JP6762059B2 - Game machine - Google Patents

Description

The present invention relates to a game machine.

Conventionally, as a game machine, a slot machine having a plurality of reels on which a plurality of symbols are written has been known. In this slot machine, the game can be started by inserting a medal as a game medium, and the game is performed based on the operation of the start lever and the stop button by the player.

In the slot machine, when the reels are stopped, three consecutive symbols (upper symbol, middle symbol, and lower symbol) are displayed per reel through the front window portion. Further, such a slot machine is known to have four reels (see, for example, Patent Document 1). The slot machine disclosed in Patent Document 1 includes four reels and four stop buttons provided corresponding to each reel.

JP-A-2010-82315

By the way, in the slot machine disclosed in Patent Document 1, the width of the stop button group (the stop located on the left side) with respect to the reel width (the distance between the left end of the reel located on the left side and the right end of the reel located on the right side). The distance between the left edge of the button and the right edge of the stop button located on the right side) is small. In other words, each stop button is arranged in a state of being moved inward in the left-right direction with respect to the reel width (a state of being packed inward in the left-right direction). For this reason, the positional relationship between the four reels and the stop buttons corresponding to the respective reels is difficult for the player to understand. Then, due to this, an erroneous operation has occurred in which the player presses a stop button corresponding to a reel other than the reel intended to be stopped. In addition, the player may feel a sense of discomfort (confusion about which stop button to operate, etc.) when pressing the eyes. Such a problem becomes a burden on the player and is one of the factors that reduce the playability of the slot machine.

The present invention has been made in view of the above circumstances, and includes four reels and four stop buttons, and the relationship between the four reels and the stop buttons corresponding to the respective reels is easy for the player to understand. It is an object of the present invention to provide a game machine whose sex does not deteriorate.

In order to achieve the above object, the gaming machines according to the present invention are arranged side by side from left to right, with the first reel, the second reel, the third reel, and the fourth reel, and the left side. It includes a first stop button, a second stop button, a third stop button, and a fourth stop button arranged in order from to the right, and the operation surface of the first stop button is the second reel. The left end of the second reel is located below the left end of the second reel so that the operation surface of the second stop button is located below the second reel and of the width of the second reel. The operation surface of the third stop button is arranged at a position within the range, and the operation surface of the third stop button is arranged below the third reel at a position within the width of the third reel to operate the fourth stop button. The surface is characterized in that it is arranged below the third reel so that its right end is located to the right of the right end of the third reel.

According to such a configuration, even if the specifications are 4 reels and 4 stop buttons, the player can easily recognize (understand) the relationship between the 4 reels and the stop buttons corresponding to the respective reels. It is possible to reduce mistakes and erroneous operations (pressing the stop button corresponding to a reel other than the reel intended to be stopped) by a person, and prevent deterioration of playability. In addition, it is possible to reduce the discomfort of the player when pressing the eyes.

Further, in the configuration of the present invention, the operation surface of the first stop button is arranged below the second reel so that its left end coincides with the right end of the first reel, or the left end thereof is said. It is arranged so as to be located to the left of the right end of the first reel, and the operation surface of the fourth stop button is arranged below the third reel so that its right end coincides with the left end of the fourth reel. Or, the right end thereof is arranged so as to be located on the right side of the left end of the fourth reel.

According to such a configuration, the player can more easily and surely recognize (grasp) the correspondence between the four reels and the stop button corresponding to each reel, so that the playability of the game machine is lowered. Can be prevented. In addition, it is possible to reduce the discomfort of the player when pressing the eyes.

According to the gaming machine of the present invention, four reels and four stop buttons are provided, and the relationship between the four reels and the stop buttons corresponding to the respective reels is easy for the player to understand, and the playability is reduced. No gaming machine can be provided.

It shows the appearance of the game machine (three reel housing) which concerns on embodiment of this invention, and is the perspective view seen from the front side. The inside of the three-reel housing is shown, (a) is a perspective view seen from the front side, and (b) is a perspective view of the frame portion of the reel unit seen from the front side. It is the figure which looked at the reel unit of the 3 reel housing from the front side. The same shows the appearance of the 4-reel housing, which is a perspective view seen from the front side. The inside of the 4-reel housing is shown, and is a perspective view seen from the front side. It is the figure which looked at the reel unit of the 4-reel housing from the front side. The middle panel unit and the reel unit are shown, (a) is an exploded perspective view of a 3-reel housing viewed from the front side, and (b) is a 4-reel housing viewed from the front side. It is an exploded perspective view. The same, the reflector is shown, (a) is a vertical sectional view of a reflector for a three-reel housing, and (b) is a vertical sectional view of a reflector for a four-reel housing. It is the figure which looked at the 3 reel housing from the front side. It is the figure which looked at the 4-reel housing from the front side. It shows the reel unit of the game machine which concerns on embodiment of this invention, and is the figure seen from the front side. The same is an axial sectional view of the start lever unit. The same is an axial sectional view of the start lever unit in a state where the start lever is tilted downward. The same is an axial sectional view for explaining the detection of the operation of the start lever. The same is an axial sectional view for explaining the characteristics of the operation of the start lever. The same is an axial sectional view for explaining the characteristics of the operation of the start lever. It is a figure which shows the tilting distance and tilting angle of the operation part. The same is the axial sectional view of the MAX bet button. The same is an axial sectional view of the stop button. It is a figure which shows the operating load of the start lever, the MAX bet button, and the stop button. The same shows the medal insertion unit, which is an exploded perspective view from the left front side. The medal insertion portion in the gaming machine of the first embodiment of the present invention is shown, and is a perspective view seen from the lower rear side. The same shows the rear member of the rail and the sensor unit, and is a perspective view seen from the front side. The same shows the rear member of the rail and the sensor unit, and is a perspective view seen from the rear side. The same shows the rail front member, which is a perspective view seen from the rear side. The same shows the medal insertion part, the rail rear member, the rail front member, and the sensor unit, and is a perspective view seen from the lower front. It shows the rail rear member, the rail front member, and the selector, and is a perspective view seen from the rear side. The same is for explaining the state in which the large-diameter medal is hung on the medal slot, and is a perspective view seen from the front side. The same is for explaining the state in which the large-diameter medal is hung on the medal slot, and is a cross-sectional perspective view seen from the side. The reel unit is shown, (a) is a part of an axial sectional view of the first reel, and (b) is a perspective view seen from the front side. The same shows a part of the stop button of the 3-reel housing, and is a view seen from the front side. It is the figure which looked at the 3 reel housing from the front side.

Hereinafter, embodiments of the present invention will be described with reference to the drawings. Although the slot machine, which is one of the gaming machines, will be described below, the gaming machine according to the present invention is not limited to the slot machine, and may be other gaming machines such as pachinko gaming machines. In the following description, "front and back" basically means "front" on the player side and "rear" on the slot machine side when the player is on the front side of the slot machine, and "up and down". Means "upper" on the upper surface side of the slot machine, "lower" on the lower surface side, and "left and right" means "left" on the left hand side of the player playing the slot machine, and "right" on the right hand side. To do.

FIG. 1 is a perspective view showing a slot machine (game machine) 100 of the present invention. The slot machine 100 shown in FIG. 1 has a 3-reel housing. The slot machine 100 includes a box-shaped housing 111 having an opening on the front side, which is a surface facing the player side, and a front door 112 that opens and closes the front side opening of the housing 111. The housing 111 houses a reel unit 50 in which a rotatable first reel 10a, a second reel 10b, and a third reel 10c are unitized, a hopper device for paying out medals, and the like.

The front door 112 is provided with an effect device such as a speaker 114 and a window portion 116. The speaker 114 outputs sounds for various effects (music, sound effects, voice, etc.). In addition to the speaker, the device for the effect may be provided with a display device such as a liquid crystal display, an illumination device such as a lamp (LED), a movable accessory that can be operated by an actuator or the like. Images (moving images, still images) for various effects are displayed on the liquid crystal display.

A part of the reel unit 50 is arranged so as to be visible through the visible area 116a of the window portion 116. A plurality of types of symbols are arranged in a row along the circumferential direction on the outer peripheral surface of each reel 10a to 10c constituting the reel unit 50, and when each reel 10a to 10c is stopped, 1 is passed through the visible area 116a. Three consecutive symbols (upper symbol, middle symbol and lower symbol) can be visually recognized per reel.
Further, the window portion 116 is provided with an upper stage, a middle stage, and a lower stage as display positions for visually recognizing the symbols of the reels 10a to 10c, and an effective line is set by a combination of the display positions of the reels 10a to 10c. Has been done. In the gaming machine of the present embodiment, the effective line is composed of the middle stage of the first reel 10a, the middle stage of the second reel 10b, and the middle stage of the third reel 10c. Further, in the gaming machine of the present embodiment, the number of medals (specified number of medals) required for one game is set to 3, and when the specified number of medals are inserted, the effective line is activated. It has become so.

In the slot machine 100, each reel 10a to 10c starts rotating with the start of the game, and the winning combination lottery is executed to determine the winning or losing (non-winning) of any of the winning combinations. Next, when each reel 10a to 10c is stopped, if the symbol combination corresponding to the winning combination won in the winning combination lottery is displayed on the valid line, this winning combination becomes a prize, and the process corresponding to the winning combination is won. (Winning process) is executed.

Further, the front door 112 is rotated by a medal insertion slot 821 for inserting medals, a bet button 23 for betting a credited medal, and a start lever 990 operated when starting a game. A stop button unit 126 (including a first stop button 126a, a second stop button 126b, and a third stop button 126c) for stopping each reel 10a to 10c, a payout port 127 for paying out medals by a hopper device, and payout. A medal tray 128 for receiving medals paid out from the mouth 127 is provided. Further, behind the medal insertion slot 821, a medal sensor for detecting the passage of medals inserted from the medal insertion slot 821 is provided.

In the slot machine 100, the operation of the start lever 990 is enabled by inserting medals into the medal insertion slot 821 or by operating the bet button 23 to bet a predetermined number of medals. Further, when the activated start lever 990 is operated, the game is started. When the game is started, the reels 10a to 10c start to rotate, and when the rotation speed of the reels 10a to 10c reaches a constant speed and becomes a steady rotation, the operation of the stop buttons 126a to 126c is enabled. Further, when the activated stop buttons 126a to 126c are operated, the reels 10a to 10c corresponding to the operated stop buttons 126a to 126c are stopped.

Inside the slot machine 100, a main control board (main control device) and a sub control board (sub control device) are provided. The main control board receives input signals from input means such as the bet button 23, the start lever 990, the stop buttons 126a to 126c, and the medal sensor, performs various calculations for executing the game, and reels based on the calculation results. Controls output means such as units and hopper devices. Further, the sub-control board receives a signal sent from the main control board, performs various calculations for executing the effect, and controls the device for the effect such as the liquid crystal display and the speaker 114 based on the calculation result. Do.

In addition, the main control board and the sub control board are electrically connected, and various information (signals) such as information indicating the game state can be transmitted from the main control board to the sub control board. Information cannot be transmitted from the control board to the main control board. The functions of each board such as the main control board and the sub control board are stored in advance in various processors (CPU, DSP, etc.), ICs, hardware such as information storage media such as ROM and RAM, and ROM and the like. It is realized by software consisting of a predetermined program.

Next, the reel unit 50 for the 3-reel housing will be described with reference to FIGS. 2 and 3. The reel unit 50 includes reels 10a to 10c arranged so as to be coaxial, and a frame-shaped frame portion 11 and the like that rotatably support the reels 10a to 10c. The reel unit 50 is arranged in a reel arrangement portion 125 provided inside the housing 111.

As shown in FIG. 2A, the reel arrangement portion 125 includes a rod-shaped upper support portion 125a that is long on the left and right, and a plate-shaped lower support portion 125b that is long on the left and right. The upper support portion 125a and the lower support portion 125b are arranged apart from each other in the vertical direction, and the left ends of the upper support portion 125a and the lower support portion 125b are connected to the left wall portion inside the housing 111 and are supported upward. The right ends of the portion 125a and the lower support portion 125b are connected to the right wall portion inside the housing 111. This connection is achieved, for example, by screw tightening.

As shown in FIG. 2B, the frame portion 11 of the reel unit 50 includes an upper frame portion 11a provided on the upper side of each reel 10a to 10c and a lower frame portion 11b provided on the lower side of each reel 10a to 10c. , The left frame portion 11c that connects the left end portion of the upper frame portion 11a and the left end portion of the lower frame portion 11b, and the right frame portion 11d that connects the right end portion of the upper frame portion 11a and the right end portion of the lower frame portion 11b. , Arranged side by side at predetermined intervals in the left-right direction, each having three motor frame portions 11f for holding a stepping motor.

The reel unit 50 is arranged in the reel arrangement portion 125 by connecting the upper frame portion 11a to the upper support portion 125a and connecting the lower frame portion 11b to the lower support portion 125b. This connection is achieved, for example, by screw tightening. The reel unit 50 is unitized as a unit outside the housing 111 and is arranged in the reel arrangement unit 125 for each component such as each reel. It may be.

In the above, the reel arrangement portion 125 is composed of the upper support portion 125a and the lower support portion 125b, but the reel arrangement portion 125 is provided in the left side wall portion and the right side wall portion inside the housing 111. May be. In this case, for example, the upper support portion 125a and the lower support portion 125b are used as components of the reel unit 50, and the upper support portion 125a and the lower support portion 125b are fixed to the hole portion as the reel arrangement portion 125 by screw tightening or the like. Therefore, the reel unit 50 may be arranged. The reel arrangement portion 125 may be a groove portion provided on the left side wall portion and the right side wall portion inside the housing 111.

Hereinafter, a set of reels 10a to 10c which are constituent parts of the reel unit 50 will be referred to as three reels 10.
As shown in FIG. 3 (FIG. 9), the width of the three reels 10 in the axial direction (left-right direction), that is, the width in the axial direction from the left end of the first reel 10a to the right end of the third reel 10c is about 270 mm. It has become. Hereinafter, the width in this axial direction is referred to as the width of the 3 reels 10. Note that FIG. 30A is a part of the axial sectional view of the first reel 10a, but the left end of the first reel 10a is a circular frame 18 made of resin or the like. It refers to the leftmost part, not the leftmost part of the reel tape. In each of the reels 10a to 10c, a reel tape is attached to the frame body 18. The frame body 18 (see FIG. 30B) is rotated together with the reel tape by the rotation of the stepping motor (not shown). Hereinafter, the term "left end" or "right end" of the reel means the left end or the right end of the frame body 18.
As shown in FIG. 3, the width (length from the left end to the right end) of the reels 10a to 10c in each axial direction is about 82 mm. Further, the reels 10a to 10c are arranged at equal intervals, and the gap in the axial direction between the adjacent reels is about 12 mm. The width in the axial direction between the left end of the second reel 10b and the right end of the third reel 10c is about 175 mm. The axial width between the right end of the first reel 10a and the left end of the third reel 10c is about 106 mm.

FIG. 4 is a perspective view when the slot machine 100 is a 4-reel housing. As shown in FIG. 5, in the 4-reel housing, the reel unit 60 is arranged inside the housing 111 instead of the reel unit 50. The reel unit 50 and the reel unit 60 are formed so as to be selectively arranged in the reel arrangement portion 125. In other words, the reel arranging portion 125 is formed so that the reel unit 50 and the reel unit 60 can be selectively arranged. Specifically, the upper support portion 125a and the lower support portion 125b of the reel arrangement portion 125 have holes for screw insertion that allow the frame portion 11 of the reel unit 50 to be screwed, and the frame portion 21 of the reel unit 60. Is provided with a hole for inserting a screw so that the reel can be screwed. Here, the holes for screw insertion may be shared by the reel unit 50 and the reel unit 60, or may be provided separately. Further, the distance between the upper support portion 125a and the lower support portion 125b of the reel arrangement portion 125 is set to a length that allows both the reel unit 50 and the reel unit 60 to be selectively fitted. The reel unit 60 includes a first reel 20a, a second reel 20b, a third reel 20c, a fourth reel 20d, a frame portion 21, and the like. Although not shown, the frame portion 21 has a configuration corresponding to the upper frame portion 11a, the lower frame portion 11b, the left frame portion 11c, the right frame portion 11d, and the motor frame portion 11f shown in FIG. 2B. have.

Further, as shown in FIG. 4, the stop button unit 129 is arranged on the front side of the front door 112 instead of the stop button unit 126. The stop button unit 129 has a first stop button 129a, a second stop button 129b, a third stop button 129c, and a fourth stop button 129d. Here, the stop buttons 129a to 129d are buttons for stopping the rotating reels 20a to 20d. The stop button unit 126 and the stop button unit 129 can be selectively arranged (mounted). In other words, the front door 112 is provided with a stop button unit arranging portion in which the stop button unit 126 and the stop button unit 129 can be selectively arranged. In the stop button units 126 and 129, the stop buttons 126a to 126d or the stop buttons 129a to 129d are unitized as one, but even if the stop button units 126 and 129 are unitized including the start lever 990 and the like. Good. That is, depending on whether the housing is a 3-reel housing or a 4-reel housing, for example, the integrated stop button units 126 and 129 including the medal insertion slot 821, the bet button 23, the start lever 990, and the like are selected. It may be arranged as a target.

Hereinafter, a set of reels 20a to 20d, which are components of the reel unit 60, will be referred to as a 4-reel 20.
As shown in FIG. 6 (FIG. 10), the width of the 4 reels 20 in the axial direction (left-right direction), that is, the width in the axial direction from the left end of the first reel 20a to the right end of the fourth reel 20d is about 275 mm. It has become. Hereinafter, the width in this axial direction is referred to as the width of the 4 reels 20.
The width of the reels 20a to 20d in each axial direction is about 63 mm. Further, the reels 20a to 20d are arranged at equal intervals, and the gap between adjacent reels in the axial direction is about 8 mm. The axial width between the right end of the first reel 20a and the left end of the third reel 20c is about 79 mm. The axial width between the left end of the first reel 20a and the right end of the third reel 20c is about 205 mm. The axial width between the left end of the second reel 20b and the right end of the third reel 20c is about 134 mm. Further, the width in the axial direction between the right end of the first reel 20a and the left end of the fourth reel 20d is about 150 mm.

The width of the 4 reels 20 (about 275 mm) is the same as or substantially the same as the width of the 3 reels 10 (about 270 mm). In addition, substantially the same means within about 2% (about 5.4 mm) of the width of the reel which has the shorter difference between the two. Further, the width of the 4-reel 20 is not limited to the width larger than the width of the 3-reel 10, and the width of the 4-reel 20 may be smaller than the width of the 3-reel 10.
Further, the axial gap (8 mm) between adjacent reels in the 4 reels 20 is narrower than the same gap (12 mm) in the 3 reels 10.

Next, the relationship between the middle panel unit and the reel unit will be described with reference to FIG. 7. The middle panel unit is a unit attached to the inside of the front door 112 from the back side, and has a window portion 116, a reflector 30, and the like. FIG. 7A shows the middle panel unit and the reel unit 50 in the 3-reel housing. FIG. 7B shows the middle panel unit and the reel unit 60 in the 4-reel housing.
The window portion 116 is formed of, for example, a transparent acrylic plate in a substantially rectangular shape. A sheet-like member (not shown) is provided on the back surface side of the window portion 116. The sheet-shaped member may be a plate-shaped member. The sheet-shaped member has a pattern display portion on which a pattern or the like is drawn and the front side to the rear side is almost invisible, and a rectangular transparent portion provided in the center of the pattern display portion. The transparent portion includes a through hole in the front-rear direction in addition to the transparent portion. This transparent portion is provided so that the reel can be visually recognized. The visible area 116a of the window portion 116 is an area in which the reel can be visually recognized, and is defined by a transparent portion of the sheet-like member. The viewing area 116a has the same size in the case of the 3-reel housing and the case of the 4-reel housing, and in the present embodiment, the width of the viewing area 116a in the left-right direction is about 283 mm. There is. The display portion such as a pattern on the sheet-shaped member may be different between the 3-reel housing and the 4-reel housing.

The sheet-shaped member is attached to the back surface side of the window portion 116, or is sandwiched and held between the window portion 116 and another plate-shaped member. The sheet-shaped member may be sandwiched and held between the window portion 116 and the reflector 30 described later. Further, the window portion 116 and the sheet-shaped member may be integrally formed by one member. Further, a liquid crystal panel may be used instead of the sheet-like member. In this case, the portion of the sheet-shaped member corresponding to the display portion such as a pattern is the display area of the liquid crystal panel. In other words, the liquid crystal panel has a donut-shaped display area that surrounds the transparent portion that makes the reel visible. The liquid crystal panel in this case may be capable of displaying an image even on a transparent portion.

Further, the window portion 116 is not limited to the one provided with the sheet-like member or the liquid crystal panel on the back side, and the window portion 116 is formed as a transparent portion so that the reflector 30 or the liquid crystal panel described later surrounds the transparent portion. You may. In this case, the entire window portion 116 becomes the visible area 116a.

In the case of the 3-reel housing, the upper symbols, middle symbols and lower symbols of each reel 10a to 10c are visually recognized through the visual recognition area 116a. Further, in the case of the 4-reel housing, the upper symbols, the middle symbols and the lower symbols of the reels 20a to 20d are visually recognized through the viewing area 116a.

A reflector 30 is provided on the back surface side of the window portion 116. The reflector 30 is, for example, a frame-shaped member made of white resin, and is used to regulate the range of light emitted from a light source provided on the back surface side (reel side) of the reflector 30 toward the window portion 116. It is provided in. At a position of the reflector 30 facing the reel unit 50 (reel unit 60), a hole portion 31 which is a rectangular through hole in the front-rear direction is provided. Hereinafter, the opening on the window portion 116 side in the hole portion 31 will be referred to as a window side opening 31a.

The outer circumference of the transparent portion described above and the size of the window side opening 31a of the reflector 30 are substantially the same. Here, when the size of the window side opening 31a of the reflector 30 is smaller than the outer circumference of the transparent portion, in other words, when the window side opening 31a is located inside the outer circumference of the transparent portion, the visible area 116a of the window portion 116 is It will be defined by the window side opening 31a. That is, the visible area 116a of the window portion 116 is defined by the outer circumference of the transparent portion or the window side opening 31a, whichever is inside.

Next, the hole 31 of the reflector 30 will be described with reference to FIG. FIG. 8A is a vertical sectional view of the reflector 30 used in the 3-reel housing, and FIG. 8B is a vertical sectional view of the reflector 30 used in the 4-reel housing. Left and right wall portions 32 and right wall portions 33 extending in the front-rear direction are provided on the left and right sides of the hole portion 31. The left side wall portion 32 is inclined to the left side with respect to the front-rear direction toward the rear. Further, the right side wall portion 33 is inclined to the right side with respect to the front-rear direction toward the rear. The inclination angles of the left side wall portion 32 and the right side wall portion 33 are different from those shown in FIG. 8 (a) (that is, in the case of the 3-reel housing) in the case shown in FIG. 8 (b) (that is, in the 4-reel housing). Case) is larger. In FIG. 8, the reflector 30 for the 3-reel housing and the reflector 30 for the 4-reel housing are provided, respectively, but the reflector 30 may be shared by both.
By forming the left side wall portion 32 and the right side wall portion 33 in a tapered shape in this way, the 3 reel 10 or 4 reel 20 when the 3 reel 10 or 4 reel 20 is viewed from the player side (front side). The gap in the left-right direction between the left end portion and the left side wall portion 32 and the gap in the left-right direction between the right end portion and the right side wall portion 33 of the 3-reel 10 or 4-reel 20 can be reduced. As a result, it is possible to suppress deterioration of appearance (decrease in design) due to a large gap, which occurs when the left side wall portion 32 and the right side wall portion 33 are not tapered. Further, by forming the left side wall portion 32 and the right side wall portion 33 in a tapered shape, when the front door 112 is opened and closed, the contact between the left end portion of the 3 reel 10 or the 4 reel 20 and the left end portion 32, and 3 The contact between the right end portion of the reel 10 or the 4 reel 20 and the right side wall portion 33 can be avoided, and the front door 112 can be smoothly opened and closed.

In the present embodiment, the 3 reels 10 and the 4 reels 20 that are selectively arranged in the reel arrangement portion 125 and are visually recognized through the viewing area 116a of the window portion 116 have the same or substantially the same width. Even in the case of the 4-reel housing, the player does not need to move the line of sight significantly in the left-right direction when operating the four stop buttons 129a to 129d, and the burden is reduced. Further, when looking at the four stopped reels, it is not necessary to move the line of sight significantly in the left-right direction, and the symbols of the four reels can be grasped at a glance. Further, when a game is played on a slot machine having a 3-reel housing and then a game is played on a slot machine having a 4-reel housing, the player does not feel uncomfortable. In other words, the player can play the game of the 4-reel housing under the same reel visibility as the 3-reel housing, and can suppress the deterioration of the gameability.

Further, as in the present embodiment, by making the width of the 4-reel 20 the same as or substantially the same as the width of the 3-reel 10, the number of parts that can be shared by the 3-reel housing and the 4-reel housing can be increased. To increase. For example, when designing a 4-reel housing based on a 3-reel housing, it is necessary to provide a reel unit 60 and a stop button unit 129 for the 4-reel housing, but other parts are for the 3-reel housing. Can be diverted. However, a relay board or the like that relays a reflector 30, a seat member, a main control board, a sub control board, a main control board or a sub control board, and an input device such as various buttons or an output device such as a reel unit is used for a 4-reel housing. May be replaced with. The main control board and the sub control board may be shared, and only the relay board may be divided into a 3-reel housing and a 4-reel housing.
In this way, the 4-reel housing can be realized by replacing some parts of the 3-reel housing. This has the effect of reducing costs and facilitating inventory management. Further, since the width of the 4-reel 20 is substantially the same as the width of the 3-reel 10, when designing the parts of the 4-reel housing, the parts of the 3-reel housing can be diverted and designed. Efficiency can be improved.

Further, the axial gap between adjacent reels in the 4 reels 20 is smaller than the clearance in the 3 reels 10. In the 4-reel 20, since the reel width of each reel is narrower than that of the 3-reel 10 and the weight per reel is lighter than that of the 3-reel 10, the runout in the axial direction when the reels are rotated. Is small. Therefore, the gap between adjacent reels in the axial direction can be reduced. That is, the width of the 4-reel 20 can be reduced, and the 4-reel 20 can be miniaturized. As a result, even in the case of the 4-reel housing, the player does not need to move the line of sight significantly in the left-right direction, the burden is reduced, and the decrease in playability can be suppressed. Further, by reducing the axial gap between the adjacent reels, it is possible to reduce the axial width of the entire 4 reels 20 and prevent the width of each reel from becoming too small. As a result, it is possible to prevent the visibility from deteriorating and the playability from deteriorating.

Next, the stop buttons 126a to 126c for the 3-reel housing will be described with reference to FIG. Hereinafter, the stop buttons 126a to 126c will be referred to as a first stop button 126a, a second stop button 126b, and a third stop button 126c. In the stop button unit 126, the width (diameter) of each stop button is about 27 mm.
Here, as shown in FIG. 19, among the pressing portions 984, the surface (the surface on the player side, that is, the front surface) that directly receives the pressing operation by the player is referred to as the operation surface (pressing surface) 984a. Hereinafter, for example, the left end or the right end of the stop button means the left end or the right end of the operation surface 984a (the surface located in front) of the stop button.
Return to FIG. The first reel 10a, the second reel 10b, and the third reel 10c are arranged at equal intervals in the left-right direction (axial direction), and the distance between adjacent stop buttons is about 22 mm. Note that FIG. 31 is a view of the first stop button 126a and the second stop button 126b viewed from the front side. In this case, the distance between the stop buttons is the right end of the operation surface 984a of the first stop button 126a. And the left end of the operation surface 984a of the second stop button 126b (minimum distance).
Further, as shown in FIG. 9, the dimension (width) between the left end of the first stop button 126a and the right end of the third stop button 126c is about 125 mm. The dimension (width) between the left end of the second stop button 126b and the right end of the third stop button 126c is about 76 mm.

Next, the stop buttons 129a to 129d for the 4-reel housing will be described with reference to FIG. Hereinafter, the stop buttons 129a to 129d are referred to as a first stop button (first stop button) 129a, a second stop button (second stop button) 129b, a third stop button (third stop button) 129c, and a fourth stop button (4th stop button). 4th stop button) 129d.
In the stop button unit 129, the width (diameter) of each stop button is about 27 mm. The first reel 20a, the second reel 20b, the third reel 20c, and the fourth reel 20d are arranged at equal intervals in the left-right direction (axial direction), and the distance between adjacent stop buttons is about 13 mm. There is. The dimension (width) between the left end of the first stop button 129a and the right end of the third stop button 129c is about 107 mm. The dimension (width) between the left end of the second stop button 129b and the right end of the third stop button 129c is about 67 mm. The dimension (width) between the left end of the first stop button 129a and the right end of the fourth stop button 129d is about 147 mm.

The first stop button 129a is located below the second reel 20b, and its left end is located (protrudes) to the left (left side) of the left end of the second reel 20b (line L2 extending the left end of the second reel 20b). ) Is arranged. Therefore, the player can see that the first stop button 129a is the first stop button 129a as compared with the case where the first stop button 129a is completely contained within the width range of the second reel 20b below the second reel 20b. It is possible to easily recognize (grasp) that the stop button corresponds to the 1 reel 20a (the reel adjacent to the left side (left side) of the 2nd reel 20b).

As described above, if the left end of the first stop button 129a is located to the left of the left end of the second reel 20b, the effect of the present invention can be sufficiently exhibited, but the left end of the first stop button 129a is the first. If it is near the line L1 that extends the right end of the 1 reel 20a (that is, if the left end of the 1st stop button 129a is approximately below the right end of the 1st reel 20a), the 1st stop button 129a is the first. It is preferable because it can be more easily recognized that the stop button corresponds to 1 reel 20a.
Further, if the left end of the first stop button 129a is on the line L1 or further to the left (left side) of the line L1 (that is, the first stop button 129a is below the second reel 20b and its left end). Is arranged so as to coincide with the right end of the first reel 20a, or its left end is located to the left of the right end of the first reel 20a), and the first stop button 129a is the first. It is more preferable because it can be more easily and surely recognized that the stop button corresponds to the reel 20a.
When the first stop button 129a is arranged below the first reel 20a at a position completely within the width range of the first reel 20a, the first stop button 129a and the second stop button 129b are separated from each other. This causes problems such as hindering the operation of the stop button at a good tempo and increasing the burden on the player. Therefore, a part of the first stop button 129a is located below the second reel 20b (within the width of the second reel 20b), and its left end is the left end of the second reel 20b (second reel). It is preferable that it is located (protrudes) on the left side of the line L2) extending the left end of 20b.

The second stop button 129b is arranged below the second reel 20b at a position within the width of the second reel 20b. In other words, the left end of the second stop button 129b is located to the right (right side) of the line L2, which is a line extending the left end of the second reel 20b, and the right end extends the right end of the second reel 20b. It is arranged so as to be located on the left side (left side) of the line L3 which is the line. Therefore, the player can easily recognize (grasp) that the second stop button 129b is a stop button corresponding to the second reel 20b.

The third stop button 129c is arranged below the third reel 20c at a position within the width of the third reel 20c. In other words, the left end of the third stop button 129c is located to the right (right side) of the line L4, which is a line extending the left end of the third reel 20c, and the right end extends the right end of the third reel 20c. It is arranged so as to be located on the left side (left side) of the line L5 which is the line. Therefore, the player can easily recognize (grasp) that the third stop button 129c is a stop button corresponding to the third reel 20c.

The fourth stop button 129d is located (protruding) below the third reel 20c and to the right (right side) of the right end of the third reel 20c (line L5 extending the right end of the third reel 20c). ) Is arranged. Therefore, the player can see that the fourth stop button 129d is the fourth stop button 129d as compared with the case where the fourth stop button 129d is completely contained within the width range of the third reel 20c below the third reel 20c. It is possible to easily recognize (grasp) that the stop button corresponds to the 4-reel 20d (the reel adjacent to the right side (right side) of the third reel 20c).

As described above, if the right end of the 4th stop button 129d is located to the right of the right end of the 3rd reel 20c, the effect of the present invention can be sufficiently exhibited, but the right end of the 4th stop button 129d is the first. If it is near the line L6 that extends the left end of the 4 reel 20d (that is, if the right end of the 4th stop button 129d is approximately below the left end of the 4th reel 20d), the 4th stop button 129d is the first. It is preferable because it can be more easily recognized that the stop button corresponds to the 4-reel 20d.
Further, if the right end of the 4th stop button 129d is on the line L6 or further to the right (right side) of the line L6 (that is, the 4th stop button 129d is below the 3rd reel 20c and its right end). Is arranged so as to coincide with the left end of the 4th reel 20d, or its right end is located to the right of the left end of the 4th reel 20d), and the 4th stop button 129d is the 4th. It is more preferable because it can be more easily and surely recognized that the stop button corresponds to the reel 20d.
When the 4th stop button 129d is arranged below the 4th reel 20d at a position where it completely fits within the width range of the 4th reel 20d, the 3rd stop button 129c and the 4th stop button 129d are separated from each other. This causes problems such as hindering the operation of the stop button at a good tempo and increasing the burden on the player. Therefore, a part of the fourth stop button 129d is located below the third reel 20c (within the width of the third reel 20c), and the right end thereof is the right end of the third reel 20c (third reel). It is preferable that it is located (protrudes) on the right side of the line L5) extending the right end of 20c.

As described above, according to the slot machine 100 shown in FIG. 10, even if the specifications are 4 reels and 4 stop buttons, the correspondence between the 4 reels and the stop buttons corresponding to the respective reels is easy for the player to understand. (It is easy for the player to intuitively recognize the corresponding relationship). For this reason, for example, mistakes in pressing by the player are reduced. Further, for example, when operating the stop button according to the instruction function (correct batting order notification), erroneous operation (pressing the stop button corresponding to a reel other than the reel intended to stop) is reduced. As a result, the decrease in playability is suppressed. In addition, it is possible to reduce the discomfort of the player when pressing the button (confusion about which stop button should be operated, etc.).

Further, the four stop buttons 129a to 129d are arranged evenly with close intervals, and the intervals are suitable so as not to be too wide. As a result, the player can operate the stop button at a good tempo and feel comfortable, so that the playability is improved. In the slot machine 100 shown in FIG. 10, the distance between the stop buttons may be approximately half the diameter of the stop buttons (27 mm). The length of about half the diameter of the stop button is about 13.5 mm ± 2.0 mm (± about 15%).

Further, in FIG. 10, the dimension (referred to as dimension α) between the left end of the first stop button 129a and the right end of the fourth stop button 129d is 147 mm, whereas the right end of the first reel 20a and the fourth reel The dimension between the left end of 20d and the left end (dimension β) was set to 150 mm. That is, the dimension β is larger than the dimension α. However, the dimension β may be the same as or less than or equal to the dimension α. When the dimension β is the same as the dimension α (that is, when the dimension β is 147 mm), the left end of the first stop button 129a is on the line L1, and the right end of the fourth stop button 129d is on the line L4. Further, when the dimension β is smaller than the dimension α (for example, when the dimension β is 146 mm), the left end of the first stop button 129a protrudes to the left of the line L1 by 0.5 mm, and the fourth stop button 129d The right end of the line L6 protrudes to the right by 0.5 mm.

Further, in FIG. 6 (FIG. 10), the reel widths of the reels 20a to 20d are set to about 63 mm and the axial gap between the adjacent reels is set to about 8 mm. For example, the reel width is set to about 58 mm and the distance between the adjacent reels is set to about 58 mm. The clearance in the axial direction of the above may be about 10 mm. In that case, the positions of the first stop button 129a to the fourth stop button 129d may be appropriately adjusted so that the positional relationship between each reel and each stop button becomes the above-mentioned positional relationship.

Further, in FIG. 10, the first reel 20a to the fourth reel 20d are used as the main reel, and the first stop button 129a to the fourth stop button 129d are used as the main stop button. Of the first reel 20a to the fourth reel 20d. Any one of the above may be used as a sub reel. In that case, the stop button corresponding to the sub reel (stopping the rotation of the sub reel) may be a sub stop button.

FIG. 32 is a front view of the slot machine 100 having a 3-reel housing, as in FIG. 9. The front door 112 is provided with a first stop button 126a, a second stop button 126b, and a third stop button 126c, and the center Xb of the operation surface 984a (see FIG. 19) of the second stop button 126b is the front door. It is located approximately in the center of the width direction (horizontal direction) of the 112 (for example, on the center line D).
Although not shown, the reels 10a to 10c (3 reels 10 (see FIG. 2)) (reel unit 50 (see FIG. 3)) may be arranged closer to the left or right side of the front door 112. Good. For example, when a predetermined effect device (movable body or the like) is provided on the right side of the front door 112, the reels 10a to 10c are provided close to the position on the left side of the front door 112. At this time, the visible area 116a (see FIG. 1) is also provided closer to the left side or the right side in accordance with the reels 10a to 10c.

When the reels 10a to 10c are provided close to the left side of the front door 112, the third stop button 126c has the center Xc of its operation surface 984a (see FIG. 19) below the third reel 10c. , The third reel 10c is arranged so as to substantially coincide with the center of the width (center Xc is on the center line Yc). Approximate coincidence means that the deviation between the two is within ± 1.5 mm. It is said that the reference position is aligned so that the center Xc of the operation surface 984a of the third stop button 126c and the center of the width of the third reel 10c (center line Yc) are substantially coincident with each other. With this configuration, even when the reels 10a to 10c are arranged at the positions on the left side of the front door 112 without changing the positions of the stop buttons 126a to 126c, the third reel 10c and the third reel 10c and the third reel 10c Since the reference position is aligned with the stop button 126c, the player can easily grasp the correspondence between the reels 10a to 10c and the stop buttons 126a to 126c. Therefore, it is possible to prevent the playability from being lowered.

When the reels 10a to 10c are provided close to the right side of the front door 112, the first stop button 126a has the center Xa of the operation surface 984a below the first reel 10a. It is arranged so as to substantially coincide with the center of the width of the reel 10a (so that the center Xa is on the center line Ya). Approximate coincidence means that the deviation between the two is within ± 1.5 mm. In this case, similarly to the above, since the reference position is aligned between the first reel 10a and the first stop button 126a, the player has a correspondence relationship between the reels 10a to 10c and the stop buttons 126a to 126c. Easy to grasp sensuously. Therefore, it is possible to prevent the playability from being lowered.

Further, for example, a rectangular liquid crystal panel 80 (see FIG. 32) may be further provided above the reels 10a to 10c arranged closer to the left side or the right side. Here, the case where the liquid crystal panel 80 and the display area 81 thereof have the same size will be described, but the liquid crystal panel 80 may be larger than the display area 81. In the display area 81, batting order navigation (correct answer batting order notification) and the like are displayed.
In the left-right direction, the left end of the reels 10a to 10c (the left end of the first reel 10a: the left end of the frame body 18 shown in FIG. 30A) does not protrude to the left (left) from the left end of the display area 81 (protrudes). Not). The position of the left end of the reels 10a to 10c (the left end of the first reel 10a) and the position of the left end of the display area 81 in the left-right direction may be substantially the same. Approximately the same means that the difference between the two is within ± 1.5 mm.

Further, in the left-right direction, the right end of the reels 10a to 10c (the right end of the third reel 10c) does not protrude (protrude) to the right (right side) from the right end of the display area 81. The position of the right end of the reels 10a to 10c (the right end of the third reel 10c) and the position of the right end of the display area 81 in the left-right direction may be substantially the same. Approximately the same means that the difference between the two is within ± 1.5 mm.
With this configuration, the distance between the display area 81 and the first reel 10a and the distance between the display area 81 and the third reel 10c do not increase (separate), and the player can use the batting order navigation. It is easy to intuitively grasp the correspondence with each reel. Therefore, it is possible to prevent the playability from being lowered.

Next, with reference to FIG. 11, the backlight device 150 provided on the inner side in the radial direction of the reels 10a to 10c shown in FIG. 3 will be described. The backlight device 150 includes an LED (light source) 200, an LED substrate (light source substrate) 210, and a reflector 220 that regulates the range of light emitted from the LED 200. The LED 200 is provided to irradiate the upper symbol, middle symbol, and lower symbol of the stopped reel with light, and is mounted on the LED substrate 210. The LED substrate 210 is held by the reflector 220. This holding is realized, for example, by providing a claw portion on the back surface side of the reflector 220 and engaging the LED substrate 210 with the claw portion. The reflector 220 is, for example, a room 229 formed of a white resin and surrounded by a wall portion extending from the radial inside of the reel (LED substrate 210 side) toward the radial outside (outer peripheral surface side) of the reel. It has a shape in which three are arranged in succession along the circumferential direction of the reel. Further, the reflector 220 (that is, the backlight device 150) holding the LED substrate 210 has its right end connected to the motor frame portion 11f shown in FIG. 2B. This connection is realized, for example, by screw tightening.

Further, on the LED substrate 210, an identification code 205 for identifying each LED 200 is written in the vicinity of each of the LEDs 200 provided on the LED substrate 210. A plurality of LEDs 200 are mounted on the LED substrate 210 so as to face the bottom side opening of each room 229 that is continuously arranged in the circumferential direction of the reel. Two to nine LEDs 200 face each room 229, and six to 27 LEDs 200 are mounted on one LED substrate 210. Note that FIG. 11 shows a case where nine LEDs 200 are mounted on one LED substrate 210, but the number of LEDs 200 is not limited to this. For example, nine LEDs 200 may face each of the bottom side openings of each room 229 of the reflector 220. In this case, 27 LEDs 200 are provided (mounted) on one LED substrate 210.

When nine LEDs 200 are mounted on one LED substrate 210, each LED 200 is given a serial number from 1 to 9. In the vicinity of each LED 200, characters from "LED1" to "LED9" are written as identification codes 205. When n (natural number) LEDs 200 are mounted on one LED substrate 210, serial numbers from 1 to n are assigned to each LED 200. Then, in the vicinity of each LED 200, characters from "LED1" to "LEDn" are written as identification codes 205.

The serial number is determined by the designer of the game machine (LED board 210). For example, when one of the nine LEDs 200 does not light up, the identification code of the LED 200 that does not light up is used. By checking 205, it is possible to determine the serial number of the LED 200 that has stopped lighting, and by tracing the circuit diagram of the LED board 210 from the identification code 205 of the LED 200 that has stopped lighting, the failure of the LED board 210 has occurred. It is possible to analyze points and the like.

Further, the identification code 205 is provided at a position where each LED 200 can be identified even when the reflector 220 is arranged on the front side of the LED substrate 210. That is, the reflector 220 is arranged in front of the LED substrate 210 so as to cover at least a part of the surface on which the LED 200 of the LED substrate 210 is mounted, but the bottom opening of each room 229 of the reflector 220 is an LED. The identification code 205 is written in the vicinity of the LED 200 so as to face the surface of the substrate 210 and face the opening on the bottom surface side. Therefore, even in the state where the reflector 220 is arranged, the serial number of each LED 200 can be known through the bottom side opening (room 229) of the reflector 220. At this time, the identification code 205 does not have to be visible as a whole, and each LED 200 may be in a state where it can be identified. For example, even if some of the characters "LED1" to "LEDn" are hidden by the reflector 220, if the number parts "1" to "n" are visible to the extent that they can be discriminated, each LED200 Can be identified.

The number portions "1" to "9" of the characters "LED1" to "LED9" as the identification code 205 are the rooms from the front side in a state where the reflector 220 is arranged on the front side of the LED substrate 210. All are visible through the 229. Therefore, all the LEDs 200 provided on the front side of the LED substrate 210 are in a state where they can be identified by the identification code 205.
Further, all the identification codes 205 provided on the front surface of the LED substrate 210 are provided on the same side as the LED 200 (lower side of the LED 200 in FIG. 11). Further, all the identification codes 205 have the same marking direction. For example, as shown in FIG. 11, all identification codes 205 are marked to read from left to right.
Further, although the reflector 220 and the LED substrate 210 of the backlight device 150 have been described here as an example, the reflectors and the LED substrates used in other lighting devices such as the lighting device for directing are similarly arranged. The identification code 205 may be configured to be discriminable in this state. Further, here, a case where the reflector 220 (for example, a white partition member) that reflects light is used as a partition member that partitions the adjacent rooms 229 and blocks the light from the adjacent room 229 has been described as an example. Instead of the reflector 220, one that does not reflect light (for example, a black partition member) may be used.

Next, the start lever unit 900 will be described with reference to FIG. FIG. 12 is a cross-sectional view of the start lever unit 900. The start lever unit 900 includes a start lever 990, a housing 901, a holder 902, a cap 903, a sleeve 904, a spring 905, a push nut 906, a mask 907, a sensor 908, and the like. Note that FIG. 12 shows the state when the start lever 990 is not operated.

The start lever 990 includes a spherical operating portion 991 and a rod-shaped shaft 992 connected to the operating portion 991. The start lever 990 is arranged so that the shaft 992 is perpendicular to the installation surface F (see FIG. 1) of the start lever 990. The installation surface F is a surface perpendicular to the front-rear direction. The operation unit 991 is made of, for example, a resin. The shaft 992 is made of, for example, stainless steel. As shown in FIG. 12, the shaft 992 includes a large diameter portion 993 and a small diameter portion 994, and a step portion 995 is formed at a portion serving as a boundary between the large diameter portion 993 and the small diameter portion 994. .. The step portion 995 is a surface perpendicular to the axial direction of the shaft 992.

The housing 901 is a member formed in a bottomed cylindrical shape, and is made of, for example, a resin. The bottom portion 901a of the housing 901 is provided with a through hole 901b for inserting the small diameter portion 994 of the shaft 992. The holder 902 is a member formed in a cylindrical shape, and is made of, for example, a resin. A housing 901 is attached to one end side (front side) of the holder 902, and a cap 903 described later is attached to the other end side (rear side) of the holder 902. The attachment of the housing 901 and the cap 903 to the holder 902 is, for example, claw fitting.

In the shaft 992, the small diameter portion 994 is inserted through the through hole 901b, a part of the small diameter portion 994 protrudes rearward from the through hole 901b, and the protruding portion is housed inside the holder 902. Further, at this time, the step portion 995 comes into contact with the bottom portion 901a of the housing 901 (the front surface of the bottom portion 901a). A sleeve 904, a spring 905, and a push nut 906, which will be described later, are inserted and attached to a portion of the small diameter portion 994 that protrudes rearward from the through hole 901b.

The sleeve 904 is a receiving member that receives the urging force of the spring 905, and is made of, for example, a resin. The sleeve 904 has a flat surface portion 904a that is a surface perpendicular to the axial direction of the shaft 992 on the side opposite to the surface that contacts the spring 905. The flat surface portion 904a of the sleeve 904 comes into contact with the rear surface of the bottom portion 901a (referred to as the back surface portion 901c of the bottom portion 901a). The spring 905 is a spring and is made of, for example, stainless steel. The push nut 906 is a receiving member that receives the urging force of the spring 905, and is made of, for example, resin.

As shown in FIG. 12, the shaft 992 is formed with a retaining portion 996 that serves to prevent the push nut 906 from coming off. The retaining portion 996 is a portion having a larger diameter than other portions of the small diameter portion 994. The sleeve 904, the spring 905 and the push nut 906 are held in a state of being inserted into the small diameter portion 994 by abutting one end of the push nut 906 against the retaining portion 996.

In the state shown in FIG. 12, the flat surface portion 904a of the sleeve 904 and the back surface portion 901c of the bottom portion 901a come into surface contact with each other due to the urging force of the spring 905. As a result, the start lever 990 maintains a posture in which the shaft 992 is horizontal with respect to the front-rear direction, that is, a posture in which the shaft 992 is perpendicular to the installation surface F (neutral state). When the installation surface F of the front door 12 is an inclined surface that is inclined with respect to the vertical direction or the horizontal direction, the posture perpendicular to the inclined surface may be set to the neutral state of the start lever 990. Further, when the front door 12 itself is inclined with respect to the vertical direction (vertical direction), the posture perpendicular to the front door 12 may be set to the neutral state of the start lever 990.
Hereinafter, the posture when the start lever 990 is not operated is referred to as an initial position. Further, the axis of the shaft 992 at the initial position is set as the reference axis X. When the start lever 990 is in the initial position, the player can tilt the start lever 990 in all directions. The start lever 990 may be operable in the front-rear direction as well. That is, the start lever 990 may be operable in the pulling direction or the pushing direction.

Next, a case where the start lever 990 is operated and tilted will be described. FIG. 13 shows a cross-sectional view of the start lever unit 900 in a state where the start lever 990 is tilted downward. In this state, one side (upper side) of the flat surface portion 904a of the sleeve 904 is in contact with the back surface portion 901c of the bottom portion 901a, and the other side (lower side) of the flat surface portion 904a is separated from the back surface portion 901c of the bottom portion 901a. The spring 905 is in a bent state by a predetermined length. Further, the force required to bend the spring 905 when tilting the start lever 990 is the force required to operate the start lever 990. In other words, the operating force of the start lever 990 is realized by the elastic force of the spring 905.

In the state shown in FIG. 13, when the player releases the finger or the like from the start lever 990, the flat portion 904a of the sleeve 904 comes into surface contact with the back portion 901c of the bottom portion 901a again as the spring 905 deforms to return to its original position. It is designed to do. As a result, the start lever 990 returns to the state (initial position) shown in FIG.

Next, the detection of the operation of the start lever 990 will be described. The following description shows an example of detecting the operation of the start lever 990, and the detection method is not limited to this, and other methods may be used. As shown in FIG. 14A, the end surface of the small diameter portion 994 of the shaft 992 is a reflecting surface 997. The reflecting surface 997 is a surface capable of reflecting the light projected from the sensor 908, which will be described later. The cap 903 is a lid-shaped member attached to the rear end side of the holder 902, and is made of resin. The cap 903 is attached to the holder 902 while holding the mask 907, the sensor 908, and the like.

The mask 907 is a plate-shaped member having a small-diameter hole 907a formed at a position substantially coaxial with the shaft 992 at the initial position. The hole 907a is provided to pass the light projected by the sensor 908, which will be described later, to the shaft 992 side. The sensor 908 includes a light emitting / receiving unit (not shown) formed at a position substantially coaxial with the shaft 992 at the initial position. The sensor 908 projects light from the light emitting / receiving unit based on a signal from the control unit (not shown), and a signal corresponding to the condition based on whether or not the reflected light of the projected light is received. Is to be output.

In the present embodiment, as shown by an arrow in FIG. 14A, the sensor 908 is a signal indicating that the start lever 990 is in the initial position when the reflected light reflected by the reflecting surface 997 is received. That is, a signal (OFF signal) indicating that the operation of the start lever 990 has not been detected is output. Further, as shown by an arrow in FIG. 14B, when the sensor 908 does not receive the reflected light reflected by the reflecting surface 997, the signal indicating that the start lever 990 is not in the initial position, that is, the start A signal (ON signal) indicating that the operation of the lever 990 has been detected is output.

Next, the operation characteristics of the start lever 990 will be described in detail with reference to the cross-sectional views of FIGS. 15 and 16. FIG. 15 is a cross-sectional view for explaining the operating characteristics of the start lever 990 in a predetermined model (referred to as the first model). FIG. 15A shows a state in which the start lever 990 is in the initial position. FIG. 15B shows a state in which the start lever 990 is in the detection position. The detection position is a position where the operation of the start lever 990 is detected. In other words, the detection position is the position of the start lever 990 when the ON signal is output from the sensor 908. FIG. 15C shows a state in which the start lever 990 is in the maximum position. The maximum position is the position where the tilt distance or tilt angle of the operation unit 991 on the start lever 990 is maximized. The tilt distance and tilt angle of the operation unit 991 will be described later. The tilt of the start lever 990 is stopped when an arbitrary portion of the start lever 990 comes into contact with the mechanical end formed on the housing 901, the holder 902, or the like. The location of the mechanical end may be one location or a plurality of locations. When the start lever 990 comes into contact with the mechanical end, the tilt distance or tilt angle of the operation unit 991 becomes the maximum, that is, the position of the start lever 990 becomes the maximum position.

Next, the tilting distance of the operation unit 991 will be described. As shown in FIG. 15A, the apex of the end of the operation unit 991 opposite to the shaft 992 connecting side, that is, the apex of the start lever 990 is set as the apex A. The tilt distance of the operation unit 991 is the minimum distance between the apex A of the start lever 990 and the reference axis X. At the initial position shown in FIG. 15A, the tilting distance of the operation unit 991 is 0 mm. On the other hand, at the detection position shown in FIG. 15B, the tilt distance of the operation unit 991 is about 4.0 mm.

Next, the tilt angle of the operation unit 991 will be described. When the axis of the shaft 992 is the axis Z, the tilt angle of the operation unit 991 is the angle formed by the axis Z and the reference axis X on the operation unit 391 side. At the initial position shown in FIG. 15A, the tilt angle of the operation unit 991 is 0 ° because the reference axis X and the axis Z coincide with each other. On the other hand, at the detection position shown in FIG. 15B, the tilt angle of the operation unit 991 is about 3.9 °.

As shown in FIG. 15A, in the first model, the distance from the fulcrum of the shaft 992 (the center of rotation of the shaft 992) to the apex A is 60.2 mm. Further, the distance (distance S) from the fulcrum of the shaft 992 to the reflecting surface 997 is 21.3 mm. Further, the distance between the reflecting surface 997 and the mask 907 arranged on the light emitting / receiving surface side of the sensor 908 is 4.2 mm. It should be noted that each dimension is a median value, and each has a predetermined tolerance.

As shown in FIG. 15B, when the start lever 990 is tilted from the initial position to the detection position, the tilt distance of the operation unit 991 is about 4.0 mm, and the tilt angle of the operation unit 991 is about 3.9. It is °. At this time, assuming that the central point of the reflecting surface 997 is the apex B, the tilting distance of the apex B on the reflecting surface 997 when the start lever 990 is tilted from the initial position to the detection position is about 1.7 mm. ing.

As shown in FIG. 15 (c), when the start lever 990 is tilted from the initial position to the maximum position, the tilt distance of the operation unit 991 is about 8.4 mm, and the tilt angle of the operation unit 991 is about 8.0. It is °. At this time, when the start lever 990 is tilted from the initial position to the maximum position, the tilt distance of the apex B on the reflecting surface 997 is about 2.9 mm.

FIG. 16 is a cross-sectional view for explaining the operating characteristics of the start lever 990 in a predetermined model (referred to as a second model). As shown in FIG. 16A, in the second model, the distance from the fulcrum of the shaft 992 to the apex A is 60.2 mm. Further, the distance (distance S) from the fulcrum of the shaft 992 to the reflecting surface 997 is 31.3 mm. Further, the distance between the reflecting surface 997 and the mask 907 arranged on the light emitting / receiving surface side of the sensor 908 is 4.2 mm. It should be noted that each dimension is a median value, and each has a predetermined tolerance.

FIG. 16A shows a state in which the start lever 990 is in the initial position. At the initial position, the tilt distance of the operation unit 391 is 0 mm, and the tilt angle of the operation unit 391 is 0 °.

FIG. 16B shows a state in which the start lever 990 is in the detection position. When the start lever 990 is tilted from the initial position to the detection position, the tilt distance of the operation unit 991 is about 3.6 mm, and the tilt angle of the operation unit 991 is about 3.4 °. At this time, when the start lever 990 is tilted from the initial position to the detection position, the tilt distance of the apex B on the reflection surface 997 is about 1.7 mm.

FIG. 16C shows a state in which the start lever 990 is in the maximum position. When the start lever 990 is tilted from the initial position to the maximum position, the tilt distance of the operation unit 991 is about 8.4 mm, and the tilt angle of the operation unit 991 is about 8.0 °. At this time, when the start lever 990 is tilted from the initial position to the maximum position, the tilt distance of the apex B on the reflecting surface 997 is about 4.3 mm.

FIG. 17 is a diagram showing a tilt distance and a tilt angle of the operation unit 991 for each model. In the first model, the tilt distance (about 4.0 mm) of the operation unit 991 from the initial position to the detection position is 50% or less of the tilt distance (about 8.4 mm) of the operation unit 991 from the initial position to the maximum position. It is the value of. Further, in the first model, the tilt angle (about 3.9 °) of the operation unit 991 from the initial position to the detection position is the tilt angle (about 8.0 °) of the operation unit 991 from the initial position to the maximum position. It is a value of 50% or less of. However, it is assumed that the tilt distance and tilt angle of the operation unit 991 from the initial position to the detection position are values exceeding 0.

In the second model, the tilt distance (about 3.6 mm) of the operation unit 991 from the initial position to the detection position is 50% or less of the tilt distance (about 8.4 mm) of the operation unit 991 from the initial position to the maximum position. It is the value of. Further, in the second model, the tilt angle (about 3.4 °) of the operation unit 991 from the initial position to the detection position is the tilt angle (about 8.0 °) of the operation unit 991 from the initial position to the maximum position. It is a value of 50% or less of. However, it is assumed that the tilt distance and tilt angle of the operation unit 391 from the initial position to the detection position are values exceeding 0.

The values of the tilt distance and the tilt angle of the operation unit 991 vary, but even if the values vary, the tilt distance and the tilt angle of the operation unit 991 from the initial position to the detection position are still present. , The value is 50% or less of the tilt distance and tilt angle of the operation unit 991 from the initial position to the maximum position.

As described above, the gaming machine according to the present embodiment is a gaming machine provided with a tiltable start lever 990 having a shaft 992 having an operation portion 991 formed on the tip side thereof, and the start lever 990 is not. It is possible to tilt from the initial position, which is the position at the time of operation, to the maximum position, which is the position where the operation amount of the start lever 990 is maximum with respect to the initial position, via the detection position, which is the position where the operation of the start lever 990 is detected. The tilt distance or tilt angle of the operation unit 991 from the initial position to the detection position is a value exceeding 0 with respect to the tilt distance or tilt angle of the operation unit 991 from the initial position to the maximum position. The value is 50% or less. Therefore, it is detected that the start lever 990 is operated with an operation amount of 50% or less of the operation amount required for tilting the operation unit 991 of the start lever 990 to the maximum position. This makes it possible to improve the sensitivity at which the operation of the start lever 990 is detected. Further, it is possible to provide a game machine in which the response of the start lever 990 is improved. Further, according to the gaming machine according to the present embodiment, the trouble of having to re-operate the start lever 990 because the operation is not detected due to insufficient tilting despite the operation of the start lever 990 is eliminated. .. Therefore, the playability of the game machine can be improved.

From the viewpoint of further improving the detection sensitivity, the tilt distance or tilt angle of the operation unit 991 from the initial position to the detection position is 50% with respect to the tilt distance or tilt angle of the operation unit 991 from the initial position to the maximum position. A value of less than 48% is preferred, a value of less than 48% is more preferred, and a value of less than 45% is even more preferred. Further, the tilt distance of the operation unit 991 from the initial position to the detection position is a value exceeding 0, and even when the tolerance is maximum, 50 with respect to the tilt distance of the operation unit 991 from the initial position to the maximum position. It is more preferable that the value is less than%. The maximum tolerance varies so that the tilt distance of the operation unit 991 from the initial position to the detection position is maximized, and the tilt distance of the operation unit 991 from the initial position to the maximum position is minimized. Refers to the case. In this way, by setting the tilt distance from the initial position to the detection position to less than 50% of the tilt distance from the initial position to the maximum position, the tilt distance from the initial position to the maximum position is tilted from the initial position to the detection position. The distance is set to more than twice the distance to improve the detection sensitivity of the operation of the start lever 990, and a sufficient range is secured so that the start lever 990 can be further operated (tilted) after the operation of the start lever 990 is detected. can do. As a result, it is possible to achieve both the improvement of the detection sensitivity and the contradictory effect of providing a feeling of operation with a feeling of pressure.

Further, as shown in FIG. 16, the second model is modified so that only the dimension of the distance S is larger than that of the first model. In this way, by increasing only the dimension of the distance S without changing the configuration of the start lever 990, the operation of the start lever 990 can be detected with a smaller amount of operation, and the response of the start lever 990 becomes. improves.

Further, although FIG. 16 shows a case where the diameter of the reflecting surface 997 is 3.6 mm, the sensitivity at which the operation of the start lever 990 is detected can be improved by reducing the size of the diameter. .. For example, in FIG. 16B, when the diameter of the reflecting surface 997 is further reduced, the tilting distance of the operating unit 991 from the initial position to the detection position can be set to about 2.5 mm.

In the above, the case where the tilt distance and tilt angle of the operation unit 991 from the initial position to the detection position are set to 50% or less of the tilt distance and tilt angle of the operation unit 991 from the initial position to the maximum position has been described. On the other hand, for example, the tilt distance and tilt angle of the operation unit 991 from the initial position to the detection position are set to 20% to 50% of the tilt distance and tilt angle of the operation unit 991 from the initial position to the maximum position. In this case, in addition to the above-mentioned effects, erroneous detection of the operation of the start lever 990 can be suppressed. Some of the false positives are caused by, for example, vibration generated by hitting the periphery of the start lever 990 in the slot machine.

Next, the operating load of the start lever 990, the MAX bet button 23, and the stop button 126 (129) will be described. Hereinafter, the operating load required to tilt the start lever 990 from the initial position to the detection position is referred to as the detection load of the start lever 990. The operating load required to tilt the start lever 990 from the initial position to the maximum position is referred to as the maximum load of the start lever 990. The detected load of the start lever 990 is about 1.5N. The maximum load of the start lever 990 is about 3.0N.

FIG. 18 is a cross-sectional view of the MAX bet button 23. The MAX bet button 23 is a button operated so as to be pushed downward from above. The MAX bet button 23 includes a pressing portion 981, a spring 982, a sensor 983, and the like. The pressing portion 981 is a component operated by a player's finger or the like, and is made of, for example, resin. The spring 982 urges the pressing portion 981 upward, and elastically deforms and bends when the pressing portion 981 is pushed in. The sensor 983 is, for example, a photo sensor. The sensor 983 outputs an ON signal when it detects that, for example, a detection object that moves by pushing the pressing portion 981 changes the light from the light emitting element to the light receiving element.

Here, it is necessary to push the pressing portion 981 to elastically deform the spring 982 and move the pressing portion 981 to a position where an ON signal (a signal indicating that the MAX bet button 23 has been operated) is output from the sensor 983. The load is the detected load of the MAX bet button 23. The detected load of the MAX bet button 23 is about 0.8N. The amount of movement (ON stroke) of the pressing portion 981 from the initial position to the detection position is about 1.0 mm.

When the pressing portion 981 is operated with a load larger than the detected load, the pressing portion 981 is further pushed while elastically deforming the spring 982. Then, the pressing portion 981 comes into contact with a mechanical stopper (mechanical end) provided at an arbitrary position and stops. Here, the load required to push the pressing portion 981 to elastically deform the spring 982 and move the pressing portion 981 until it comes into contact with the mechanical stopper is set as the maximum load of the MAX bet button 23. The maximum load of the MAX bet button 23 is about 1.6N. The amount of movement (full stroke) from the initial position of the pressing portion 981 to the contact with the mechanical stopper is about 2.0 mm. The full stroke of the MAX bet button 23 may be, for example, about 3.0 mm, and the ON stroke may be about 1.5 mm. However, the full stroke of the MAX bet button 23 is preferably equal to or greater than the full stroke of the stop button 126 (129) described later.

FIG. 19 is a cross-sectional view of the stop button 126 (129). The stop button 126 (129) is a button operated so as to be pushed from the front to the rear. The stop button 126 (129) includes a pressing portion 984, a spring 985, a sensor 986, and the like. Since the pressing portion 984, the spring 985, and the sensor 986 have the same functions as the pressing portion 981, the spring 982, and the sensor 983 shown in FIG. 18, overlapping description will be omitted.

The detected load of the stop button 126 (129) is about 0.7N. The ON stroke of the stop button 126 (129) is about 1.0 mm. The maximum load of the stop button 126 (129) is about 1.4N. The full stroke of the stop button 126 (129) is about 2.0 mm. However, the full stroke of the stop button 126 (129) may be less than that, for example, about 3.0 mm, when the full stroke of the MAX bet button 23 is about 3.0 mm. Further, in this case, the ON stroke of the stop button 126 (129) may be about 1.5 mm, which is equal to or less than the ON stroke of the MAX bet button 23.

FIG. 20 is a diagram showing operating loads of the start lever 990, the MAX bet button 23, and the stop button 126 (129). In the gaming machine according to the present embodiment, the operating load of each button is set so as to be a relatively suitable operating load for the player. The operating load required to move the start lever 990 from the initial position, which is the non-operation position, to the detection position, which is the position where the operation is detected (detection load of the start lever 990: about 1.5N) (No. 1 detection load) is from the operation load required to move the stop button 126 (129) from the initial position to the detection position (detection load of stop button 126 (129): about 0.7N) (third detection load). It is a large value. In other words, the first detection load, which is the operation load required to move the start lever 990 from the initial position, which is the non-operation position, to the detection position, which is the position where the operation is detected, is the stop button 126 ( It is larger than the third detection load, which is the operating load required to move 129) from the initial position to the detection position. Further, the third detected load is 50% or less of the first detected load.

Further, the operating load required to move the start lever 990 from the initial position, which is the non-operated position, to the maximum position, which is the position where the amount of operation with respect to the initial position is maximum (maximum load of the start lever 990: about). 3.0N) (first maximum load) is the operating load required to move the stop button 126 (129) from the initial position to the maximum position (maximum load of the stop button 126 (129): about 1.4N) ( The value is larger than the third maximum load). In other words, the first maximum load, which is the operating load required to move the start lever 990 from the initial position, which is the non-operated position, to the maximum position, which is the position where the amount of operation with respect to the initial position is maximum, is It is larger than the third maximum load, which is the operating load required to move the stop button 126 (129) from the initial position to the maximum position. Further, the third maximum load is 50% or less of the first maximum load.

The start lever 990 is operated when executing the winning combination lottery, and the player may operate it powerfully with expectation. Therefore, by giving the start lever 990 a feeling of operation that is heavier than that of the stop button 126 (129), it is possible to provide the player with a feeling of operation that is responsive and comfortable. As a result, the operation feeling of the start lever 990 becomes suitable for the player, and the playability is improved. Further, when the stop button 126 (129) is operated, a light and comfortable operation feeling can be provided to the player.

Further, the detected load (about 1.5N) of the start lever 990 is larger than the detected load (about 0.8N) (second detected load) of the MAX bet button 23. Further, the maximum load (about 3.0N) of the start lever 990 is larger than the maximum load (about 1.6N) (second maximum load) of the MAX bet button 23. In this way, by giving the start lever 990 a feeling of operation that is heavier than that of the MAX bet button 23, it is possible to provide the player with a feeling of operation that is responsive and comfortable. As a result, the operation feeling of the start lever 990 becomes suitable for the player, and the playability is improved.
The first detected load, the second detected load, and the third detected load are preset and immutable operating loads. Further, the first maximum load, the second maximum load, and the third maximum load are preset and immutable operating loads.

Further, as shown in FIG. 20, the operating load (detected load and maximum load) of the stop button 126 (129) is smaller than the operating load (detected load and maximum load) of the MAX bet button 23. The stop button 126 (129) is a button that must be operated in plurality according to the number of rotating reels for each game. By setting the operating load of the stop button 126 (129) to be smaller than the operating load of the MAX bet button 23, the player can obtain a light and comfortable operating feeling with respect to the operation of the stop button 126 (129). At the same time, it is possible to press all the stop buttons 126 (129) at a good tempo. As a result, the player can comfortably play the game, and the playability is improved. Further, since the operating load of the frequently used stop button 126 (129) is set to be small, the accumulation of fatigue of the player is reduced and the playability is improved.

Further, the MAX bet button 23 is a button used for an operation for starting a game, and is a button that is often operated with a strong force because an operation such as hitting from above is possible. By setting the operating load of the MAX bet button 23 to be larger than the operating load of the stop button 126 (129), the player can obtain an operation feeling that is appropriately pressed, and the playability is improved. ..

Further, although not shown in FIG. 1, an effect button may be provided at an arbitrary position on the front door 12. The effect button is a button formed so as to be pushed from the front to the rear. The operating load (detected load and maximum load) of the effect button is larger than the operating load (detected load and maximum load) of the stop button 126 (129) and larger than the operating load (detected load and maximum load) of the MAX bet button 23. Larger or equivalent. For example, the effect button has a detected load of about 3.0 N and a maximum load of about 6.0 N. The effect button is operated less frequently than the stop button 126 (129) and the MAX bet button 23. In addition, when the effect button notifies the player that it is pleasing to the player, or when it is a game place for the player, the pressing operation for changing the mode of the effect becomes effective, so that the mood is felt. It tends to be operated with a strong force by an uplifted player. Therefore, the operating load of the effect button is set to be larger than the operating load of the stop button 126 (129) and equal to or greater than the operating load of the MAX bet button 23, so that the player can perform a heavy and heavy operation. Feeling can be obtained and playability is improved. Further, the effect button may be a button (up and down direction effect button) formed so as to be pushed downward from above. The vertical direction effect button is set to have a smaller operating load (detected load and maximum load) than the MAX bet button 23 having the same operating direction, and the operating load is the same as that of the stop button 126 (129). Alternatively, the value is smaller than the stop button 126 (129). The vertical effect button has, for example, a detected load of about 0.6 N and a maximum load of about 1.2 N. Since the vertical direction effect button may be repeatedly hit by the player when it becomes an opportunity to improve the interest, the operation load is set to be small so that the repeated hits can be facilitated. Further, since the operation in the vertical direction is easier to hit repeatedly than in the front-back direction, the operation is performed in the vertical direction.

In the start lever 990 according to the present embodiment, the tilt distance or tilt angle of the operation unit 991 from the initial position to the detection position is 50% or less of the tilt distance or tilt angle of the operation unit 991 from the initial position to the maximum position. It is a value. Further, the detected load of the start lever 990 is 50% or less of the maximum load. With such a configuration, it is possible to improve the sensitivity of detecting the operation and to provide the player with a feeling of operation that is responsive when the operation is further operated after the operation is detected. That is, it is possible to achieve both the improvement of the detection sensitivity and the contradictory effect of providing a feeling of operation with a feeling of pressure. As a result, playability is improved.
Further, from the viewpoint of suppressing false detection, the tilt distance and tilt angle of the operation unit 991 from the initial position to the detection position are set to 20% to 50% of the tilt distance and tilt angle of the operation unit 991 from the initial position to the maximum position. As a value, it is more desirable that the detected load of the start lever 990 is a value of 20% to 50% of the maximum load. If you want to further improve the detection sensitivity, the tilt distance and tilt angle of the operation unit 991 from the initial position to the detection position with respect to the tilt distance and tilt angle of the operation unit 991 from the initial position to the maximum position, and the start lever 990. The detected load with respect to the maximum load of may be a value of 20% to 48%, and further may be a value of 25% to 45%.

Further, the stop button 126 (129) according to the present embodiment has an ON stroke of 50% or less of the full stroke and a detected load of 50% or less of the maximum load. Further, the MAX bet button 23 according to the present embodiment has an ON stroke of 50% or less of the full stroke and a detected load of 50% or less of the maximum load. For this reason, the stop button 126 (129) and the MAX bet button 23 also improve the sensitivity at which the operation is detected, and provide the player with a feeling of pressing when the operation is further operated after the operation is detected. can do. As a result, playability is improved.
Further, from the viewpoint of suppressing false detection, the ON stroke of the stop button 126 (129) is set to a value of 20% to 50% of the full stroke, and the detected load of the stop button 126 (129) is set to 20% to 50% of the maximum load. It is more desirable to set it as a value. Further, when it is desired to further improve the detection sensitivity, the ON stroke for the full stroke of the stop button 126 (129) and the detection load for the maximum load of the stop button 126 (129) may be set to a value of 20% to 48%. Further, the value may be 20% to 45%.
Further, from the viewpoint of suppressing false detection, the ON stroke of the MAX bet button 23 should be set to a value of 20% to 50% of the full stroke, and the detected load of the MAX bet button 23 should be set to a value of 20% to 50% of the maximum load. Is more desirable. Further, when it is desired to further improve the detection sensitivity, the ON stroke for the full stroke of the MAX bet button 23 and the detected load for the maximum load of the MAX bet button 23 may be set to a value of 20% to 48%, and further 20%. It may be a value of ~ 45%.

In the slot machine of the present embodiment, the regular medal that can be used for the game is φ25 (diameter about 25 mm) and thickness about 1.6 mm. Further, in the following explanation, when the term "medal" is simply used, it basically means a regular medal. Further, as a medal that can be used in a game in another slot machine and has a diameter larger than that of a regular medal that can be used in the slot machine of the present embodiment, a medal having a diameter of φ30 (diameter of about 30 mm) is assumed. .. In the following description, the term "large diameter medal" basically means a medal having a diameter of 30 and a thickness of about 1.7 mm.
In the present invention, the regular medal and the large-diameter medal do not necessarily have to be φ25 and φ30 medals, respectively, and the present invention can be applied as long as the large-diameter medal is larger than the regular medal. Is.

The medal insertion unit 800 including the medal insertion slot 821 (medal insertion slot portion) will be described. As shown in FIG. 21, the medal insertion unit 800 includes a medal insertion unit 811, a selector 813 for selecting medals, a medal passage 815 for guiding medals inserted from the medal insertion unit 811 to the selector 813, and a sensor unit 817. , R chute 819, and.
The medal is inserted from the medal insertion slot 821 of the medal insertion unit 811, passes through the medal passage 815, and reaches the selector 813. Then, the selector 813 selects medals. Specifically, when the medal is a regular medal, the medal is swept toward the R shoot 819 and reaches the hopper unit through the R shoot 819. On the other hand, medals of a size different from the predetermined size, for example, medals smaller than the specified size medals or medals inserted at inappropriate timings are regarded as non-regular medals and are received from the medal payout port. It is guided to be discharged to 128.

The medal insertion portion 811 includes a medal insertion port 821, a medal restraint wall 822 (wall portion), and a medal guide portion 823, and is integrally formed of metal (for example, stainless steel or the like). The medal guide portion 823 is a portion for guiding the medal to the medal insertion slot 821, and is a groove having an arcuate cross section extending back and forth toward the medal insertion slot 821. Further, the medal restraining wall 822 collides the medals moved along the medal guide portion 823 to stop the movement of the medals in the front-rear direction, and guides the medals to be inserted from the medal insertion slot 821. The wall surface is facing the medal slot 821 side. Further, the medal restraint wall 822 is arranged slightly apart from the rear end of the medal guide portion 823 with a thickness of one medal. The medal insertion slot 821 is a left-right long slit-shaped hole (hole portion) formed between the medal guide portion 823 and the medal restraint wall 822. Then, the player moves the medal to the medal restraint wall 822 side along the medal guide portion 823, and releases the medal while the medal is in contact with the medal restraint wall 822, whereby the medal is inserted from the medal insertion slot 821. It is supposed to be done.

The medal slot 821 has a rectangular shape in a plan view, and the length (depth) of the short side (front-back direction) is slightly longer than the thickness of one regular medal, and the long side (long side (front-back direction)). The length (width) in the left-right direction is slightly longer than the diameter of the regular medal. Further, the length of the short side of the medal insertion slot 821 is shorter than the thickness of two regular medals. In addition, the length of the short side of the medal slot 821 is slightly longer than the thickness of one large-diameter medal, and the length of the long side is shorter than the diameter of one large-diameter medal. ing. Further, the length of the short side of the medal insertion slot 821 is shorter than the thickness of two large-diameter medals. In other words, the width of the medal slot 821 is longer than the diameter of the regular medal and shorter than the diameter of the large-diameter medal. Specifically, for example, it is about 28 mm to 29 mm.

Further, the medal restraint wall 822 constitutes the rear surface of the medal passage 825 on the insertion slot side that guides the medals inserted from the medal insertion slot 821 to the medal passage 815 (see FIG. 3). The wall surface of the medal restraint wall 822 and the rear surface of the medal passage 825 on the slot side are flush with each other. Further, the upper portion of the medal restraint wall 822 extends upward from the rear portion of the medal insertion slot 821. Further, the upper edge of the medal restraint wall 822 is located above the medal guide portion 823, so that the wall surface of the medal restraint wall 822 can be seen behind the medal guide portion 823 in front view. Further, the upper edge of the medal restraint wall 822 has a mountain shape in which the portion corresponding to the central portion of the medal insertion slot 821 is convex upward in the left-right direction.
The wall surface of the medal restraint wall 822 and the rear surface of the medal passage 825 on the insertion slot side do not have to be flush with each other. For example, the wall surface of the medal restraint wall 822 is behind the rear surface of the medal passage 825 on the insertion slot side. It may be formed so as to be located at. Further, the medal stop wall 822 and the rear surface of the medal passage 825 on the insertion slot side may be formed of different members.

The medals inserted from the medal insertion slot 821 pass through the medal passage 825 on the insertion slot side and reach the medal passage 815.
In the following, the length in the long side direction (direction corresponding to the radial direction of the medal) of the passage through which the medal passes, such as the medal passage 815 and the medal passage 825 on the insertion slot side, is referred to as "width". , The length in the short side direction (the direction corresponding to the thickness direction of the medal) is referred to as "height". Regarding the passage through which the medal passes, the surface facing the rear surface of the medal (the surface of the medal passing through the medal passage 815 facing the rear side, the same applies hereinafter) is referred to as the rear surface, and the front surface of the medal (the medal passing through the medal passage 815). The surface facing the front side, the same applies hereinafter) is referred to as the front surface, and the surface facing the side surface of the medal (the surface connecting the front surface and the rear surface of the passage) is referred to as a side surface.

As shown in FIGS. 22 and 29, the insertion slot side medal passage 825 has a linear shape from the top to the bottom, and the medals flow straight down from the top to the bottom. Further, the insertion port side medal passage 825 becomes narrower and lower in height from the upper entrance to the lower exit. Specifically, since the entrance of the medal passage 825 on the insertion port side corresponds to the medal insertion port 821, the width thereof is about 28 mm to 29 mm as described above. The width of the exit of the medal passage 825 on the insertion slot side is about 26 mm. The medal passage 825 on the insertion port side may be formed so that the width is narrowed substantially linearly from the entrance to the exit, and the width is widened only in the vicinity of the entrance, and the width of the other parts is about. It may be a constant linear shape at 26 mm. In addition, the height of the medal passage 825 on the slot side is longer than the thickness of one large-diameter medal in any part from the highest part to the lowest part, and shorter than the thickness of two regular medals. ing.

The lower portion of the medal passage 825 on the insertion slot side is formed by a square tubular protrusion 827 that projects downward from the lower surface of the medal insertion portion 811. Further, bosses 828 and 828 projecting downward from the lower surface of the medal insertion portion 811 are provided on the left front side and the right rear side of the square tubular protrusion 827, respectively. Further, the bosses 828 and 828 have screw holes. Further, a rectangular plate-shaped locking piece 829 is provided so as to project downward from the right front portion of the lower end surface of the square tubular protrusion 827.

The medal passage 815 is formed by a rail rear member 830 and a rail front member 831 (see FIGS. 21, 26, and 29). The rail rear member 830 constitutes the rear surface and both side surfaces of the medal passage 815. Further, the rail front member 831 constitutes the front surface of the medal passage 815.

The medal passage 815 is in a state where the entrance faces upward and the exit faces downward. Further, as shown in FIG. 23, in the medal passage 815, the medals entering from the entrance are guided to the left as they go downward, and the medals coming out from the first music section 815a. It is provided with a second curved portion 815b that guides the medal toward the left and a straight portion 815c that guides the medal coming out of the second curved portion 815b downward. As a result, the medal passage 815 has a crank shape. Further, the entrance and the exit of the medal passage 815 are arranged so as to be offset by one medal or more in the left-right direction of the medal passage 815. Since the medal passage 815 has a crank shape, it is prevented that foreign matter is inserted from the medal insertion slot 821 to the deep part of the medal passage 815 and the selector 813 to perform a goto action.

The rail front member 831 is formed of a transparent synthetic resin. As shown in FIGS. 25 and 26, the rail front member 831 has a plate shape, and its outer shape substantially matches the outer shape of the rail rear member 830 when viewed from the front. Further, on the left side of the upper end portion of the rail front member 831, a protruding portion 835 projecting forward is provided. The protruding portion 835 is provided with a notch portion notched from the front to the rear, and this notch portion serves as a screw insertion portion 835a through which a screw is inserted from the lower side to the upper side. Further, on the right side of the upper end portion of the rail front member 831, a notch portion 836 notched in a rectangular cross section from the front to the rear is formed. Further, screw insertion holes 837, 837 for inserting screws and protrusions 838, 838 protruding rearward are provided at both left and right ends of the lower end portion of the rail front member 831, respectively. Further, the back surface of the rail front member 831 is flat.

As shown in FIGS. 23 and 24, the rail rear member 830 has a back plate 840 forming the rear surface of the medal passage 815, a right side wall 841 forming the right side surface of the medal passage 815, and a left side surface of the medal passage 815. The left side wall 842 to be formed and the flange portions 844 and 844 protruding outward in the left-right direction from the lower end portion of the right side wall 841 or the left side wall 842 are provided. Further, the rail rear member 830 is integrally formed of metal (for example, stainless steel or the like). The back plate 840 has a plate shape, and the plate surface is oriented in the front-rear direction. Further, the back plate 840 has a shape that follows the shape of the above-mentioned medal passage 815 (first curved portion 815a, second curved portion 815b, straight portion 815c) when viewed from the front. Further, the right side wall 841 and the left side wall 842 are formed so as to project forward along the right end edge or the left end edge of the back plate 840. Further, the flange portions 844 and 844 are integrally formed with the lower end portion of the right side wall 841 or the left side wall 842. Further, the front surface of the flange portions 844 and 844, the front end surface of the right side wall 841 and the front end surface of the left side wall 842 are flush with each other. Further, each of the left and right flange portions 844 and 844 is provided with screw insertion holes 845 and 845 for inserting screws and protrusion insertion holes 846 and 846 into which the protrusion 838 of the rail front member 831 is inserted. ..

The rail rear member 830 and the rail front member 831 have the back surface of the rail front member 831 in contact with the front surface of the flange portions 844 and 844 of the rail rear member 830, the front end surface of the right side wall 841, and the front end surface of the left side wall 842. In a state where the protrusions 838 and 838 are inserted into the protrusion insertion holes 846 and 846, they are integrated by screwing described later. A medal passage 815 is formed as a space surrounded by the back plate 840 of the rail rear member 830, the right side wall 841, the left side wall 842, and the rail front member 831.

Further, on both side portions of the back plate 840, convex portions 850 and 850 projecting forward are formed along the extending direction of the medal passage 815. The medal flowing down the medal passage 815 is adapted to flow down the medal passage 815 in a state where it can always contact both the left and right convex portions 850 and 850. In other words, the medal flowing down the medal passage 815 does not come into contact with the concave portion formed between the left and right convex portions 850 and 850.

Further, the back plate 840 of the rail rear member 830 is provided with a rectangular opening 860 that is long on the left and right. Further, a boss 864 projecting rearward is provided at a position above the opening 860 on the back surface of the back plate 840 of the rail rear member 830. Further, the boss 864 has a screw hole. Further, on the right side of the upper end portion of the back surface of the back plate 840, a protruding portion 866 protruding rearward is provided. The protruding portion 866 is provided with a notch portion notched from the rear to the front, and this notch portion serves as a screw insertion portion 866a through which a screw is inserted from the lower side to the upper side. Further, an L-shaped locking portion 868 in a plan view is provided at the upper end of the left side wall 842 of the rail rear member 830 so as to project forward.

As shown in FIG. 26, the rail rear member 830 and the rail front member 831 have a screw inserted into the screw insertion portion 866a of the rail rear member 830 and a screw inserted into the screw insertion portion 835a of the rail front member 831. , It is integrated with the medal insertion section 811 by being screwed into the screw holes of the two bosses 828 and 828 of the medal insertion section 811. Further, the locking portion 868 of the rail rear member 830 is locked to the side surface of the square tubular protrusion 827 of the medal insertion portion 811, and the locking piece 829 of the medal insertion portion 811 is cut by the rail front member 831. By being locked to the notch 836, the rail rear member 830 and the rail front member 831 are positioned with respect to the medal insertion portion 811. Further, the upper end surfaces of the rail rear member 830 and the rail front member 831 are in contact with the lower end surfaces of the square tubular protrusion 827 of the medal insertion portion 811. As a result, the medal passage 825 on the slot side and the medal passage 815 are in communication with each other.
The upper end surfaces of the rail rear member 830 and the rail front member 831 and the lower end surface of the medal insertion portion 811 do not necessarily have to be in contact with each other, and a predetermined gap is provided between both end surfaces. May be in close proximity.

The length from the exit of the medal passage 825 on the slot side to the upper end of the medal restraint wall 822 is shorter than the diameter of one medal (25 mm). In other words, the length from the boundary between the medal passage 825 formed on the medal insertion portion 811 and the medal passage 815 formed by other members to the upper end of the medal restraint wall 822 is larger than the diameter of one medal. It's getting shorter. That is, in the gaming machine of the present embodiment, the medal is not caught at the joint between the medal passage 815 and the medal passage 825 on the insertion slot side, but the medal can be caught at the joint. Even if the medal is caught in the joint, the upper end of the medal is located above the upper edge of the medal restraint wall 822, and the player can touch the rear surface of the medal. .. As a result, when the medal is caught, the medal can be grasped and easily pulled out.
The rear surface or the front surface of the medal passage 815 does not necessarily have to be formed by a member separate from the medal insertion portion 811. That is, for example, the rail rear member 830 or the rail front member 831 is integrally formed with the medal insertion portion 811, and the rail front member 831 or the rail rear member 830 as a cover member is attached to the medal passage 815. May be formed. Further, the medal passage 815 (rail rear member 830 and rail front member 831) may not exist, and the insertion port side medal passage 825 may be directly connected to the selector 813.

As shown in FIGS. 23 and 24, the sensor unit 817 includes a sensor 880 and a movable piece 881 (movable member) (see FIG. 21). The sensor 880 is an electronic circuit whose main element is a photo interrupter. The sensor 880 detects the operation of the movable piece 881 and outputs a detection signal.

The movable piece 881 includes a medal contact portion 882 with which the medals come into contact, and is formed of a black synthetic resin. The sensor 880 is fixed to the rail rear member 830 by screwing, and the movable piece 881 is urged by a spring (elastic member) so that the medal contact portion 882 of the movable piece 881 projects from the opening 860 into the medal passage 815. Has been done. Then, when the medal or the like passes through the medal passage 815, the movable piece 881 is pressed by the medal or the like that comes into contact with the medal contact portion 882, and when the pressing by the medal or the like is released, the urging force of the spring causes the movable piece 881. The medal contact portion 882 returns to the state of protruding into the medal passage 815. Further, the movable piece 881 is provided with a light-shielding plate that projects rearward, and when the movable piece 881 is pressed, the sensor 880 detects the movement of the light-shielding plate, and the detection indicating that the movable piece 881 is pressed. The sensor 880 is designed to emit a signal.

The detection signal from the sensor 880 is sent to the above-mentioned board unit (main control board) via the wiring connected to the sensor 880. Then, when the detection signal is continuously sent for a predetermined time (for example, about 1 second), the board unit determines that there is a possibility that a goto action is being performed, and emits a sound through a speaker or the like. It is designed to notify the abnormality. The sensor unit 817 does not detect an abnormality such as a goto action, and may, for example, count the number of medals passing through the medal passage 815. Further, the sensor 880 may use a sensor other than the photo interrupter as long as it can detect the operation of the movable piece 881.

As shown in FIG. 27, the rail rear member 830, the rail front member 831, and the selector 813 have screws inserted into the screw insertion holes 845 and 845 of the rail rear member 830 and the screw insertion holes 837 and 837 of the rail front member 831. The 883 and 883 are integrated by being screwed into a screw hole (not shown) provided on the upper part of the selector.

The selector 813 includes a medal selection unit 885 that selects medals, and a selector-side medal passage 886 that guides medals to the medal selection unit 885. The selector-side medal passage 886 is a passage through which medals pass. The medal passage 886 on the selector side is a passage curved in the height direction (the thickness direction of the medal), but the height is slightly higher only at the entrance portion, and the height is almost the entire passage excluding the entrance portion. Is constant. Further, the height of the medal passage 886 on the selector side is less than the thickness of two medals at any portion. Further, the height of the selector side medal passage 886 is higher than the height of the communicating medal passage 815. Specifically, the height of the medal passage 815 is about 2.3 mm, while the height of the selector side medal passage 886 is about 3.1 mm. Further, the width of the medal passage 886 on the selector side is slightly longer than the diameter of the regular medal in any portion, and is shorter than the diameter of the large-diameter medal. In other words, the selector side medal passage 886 has a width at which large-diameter medals cannot flow down. That is, the selector 813 cannot select and play a large-diameter medal.

The medal sorting unit 885 includes a medal sorting mechanism 888 and a medal discharging unit 889 arranged behind the medal sorting mechanism 888. The medal sorting mechanism 888 supports the medals, which are predetermined medals and are inserted at appropriate timings, so as not to fall from the medal ejection unit 889, and guides the medals toward the hopper unit. On the other hand, the medal selection mechanism 888 is designed to drop medals having a size different from the predetermined size or non-regular medals such as medals inserted at inappropriate timings toward the medal ejection unit 889. .. Then, the medals dropped from the medal ejection unit 889 are ejected from the medal payout port to the medal tray 128. As the mechanism for selecting medals in this way, a conventional selector may be used.

Next, in the gaming machine of the present embodiment, a case where a large-diameter medal M having a diameter of 30 is inserted into the medal insertion slot 821 will be described with reference to FIGS. 28 and 29. Note that FIG. 29 is a diagram showing a rail rear member 830 and a rail front member 831 added to the cross-sectional view taken along the line AA of FIG. 28.
Since the width of the medal insertion slot 821 is shorter than the diameter of the large diameter medal M, the large diameter medal M is caught in the medal insertion slot 821. Specifically, the left and right ends (the portions indicated by points P and Q in FIG. 28) of the lower portion of the side surface of the large-diameter medal M abut on the edge (short side) of the medal insertion slot 821, whereby the large-diameter medal M is hooked on the medal slot 821. In other words, the medal slot 821 is formed to a size that does not flow inside the game machine because medals of a size that cannot be selected by the selector 813 are caught.

Further, the lower end of the large-diameter medal M is inserted into the medal insertion slot 821 in a state of being hung on the medal insertion slot 821, and the lower end of the front surface of the large-diameter medal M is from the front edge of the medal insertion slot 821. Is also located below. In other words, the lower end of the front surface of the large diameter medal M is located below the upper end edge of the front surface of the insertion slot side medal passage 825, and the lower end portion of the front surface of the large diameter medal M is the insertion opening side medal passage 825. It is covered in the front of the. Specifically, the distance T1 from the lower end of the large-diameter medal M to the front edge (medal guide portion 823) of the medal insertion slot 821 is 1.5 mm or more, and the lower end of the front surface of the large-diameter medal M is It is located 1.5 mm or more below the front edge of the medal insertion slot 821. The region 1.5 mm from the lower end of the large-diameter medal M is covered with the front surface of the medal passage 825 on the insertion slot side.
In this way, since the lower end of the large-diameter medal M is inserted into the medal insertion slot 821, it is possible to prevent the large-diameter medal M hanging from the medal insertion slot 821 from falling over. The large diameter medal M can be stably supported. In the above example, T1 is 1.5 mm or more, but it is preferably 0.5 mm or more and 5.0 mm or less.

Further, in the gaming machine of the present embodiment, the large-diameter medal M in the state of being hung on the medal insertion slot 821 has the front surface of the large-diameter medal passage 825 in the vicinity of the portions indicated by the points P and Q in FIG. 28. It is in contact with the front of the. That is, the side surface of the large-diameter medal M can abut on the medal insertion slot 821 at points P and Q, and the front surface thereof can abut on the medal insertion slot 821 near the points P and Q. ing. In other words, at two points separated from each other to the left and right (distanced in the direction of the surface of the medal), the side surface of the large-diameter medal M abuts on the medal insertion slot 821, and the front surface thereof inserts medals in the vicinity of each of the two points. It is in a state of being in contact with the mouth 821, or in a state of being in close contact with the mouth. In other words, the large-diameter medal M is in a state in which two points separated from each other on the left and right are inserted into the upward-viewing U-shaped notches formed separately on the left and right of the medal insertion slot 821. There is. With such a configuration, the side surface and the front surface of the large-diameter medal M inserted into the medal insertion slot 821 can be stably supported, and the large-diameter medal M can be more reliably prevented from falling.

By inserting the lower end portion of the large-diameter medal M into the medal insertion slot 821 in this way, the large-diameter medal M is hooked on the medal insertion slot 821 in an upright state. In other words, the large-diameter medal M is hung on the medal insertion slot 821 with both sides facing the front-rear direction. Further, at this time, the rear surface of the large-diameter medal M is in a state of being close to or in contact with the medal restraint wall 822.

Further, the curvature of the medal guide portion 823 at the rear end thereof is equal to or greater than the curvature of the large-diameter medal M. Therefore, in the large-diameter medal M whose lower end is inserted into the medal insertion slot 821, the lower end on the front side is firmly supported along the circumferential direction of the large-diameter medal M and is inserted into the medal insertion slot 821 in a stable state. It is designed to be caught.

Further, the lower end of the large-diameter medal M is positioned above the lower end of the medal passage 825 on the insertion port side when it is hung on the medal insertion slot 821. That is, the lower end of the large-diameter medal M does not reach the boundary (connection portion) between the insertion port side medal passage 825 formed in the medal insertion portion 811 and the medal passage 815 communicating therewith. In this way, the large-diameter medal M does not reach the boundary between the medal insertion portion 811 provided with the insertion port side medal passage 825 and the other members forming the medal passage 815, so that the large-diameter medal M does not reach the boundary. When the medal is inserted into the medal insertion slot 821, the large-diameter medal M does not hit the boundary and float, and is surely caught on the edge of the medal insertion slot 821. Therefore, since the large-diameter medal M that has been erroneously or intentionally inserted is stably supported, the large-diameter medal can be easily taken out.

Further, the large-diameter medal M is such that the lower end of the large-diameter medal M is located above the sensor 880, the sensor provided in the selector 813, and other sensors that detect medals when the medal slot 821 is hung. The large-diameter medal M does not reach these sensors. Therefore, when the large-diameter medal M is erroneously inserted and hangs on the medal insertion slot 821, the sensor 880 reacts and mistakenly determines that a goto action is being performed, or the medal is inserted. It is possible to prevent erroneous judgment.

As described above, the medal restraint wall 822 extends upward from the rear part of the medal insertion slot 821. Therefore, in the state where the large-diameter medal M is hung on the medal insertion slot 821, at least a part of its rear surface is covered with the medal restraint wall 822. Further, the upper end of the medal restraint wall 822 is located above the center of the rear surface of the large-diameter medal M hanging on the medal insertion slot 821 (center in the vertical direction: shown by the alternate long and short dash line C in FIG. 28). It is formed. In other words, in the gaming machine of the present embodiment, the medal blocking wall 822 covers an area of 15 mm or more from the lower end of the rear surface of the large-diameter medal M. In this way, when the upper end of the medal restraint wall 822 is formed so as to be located above the center of the large-diameter medal M in the vertical direction, the large-diameter medal M is likely to tilt backward. Since the medal restraining wall 822 is supported above the center of the large-diameter medal M in the vertical direction, the large-diameter medal M is prevented from falling backward, and the large-diameter medal M is stably supported. Therefore, the posture of the large-diameter medal M is stable, and the large-diameter medal M can be easily taken out.
It should be noted that the upper end of the medal restraint wall 822 may not be formed so as to be located exactly above the center of the rear surface of the large-diameter medal M. That is, for example, the position of the upper end of the medal restraint wall 822 in the vertical direction may be formed so as to be within ± 1.5 mm from the center of the large diameter medal M in the vertical direction. In other words, the position of the upper end of the medal restraint wall 822 in the vertical direction may be formed so as to be the position of the central portion in the vertical direction of the large-diameter medal M. Even with such a configuration, the posture of the large-diameter medal M can be stabilized.

Further, the medal restraint wall 822 is formed so that the upper end of the medal restraint wall 822 is located below the upper end of the large diameter medal M when the large diameter medal M is hung on the medal insertion slot 821. As a result, in this state, the player can touch the rear surface of the large-diameter medal M. In other words, the large-diameter medal M is in a state in which a part of the rear surface of the large-diameter medal M is exposed when viewed from the back side of the medal restraint wall 822 in a state of being hung on the medal insertion slot 821. By being able to touch the rear surface of the large-diameter medal M in this way, it is possible to touch the front and rear surfaces of the large-diameter medal M hanging on the medal insertion slot 821 and pinch the large-diameter medal M. , Can be easily taken out. If it is possible to touch the rear surface of the large-diameter medal M as much as possible, the large-diameter medal M can be pinched. Therefore, the upper end of the medal restraint wall 822 does not necessarily have a large diameter hanging on the medal insertion slot 821. It does not have to be formed so as to be located below the upper end of the medal M. However, the amount T2 of the upper end of the large-diameter medal M hanging on the medal insertion slot 821 from the upper end of the medal restraint wall 822 is preferably 3 mm or more, and preferably 6 mm or more. More preferred. According to such a configuration, it becomes easy to pinch the large-diameter medal M, and the large-diameter medal M can be taken out more easily.
The positions of the upper end of the large-diameter medal M and the upper end of the medal restraint wall 822 in the left-right direction do not have to be the same. Further, the positions of the lower end of the large-diameter medal M and the lower end (the bottommost portion of the groove) at the rear end of the medal guide portion 823 do not have to be the same in the left-right direction.

20a 1st reel 20b 2nd reel 20c 3rd reel 20d 4th reel 129a 1st stop button (1st stop button)
129b 2nd stop button (2nd stop button)
129c 3rd stop button (3rd stop button)
129d 4th stop button (4th stop button)
984a Operation surface

Claims (2)

A bet button that can be pressed, a start lever that can be tilted, a stop button that can be pressed, a medal insertion slot for inserting a φ25 medal, and an upper part from the rear of this medal insertion slot. With a wall that extends to
It is a game machine that can play games using φ25 medals.
The operating load required to move the start lever from the initial position, which is the non-operated position, to the maximum position, which is the position where the amount of operation with respect to the initial position is maximum, is defined as the start lever maximum load.
The operating load required to move the bet button from the initial position to the maximum position is defined as the maximum bet button load.
Assuming that the operation load required to move the stop button from the initial position to the detection position where the operation is detected is the stop button detection load.
The maximum load of the start lever is larger than the maximum load of the bet button, and the maximum load of the bet button is larger than the detected load of the stop button.
The opening width of the medal insertion slot is formed to be shorter than the diameter of the medal of φ30.
In the wall portion, when the φ30 medal is hung on the medal insertion slot, the upper end of the wall portion is below the upper end of the φ30 medal and above the center of the φ30 medal in the vertical direction. Formed to be located,
A gaming machine characterized in that a player can touch a surface of a φ30 medal facing the wall side in the above state. A bet button that can be pressed, a start lever that can be tilted, a stop button that can be pressed, a medal insertion slot for inserting a φ25 medal, and an upper part from the rear of this medal insertion slot. With a wall that extends to
It is a game machine that can play games using φ25 medals.
The operating load required to move the start lever from the initial position, which is the non-operated position, to the maximum position, which is the position where the amount of operation with respect to the initial position is maximum, is defined as the start lever maximum load.
The operating load required to move the bet button from the initial position to the maximum position is defined as the maximum bet button load.
Assuming that the operation load required to move the stop button from the initial position to the detection position where the operation is detected is the stop button detection load.
The maximum load of the start lever is larger than the maximum load of the bet button, and the maximum load of the bet button is larger than the detected load of the stop button.
The opening width of the medal insertion slot is formed to be shorter than the diameter of the medal of φ30.
The wall portion is formed so that the position of the upper end of the wall portion in the vertical direction becomes the position of the central portion in the vertical direction of the φ30 medal when the φ30 medal is hung on the medal insertion slot portion. And
A gaming machine characterized in that a player can touch a surface of a φ30 medal facing the wall side in the above state.

Images