so that the activation of the game control device 100 is delayed.

  Further, during this delay process, the user work RAM 104 is not accessed at all. That is, the delay process can be executed without rewriting the value of the user work RAM 104 including the storage area where the validity is determined.

  FIG. 25 is an explanatory diagram of a delay process according to a modification of the present embodiment.

  The delay process of FIG. 24 described above is performed without using the storage area of the user work RAM 104 at all. In this modified example, the correctness determination target is included in the storage area of the user work RAM 104. The storage areas of the first power failure recovery area 701, work area 702, checksum area 703, and second power failure recovery area 704 are not accessed, but processing is performed using the stack area 706 that is not subject to validity determination. Like to do.

  Therefore, when the delay process is executed in step 1005 of FIG. 22 according to the procedure of FIG. 25, it is necessary to set the user work RAM 104 in a RAM writable state before executing step 1005. For example, the process of changing to the RAM writable state in step 1007 in FIG. 22 is executed immediately before the process in step 1005.

  A delay process using the stack area 706 will be described below.

  First, a row 1301 corresponds to the first processing of the delay processing, and information stored in the A register and F register (flag register) of the CPU core 102 is saved in the stack area 706 as an AF register pair. Let

  In row 1302, the information stored in the H and L registers of the CPU core 102 is regarded as an HL register configured as one pair, and is saved in the stack area 706.

  In line 1303, “0400H” is loaded into this HL register. Specifically, “04H” is loaded into the H register, and “00H” is loaded into the L register.

  Next, proceed to line 1305, where the value of the HL register is decremented. When row 1305 is executed for the first time, the value of the HL register is “03FFH”.

  The process then proceeds to line 1306, where the value stored in the H register is loaded into the A register.

  Proceeding to row 1307, the logical sum of the A register and the L register is calculated. In line 1308, if the logical sum calculated in line 1307 is not zero, the process returns to line 1304. Therefore, the processing in rows 1305 to 1308 is repeated until both the H register and the L register become “00H”.

  In line 1308, if the logical sum calculated in line 1307 is zero, the process proceeds to line 1309, and the information stored in the H register saved in the stack area 706 is returned to the H register of the CPU core 102. Then, the information stored in the L register saved in the stack area 706 is returned to the L register of the CPU core 102.

  Then, the process proceeds to line 1310, the information stored in the A register saved in the stack area 706 is returned to the A register of the CPU core 102, and the information stored in the F register saved in the stack area 706 is returned to the CPU core 102. Return to F register.

  As described above, in the delay process of FIG. 25, the information stored in the A register, F register, H register, and L register of the CPU core 102 used in the delay process is changed into the stack area before the delay process is performed. The information stored in the A register, F register, H register, and L register can be prevented from being lost by the delay process.

  As described with reference to FIGS. 24 and 25, in this embodiment, the delay processing is realized by software using a region that does not contribute to the validity determination, that is, does not calculate the checksum, without using hardware. 22), it is possible to accurately perform the legitimacy determination in step 1014 shown in FIG. 22, and it can be realized at a lower cost than the delay processing by hardware.

  24 and 25 are compared, the method of FIG. 25 is more effective when the number of registers that can be used by the CPU core 102 is small. However, it is desirable to prevent as much as possible that the storage areas of the first power failure recovery area 701, work area 702, checksum area 703, and second power failure recovery area 704, which are subject to the validity determination, are rewritten due to noise or the like. If this is the case, it can be said that the method of FIG. 24 in which the user work RAM 104 is in the RAM write-inhibited state throughout the delay process is superior.

  FIG. 26 is a flowchart showing the timer interrupt process of the present embodiment. This timer interrupt process is executed by the CPU core 102 of the game control apparatus 100.

  When the power of the gaming machine is turned on, the game control device main process (see FIGS. 22 and 23) is executed. When a timer interrupt is generated at a predetermined time period (for example, a period of 4 milliseconds) by the CTC activated in the process of step 1017, the timer interrupt process is repeatedly executed by the CPU 102 of the game control device 100.

  However, all of these processes (processes 1412 to 1422) are not necessarily performed every time an interrupt occurs. For example, in the input / output process (S1412), the input signal is monitored every time, but the output process may be executed every other occurrence of an interrupt. That is, instead of completing all the processes in one interrupt process, the interrupt process may be repeatedly executed a plurality of times to complete a series of game control processes.

  In the timer interrupt process of this embodiment, first, the register data is saved (1411).

  Next, input / output processing is executed (1412). The input / output process includes an input process and an output process. Input processing is input from various sensors (special drawing start SW25A, 30A, universal start SW31A, count SW27A, winning port SW32A-32N, overflow SW109, out of ball SW110, frame opening SW111, etc.) via the input I / F 105. This process is a process of removing chattering and the like on the signal to determine input information.

  The output process is performed through the output I / F 106 based on the parameters set in the special figure game process (1419) and the general figure game process (1420), and the special figure display unit 120, the universal figure display unit 121, Signals for controlling the electric SOL 95 and the special winning opening SOL 96 are output.

  As described above, the input process and the output process do not have to be executed simultaneously by a single timer interrupt.

  Next, command transmission processing for outputting (command) set in the transmission buffer in various processes to the effect control device 150 and the payout control device 210 is performed (1413). Specifically, an effect command signal (effect command) related to the special symbol variation display game is output to the effect control device 150, or a payout command signal (payout command) is output to the payout control device 124.

  The payout command will be described in detail with reference to FIG. 29, and the effect command will be described in detail with reference to FIG.

  Thereafter, a random number update process 1 is performed in which the value of the hit random number counter for determining the hit of the special symbol variation display game is incremented by 1 (1414). In addition, in this random number update process 1, 1 is also added to the value of the hit symbol random number counter for determining the stop symbol of the special symbol variation display game, and the random number per symbol for determining the hit of the normal symbol variation display game. .

  Next, the initial value of the random number is updated, and an initial value random number update process for breaking the temporal regularity of the random number is executed (1415). The initial value random number update process 1415 is the same as the initial value random number update process (1020) shown in FIG.

  Then, a random number update process 2 is performed in which the value of the variation display pattern random number counter for updating the random number for determining the variation display pattern in the decorative special symbol variation display game related to the special symbol variation display game is incremented by one (1416). .

  Next, in order to monitor whether or not a game ball has won a prize at each prize opening, a prize opening monitoring process is performed (1417). Specifically, whether or not a signal is input from the special figure starting SW 25A, 30A, the general chart starting SW 31A, the count SW 27A, or the winning holes SW 32A to 32N (whether or not a signal indicating detection of a game ball is input). ).

  At this time, if the game ball is detected by the special figure start SW 25A, 30A, the special figure random number counter value (random number related to the result mode of the special symbol variation display game) is stored in the special figure start winning storage area, and the normal figure start SW 31A If the game ball is detected by the above, the usual random number counter value (random number related to the result pattern of the normal symbol variation display game) is stored in the usual start winning storage area.

  Thereafter, an error monitoring process is performed to monitor the clogging of the discharged balls and abnormalities of various switches and sensors (1418).

  Thereafter, a special figure game process (1419) for performing a process related to the special symbol variation display game, and a general figure game process (1420) for performing a process related to the normal symbol variation display game are performed.

  The special figure game process (1419) is extracted based on the winning of the game ball to the first start winning opening 25 or the second starting winning opening 30 detected by the special figure starting SW 25A, 30A, and is stored in the special symbol start winning memory. It is determined whether or not the stored special symbol random number counter value (random number related to the result of the special symbol variation display game extracted and stored in the process of 1417) is hit, and the special symbol display unit 120 executes the special symbol variation display game. .

  The special figure start winning memory stores the random number extracted when a game ball wins the first start winning opening 25 or the second starting winning opening 30 in a state where the variable display game cannot be immediately executed. It is stored as a start winning memory.

  In addition, a process for displaying the variation of the identification information corresponding to the display on the special figure display 120 is performed. If the extracted random number is a predetermined value, the hit state related to the special symbol is entered, and the variation display of the identification information stops at the hit symbol. Moreover, when it becomes a winning state, it will be in the open state which is easy to accept a game ball in the special fluctuation winning device 27.

  The normal game process (1420) is extracted based on the passing of the game ball to the normal symbol start gate 31 detected by the normal symbol start SW 31A, and is stored in the normal symbol start winning memory (1417). It is determined whether or not the random symbol related to the result of the normal symbol variation display game extracted and stored in the above process is hit, and the normal symbol variation display game is executed by the general symbol display 121. If the common random number counter value is a predetermined value, a hit state related to the normal figure is entered, and a parameter is set for stopping the fluctuation display of the normal symbol in the win state.

  Next, the game control device 100 performs processing for editing a signal that is provided in the gaming machine 1 and that is output to a segment LED (a special display display 120 and a general display display 121) that displays various information related to the game (1421). ). Specifically, when the special symbol variation display game is started, the special symbol winning memory number obtained by subtracting the number of executions of the special symbol variation display game started this time is displayed on the special symbol memory display unit of the special symbol display 120. Edit the parameters for:

  Similarly, when the normal symbol variation display game is started, the normal symbol winning memory number obtained by reducing the number of times of execution of the normal symbol variation display game started this time is displayed on the general symbol display of the general symbol display 121. Edit the parameters.

  Thereafter, external information editing processing for editing external information for outputting the state of the gaming machine 1 to the management computer connected via the inspection apparatus connection terminal 107 is performed (1422). External information includes information related to the progress status of the variable display game, such as whether the symbol has been confirmed, winning, changing the probability, shortening the variable time, starting the variable display game, etc. It is. An error signal indicating that an error has occurred is also included.

  Next, the end of the timer interrupt process is declared (1423).

  Thereafter, a return process (1424) for restoring the temporarily saved register and a process for setting permission of the interrupt that has been prohibited are performed (1425). Then, the timer interrupt process is terminated, and the process returns to the game control apparatus main process (FIGS. 22 and 23). Then, the initial value random number update process and the like (the processes of steps 1020 to 1022 in FIG. 23) are repeated until the next timer interrupt occurs.

  FIG. 27 is a timing chart of processing performed by the game control device 100, the payout control device 210, and the effect control device 150 when the power is turned on, and the communication ports 670 and 680 provided in the game control device 100 according to the present embodiment. is there.

  When the reset signal is transmitted to the payout control communication port 680 and the effect control communication port 670, Q0 to Q0 provided in each of the payout control communication port 680 and the effect control communication port 670 are processed by the process of step 902 shown in FIG. By setting all the voltage levels of the Q7 terminal to the low level, the payout control communication port 680 and the effect control communication port 670 are changed from the undefined state (1501) to the initial state (1502).

  In the initial state of the payout control communication port 680 and the effect control communication port 670, the game control device 100 transmits an initialization command in the process of step 1011 shown in FIG. It continues until it is set to the production control communication port 670 (1503).

  On the other hand, when the reset signal is transmitted to the security circuit 630 of the game control apparatus 100, the self-diagnosis process is executed in the process of step 904 shown in FIG. 21, and the security check process is executed in the process of step 905 (1504). After execution of the security check process, the CPU 102 is activated, and the game control apparatus main process (FIGS. 22 and 23) is executed by the CPU 102.

  The CPU 102 fetches the first RAM clear signal (1505) before executing the delay process (1506) and fetches the second RAM clear signal (1507) after executing the delay process. In other words, the first RAM clear signal fetch (1505) and the second RAM clear signal fetch (1507) are executed with a delay process (1506) in between.

  As described above, since the delay process is executed during the RAM clear signal fetching executed at each time point 1505 and 1507, the chattering removal etc. fetched by the first RAM clear signal fetching is performed during the delay process. be able to.

  After waiting for processing in the delay processing (1506), initialization processing of the RAM 104 is performed in the processing of steps 1016 and 1010 shown in FIG. 22 (1508), and an initialization command is transmitted in processing of step 1011. The game control is performed (1509).

  When normal game control is executed, a payout control command is set in the payout control communication port 680 in order to transmit a payout control command to the payout control device 210 in accordance with the gaming state (1510). Further, during the execution of the normal game control, the effect control command is set in the effect control communication port 670 in order to transmit the effect control command to the effect control device 150 according to the game state (1511).

  While normal game control is being executed, a bit pattern of a specification specifying signal that specifies the specification of the gaming machine 1 using a period during which no effect control command is output (steady output bit pattern of FIG. 32). 2003) is set in the effect control communication port 670.

  On the other hand, when the reset signal is transmitted to the security circuit of the payout control device 210, the security circuit of the payout control device 210 executes a self-diagnosis process in step 914 shown in FIG. Check processing is executed (1512).

  After executing the security check process, the CPU 212 is activated, and the CPU 212 executes the initialization process at the time of power-on in the process of step 916 in FIG. 21 (1513). When the initialization process of the payout control device 210 is executed, the state of the receiving port of the payout control device 210 is set to a state in which an instruction from the game control device 100 can be received (1514).

  When the reset signal is transmitted to the effect control device 150, the effect control device 150 executes the initialization process at the time of power-on in the process of step 923 in FIG. 21 (1515). When the initialization process of the effect control device 150 is executed, the state of the reception port of the effect control device 150 is changed to a state in which an instruction from the game control device 100 can be received (1516).

  The game control apparatus 100 delays the execution start timing of the initialization process of the RAM 104 by executing the delay process. In other words, the timing for transmitting the initialization command to the effect control device 150 and the payout control device 210 is delayed by the delay process.

  For this reason, the delay process ensures sufficient time for the payout control communication port 680 and the effect control communication port 670 to maintain the initial state, during which the payout control device 210 and the effect control device 150 execute the initialization process. Then, it is possible to make the reception port of itself receive a command from the game control device 100.

  Therefore, by providing a delay process, as shown in FIG. 27, even if the gaming machine has a configuration in which the reset signal is simultaneously transmitted to the game control device 100, the payout control device 210, and the effect control device 150, hardware or the like The timing at which each control device starts to start can be appropriately set without providing the delay circuit configured as described above.

  Therefore, as shown in FIG. 27, first, the payout control communication port 680 and the effect control communication port 670 are maintained in the initial state, and in this state, the receiving ports of the payout control device 210 and the effect control device 150 are in a command receivable state. Then, it becomes possible to reliably execute transmission of the initialization command to the payout control device 210 and the effect control device 150.

  If the gaming machine 1 immediately after power-on, the payout control device 210 or the effect control device 150 receives the payout control communication port 680 and the effect control communication port 670 of the game control device 100 before the game control device 100 is maintained in the initial state. Since the signal level output from the payout control communication port 680 and the effect control communication port 670 is unstable when the command port is ready for command reception, the payout control device 210 or the effect control device 150 causes the unstable signal to be output. The level information may be erroneously received as a legitimate signal, which may cause a malfunction.

  Also, if an initialization command is transmitted from the game control device 100 to the payout control device 210 or the effect control device 150 before the receiving port of the payout control device 210 or the effect control device 150 becomes ready for command reception. The payout control device 210 and the production control device 150 cannot receive the initialization command, which may cause a malfunction.

  In particular, as in the gaming machine of the present embodiment, a configuration in which a command is transmitted from the game control device 100 to the payout control device 210 in a single direction, or a configuration in which a command is transmitted from the game control device 100 to the effect control device 150 in a single direction. In this case, since there is no way to confirm whether the commanded information is correctly transmitted, such a configuration is very effective.

  22 and 27 show an example in which the RAM clear signal is fetched twice, but it may be a plurality of times. By executing the delay processing between the plurality of times, the time required for chattering removal of the RAM clear signal fetching immediately before the execution of the delay processing can be overlapped with the delay time by the delay processing, so that the processing becomes efficient.

  FIG. 28 is a flowchart for explaining a procedure when a command is transmitted from the game control device 100 to the effect control device 150 and the payout control device 210.

  In the present embodiment, when the initialization command signal is transmitted from the game control device 100 to the effect control device 150 and the payout control device 210, the normal control signal is sent from the game control device 100 to the effect control device 150 and the payout control device 210. A description will be given in comparison with a case where a command (production command signal, payout command signal) is transmitted.

  FIG. 28A is a flowchart in the case of transmitting an initialization command signal, and corresponds to the initialization command communication process in step 1011 of FIG. (B) of FIG. 28 is a flowchart in the case of transmitting a normal command (effect command signal, payout command signal), and corresponds to the command transmission processing in step 1413 of FIG.

  First, in (a) of FIG. 28, the initialization command signal transmitted first to the production control device 150 is selected (1601A), and the data corresponding to the mode (MODE) portion of the selected initialization command signal is produced. The data is output to the control communication port 670, and the output state is maintained for a predetermined time (1602A). The mode part will be described later.

  Next, the bit corresponding to the strobe (STB) signal of the production control communication port 670 is set to ON and the output state is maintained for a certain time (1603A), and then the bit corresponding to the strobe signal is set to OFF. The output state is maintained for a certain time (1604A).

  Next, data corresponding to the action (ACTION) part of the initialization command signal transmitted to the effect control device 150 is output to the effect control communication port 670, and the output state is maintained for a predetermined time (1605A). The action part will be described later.

  Next, the bit corresponding to the strobe (STB) signal of the effect control communication port 670 is set to ON, the output state is maintained for a certain time (1606A), and then the bit corresponding to the strobe signal is set to OFF. The output state is maintained for a certain time (1607A).

  Next, it waits for a predetermined time d (details will be described later) (1608A), and if there is an initialization command signal to be transmitted next (1609A), it returns to step 1601A and transmits the next initialization command signal. Are repeated (1601A to 1609A).

  If all initialization command signals have been transmitted to the production control device 150 at step 1609A, the process returns to step 1601A to select the initialization command signal to be transmitted first to the payout control device 210. Then, the processing of 1602A to 1609A is repeated.

  However, the initialization command signal to the payout control device 210 is output not to the production control communication port 670 but to the discharge control communication port 680, and the strobe (STB) signal also uses the bit of the discharge control communication port 680.

  After that, when all the initialization command signals have been transmitted to the payout control device 210, the output step 1609A is determined as “YES”, so a specification specifying signal is output to the effect control communication port 670 (1610A).

  Here, the data of the steady output bit pattern 2003 described later in FIG. 32 is output to each bit of Q0 to Q7 of the effect control communication port 670. Since this bit pattern signal (corresponding to “TYPE” described later in FIG. 29) continues until the next command is transmitted from the effect control communication port 670, the signal is constantly transmitted while the effect command signal is not transmitted. (The details will be described later with reference to FIG. 29).

  When the process of step 1610A is completed, the process returns to the caller (the process subsequent to the initialization command communication process of step 1011 in FIG. 23).

  On the other hand, in (b) of FIG. 28, it is determined whether or not it is timing to transmit the effect command signal to the effect control device 150 (1601B). If it is the transmission timing of the effect command signal, the mode (MODE) of the effect command signal to be transmitted The data corresponding to the section is output to the production control communication port 670 and the output state is maintained for a certain time (1602B).

  Next, the bit corresponding to the strobe (STB) signal of the effect control communication port 670 is set to ON, the output state is maintained for a certain time (1603B), and then the bit corresponding to the strobe signal is set to OFF. The output state is maintained for a certain time (1604B).

  Next, data corresponding to the action (ACTION) part of the initialization command signal transmitted to the effect control device 150 is output to the effect control communication port 670, and the output state is maintained for a certain time (1605B).

  Next, the bit corresponding to the strobe (STB) signal of the effect control communication port 670 is set to ON, the output state is maintained for a certain time (1606B), and then the bit corresponding to the strobe signal is set to OFF. Then, the output state is maintained for a certain time (1607B), a specification specifying signal is output to the effect control communication port 670 (1608B), and then to the caller (the process subsequent to the command transmission process in step 1413 in FIG. 26). Return.

  Even when a specification specifying signal is output to the effect control communication port 670 in step 1608B, the data of the steady output bit pattern 2003, which will be described later with reference to FIG. Output to each bit of Q7.

  As described above, this bit pattern signal (corresponding to “TYPE” described later in FIG. 29) continues until the next command is transmitted from the effect control communication port 670, so that the effect command signal is not transmitted. Is output constantly (details will be described later with reference to FIG. 29).

  On the other hand, if it is not time to transmit the production command signal to the production control device 150 in step 1601B, it is determined whether it is time to send the emission command signal to the discharge control device 150 (1609B), and transmission of the emission command signal is performed. If it is timing, a discharge command signal is transmitted (1610B). At this time, the discharge command signal is output from the discharge control communication port 680 in the same procedure as the procedure of 1602B to 1607B described above.

  In step 1601B, if it is not time to transmit a discharge command signal to the discharge control device 150, and if the discharge command transmission processing in step 1609B is completed, the caller (next to the command transmission processing in step 1413 in FIG. Return to processing.

  FIG. 29 is an explanatory diagram of command signals transmitted from the game control device 100 of the present embodiment to the payout control device 210 and the effect control device 150.

  In particular, FIG. 29A is an explanatory diagram of an initialization command signal transmitted from the game control device 100 of the present embodiment to the payout control device 210 and the effect control device 150, and FIG. 29B is the present embodiment. It is explanatory drawing of the payout command signal and effect command signal which are transmitted to the payout control apparatus 210 and the effect control apparatus 150 from the game control apparatus 100 of a form.

  First, the initialization command signal will be described with reference to FIG. This corresponds to the processing of the procedure according to the flowchart of FIG.

  The initialization command signal includes a mode (MODE) part and an action (ACTION) part, and is transmitted in the initialization command communication process of step 1011 shown in FIG.

  As shown in FIG. 28A, the initialization command communication process of step 1011 shown in FIG. 22 includes a plurality of transmission processes for transmitting the mode part and the action part until the transmission of the initialization command signal is completed. It is a loop process that is repeated once. In FIG. 29A, the initialization command signal is transmitted by repeating the transmission process three times.

  The Q0 to Q6 terminals of the communication ports 670 and 680 are used to transmit data of the mode part and the action part, and the Q7 terminal is used to transmit a strobe signal that is a timing signal for reading.

  In each transmission process, the strobe signal is output from the Q7 terminal for a predetermined time, and the mode part and the action part are transmitted from the Q0 to Q6 terminals. When the strobe signal is input from the Q7 terminal, the payout control device 210 or the effect control device 150 to be received takes in the mode part or action part input from the Q0 to Q6 terminals.

  As described above with reference to FIG. 28A, in the initialization command communication process, after the transmission process is executed, the software timer delay process for waiting the process for software for a predetermined time (d) is executed, and the transmission process is performed again. Execute.

  On the other hand, if all the data of the initialization command signal has been transmitted, the initialization command communication process is exited and the process returns to the game control apparatus main process shown in FIG.

  In FIG. 29A, every time an initialization command signal is transmitted, a software delay process of the time value d is executed. For this reason, the transmission cycle of the initialization command signal is f1, and the time until the transmission of all data of the initialization command signal is completed (the time until the third transmission process is completed) is T. ing.

  When the transmission of all data is completed, the data of the steady output bit pattern 2003 described later in FIG. 32 is output to each bit of Q0 to Q7 of the effect control communication port 670 (corresponding to “TYPE” in the figure). ).

  Since this bit pattern signal continues until the next command is transmitted from the effect control communication port 670, the signal is constantly output while the effect command signal is not transmitted.

  Note that the data of the steady output bit pattern 2003, which will be described later with reference to FIG. 32, is “71H”, “72H”, and “73H”, so the bit of Q7 of the effect control communication port 670 is always “0”. Therefore, the STB of the production control communication port 670 does not rise while the “TYPE” data (specification specification signal) is being output.

  Next, a command signal transmitted to the payout control device 210 or the effect control device 150 at the normal time will be described with reference to FIG.

  This normal command signal is transmitted in the command transmission process of step 1413 shown in FIG.

  Transmission of all data of the command signal is completed by command transmission processing by a plurality of timer interruptions, without completion of transmission by command transmission processing by one timer interruption. In other words, the command signal is transmitted across a plurality of timer interruption processes. In FIG. 28 (B), it is assumed that transmission of all data of the command signal is completed by command transmission processing by three timer interruptions.

  The execution period (f2) of each command transmission process is synchronized with the generation period of the timer interrupt and is a period of 4 milliseconds.

  In addition, the normal command signal includes a mode part and an action part, like the initialization command signal. In other words, the normal command signal and the initialization command signal have the same time during which the mode section is output, the time during which the action section is output, and the output time of the strobe signal, that is, the format is the same. It is common.

  Therefore, transmitting the data of the mode part and the action part from the Q0 to Q6 terminals of the communication ports 670 and 680 and outputting the strobe signal from the Q7 terminal is the same as the case of the initialization command signal.

  28A and 28B, when the initialization command signal sets the delay time (d) by the software delay processing of the loop processing, the transmission cycle (f1) of the initialization command signal is the normal command. It is set to be shorter than the signal transmission cycle (f2).

  For this reason, the initialization command signal can be transmitted at a higher speed than the normal command signal. This can be shorter than the time required to complete the data transmission.

  Therefore, it is possible to shorten the time from when the power is turned on until the payout control device 210 and the effect control device 150 perform control based on the normal command signal.

  When the data transmission between the mode part and the action part is completed, the data of the steady output bit pattern 2003 described later in FIG. 32 is output to each bit of Q0 to Q7 of the effect control communication port 670 (“TYPE” in the figure). ”). Since this bit pattern signal continues until the next command is transmitted from the effect control communication port 670, the signal is constantly output while the effect command signal is not transmitted.

  FIG. 30 is an explanatory diagram of signals transmitted to the payout control apparatus 210 of the present embodiment.

  Signals transmitted to the payout control device 210 include an initialization command signal and a payout command signal that is a normal command signal, and these signals are transmitted in a common format including a mode portion and an action portion.

  First, the initialization command signal will be described.

  The initialization command signal is composed of a first half initialization command signal and a second half initialization command signal.

  The initialization command signal in the first half has a value of “40H” in the mode portion and any value from “00H to 7FH” in the action portion. The action part of the initialization command signal in the first half is a value corresponding to the authentication code set in the payout control device 210 (any value of “00H to 7FH”). It is assumed that a value corresponding to the authentication code set in the payout control device 210 is set in the RAM 104, for example.

  The output timing of the initialization command signal in the first half is when the game control apparatus 100 is powered on, and specifically, is the process of step 1011 shown in FIG.

  In the initialization command signal in the latter half, the mode part has a value of “40H” and the action part has any value of “7FH to 00H”. The action part of the initialization command signal in the latter half is a negative logic value (inverted bit) of the value of the action part of the initialization signal in the first half.

  The output timing of the latter half of the initialization command signal is immediately after the output of the first half of the initialization command signal is completed.

  Upon receiving the first half initialization command signal, the payout control device 210 authenticates whether the value of the action part of the received initialization command signal matches the authentication code set in itself.

  When the value of the action part of the received initialization command signal does not match the authentication code set in itself, the payout control device 210 prohibits the control based on the normal command signal. That is, payout of game media based on the payout command signal is prohibited.

  On the other hand, when the value of the action part of the received initialization command signal matches the authentication code set in itself, the payout control device 210 receives the initialization command signal in the latter half and receives the initial It authenticates whether the negative logic value of the action part value of the commutation command signal matches the authentication code set in itself.

  If the value that is the negative logic of the action part of the received initialization command signal in the latter half does not match the authentication code set in itself, the latter initialization command signal has not been correctly received, Since there is a possibility that a disconnection has occurred between the game control device 100 and the payout control device 210, the payout control device 210 reports an error.

  Next, the payout command signal will be described.

  Fifteen payout control command signals are prepared corresponding to the number of game media to be paid out by the payout control device 210.

  The mode part of the payout command signal is “21H to 2FH”. Note that the second digit of the mode portion matches the number of game media whose payout command signal commands payout. The action part of the payout command signal is “5EH to 50H”. This action part is a negative logic of the value of the mode part.

  For example, the mode part of the payout command signal for instructing payout of one game medium is “21H”, and the action part is “5EH”.

  The payout command signal is output at the timing when the game ball is won in the general winning opening 32, the first starting winning opening 25, the second starting winning opening 30, and the special variable winning apparatus (large winning opening) 27. .

  Further, when the payout control device 210 receives the payout command signal, the payout command signal received when the negative logic value of the mode portion of the received payout command signal does not match the negative logic value of the action portion. Dispensing of the number of game media corresponding to is not permitted.

  FIG. 31 is an explanatory diagram of signals transmitted to the effect control device 150 of the present embodiment.

  The signals transmitted to the effect control device 150 include an initialization command signal and an effect command signal that is a normal command signal, and are transmitted in a common format including these mode part and action part.

  First, the initialization command signal will be described.

  The initialization command signal includes a power-on notification signal indicating whether or not all areas of the RAM 104 have been initialized, and a command signal for specifying the specifications of the gaming machine 1 (a command including specification specification information at initialization). )

  In addition, a signal for notifying the gaming state (low probability state, high probability state, winning suppression state, winning promotion state) of the gaming machine 1 at the time of the previous power interruption, and the number of special symbol winning memories at the time of the previous power interruption. The signal to be notified is also included in the initialization command signal.

  The mode part of the power-on signal indicating that all areas of the RAM 104 are initialized is “10H”, and the action part is “01H”. The fact that all the areas of the RAM 104 have been initialized means that the processing of step 1010 shown in FIG. 22 has been executed.

  On the other hand, the mode part of the power-on signal indicating that all areas of the RAM 104 are not initialized, that is, a part of the area of the RAM 104 is initialized is “10H”, and the action part is “02H”. It is.

  That all areas of the RAM 104 have not been initialized, that is, that a part of the area of the RAM 104 has been initialized means that the processing of step 1014 shown in FIG. 22 has been executed.

  Therefore, when the process of step 1010 shown in FIG. 22 is executed, an initialization command signal in which the mode part is “10H” and the action part is “01H” is transmitted in the process of step 1011. When the process of step 1014 shown in FIG. 22 is executed, in step 1011, an initialization command signal having a mode part “10H” and an action part “02H” is transmitted.

  When the effect control device 150 receives a power-on signal indicating that all areas of the RAM 104 have been initialized, the effect control apparatus 150 displays on the display device 8 that all areas of the RAM 104 have been initialized.

  In addition, when receiving the power-on signal indicating that all areas of the RAM 104 are not initialized, the effect control apparatus 150 displays on the display device 8 that all areas of the RAM 104 have not been initialized.

  Further, the mode part of the command signal for specifying the specification transmitted at the time of activation is “11H”, and the action part is “01H to 03H”. The action part is one of the values “01H to 03H” corresponding to the specifications of the gaming machine 1. Note that values corresponding to the specifications of the gaming machine 1 are set in the ROM 103.

  In addition, the signal for notifying the gaming state (low probability state, high probability state, winning suppression state, winning promotion state) has a mode portion of “20H”, and the action portion has a game at the time of the previous power cut-off. A value associated with each state is stored.

  For example, the action part is “01H” in the low probability state, and the action part is “02H” in the high probability state. When receiving the signal for notifying the gaming state, the effect control device 150 performs an effect for notifying the gaming state.

  In addition, the signal for notifying the number of special symbol winning memories is “28H” in the mode portion and any value from “00H to 04H” in the action portion. The action part is a value corresponding to the starting memory number (0 to 4) at the time of the previous power shutdown.

  When receiving the start memory number effect command signal, the effect control device 150 displays the start memory number corresponding to the received start memory number effect command signal on a decoration start memory number display unit (not shown) of the display device 8.

  The output timing of these specification specifying signals, signals notifying the gaming state, and signals notifying the number of special symbol winning memories is when the power is turned on, and is transmitted in the process of step 1011 shown in FIG.

  Note that the output order of each of these signals and the power-on notification signal may be first or later. Further, when there is other information to be notified from the game control device 100 to the effect control device 150 when the power is turned on, it may be transmitted together as an initialization command signal.

  In this way, in this embodiment, even if the types of initialization command signals (power-on notification signal, specification specifying signal, signal notifying the gaming state, and signal notifying the number of special symbol winning memory) increase, Since the initialization command signal is sequentially transmitted through the main processing loop, the time until all the initialization command signals are transmitted is shortened.

  Next, each effect command signal will be described.

  First, the variation start effect command signal for instructing the symbol variation start in the variation display game executed on the display device 8 will be described.

  The mode part of the variation start effect command signal is “30H”, and the action part is any value of “01H to 6FH”. The action part is a value corresponding to the fluctuation time from the start of the symbol fluctuation display to the stop.

  When the effect control device 150 receives the change start effect command signal, the display device 8 starts changing the symbol display on the display device 8 and starts the change display game.

  The variation start effect command signal is transmitted at a timing at which the display device 8 starts the variation display of the symbol of the variation display game. Specifically, when the display device 8 finishes the variable display game and there is a start memory, or when the display device 8 does not execute the variable display game, the first start winning opening 25 or the second start winning opening This is a case where a game ball wins 30.

  A stop symbol effect command signal for specifying a stop symbol in the variable display game on the display device 8 will be described.

  The mode part of the stop symbol effect command signal is “31H”, and the action part is any value of “01H to 6FH”. The action part is a value corresponding to the stop symbol.

  When receiving the stop symbol effect command signal, the effect control device 150 specifies the stop symbol of the variable display game on the display device 8 based on the received stop symbol effect command signal.

  The stop symbol effect command signal is transmitted when starting the variable display of the variable display game on the display device 8 and immediately after the transmission of the change start effect command signal is completed.

  A stop notification effect command signal for stopping the symbol whose change time has elapsed and whose change is being displayed will be described.

  The mode part of the stop notification effect command signal is “40H”, and the action part is “01H”.

  When receiving the stop notification effect command signal, the effect control device 150 stops the symbols that are variably displayed on the display device 8.

  The stop notification effect command signal is transmitted at the timing when the fluctuation time has elapsed.

  The jackpot related effect command signal transmitted during the occurrence of the special gaming state will be described.

  The mode portion of the jackpot related effect command signal is “48H”, and the action portion is any value of “01H to 6FH”. The action part is a value corresponding to the progress status of the special game state.

  When receiving the jackpot related effect command signal, the effect control device 150 performs an effect related to the special gaming state based on the received jackpot related effect command signal.

  An error-related effect command signal for notifying the occurrence of an error when an error occurs in the gaming machine 1 will be described.

  The mode part of the error-related effect command signal is “50H”, and the action part is any one of “01H to 6FH”. The action part is a value corresponding to the error that has occurred.

  When receiving the error-related effect command signal, the effect control device 150 performs an effect for notifying the error that has occurred based on the error-related effect command signal.

  The error-related effect command signal is transmitted at a timing when the game control device 100 detects an error.

  Note that the above-described signal for notifying the gaming state (mode part = “20H”) is transmitted not only when the power is turned on, but also when the gaming state changes during normal gaming. For example, when a low probability state occurs during a game, a signal of mode portion = “20H” and an action portion = “01H” is transmitted, and when a high probability state occurs during a game, the mode portion = “ 20H "and action part =" 02H "are transmitted.

  In addition, the signal (mode portion = “30H”) for notifying the number of special symbol winning memories described above is not only when the power is turned on, but also at the first starting winning opening 25 or the second starting winning opening 30 during a normal game. The command signal is also transmitted when the game ball wins and the starting memory number increases. For example, when a game ball is won in the first start winning opening 25 or the second start winning opening 30 during the game and the start memory number is changed to “3”, the mode portion = “30H” and the action portion = “03H”. Is transmitted.

  Accordingly, the signal for notifying the gaming state and the signal for notifying the number of special symbol winning memories also function as an effect command signal.

  Next, the specifications of the gaming machine 1 of this embodiment will be described. FIG. 32 is a diagram for explaining the specifications of the gaming machine 1. In the present embodiment, description will be made assuming that the gaming machine 1 has three types of specifications. Note that the types of specifications are not necessarily limited to three.

  First, the specifications of the gaming machine will be described. In the gaming machine 1, various hardware provided in the game board 2 and each control device (the game control device 100 and the effect control device 150) are common to each other, but their operation modes are different from each other. There is a series machine.

  These series machines use a common effect control device 150, but the contents of the images displayed on the display device 8 are slightly different. In the present embodiment, when the content of the image displayed on the display device 8 is different between the same series machines, the specifications of the gaming machine are different.

  In the effect control device 150, necessary data is stored in advance in a control ROM 153 and a character ROM (not shown) so that a specification image can be displayed on all the same series machines.

  The production control device 150 reads the initialization command signal transmitted from the game control device 100 or reads the specification specific signal that is constantly output from the production control communication port 670 to determine the specifications of the gaming machine. Identify and execute a game effect corresponding to the specification.

  The model name column 2001 in FIG. 32 defines model names associated with each specification. Here, the model name is “CRXXX” for the “spec A” gaming machine, the model name is “CR △△△” for the “spec B” gaming machine, and the “spec C” If it is a gaming machine, the model name will be “CR ☆☆☆”.

  Initialization ACTION code column 2002 shows the correspondence between the value of the ACTION part (specification specification information at initialization) included in the command of the initialization command signal (notice of gaming machine specifications) and the specifications of the gaming machine. ing.

  When the effect control device 150 receives from the gaming control device 100 the command of the MODE unit “11H” (notice of the gaming machine specifications), if the value of the ACTION section included in the command is “01H”, If the specification is “Specification A” and the value of the ACTION part is “02H”, the specification of the gaming machine is “Specification B”, and if the value of the ACTION part is “03H”, the specification of the gaming machine is “Specification”. C ".

  A regular output bit pattern column 2003 indicates a correspondence relationship between a specification specifying signal constantly output from the effect control communication port 670 and the specifications of the gaming machine.

  When the production control device 150 restarted due to the occurrence of an abnormality reads the specification specific signal of the production control communication port 670, if the bit pattern of the read signal is “71H”, the specification of the gaming machine is “specification A”. If the bit pattern of the read signal is “72H”, the specification of the gaming machine is “specification B”, and if the bit pattern of the read signal is “73H”, the specification of the gaming machine is “specification C”. It shows that it becomes.

  Note that the values such as “71H”, “72H”, and “73H” defined as the specification specifying signal are different from the values of the command signal defined in FIG. This is whether the signal output to the effect control communication port 670 is a command signal or a specification specifying signal specified in FIG. 31 when the effect control device 150 is reset and restarted due to the influence of static electricity or the like. This is for clear identification.

  The symbol design column 2004 defines a symbol design associated with each specification. The symbol is identification information of a variable display game executed on the display device 8. In any of the specifications of the gaming machine, a white symbol corresponds to a “normal symbol” and a black symbol corresponds to a “probable symbol”. In order to visually express that the frequency of transition to the probability variation state differs for each specification, the color of the identification information used in the variation display game is varied depending on the specification.

  Here, in the case of a “spec A” gaming machine, “1”, “3”, “5”, “7” among the symbols used are “probable variation symbols”, and the other symbols are “normal symbols”. Become. Further, in the case of a “spec B” gaming machine, “3” and “7” of the symbols used are “probability variation symbols”, and the other symbols are “normal symbols”. Further, in the case of a game machine of “specification C”, only “7” of the symbols used is “probable variation”, and the other symbols are “normal symbols”.

  In the appearance character column 2005, a character associated with each specification is defined. The character appears in a variable display game executed on the display device 8, and details will be described later with reference to FIG.

  Here, in the case of a “spec A” gaming machine, the flying object shown in the figure becomes a character, and in the case of a “spec B” gaming machine, the ship shown in the figure becomes a character, and the “spec C” gaming machine. If there is, the vehicle shown in the figure becomes the character.

  The reach variation time column 2006 defines the reach variation time associated with each specification. In the variable display game executed on the display device 8, a reach state is generated in which two symbols are gathered to notify the possibility of a big hit (details will be described later in FIG. 33), but the time of the reach state is defined. . The reach state time is divided into three types, “short reach”, “medium reach”, and “long reach” in order from the shortest time value.

  Here, when each reach of “short reach”, “medium reach”, and “long reach” occurs, “20 seconds”, “25 seconds”, and “30 seconds” for the gaming machine of “specification A”, respectively. Reach state corresponding to the time of "Specification B" When the game machine of "Specification B", reach state corresponding to the time of "10 seconds" "15 seconds" "20 seconds" respectively, At this time, reach states corresponding to times of “8 seconds”, “12 seconds”, and “16 seconds” are obtained.

  The jackpot probability column 2007 defines the jackpot probability associated with each specification. The big hit probability is a probability that the variable display game executed on the display device 8 becomes a special result mode for giving a privilege to the player.

  Here, for a gaming machine of “Specification A”, the jackpot probability is “1/350”, and for a gaming machine of “Specification B”, the jackpot probability is “1/250”. In the case of a gaming machine, the jackpot probability is “1/150”.

  Next, the progress of the variable display game executed on the display device 8 will be described. FIG. 33 is an explanatory diagram of display contents of the display device 8 of the present embodiment. FIG. 33 shows the display contents of the display device 8 when the specification of the gaming machine 1 is “specification A”.

  As described above, when a game ball wins the first start winning opening 25 or the second start winning opening 30, the display device 8 executes the variable display game. In a state where no game balls are won in these start winning ports 25 and 30, the left symbol 2101, the middle symbol 2102, and the right symbol 2103 are displayed in the display area of the display device 8, as shown in FIG. Displayed in a stopped state.

  In addition, the display area of the display device 8 includes an area 2104 for displaying the model name, an area 2105 for displaying the number of pending storages of the variable display game, and an area 2106 for displaying the jackpot probability of the variable display game.

  Here, of the symbol designs described above with reference to FIG. 32, symbols having a design corresponding to “specification A” are displayed on the left symbol 2101, the middle symbol 2102, and the right symbol 2103. In addition, in the area 2104 for displaying the model name and the area 2106 for displaying the jackpot probability, those corresponding to “specification A” are displayed.

  If the specification of the gaming machine 1 is “specification B” or “specification C”, the symbol design of the left symbol 2101, the middle symbol 2102, the right symbol 2103, the model name display area 2104, and the jackpot probability are displayed. The display of the area 2106 to be changed is changed to one corresponding to “specification B” or “specification C”.

  Next, when a game ball wins in the first start winning opening 25 or the second starting winning opening 30, each of the left symbol 2101, the middle symbol 2102, and the right symbol 2103 is variably displayed in the vertical direction, and the variable display game is executed. Is done. When a certain amount of time has elapsed from the start of the execution of the variable display game, the left symbol 2101 is stopped and then the right symbol 2103 is stopped and displayed.

  At this time, if the left symbol 2101 and the right symbol 2103 are not stopped and displayed with the same symbol, the middle symbol 2102 is immediately stopped and the detachment is confirmed. When the left symbol 2101 and the right symbol 2103 are stopped and displayed with the same symbol, the reach state occurs.

  FIG. 33B shows a state where the reach state has occurred. When the reach state is generated, the middle symbol 2102 is displayed in a vertically varying manner more slowly than usual, and the middle symbol 2102 is stopped and displayed after a predetermined time has elapsed.

  Note that the character 2107 may appear in the display area of the display device 8 during the reach state. In this case, among the characters described above with reference to FIG. 32, the character corresponding to “specification A” is selected and displayed.

  Further, this reach state is executed over a time commanded from the game control device 100. Since the game control device 100 transmits a command indicating which of the “short reach”, “medium reach”, and “long reach” described above with reference to FIG. 32, the one corresponding to “specification A” is selected from the variation time at the time of reach described above with reference to FIG. 32 and executed. For example, if execution of “long reach” is instructed from the game control device 100, display is performed so that the reach state time is 30 seconds.

  If the specification of the gaming machine 1 is “specification B” or “specification C”, the character 2107 is changed to one corresponding to “specification B” or “specification C”, and the reach state time is also “specification”. B ”or“ Specification C ”.

  Then, a reach state occurs in FIG. 33 (b), and if the middle symbol 2102 is stopped and displayed with the same symbol as the left symbol 2101 (right symbol 2103), a big hit is generated and a special gaming state occurs. When the middle symbol 2102 is stopped and displayed with a symbol different from the left symbol 2101 (right symbol 2103), it is out of place.

  Here, if each stop symbol (left symbol 2101, middle symbol 2102, right symbol 2103) when a big hit occurs is a “probable variation symbol” with a black color scheme, A probability fluctuation state (high probability state) in which the big hit probability of the display game is increased by 10 times occurs.

  On the other hand, if each stop symbol when a big hit occurs is a “normal symbol” with a white color scheme, after the special game state ends, the normal state where the jackpot probability of the variable display game does not increase (low probability) State) occurs.

  In addition, depending on each stop symbol when a big hit occurs, the game state after the end of the special gaming state is not limited to setting either a high probability state or a low probability state, but when a big hit occurs Control may be performed so that the game state after the end of the special game state is set to one of the above-described winning suppression state and winning promotion state by each of the stop symbols. With such a configuration, the frequency at which the winning suppression state and the winning promotion state occur can be made different for each specification of the gaming machine.

  FIG. 34 is a flowchart of the latter half of the main process of the production control device according to this embodiment.

  With regard to the control of the effect control device 150, the processing immediately after turning on the power to the gaming machine 1 has been described in FIG. 21C, but the processing after receiving the initialization command signal will be described here. To do.

  First, it waits until it receives the effect command signal transmitted from the game control apparatus 100 (2201). When the production command signal is received, the process branches depending on the type of the received signal (2202).

  The timing at which the bit of Q7 (STB) of the production control communication port 680 rises is the timing when the production command signal is received, and the values of Q0 to Q6 of the production control communication port 680 at that time are represented by the production command signal. (See FIG. 29, etc.).

  If the received signal relates to the start or stop of the variable display game, the process branches to step 2203 to start or stop the change of the symbol (identification information) displayed on the display device 8 in the variable display game. (2203).

  Specifically, when the command received in step 2201 is a symbol change start notification (MODE portion in FIG. 31 is “30H”), the change pattern of the change time specified in the ACTION portion is used using a random number. decide.

  In this case, since the types such as “short reach”, “medium reach”, and “long reach” described above with reference to FIG. 32 may be designated, the game specification information stored in the RAM 154 is referred to and the specifications of the gaming machine (FIG. The variation pattern is determined in correspondence with the reach time corresponding to 32 specifications A to C). If it is a predetermined condition at this time, the above-mentioned movable objects 60-62 are moved. At the same time, at least one of the light emitting devices 92a to 92h can be appropriately selected to emit light.

  If the command received in step 2201 is a stop symbol notification (MODE portion in FIG. 31 is “31H”), the final result of the variable display game is made corresponding to the data specified in the ACTION portion. Determine the stop symbol. Also in this case, with reference to the game specification information stored in the RAM 154, a stop symbol corresponding to the specification of the gaming machine (specifications A to C in FIG. 32) is selected.

  Next, according to the variation pattern determined by receiving the symbol variation start command, variation display of the left symbol 2101, the middle symbol 2102, and the right symbol 2103 is performed in the display area of the display device 8 (see FIG. 33). During the execution of the variable display game, a character 2107 corresponding to the specifications of the gaming machine (specifications A to C in FIG. 32) appears as necessary (see FIG. 33).

  If the command received in step 2201 is a symbol change stop notification (MODE portion in FIG. 31 is “40H”), the left symbol 2101 and the middle symbol 2102 that are variably displayed in the display area of the display device 8. The right symbol 2103 is stopped and displayed.

  Also in this case, the game specification information stored in the RAM 154 is referred to, and the game is stopped and displayed with a stop symbol having a design corresponding to the specifications of the game machine (specifications A to C in FIG. 32).

  When the command received in step 2201 is a command for notifying the occurrence of a high probability state (or occurrence of a low probability state) (MODE portion in FIG. 31 is “20H”), the command is made to correspond to the generated probability state. The background display of the left symbol 2101, middle symbol 2102, and right symbol 2103 displayed in the display area of the display device 8 is changed to notify the player of the occurrence of the high probability state (or the occurrence of the low probability state). .

  When the processing of step 2203 is executed, the process proceeds to step 2201 to receive the next command.

  On the other hand, if the command received at step 2201 relates to the change of the hold memory display, the process branches to step 2204 to change the display of the area 2105 (FIG. 33) for displaying the hold memory number of the display device 8.

  Specifically, if the command received in step 2201 is a notification of the number of reserved memories (MODE section in FIG. 31 is “28H”), the number of reserved memories specified in the ACTION section is displayed. The area 2105 is changed. When the process of step 2204 is executed, the process proceeds to step 2201 to receive the next command.

  On the other hand, if the command received in step 2201 is related to the change in the display related to the big hit, the process branches to step 2205 and the display related to the effect in the big hit is started on the display device 8. Specifically, when the command received in step 2201 is a jackpot-related notification (the MODE portion in FIG. 31 is “48H”), the display on the display device 8 is displayed in correspondence with the information specified by the ACTION portion. Change the contents. If it is a predetermined condition at this time, the above-mentioned movable objects 60-62 are moved. At the same time, at least one of the light emitting devices 92a to 92h can be appropriately selected to emit light.

  Also in this case, with reference to the game specification information stored in the RAM 154, a big hit effect corresponding to the specifications of the gaming machine (specifications A to C in FIG. 32) is performed. If the process of step 2205 is executed, the process proceeds to step 2201 to receive the next command.

  On the other hand, if the command received in step 2201 relates to the error notification, the process branches to step 2206, and the display device 8 starts or ends the display related to the error notification.

  Specifically, if the command received in step 2201 is an error-related notification (MODE section in FIG. 31 is “50H”), the display device 8 corresponds to the information specified by the ACTION section. Start or end error notification. If the process of step 2206 is executed, the process proceeds to step 2201 to receive the next command.

  In addition, the production control device 150 cannot deny the possibility that the CPU 152 does not operate according to the program and runs away due to the occurrence of noise or the like. In such a case, the CPU 152 is reset by the action of the monitoring circuit 158, and the effect control device 150 is restarted.

  However, even if only the effect control device 150 is restarted due to the influence of noise or the like, if the game control device 100 is not restarted, an initialization command signal (from the game control device 100 to the effect control device 150 ( Since the notification of the gaming machine specifications) is not transmitted, the effect control device 150 cannot determine the gaming machine specifications.

  Therefore, in the gaming machine of this embodiment, even when only the effect control device 150 is restarted and the game control device 100 is not restarted, the effect control device 150 is connected from the effect control communication port 670 of the game control device 100. It is configured so that the specification of the gaming machine can be discriminated by reading the specification specifying signal that is constantly output. In this way, the processing when only the effect control device 150 is restarted will be described as processing at the time of “failure detection” with reference to FIG.

  First, when the CPU 152 is reset by the monitoring circuit 158 due to the influence of noise or the like (2207), the production control device 150 initializes an output port by hardware (2208), initialization processing at power-on (2209), Processing for generating a command receivable state (2210) and capturing data of a communication port (2211) is performed. Note that these processes are the same as the processes in steps 922 to 925 in FIG.

  At this time, if the gaming machine 1 is immediately after the power is turned on, the bit pattern output from the effect control communication port 670 (FIG. 18) is in the initial state (all bits are 0). When the game control device 100 is not restarted as in step 926 of step 21, the specification control signal (steady output is performed) when the game control device 100 is not restarted. Data of a bit pattern (column 2003 in FIG. 32) corresponding to the specification specifying signal) is output.

  Therefore, when the data fetched from the effect control communication port 670 in step 2211 in FIG. 34 corresponds to the specification specifying signal (specification output signal that is steadily output), a game corresponding to the specification specifying signal is performed. The machine specification is identified, and data corresponding to the specification is stored in the RAM 154 as game specification information (2212).

  In this case, as described above with reference to FIG. 29, the bit pattern of the specification specifying signal is set to “71H”, “72H”, “73H”, etc., and the bit of Q7 of the effect control communication port 670 is always “0”. is there.

  Therefore, since the STB of the production control communication port 670 does not rise while the specification specific signal is output, the bits Q0 to Q7 of the production control communication port 670 are read and coincide with the bit pattern of the specification specific signal. Identify the specifications of the gaming machine depending on whether or not

  It should be noted that when step 2211 is executed at the timing when the effect command signal is output to the effect control communication port 670 or when the effect control communication port 670 is in the initial state, the specification specifying signal is output from the effect control communication port 670. May capture different data.

  Therefore, in step 2211, when the initial state data (bits Q0 to Q7 are “00H”) is captured for a certain period, the process proceeds to step 926 in FIG. 21 to wait for reception of the initialization command signal. To do.

  In step 2211, when bit pattern data that is neither the initial state nor the specification specifying signal (for example, data corresponding to the effect command signal) is captured, the bit pattern of the effect control communication port 670 is the initial state or specification specifying. What is necessary is just to wait until it becomes one of the signals.

  Even in this case, as described above with reference to FIG. 32, values such as “71H”, “72H”, and “73H” defined as the specification specifying signal are different from the numerical values of the command signal (different from the initial state “00H”). Therefore, it is clearly identified whether or not the signal output to the effect control communication port 670 is a specification specific signal when the effect control device 150 is reset and restarted due to the influence of static electricity or the like. be able to.

  When the process of step 2212 is completed, the process proceeds to step 2201 in order to receive a command from the game control apparatus 100.

  According to the present embodiment, since the specification specifying signal is constantly output to the effect control communication port 670, the specification specifying from the effect control communication port 670 is possible regardless of when the effect control device 150 starts to be activated. The specification of the gaming machine 1 can be immediately identified by capturing the signal.

  Therefore, when the production control device 150 is restarted, the specification of the gaming machine 1 can be identified before receiving the production command signal from the game control device 100. Therefore, even when the production control device 150 is restarted, It is possible to accurately perform the production process according to the specifications of the gaming machine.

  In addition, immediately after the power is turned on, the production control communication port 670 is in an initial state and held for a predetermined time, and during this time, the production control device 150 is in a command receivable state. It is possible to prevent erroneous data from being transmitted while the effect control communication port 670 is in an unstable state. Then, an initialization command signal is transmitted from the game control device 100 to the effect control device 150, and the effect control device 150 can determine the specifications of the gaming machine based on this initialization command signal.

  Accordingly, immediately after the power is turned on to the gaming machine, the presentation control device 150 can determine the specification of the gaming machine by the initialization command signal without outputting the specification specifying signal to the presentation control communication port 670. .

  In addition, when the communication ports 670 and 680 are in the initial state and are held for a predetermined time, the delay processing is performed without using the storage area of the RAM 104 whose validity is determined when the game control device 100 is turned on. Therefore, the time during which the communication ports 670 and 680 are maintained in the initial state can be extended, and during this extended time period, the subordinate control devices (the effect control device 150 and the payout control device 210) are disconnected from the game control device 100. The command can be received.

  As a result, immediately after the power is turned on, the communication port is in the initial state and held for a predetermined time. During this time, the dependent control device is ready to receive a command, so the communication port is in an unstable state when the dependent control device is started. It is possible to prevent erroneous data from being transmitted. In addition, by performing delay processing for a predetermined time using software, the state in which the communication port is in the initial state is maintained for a predetermined time, so that a configuration that is less expensive than a method using hardware is sufficient. Further, since the delay process is performed without using the validity determination storage area, the correctness determination process can also be performed accurately.

  Further, according to the present embodiment, the initialization command signal is transmitted by the game control device main processing loop, and the command signal to the subordinate control device at the normal time is transmitted by the timer interrupt processing. The transmission cycle can be made shorter than the normal command signal transmission cycle.

  As a result, the time until all initialization commands are transmitted is also shortened, so that it is possible to prevent a delay in starting the entire gaming machine when the power is turned on.

Here, the prior art in contrast to the present embodiment is shown.
For example, for the purpose of providing a gaming machine that can divert the display control device between series models while suppressing an increase in manufacturing cost, a game specification command is sent from the main control means to the display control means when the power is turned on. When transmitted, there is a gaming machine configured to store game specification information corresponding to the game specification command in the game specification storage means in the display control means. And as shown in Unexamined-Japanese-Patent No. 2007-267863 etc., when the display control means receives the effect command from the main control means after that, the display control means outputs the effect output from the main control means based on which game specifications A process of recognizing whether it is a command and reading effect data corresponding to the game specifications from the effect data storage means is performed based on the recognition.

  In this gaming machine, when diverting the display control device between the series models, it is not necessary to set a command for performance according to the content of the performance for each game specification, so that an increase in the storage amount of the display control device is suppressed. There is an advantage that can be.

  However, in the gaming machine described in the above-mentioned patent document, problems may frequently occur on the control board of the gaming machine due to the influence of static electricity charged on the gaming ball. At this time, in many cases, the control board resets the CPU and performs initialization to restart the board itself.

  By the way, when the control board of the gaming machine is restarted due to the influence of static electricity, not all the control boards included in the gaming machine are restarted, but only a part of the control boards may be restarted. For example, in the gaming machine described in the above-mentioned patent document, it is possible that only the display control means is restarted and the main control means is not restarted due to the influence of static electricity.

  Therefore, in the gaming machine of the above-mentioned patent document, when the gaming machine is powered on, the game specification command is transmitted from the main control means to the display control means, so that only the display control means is restarted due to the influence of static electricity. When this is done, a game specification command is not transmitted from the main control means to the display control means. Therefore, in such a case, there was a problem that the display control means cannot determine the game specifications of the gaming machine.

  The gaming machine disclosed in the above-mentioned patent document discloses the technical content that a game specification command is transmitted from the main control means to the display control means even at the timing when the customer waiting demonstration screen is displayed on the display device. However, even with such a configuration, when only the display control means is restarted due to the influence of static electricity, it is impossible to determine the gaming specifications of the gaming machine until the customer waiting demonstration screen is displayed.

  In this way, if a state occurs in which the display control means cannot determine the game specifications of the gaming machine, it may display a screen with a game specification different from the original gaming machine, which is misunderstood by the player. There was a fear of giving.

  On the other hand, in the gaming machine 1 of the present embodiment, in the gaming machine 1 provided with a display control device that can be commonly used for a plurality of types of gaming specifications, no matter what timing the display control device is restarted, Game specifications can be identified early.

  Specifically, the gaming machine 1 of the present embodiment executes an auxiliary game in the game area 3 based on the establishment of a predetermined start condition, and gives a privilege to the player in accordance with the result of the auxiliary game In the gaming machine 1 capable of generating a special gaming state, a game control device 100 that controls the game in the gaming area 3 in an integrated manner, and a game related to the gaming machine 1 in response to a command from the game control device 100 An effect control device 150 that controls the effect, and the gaming control device 100 is a communication port (effect control communication port 670) for outputting a command to the effect control device 150, and the gaming machine 1 A specification specifying signal output means for outputting a specification specifying signal for specifying the specification of the game from the communication port, and an effect command signal output for outputting an effect command signal for specifying the contents of the game effect from the communication port. And the production control device 150 identifies a specification of the gaming machine 1 by taking a specification specifying signal from the game control device 100 and stores it as game specification information, and A game effect execution means for taking an effect command signal from the game control device 100 and executing a game effect corresponding to the game specification information stored in the game specification information storage means, and the specification specifying signal output means Is characterized in that a specification specifying signal is steadily output via the communication port when the effect command signal output means is not outputting an effect command signal.

According to this, since the specification specifying signal is constantly output to the communication port, the specification specifying signal is taken in from the communication port whenever the effect control device 150 starts to start, and immediately the gaming machine It becomes possible to identify one specification.
Therefore, when the production control device 150 is restarted, the specification of the gaming machine 1 can be identified before receiving the production command signal from the game control device 100. Therefore, even when the production control device 150 is restarted, It is possible to accurately perform the effect processing according to the specifications of the gaming machine 1.

  In addition, the game control device 100 includes an initializing unit that sets the communication port in an initial state in response to a predetermined activation signal, and an initial state maintaining unit that maintains the communication port in the initial state for a predetermined time. An initialization command signal transmission for transmitting an initialization command signal for instructing the effect control device 150 to initialize after the communication port is maintained in the initial state for a predetermined time by the initial state maintaining means. And the initialization command signal includes information that can specify the specifications of the gaming machine 1, and the effect control device 150 maintains the initial state of the communication port. During this time, the command receiving state in which the command from the communication port can be received is entered, and the gaming specification information storage means has the communication port in the initial state, and then the game control Even when receiving an initialization command signal from the location 100, and to store the game specification information by identifying the specifications of the gaming machine 1.

According to this, immediately after the power is turned on, the communication port is in an initial state and held for a predetermined time. During this time, the effect control device 150 is in a command receivable state, so when the effect control device 150 is activated when the power is turned on. It is possible to prevent erroneous data from being transmitted while the communication port is in an unstable state. Then, an initialization command signal is transmitted from the game control device 100 to the effect control device 150, and the effect control device 150 can determine the specifications of the gaming machine 1 based on the initialization command signal.
Accordingly, immediately after the gaming machine 1 is turned on, the presentation control device 150 can determine the specification of the gaming machine 1 by the initialization command signal without outputting the specification specifying signal to the communication port. .

Further, the gaming control device 100 stores arithmetic processing means for performing required arithmetic processing by a game control program and information updated by the arithmetic processing means, and even if power supply to the gaming machine 1 is stopped The storage means capable of storing and storing the stored information, the validity determining means for determining the validity of the information stored and held in the storage means after generation of the activation signal, and the initial state maintaining means Timer timing means for timing a maintenance timer for maintaining the communication port in the initial state for a predetermined time, and the timer timing means is stored in the storage means whose validity is determined by the validity determination means. The maintenance timer is timed without updating the stored information.
Further, the game control device 100 is provided with a non-judgment storage area that stores updatable information and is not subject to legitimacy judgment by the legitimacy judging means. The maintenance timer is timed using a non-target storage area.
Further, the non-determined storage area is a register provided in the arithmetic processing means.

  According to this, even if no hardware is used, the communication port is maintained in the initial state immediately after the power is turned on, so that the configuration is less expensive than the method using hardware. At this time, the timer timing is performed without using the validity determination storage area, so that the validity determination process can be performed accurately.

  In addition, the game control device 100 updates the information stored in the storage unit and updates the storage unit according to the validity determined by the validity determination unit. And means for initializing the storage, and the update restricting means restricts updating of the storage means by the arithmetic processing means when the activation signal is generated, and the storage means is initialized by the storage means initializing means. In this case, the restriction on updating of the storage means is released.

  According to this, since the write restriction state can be set as necessary until the validity determination is performed, it is possible to prevent inadvertent writing to the storage unit.

  Furthermore, in the prior art shown in Japanese Patent Application Laid-Open No. 2002-224394, etc., at the time of return after the power is turned off, the award medium payout operation can be stopped until the inconvenient state of payout is resolved, In order to prevent troubles between the player and the hall regarding the payout of the award medium, the payout control means is activated prior to the main control means to start payout control when returning from a power failure. In this case, since the initialization switch has not been operated, the payout operation return process is executed, and thereafter, until the payout restart command is received from the main control means, the payout operation is stopped and the game waits in a state where the payout can be resumed. A machine is disclosed.

  In this gaming machine, when the main control means activated later does not detect an error related to payout based on the detection switch from the supply replenishment detection switch or the fullness detection switch, a payout restart command is transmitted from the main control means. Therefore, the payout control means is configured to restart the payout operation with the payout resumption command received as a trigger.

  In this prior art, a delay circuit 90 is provided in the main control means (main control board 39) in order to start the main control means with a delay relative to the payout control means, and the reset signal from the reset signal generating means 77 is received. , The main control means is reached with a delay of time t from reaching the payout control means (payout control board 46) (paragraphs [0051] to [0053] of the prior art document, FIG. (See FIG. 23).

  For this reason, the gaming machine of the prior art requires hardware such as the delay circuit 90, so that there is a problem that the cost becomes high. Also, since the delay circuit 90 is configured by hardware, there is a delay. There was also a problem that the time value could not be changed by the program.

  In this case, if the function corresponding to the delay circuit 90 is realized by software using a CPU provided in the main control means (main control board 39), the problem in terms of cost is solved.

  However, in order to measure the delay time using the CPU, the backup memory 39b of the main control means (main control board 39) must be used. In this case, after the main control means is started, the backup memory 39b Since the delay time is measured after the validity is confirmed and the backup memory 39b becomes usable, there is a problem that the start-up of the entire gaming machine is delayed.

  On the other hand, in the present embodiment, the activation of the entire gaming machine is prevented from being delayed while the cost is reduced by delaying the activation of the game control device from the activation of the dependent control device by software. Since it aims also to provide a gaming machine, it can be applied even when solving the problems of gaming machines as in the prior art.

  It should be understood that the above-described embodiment is illustrative in all respects and not restrictive. The present invention is not limited to the above description, but is defined by the scope of the claims, and includes all modifications within the scope and meaning equivalent to the scope of the claims.

2 Game board 3 Game area 4 Center case 5 Game board 6 Control base 7 Opening part 16 Flowing area 22 Obstacle nail 23 Obstacle nail row 24 Cell sheet 26 First prize opening decoration member 35 Reference hole 36 Reference convex part 38 First start prize Mouth linear decorative body 39 Case decorative member 40 Armor decorative member 41 Upper decorative member 44 Lower stage decorative member 48 Lower stage linear decorative body 49 Case linear decorative body 51 Side armor decorative member 52 Upper linear decorative body 53 Metal layer 54 Alignment concave portion 55 Alignment convex portion 58 Upper movable accessory 59 Lower movable accessory 60 First light emitting movable accessory 61 Second light emitting movable accessory 62 Linkable movable accessory 66 Upper movable accessory decorative member 68 Upper movable accessory linear Decorative body 69 Protruding portion 70 Recessed portion 73 Lower movable accessory decorative member 74 Lower movable accessory linear decorative bodies 77, 77 'Non-translucent portions 78, 78' Translucent portion 79 LED
80 Illumination board 81 Reflective member 82 Groove 83 Notch 84 Buffering part 86 Adjustment notch

The present invention has been made in view of the above circumstances, an object thereof is intended to provide a game machine that can be enhanced decorative effect.

The present invention has been proposed in order to achieve the above object. According to the present invention , a game area is provided on a game board,
A center case of a frame structure forming an opening;
A display device capable of visually recognizing the display unit from the opening of the center case, and performing an effect display on the display unit;
In a gaming machine comprising a decorative member for decorating the gaming board,
The decorative member is
A first decorative member provided in the center case,
A second decorative member capable of flowing down the front of the game ball launched into the game area ;
A third decorative member provided on the front surface of the movable accessory that moves at least inside the opening of the center case ,
It said movable combination comprises a first state and a second state than in the state of the first located on the center side of the opening, the movable conversion,
In the second state, the first decorative member to form a second decorative member, and the third one set decorations decorative member,
Each of the first decorative member and the third decorative member includes a light emitting portion,
In the second state, the above-described light emitting units are caused to emit light integrally .

According to a second aspect of the present invention, the second decorative member is disposed apart from the first decorative member with the opening interposed therebetween.
2. The gaming machine according to claim 1, wherein in the second state, the third decorative member is located between the first decorative member and the second decorative member. 3.

According to the present invention, the decoration effect of the game board can be enhanced. Note that the collective decorative body is a single character, symbol, design, or the like formed by a collection of a plurality of decorative members, or a combination thereof, which is recognized as a single decorative body through vision.

The case decoration member 39 is one of decoration members for decorating the game board 2 and is formed so as to protrude forward so that the game ball can be prevented from flowing into the center case 4 together with the upper armor member 19. Has been. The case decorative member 39 is formed by the front transparent decorated to side (or translucent) resin member, such as an LED having a rear light-emitting source (light emitting device 92b in FIG. 16 (a first in the present invention Corresponding to the light emitting part provided in the decorative member) )). In addition, a case line-shaped decorative body 49 is formed along the outer shape of the case decorative member 39 at the inner edge (in the display unit 9 side) of the case decorative member 39 and the edge facing the armor decorative member 40. Yes. A metal layer formed by metal plating is formed on the surface of the case linear decorative body 49.

The upper decorative member 41 is a plate-shaped member whose upper side on the case decorative member 39 side is aligned with the upper side of the case decorative member 39 and whose lower side is formed along the outer left edge of the case decorative member 39. The upper decorative member 41 of the present embodiment is formed of a transparent (or translucent) resin member, and the rear surface is decorated. For this reason, the decoration can be visually recognized from the front. Further, a light source (such as a light emitting device 92c in FIG. 16) such as an LED is provided behind the upper decorative member 41, and light from this light source can be transmitted. The front surface of the upper decorative member 41 is located behind the front surface of the case decorative member 39, and is aligned so that the front surface of the game board 5 is substantially flush with the front and rear direction. That is, the upper decorative member 41 constitutes one of decorative members that decorate the game board 2, and its front surface defines a part of the flow-down area 16. Further, the upper linear decoration that is aligned with the same width as the case linear decorative body 49 is formed on the upper side (opposite to the case decorative member 39) of the periphery (edge) of the upper decorative member 41. A body 52 is provided. The upper linear decorative body 52 is integrally formed of a transparent (or translucent) resin member. As shown in FIG. 6, a metal layer 53 (in the present invention) is formed on the surface on the back side thereof. A kind of surface treatment layer) is formed. For this reason, the decoration by the metal layer 53 can be visually recognized from the front.

The upper movable accessory 58 is a hollow box-like vertically long member, and its front surface constitutes one of the decorative members. Specifically, as shown in FIG. 8, the upper movable accessory 58 is a light emitting source such as an LED (light emitting device 92e in FIG. 16 ( corresponding to one of the light emitting portions provided in the third decorative member in the present invention). ) ), A box-shaped upper movable accessory base member 65, and an upper movable accessory decoration member 66 that forms a front surface of the upper movable accessory 58 by covering the front of the box. And a light diffusing plate 67 arranged in front of the light emitting source. The upper movable accessory base member 65 is a member that forms a side wall surrounding the periphery of the upper movable accessory 58 (the rear surface of the upper movable accessory 58) and its periphery. The light diffusing plate 67 is a member that diffuses light from the light source, and is a transparent resin member in which a groove that diffuses light is formed on the surface. The upper movable accessory decoration member 66 is a transparent (or translucent) resin member with a decoration on the front surface, and is formed so as to transmit diffused light transmitted through the light diffusion plate 67. In addition, on both the left and right sides of the upper movable accessory decoration member 66, an elongated movable movable accessory linear ornament body 68 is provided (the upper movable accessory decoration member 66 and the upper movable accessory linear ornament body). 68 (that is, the member constituting the front surface of the upper movable accessory 58 corresponds to the upper portion of the third decorative member of the present invention). The upper movable accessory linear decorative body 68 has a metal layer 53 formed by metal plating on the front side surface, and the width thereof is the width of the lower movable accessory linear decorative body 74 and the case linear decorative body 49. The width is aligned to the same level. The upper movable accessory linear decorative body 68 of the present embodiment is formed in a bowl shape at the front end of the side wall (the standing wall standing up from the bottom portion) located on the left and right of the upper movable accessory base member 65. Yes. Further, on the upper part of the upper movable accessory base member 65, there is a swing shaft 71 that swings by transmitting power from a drive source such as a motor (drive source 93a in FIG. 16) via a gear or the like. The swing shaft 71 is attached to the upper end of the right side of the control base 6. As a result, when the drive source is driven, the upper movable accessory 58 can be swung around the swinging shaft 71, and the display device 8 displays from the state of waiting on the right edge of the opening 7 of the center case 4. It can convert into the state which coat | covers the center part of the part 9. FIG. The upper movable accessory 58 is partially exposed from the opening 7 (see FIG. 1) in a state where it waits at the right edge of the opening 7 of the center case 4. It constitutes part of the edge. In addition, a protrusion 69 having a shape that tapers in a downward direction on a lower side (lower movable accessory 59 side) surface (a connection surface with the lower movable accessory 59) of the upper movable accessory base member 65. Is provided. Two protrusions 69 are provided at positions corresponding to the recesses 70 of the lower movable accessory 59 so that the projections 69 can be fitted into the recesses 70 of the lower movable accessory 59 described later.

Similar to the upper movable accessory 58, the lower movable accessory 59 is a hollow box-like vertically long member, and its front surface constitutes one of the decorative members. More specifically, the lower movable accessory 59 is a box that houses a light emitting source such as an LED (light emitting device 92f in FIG. 16 ( corresponding to one of the light emitting portions provided in the third decorative member in the present invention) ). Shaped lower movable accessory base member 72, lower movable accessory decoration member 73 that forms the front surface of lower movable accessory 59 by covering the front thereof, and disposed in front of the light source. And a light diffusing plate formed. The lower movable accessory base member 72 is a member constituting a bottom portion of the lower movable accessory 59 (a rear surface of the lower movable accessory 59) and a side wall surrounding the periphery thereof. The light diffusing plate is a member that diffuses light from the light emitting source, and is a transparent resin member in which a groove that diffuses light is formed on the surface. The lower movable accessory decoration member 73 is a transparent (or translucent) resin member having a decoration on the front surface, and is formed so as to transmit the diffused light transmitted through the light diffusion plate. In addition, on both the left and right sides of the lower movable accessory decoration member 73, elongated lower movable accessory linear ornaments 74 are provided (the lower movable accessory decoration member 73 and the lower movable accessory linear ornaments). 74 (that is, the member constituting the front surface of the lower movable accessory 59 corresponds to the lower portion of the third decorative member of the present invention). The lower movable accessory linear decorative body 74 has a metal layer 53 formed by metal plating on the surface on the front side, and the width of the lower movable accessory linear decorative body 68 and the stage lower linear decorative body 48 is the same. It is aligned to the same width as the width. The lower movable accessory linear decorative body 74 of the present embodiment is formed in a bowl shape at the front ends of the side walls (standing walls standing up from the bottom portion) located on the left and right of the lower movable accessory base member 72. Yes. A rack gear (not shown) that transmits power from a drive source such as a motor (drive source 93b in FIG. 16) via a gear or the like is provided at the bottom of the lower movable accessory base member 72. It arrange | positions along the linear decoration body 74 (up-down direction). Thereby, if the drive source is driven, the lower movable accessory 59 can be moved up and down, and the center lower portion of the display unit 9 of the display device 8 from the state of waiting at the lower edge of the opening 7 of the center case 4. Can be converted into a covering state. In addition, a concave portion 70 that fits with the protrusion 69 is provided on the surface (connecting surface) on the upper side (upper movable accessory 58 side) of the lower movable accessory base member 72. The recess 70 opens in a V-shaped cross section in accordance with the tapered shape of the protrusion 69. For this reason, when the upper movable accessory 58 and the lower movable accessory 59 move to a predetermined position, the tips of the protrusions 69 slide into the recesses 70 from the edges of the recesses 70, and the connecting surfaces of both members Can be connected together.

Claims (5)

A part of the game area partitioned on the game board, and a flow-down area where game balls can flow down the front,
A center case of a frame structure that forms part of the gaming area and forms an opening on the front surface of the gaming board;
A display device that exposes the display unit from the opening of the center case and displays the effect on the display unit;
In a gaming machine comprising a decorative member for decorating the gaming board,
The decorative member is
A first decorative member provided on the front surface of the center case;
A second decorative member that defines a part of the flow-down region;
A third decorative member provided on the front surface of the movable accessory moving in the game area,
The movable accessory can be converted into a first state stored at an edge of the opening of the center case and a second state covering a part of the front surface of the display unit inside the opening. And
In the second state, the first decorative member, the second decorative member, and the third decorative member are connected to form one collective decorative body.   The game according to claim 1, wherein the first decorative member, the second decorative member, and the third decorative member are provided with a linear decorative body that represents an outline of the collective decorative body. Machine.   The said 2nd decoration member is provided with the light transmissive area | region which can permeate | transmit light to at least one part, The surface treatment layer was formed in the back surface side of this light transmissive area | region. The gaming machine described in 1. The movable accessory is constituted by a plurality of movable members that can be connected to each other by moving to a predetermined position,
A protrusion is provided on the connection surface of one movable member in the movable members that are connected to each other among the plurality of movable members,
The gaming machine according to any one of claims 1 to 3, wherein a concave portion that fits with the protruding portion is provided on a connecting surface of another movable member that is connected to the one movable member. The protrusion is a shape that tapers toward the connection surface of the other movable member,
5. The projection according to claim 4, wherein when the one movable member and the other movable member move to a predetermined position, the tip of the projection is slid into the recess from the edge of the recess. The gaming machine described.

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