JP7396860B2 - gaming machine - Google Patents

Description

The present invention relates to a gaming machine.

2. Description of the Related Art Slot machines are known as gaming machines that are equipped with a plurality of reels on which a plurality of symbols are arranged, a start lever, a stop button, and the like. In a slot machine, when it is detected that a start lever has been operated after game media (medals) have been bet, rotation of a plurality of reels starts. Further, when it is detected that a stop button provided corresponding to each reel has been operated, the rotation of the reel corresponding to the stop button is stopped. At this time, when a symbol combination corresponding to a winning combination is displayed on the active line to be paid out, a gaming benefit is given to the player, such as a predetermined number of medals being paid out.

Furthermore, as a game machine, a pachinko game machine equipped with a game board, a firing device, and the like is known. In a pachinko game machine, a game medium (game ball) is fired into a game area provided on the front of the game board, and based on the game ball entering a prize opening provided in the game area, a player is given a game. The above benefits will be granted.
Such a gaming machine includes a lighting device, and the lighting device includes a board on which a plurality of LEDs are arranged. The gaming machine disclosed in Patent Document 1 includes an LED board for illuminating the reels.

Japanese Patent Application Publication No. 2019-058552

By the way, in gaming machines, it is required to suppress deterioration in quality.

The present invention has been made in view of the above circumstances, and an object of the present invention is to provide a gaming machine in which deterioration in quality is suppressed.

In order to solve the above problems, the gaming machine of the present invention includes:
A board (e.g., board 720) on which a connector (e.g., connector 721) is arranged, and a case (e.g., case 710) that protects the board,
A first gap (for example, about 0.5 mm) is defined as a gap between an end surface of the substrate (for example, the outer peripheral surface) and an inner surface of the side wall of the case (for example, the side plate 712), and
A second gap (for example, approx. 1mm), then
The second gap is larger than the first gap (for example, see paragraphs [0137], [0138], [0140], [0142], and [0149]).
With this configuration, it is possible to prevent the connector from being deformed or damaged, and from coming off the board. Thereby, deterioration in the quality of the gaming machine can be suppressed (for example, paragraph [0150]).
According to such a configuration, it is possible to provide a gaming machine in which deterioration in quality is suppressed.

Furthermore, the gaming machine of the present invention includes:
A board on which a light source is arranged,
a heat dissipation sheet having thermal conductivity and in contact with a surface of the substrate opposite to the surface on which the light source is disposed;
a metal heat sink in contact with the heat sink;
It is characterized by having the following.
According to such a configuration, a substrate on which a light source is disposed, a heat dissipation sheet having thermal conductivity that contacts a surface of the substrate opposite to a surface on which the light source is disposed, and a heat dissipation sheet. Since it is equipped with a metal heat dissipation plate that comes into contact with the LED board, even if the LED is placed on the LED board and the amount of heat generated from the LED increases, the heat can be dissipated quickly and the LED will not be damaged. be able to. Thereby, it is possible to suppress the quality deterioration of the gaming machine.

Further, in the configuration of the present invention, the substrate is provided with a through hole, and the heat dissipation sheet is arranged at a position corresponding to the through hole.

According to this configuration, the board is provided with a through hole, and the heat dissipation sheet is arranged at a position corresponding to the through hole, so that short circuit due to direct contact between the LED board and the heat dissipation plate is avoided. At the same time, the heat of the LEDs on the front surface of the substrate can be more easily transferred to the back surface side of the substrate (toward the heat dissipation sheet side). This further enhances the heat dissipation effect and further reduces the risk of damage to the LED.

According to the gaming machine of the present invention, deterioration in quality can be suppressed.

1 is a perspective view showing an example of a gaming machine according to a first embodiment of the present invention. It is a view of the design member seen from the front side. It is a schematic diagram showing a part of the upper door seen from the left side. It is a schematic diagram which shows a part of upper door seen from the left side, and is a figure which shows a modification. It is a perspective view showing an example of a gaming machine according to a second embodiment of the present invention. It is a diagram seen from the front side of the game board. It is a view of the design member seen from the front side. 8 is a schematic side view showing the design member as seen from the P direction shown in FIG. 7. FIG. 9 is a schematic side view of the design member as seen from the Q direction shown in FIG. 8. FIG. This figure shows a sub-board unit that can be used in the gaming machine of the present invention, in which (a) is a view seen from the back side, and (b) is a schematic cross-sectional view taken along the line AA shown in (a). be. It is a view (plan view) of the sub-board seen from the back side. The same figure shows the volume adjustment switch, in which (a) is a view (plan view) seen from the back side, and (b) is a view of the housing of the volume adjustment switch seen from the back side. 10A is a schematic cross-sectional view taken along the line BB shown in FIG. 10(a). It is a perspective view of the volume adjustment switch seen from the back side. FIG. 3 is a view (plan view) of the volume adjustment switch as seen from the back side. 1 is a perspective view from the front showing a liquid crystal unit that can be used in the gaming machine of the present invention. It is an exploded perspective view of the same. It is a perspective view of the liquid crystal module of the liquid crystal unit seen from the back side. FIG. 3 is a diagram (plan view) of the liquid crystal control board of the liquid crystal unit as viewed from the back side. It is a side view of the liquid crystal control board in the same embodiment. FIG. 3 is a diagram showing the same liquid crystal control board as viewed from the back side, showing a state in which wiring is connected to the connector. FIG. 3 is a view of the same liquid crystal control board seen from the back side, showing a mounting-prohibited area. FIG. 3 is a diagram (plan view) of the liquid crystal control board seen from the rear side. An example of the configuration of a sub-board unit of a gaming machine according to the present invention is shown, in which (a) is a schematic diagram (plan view) seen from the back side, and (b) is a VV line shown in (a). FIG. 3(c) is a schematic sectional view (plan view) of the sub-board viewed from the back side. 2 is a schematic diagram (plan view) of the sub-board unit viewed from the rear side, in which (a) shows a state where the opening of the connector and the end of the case are aligned, and (b) FIG. 6 is a diagram showing a modification of (a), and (c) is a diagram showing a case where a male connector is connected to the state of (b). FIG. 3 is a schematic diagram (plan view) of the sub-board unit viewed from the rear side, and is a diagram showing another configuration example. FIG. 3 is a schematic diagram (plan view) of the sub-board unit viewed from the rear side, and is a diagram showing another configuration example. It is a schematic diagram (plan view) of the sub-board unit seen from the rear side, showing another configuration example, and (a) is a diagram showing a state where there is no case directly above the connector. (b) is a diagram showing a modification of (a). FIG. 3 is a schematic diagram (plan view) of the sub-board unit viewed from the rear side, and is a diagram showing another configuration example. FIG. 4 is a diagram showing the surface of the wiring means that can be used in the game machine of the present invention, on the side facing the board. This shows another example of the sub-board unit that can be used in the gaming machine of the present invention, in which (a) is a view seen from the back side, and (b) is a view taken along the U-U line shown in (a). It is a schematic sectional view. 31(a) is an enlarged view of the S portion in FIG. 31(a), and FIG. 32(b) is a schematic sectional view taken along the line WW shown in FIG. 32(a). 31A is a schematic cross-sectional view taken along the line TT shown in FIG. 31(a). 14 is a diagram showing a modification of the schematic cross-sectional view of the sub-board shown in FIG. 13. FIG. This shows a gaming machine according to a third embodiment of the present invention, in which (a) is a front view of the casing with the front door removed, and (b) is a view of the main back box board unit and FIG. 3 is an exploded perspective view of the bracket, seen from the front side. It is a diagram of the main back box board unit seen from the front side. 36, (a) is a schematic sectional view taken along the line CC shown in FIG. 36, and (b) is a schematic sectional view taken along the line DD shown in FIG. 36. It is a view of the main back box board unit seen from the back side. It is a perspective view of the case of the main back box board unit seen from the back side. 38, (a) is a schematic cross-sectional view taken along the line HH shown in FIG. 38, and (b) is a schematic cross-sectional view taken along the line II shown in FIG. 38. This shows a gaming machine according to a fourth embodiment of the present invention, in which (a) is a perspective view of a liquid crystal display device and a reel unit seen from the front side, and (b) is a perspective view of a liquid crystal display device and a reel unit. It is a perspective view seen from the back side. FIG. 2 is an exploded perspective view of the lighting board unit and its peripheral parts, as seen from the front side. It is a perspective view of the heat dissipation plate of the lighting board unit seen from the front side. It is an exploded perspective view seen from the front side, explaining how heat is transmitted in the lighting board unit. It is a front view of the upper door showing a gaming machine according to a fifth embodiment of the present invention. FIG. 3 is a sectional view of the liquid crystal display and the decorative member viewed from above. This figure shows a game machine according to a sixth embodiment of the present invention, and is a view of the game board seen from the front side. It is a front view of the same gaming machine. 39 is a schematic cross-sectional view taken along line AA shown in FIG. 38. FIG. This figure shows a gaming machine according to a sixth embodiment of the present invention, and is a view of the board viewed from a direction perpendicular to the board surface.

(First embodiment)
Hereinafter, a first embodiment of the present invention will be described with reference to the drawings. In the first embodiment, a slot machine, which is one type of gaming machine, will be described, but other gaming machines may be used. In the following explanation, "front and rear" basically means that when a player is on the front side of the slot machine, the player side is the "front" and the slot machine side is the "rear", and "up and down" means the slot machine. The top side of the machine means "top", the bottom side means "bottom", and "left and right" means that the left hand side of the player playing the slot machine means "left", and the right hand side means "right".
Note that within the scope of the present invention, it is possible to freely combine each of the embodiments, to modify any component of each embodiment, or to omit any component of each embodiment. .

As shown in FIG. 1, the slot machine (gaming machine) 100 of the present invention includes a box-shaped housing 111 that is open on the front side that faces the player, and the front opening of the housing 111 that can be opened and closed. A front door 112 is provided. The housing 111 houses a reel unit 130 in which a rotatable first reel 131, a second reel 132, and a third reel 133 are unitized, a hopper device for dispensing medals, and the like. Further, the front door 112 is divided into an upper door 112a and a lower door 112b, and each of the upper door 112a and the lower door 112b can be opened and closed with respect to the housing 111.

The upper door 112a is provided with a liquid crystal display 113, a speaker 114, and other performance devices, and a display window 115. On the liquid crystal display 113, images for various effects (videos, still images) are displayed. The speaker 114 outputs various effects sounds (music, sound effects, voices, etc.). In addition to the liquid crystal display 113 and the speaker 114, the display device may include an illumination device (lighting device) such as a lamp (LED), a movable accessory that can be operated by an actuator, etc.

At the back of the display window 115, the reel unit 130 is arranged so that a part of the reel unit 130 is visible from outside the display window 115. On the outer peripheral surfaces of the first reel 131, second reel 132, and third reel 133, a plurality of types of symbols are arranged in a line along the circumferential direction, and when each reel 131, 132, 133 stops, a display is displayed. Three consecutive symbols are displayed per reel through the window 115. In addition, the display window 115 is provided with an upper stage, a middle stage, and a lower stage as display positions for visually recognizing the symbols of each reel 131, 132, 133. A valid line is set. In the gaming machine of this embodiment, the active line is constituted by the middle stage of the first reel 131, the middle stage of the second reel 132, and the middle stage of the third reel 133. In addition, in the gaming machine of this embodiment, the number of medals required for one game (regular number) is set to 3, and when the specified number of medals is inserted, the active line is activated. It is now possible to do so.

In the slot machine 100, each reel 131, 132, 133 starts rotating with the start of the game, and a winning combination lottery is executed to determine whether one of the winning combinations is won or lost. Next, when each reel 131, 132, 133 stops, if a symbol combination corresponding to a winning combination won in the winning combination lottery is displayed on the active line, this winning combination becomes a prize, and the winning combination corresponds to the won winning combination. The process (winning process) is executed.

The lower door 112b includes a rotating medal slot 121 for inserting medals, a MAX bet button (bet button) 122 for betting credited medals, and a rotating start lever 123 that is operated when starting a game. A stop button 124 for stopping each reel 131, 132, 133, a payout port 125 for paying out medals by a hopper device, a medal receiving tray 126 for receiving medals paid out from the payout port 125, and the like are provided. Furthermore, a medal sensor is provided at the back of the medal slot 121 to detect passage of medals inserted from the medal slot 121. Further, a production button 128 is provided on the lower door 112b. The production button 128 includes, for example, a push switch and a rotary switch (jog dial), and is configured to be able to be pressed and rotated. When the performance button 128 is operated, the mode of performance changes, thereby increasing the interest of the game.

In the slot machine 100, the operation of the start lever 123 is enabled when medals are inserted into the medal slot 121 or when the MAX bet button 122 is operated and a prescribed number of medals are bet. Further, when the activated start lever 123 is operated, the game is started. When the game starts, each reel 131, 132, 133 starts rotating, and when the rotation speed of each reel 131, 132, 133 reaches a constant speed and becomes steady rotation, the operation of the stop button 124 is activated. Ru. Further, when the enabled stop button 124 is operated, each reel 131, 132, 133 corresponding to the operated stop button 124 stops.

Inside the slot machine 100, a main control board (main board) and a sub-control board (sub board) are provided. The main control board receives input signals from input means such as the MAX bet button 122, the start lever 123, the stop button 124, and the medal sensor, performs various calculations to execute the game, and based on the calculation results, the reel unit 130 and output means such as a hopper device. In addition, the sub-control board receives signals sent from the main control board, performs various calculations to execute the performance, and controls the display devices such as the liquid crystal display 113 and the speaker 114 based on the calculation results. I do.

In addition, the main control board and the sub-control board are electrically connected, and it is possible to send various information (signals) such as information indicating the gaming status from the main control board to the sub-control board. Information cannot be sent from the control board to the main control board. In addition, the functions of each board such as the main control board and sub-control board are stored in advance in hardware such as various processors (CPU, DSP, etc.), ICs, or information storage media such as ROM and RAM, ROM, etc. This is realized by software consisting of a predetermined program.

A design member 150 having a plurality of symbol parts (eg, symbol part 101, symbol part 102, symbol part 103, symbol part 104, and symbol part 105: see FIG. 2) is provided on the left side of the upper door 112a. However, the position where the design member 150 is provided is not limited to this position, and may be any position on the front door 112. For example, the design member 150 may be provided above the liquid crystal display 113 (top lens).

In this embodiment, symbol portions 101 to 105 protrude toward the front side (player side). In addition, identification information is expressed by the shape of the front surface (tip surface) of each of the symbol portions 101 to 105. Identification information includes characters, figures, symbols, and the like. Hereinafter, in this embodiment, one symbol part represents one character, but for example, one symbol part represents two or more characters, or a combination of a character and a symbol. It may also represent something.

FIG. 2 is a front view of a portion where the design member 150 is provided.
Symbol sections 101 to 105 are a series of broadcast information (character strings). In this embodiment, the symbol parts 101 to 105 form a series of notification information such as "The main character is ○○"("○○" represents the name of the character, etc.). Specifically, the shape of the tip end face of the symbol portion 101 represents one character "main". Furthermore, the shape of the tip end face of the symbol portion 102 represents one character, ``Waku''. Further, the shape of the tip end face of the symbol portion 103 represents one character “ha”. Further, the shape of the tip end face of the symbol portion 104 represents one character “◯”. Further, the shape of the tip end face of the symbol portion 105 represents one character “◯”.

The symbol portions 101 to 103 are provided so as to be lined up in the left-right direction. Further, below the symbol parts 101 to 103, a symbol part 104 and a symbol part 105 are provided so as to be vertically arranged in this order.
The symbol sections 101 to 105 include identification information (characters) of different sizes. Specifically, the character size of the symbol portion 103 is formed to be the smallest, and the character size of the symbol portion 104 is formed to be the largest. Further, the symbol parts 101 and 102 have the same font size, and are formed so that the font size is larger than the symbol part 103 and smaller than the symbol parts 104 and 105. Further, the character size of the symbol portion 105 is formed to be larger than the symbol portions 101 to 103 and smaller than the symbol portion 104. That is, the font size increases in the order of (1) symbol portion 103, (2) symbol portions 101 and 102, (3) symbol portion 105, and (4) symbol portion 104.

FIG. 3 is a schematic diagram showing a part of the upper door 112a seen from the left. The design member 150 has a base surface 151 that serves as a reference surface for protruding the symbol portions 101 to 105. This base surface 151 is a surface perpendicular to the front-rear direction. The symbol portions 101 to 105 are formed such that their respective tip surfaces (front surfaces) protrude forward from the base surface 151. Hereinafter, the amount of protrusion refers to the amount of protrusion of the symbol portions 101 to 105 from the base surface 151.
At this time, the protrusion amount L3 of the symbol portion 103 is formed to be the smallest, and the protrusion amount L4 of the symbol portion 104 is formed to be the largest. Further, the protrusion amounts L1 and L2 of the symbol portions 101 and 102 are formed to be larger than the protrusion amount L3 of the symbol portion 103 and smaller than the protrusion amounts L4 and L5 of the symbol portions 104 and 105. Further, the protrusion amount L5 of the symbol portion 105 is larger than the protrusion amounts L1 to L3 of the symbol portions 101 to 103, and smaller than the protrusion amount L4 of the symbol portion 104. That is, the protrusion amount increases in the order of (1) symbol section 103, (2) symbol sections 101 and 102, (3) symbol section 105, and (4) symbol section 104.
In this way, the symbol portions 101 to 105 are formed to have different character sizes and to have different protrusion amounts depending on the character size. Specifically, symbol portions 101 to 105 are formed such that the larger the size of the character (identification information), the larger the amount of protrusion. This creates a three-dimensional visual effect, making the characters (identification information) more three-dimensionally visible, attracting the player, giving a novel impression, and improving the interest of the game. Specifically, in addition to the difference in the size of the letters (identification information), the amount of protrusion toward the player also differs, so the difference in the degree of emphasis between large and small letters becomes larger, making them even more attractive to players. . As in this example, if the larger the font size, the larger the amount of protrusion, the larger font will seem to come closer to the player, which will attract the player.

Note that in this embodiment, the symbol parts 101 to 105 and the base surface 151 are integrated (one member), but the symbol parts 101 to 105 and the base surface 151 are separate parts (separate members). ). Further, the base surface 151 of the symbol parts 101 to 105 forming a series of broadcast information is not limited to one member, but may be composed of a plurality of members. In other words, the base surface 151 may be a single piece or a plurality of pieces. Furthermore, when the base surface 151 is composed of a plurality of base surfaces, the positions of the base surface of a predetermined symbol section and the base surface of another symbol section different from the predetermined symbol section in a predetermined direction (for example, the front-back direction) are different. You can. Specifically, in FIG. 3, for example, a base surface 151 (referred to as a first base surface) of symbol portions 101 to 103 and a base surface 151 (referred to as a second base surface) of symbol portions 104 to 105 are provided, respectively. In that case, the positions of the first base surface and the second base surface in the front-rear direction may be different. For example, the position of the second base surface may be approximately 1 to 2 mm forward or rearward of the position of the first base surface in the front-rear direction.

Furthermore, in this embodiment, the symbol parts 101 to 105 are formed so that the larger the size of the characters (identification information), the larger the amount of protrusion. It may be formed so that the amount of protrusion is small. That is, in FIG. 3, the protrusion amount may be increased in the order of (1) symbol section 104, (2) symbol section 105, (3) symbol sections 101 and 102, and (4) symbol section 103. Even in this case, a three-dimensional visual effect is produced, and the characters (identification information) are more three-dimensionally visible, attracting the player, giving a novel impression, and improving the interest of the game. In this case, the degree of cooperation differs depending on the size of the characters (identification information), and the smaller characters protrude more, so the smaller characters are closer to the front (towards the player) than the larger characters. Both large and small fonts attract players.
Furthermore, at least a portion of the plurality of symbols constituting a series of broadcast information is configured such that the amount of protrusion becomes larger in stages or the amount of protrusion becomes smaller in stages as the size of the identification information becomes larger. Good too.

In addition, if the identification information with the largest size among a series of broadcast information is formed with the largest or smallest protrusion amount, other identification information with a different size from the relevant identification information (The size of the identification information is other than the maximum) may have the same (same or substantially the same) protrusion amount.
In this case, the largest font size (identification information) is located in front of other identification information (on the player's side), or the largest font (identification information) is located ahead of other identification information. Since it is located on the rear side and is visible, a three-dimensional visual effect is generated and attracts players.

Further, in this embodiment, the tip surfaces of the symbol portions 101 to 105 are perpendicular to the front-rear direction (flat surface); however, the tip surfaces of the symbol portions 101 to 105 may be inclined surfaces, curved surfaces, uneven It may be a shape having. Note that when the tip surfaces of the symbol portions 101 to 105 have a shape other than a flat surface, the amount of protrusion of the symbol portions 101 to 105 is measured at the most forward position (the most protruding position) (the topmost portion) on the tip surface. shall be taken as a thing.

FIG. 4 is a schematic diagram showing a part of the upper door 112a seen from the left, and the tip surfaces of each of the symbol parts 101 to 105 are sloped surfaces that protrude forward as they move upward in the vertical direction. A modified example is shown. The font size increases in the order of (1) symbol section 103, (2) symbol sections 101 and 102, (3) symbol section 105, and (4) symbol section 104. Further, the protrusion amount increases in the order of (1) symbol portion 103, (2) symbol portions 101 and 102, (3) symbol portion 105, and (4) symbol portion 104.
In this way, even when the tip surfaces of the symbol portions 101 to 105 are inclined surfaces, the larger the character size, the larger the amount of protrusion. This makes the characters more three-dimensionally visible and increases the interest of the game.
Note that in FIG. 4, in the relationship between the symbol portion 104 and the symbol portion 105, it is assumed that the amount of protrusion of the minimum protrusion on the front surface of the symbol portion 104 is smaller than the amount of protrusion of the topmost portion of the symbol portion 105; However, the present invention is not limited to this, and the minimum protruding portion of the symbol portion 104 may protrude further forward than the highest portion of the symbol portion 105.
Further, the inclination angle of the tip surface (slanted surface) with respect to the base surface 151 may be changed depending on the font size of the symbol portions 101 to 105. For example, the larger the font size, the larger the inclination angle of the tip surface. Further, the tip surfaces of the symbol portions 101 to 105 may be inclined in different directions.

Further, in this embodiment, the symbol parts 101 to 105 of the design member 150 are exposed, but the design member 150 has a translucent material that covers the periphery (front and side) of the symbol parts 101 to 105. (transparent resin) cover (not shown), and inside the cover, the character sizes and protrusion amounts of the symbol parts 101 to 105 may be configured to have the above-mentioned relationship. good. The cover is fixed to the upper door 112a by, for example, screwing. In this case, the symbol parts 101 to 105 can be viewed three-dimensionally through the cover, improving the interest of the game. Further, by providing the cover, each symbol portion can be protected from damage.

Further, the symbol parts 101 to 103 are formed of a non-transparent resin, and the symbol part 104 and the symbol part 105 are formed of a transparent resin. ) may be provided. In this case, the symbol portion 104 and the symbol portion 105 emit light due to the light emitted from the light emitter. In this way, the larger the size of the letters, the larger the amount of protrusion, and by configuring the large letters so that they can be illuminated, the game becomes more interesting. Note that the symbol parts 101 to 103 may also be made of a transparent resin, and an LED board may be provided on the back side of the symbol parts so that they can be illuminated. Furthermore, for example, the illumination brightness and emitted light color may be changed depending on the font size of each symbol portion.

Further, in this embodiment, the base surface 151 is a surface perpendicular to the front-rear direction, but the present invention is not limited to this, and the base surface 151 may be an inclined surface of the front door 112. For example, the base surface 151 may be the inclined surface F on which the MAX bet button 122 and the production button 128 on the lower door 112b shown in FIG. 1 are provided. This inclined surface F is inclined downward toward the front in the front-rear direction. If this inclined surface F is used as the base surface 151, the symbol parts 101 to 105 will protrude in a direction perpendicular to the inclined surface F.

Further, the design member 150 may be provided on a pressing portion of a button (for example, the MAX bet button 122, the production button 128, etc.). The pressing portion is a member that is made of resin or the like, is supported by a biasing member such as a spring, and can be pushed. In this case, the pressing portion has a base surface 151 that is, for example, a surface perpendicular or substantially perpendicular to the operation direction (pressing direction), and the symbol portion is formed on this base surface 151. The symbol portion protrudes in a direction perpendicular to the base surface 151.

Here, an example in which the design member 150 is provided on the pressing portion of the MAX bet button 122 will be described. In this case, for example, six symbol parts are provided, and the shape of the top surface (top surface) of the first symbol part is the letter "M", and the shape of the top surface (top surface) of the second symbol part is the letter "A". , the shape of the tip surface (top surface) of the third symbol section is the letter "X", the shape of the tip surface (top surface) of the fourth symbol section is the letter "B", and the shape of the tip surface (top surface) of the fifth symbol section is the letter "X". ) is the letter "E", and the tip surface (upper surface) of the sixth symbol part is the letter "T". Then, the first to third symbol parts are arranged in this order in the left-right direction to form an upper stage, and the fourth to sixth symbol parts are arranged in this order in the left-right direction to form a lower stage, so that they are arranged in two stages.

At this time, the font size of the first to third symbol portions (MAX) is formed larger than the font size of the fourth to sixth symbol portions (BET). Note that the font sizes of the first to third symbol parts are the same, and the font sizes of the fourth to sixth symbol parts are the same. Further, the amount of protrusion of the first to third symbol portions (MAX) is formed to be larger than the amount of protrusion of the fourth to sixth symbol portions (BET). As a result, the first to sixth symbol portions can be viewed more three-dimensionally, improving the interest of the game.
In addition, in order to prevent each symbol from being directly exposed, a translucent (transparent resin) cover is provided to cover the periphery (top and side surfaces) of each symbol, so that each symbol can be seen through the cover. You can do it like this. The cover is fixed to the pressing part by, for example, adhesive. By providing the cover, each symbol part can be protected from damage, etc., and since the symbol part does not come into direct contact with the finger when operating the pressing part, the player can operate it comfortably.

Next, an example in which the design member 150 is provided on the pressing portion of the effect button 128 will be described. In this case, for example, four symbol parts are provided, and the shape of the top surface (top surface) of the first symbol part is the letter "P", and the shape of the top surface (top surface) of the second symbol part is the letter "U". , the shape of the tip end surface (top surface) of the third symbol part is the letter "S", and the shape of the tip surface (top surface) of the fourth symbol part is the letter "H". The first to fourth symbol portions are arranged in this order, for example, so as to be lined up in the left-right direction (lined up horizontally).

At this time, the first to fourth symbol parts (PUSH) are formed such that, for example, the character size gradually decreases from both ends toward the center. Further, the first to fourth symbol portions are formed such that the amount of protrusion gradually decreases from both ends toward the center. In other words, the font size and the amount of font protrusion gradually increase from the inside to the outside in the left-right direction. As a result, the first to fourth symbol portions can be viewed more three-dimensionally, improving the interest of the game. In order to prevent the first to fourth symbol parts from being directly exposed, a translucent (transparent resin) cover is provided to cover the first to fourth symbol parts, and the first to fourth symbol parts are exposed through the cover. The 4-symbol portion may be visually recognized. Further, the first to fourth symbol portions may be configured such that large characters and small characters alternate, for example, so that the amount of protrusion of the large characters is greater than the amount of protrusion of the small characters.

(Second embodiment)
Next, a second embodiment of the present invention will be described. In the second embodiment, a pachinko game machine, which is one of the game machines, will be described, but other game machines may be used.
FIG. 5 is a perspective view showing the external configuration of the pachinko gaming machine 1 according to the present embodiment. The game machine of this embodiment is used to play games using game balls (game media) lent from a game parlor, and includes an outer frame 2 forming the outer surface of the game machine, and a frame 2 provided inside the game machine. , a game board 6 forming a game area 4 in which game balls move, a glass unit 8 that makes the game board 6 visible to players but inaccessible to them, and a front frame 10 to which the glass unit 8 is attached. ing.

The part of the front frame 10 that surrounds the glass unit 8 is made of a semi-transparent material that transmits light, and inside the part made of the semi-transparent material, there are lighting lights etc. to enliven the game. A plurality of front frame lamps 12 are provided. Further, speakers 14 are provided on the upper left and right sides of the front frame 10 and the lower left and right sides of the front frame 10 for outputting sound effects to enliven the game.

At the center of the lower part of the front frame 10, an upper tray 16 for storing game balls is provided, and on the left side of the inner side of the upper tray 16, there is a tray for dispensing game balls from the gaming machine to the player. A payout port 18 is provided. A grip unit 20 is provided on the lower right side of the front frame 10, and when the player rotates the grip unit 20 clockwise toward the gaming machine, a grip unit 20 (not shown) provided inside the gaming machine is rotated. The firing device is activated to fire game balls into the game area 4. The firing device of this embodiment can fire 99 game balls per minute (1.65 balls per second).

A supply port 22 for supplying game balls from the upper tray 16 to the firing device is provided on the right side of the inner side surface of the upper tray 16. Further, below the upper tray 16, a lower tray 24 is provided for storing surplus game balls when the upper tray 16 cannot store all the game balls.

A performance operation device 26 is provided on the near side of the edge of the upper tray 16, and when a player operates the performance operation device 26, the performance performed on the gaming machine changes. In detail, the production operation device 26 has a built-in push button switch and a rotary switch (jog dial), and is capable of detecting an operation of pressing the production operation device 26 and an operation of rotating the production operation device 26. It has become.

FIG. 6 is a front view showing the external configuration of the game board 6 shown in FIG. As shown in FIG. 6, the game board 6 is provided with a circular outer rail 28, and the area surrounded by the outer rail 28 is the game area 4 in which the game balls move. Further, at the left end of the game area 4, an inner rail 30 is provided in an arc shape along the outer rail 28, and the outer rail 28 and the inner rail 30 are arranged below the game board 6 (not shown). A game ball fired from a firing device is guided to a game area 4.

At the center of the game board 6, a performance unit 36 is provided, which includes a liquid crystal display 32 for displaying performance images to enliven the game, and a display frame 34 formed to surround the liquid crystal display 32. This display frame 34 is provided with a design member 38. Note that although this embodiment shows a case where the design member 38 is provided above the liquid crystal display 32, the position of the design member 38 is not limited to this.

In this embodiment, the game ball is not allowed to pass through the front side of the liquid crystal display 32, and the game ball fired from the firing device hits the game area 4 on the left side or the game area 4 on the right side of the liquid crystal display 32. It's supposed to fall. In the game area 4, a large number of game nails (not shown) are nailed so as to cross the surface of the game board 6, so that the moving direction of the game ball moving in the game area 4 changes randomly. .

An opening 40 is formed on the left side of the display frame 34 through which a game ball falling in the game area 4 on the left side of the liquid crystal display 32 can pass. The liquid crystal display 32 is configured to pass through a passage 42 and fall onto a stage 44 provided below the liquid crystal display 32. The upper surface of this stage 44 is a smooth curved surface, and a gap is formed between the stage 44 and the glass unit 8 so that the game ball can fall downward from the stage 44, and fall onto the stage 44 from the passage 42. After the game ball moves back and forth from side to side on the stage 44, it falls downward from near the center of the stage 44.

A first starting prize opening 46 is provided below the center of the stage 44.
Furthermore, a passage gate 48 is provided in the gaming area 4 on the right side of the liquid crystal display 32. Further, a second starting prize opening 50 is provided below the passage gate 48. This second starting prize opening 50 has a reduced state in which it is difficult for the game ball to enter the second starting winning opening 50 (a state in which entry is not assisted/non-assisted state) and an enlarged state in which the game ball is easy to enter (in a state in which it is easy to enter). A normal accessory 52 is provided that includes an auxiliary member that can move between the two states (the state and the auxiliary state).

In the gaming area 4 on the right side of the liquid crystal display 32, a large winning opening 54 is provided below the second starting winning opening 50. This big prize opening 54 is provided with a special accessory 56 including a movable member that closes the big winning opening 54. The special accessory 56 is configured to be operable between a closed state in which the game ball cannot enter the big prize opening 54 and an open state in which the game ball can enter the big prize opening 54 (FIG. 6 shows (indicates closed state). The special accessory 56 is controlled to be in an open state under predetermined conditions in a special game state that starts when a jackpot is won.

A grand prize passage 58 is provided below the grand prize opening 54 facing downward. A normal entry port 62 is provided at the lower end of the grand prize path 58. Furthermore, a specific passage 65 is provided below the grand prize passage 58 so as to branch downward from the middle of the grand prize passage 58. This specific passage 65 is provided with a specific accessory 66 that includes a movable member that blocks the specific passage 65. The specific accessory 66 is configured to be operable between a closed state in which the game ball cannot enter the specific passage 65 and an open state in which the game ball can enter the specific passage 65 (FIG. 6 shows the closed state). ). The specific accessory 66 is controlled to be in an open state under predetermined conditions in the special game state. A specific entrance 68 is provided at the lower end of the specific passage 65 . Further, at the lowest part of the game area 4, an out port 69 is provided for collecting game balls that have fallen from the game area 4 without entering any of the winning holes into the inside of the game machine.

The game ball launching device is configured such that the ejection force of the game ball is changed by adjusting the amount of rotation of the grip unit 20 shown in FIG. 5, and when the amount of rotation of the grip unit 20 is small, the liquid crystal display The game ball is fired so that it falls in the game area 4 on the left side of the display 32, and when the amount of rotation of the grip unit 20 is large, the game ball falls in the game area 4 on the right side of the liquid crystal display 32. A game ball is fired.

The player adjusts the amount of rotation of the grip unit 20 according to the gaming situation, and allows the game ball to fall down the left side game area 4 or pass through the opening 40, passage 42, and stage 44 and reach the first starting prize opening. 46 (left hit), the game ball falls down the right side game area 4, and the game ball passes through the passage gate 48, or the second starting prize opening 50. The game ball is fired so that the game ball enters, or the game ball enters the grand prize opening 54 (right-handed hit).

At the lower right portion of the game board 6 and outside the game area 4, a status display section 70 is provided that indicates various statuses of the game machine by lighting and extinguishing lamps or the like. The gaming machine of this embodiment is controlled by a control board including a main board and a sub board. The functions of each board such as the main board and sub-boards are determined by hardware such as various processors (CPU, DSP, etc.), ASIC (gate array, etc.), ROM (an example of an information storage medium), or RAM. This is realized by software consisting of a given program stored in advance in, for example, a computer.

The main board receives input signals from input means (first starting winning opening sensor, passing gate sensor, second starting winning opening sensor, big winning opening sensor, normal entrance sensor, specific passage sensor, payout sensor, etc.) , performs various calculations to execute the game, and based on the calculation results, outputs the output means (status display drive device, normal role object drive device, special role object drive device, specific role object drive device, payout device, etc.) Performs operation control.

The sub-board receives commands sent from the main board and input signals from the performance operation sensor that detects operations on the performance operation device 26, and performs various calculations to execute performances in accordance with the progress of the game. Based on the calculation results, the operation of the performance devices (effect display device, sound device, performance drive device, etc.) is controlled.

Next, the design member 38 will be explained. The design member 38 includes a plurality of symbol parts (for example, a symbol part 101, a symbol part 102, a symbol part 103, and a symbol part 104). In the symbol parts 101 to 104, characters (identification information) are represented by the shape of the respective tip surfaces. In this embodiment, one character "Minami" is represented by the shape of the tip end face of the symbol portion 101. Furthermore, the shape of the tip end face of the symbol portion 102 represents one character "Kuni". Further, the shape of the tip end face of the symbol portion 103 represents one character “Otsu”. Further, the shape of the tip end face of the symbol portion 104 represents one character "woman". The symbol parts 101 to 104 constitute a series of character strings "Tropical Maiden". The symbol parts 101 and 102 are provided so as to be lined up in the left-right direction, and between the symbol part 101 and the symbol part 102, the symbol parts 103 and 104 are provided so as to be lined up in this order in the vertical direction.

FIG. 7 is a front view of the design member 38. Comparing the sizes of the identification information (characters) in the symbol parts 101 to 104, the symbol parts 101 and 102 have the same character size, and are formed so that the character size is the smallest. Further, the symbol portion 104 is formed so that the font size is the largest. Further, the symbol portion 103 is formed so that the character size is larger than the symbol portions 101 and 102 and smaller than the symbol portion 104. That is, the font size increases in the order of (1) symbol portions 101 and 102, (2) symbol portion 103, and (3) symbol portion 104.

8 is a schematic side view seen from the P direction shown in FIG. 7, and FIG. 9 is a schematic side view seen from the Q direction shown in FIG. 7.
The design member 38 has a base surface 38a that serves as a reference surface for protruding the symbol parts 101 to 104. In this embodiment, the base surface 38a is a surface perpendicular to the front-rear direction. The symbol portions 101 to 104 are formed such that their respective tip surfaces (front surfaces) protrude forward from the base surface 38a. Hereinafter, the amount of protrusion refers to the amount of protrusion of the symbol portions 101 to 104 from the base surface 38a.
Comparing the protrusion amounts of the symbol portions 101 to 104 with reference to FIGS. 8 and 9, it is found that the protrusion amounts L1 and L2 of the symbol portions 101 and 102 are the smallest, and the protrusion amount L4 of the symbol portion 104 is the largest. . Further, the protrusion amount L3 of the symbol portion 103 is larger than the protrusion amounts L1 and L2 of the symbol portions 101 and 102, and smaller than the protrusion amount L4 of the symbol portion 104. That is, the protrusion amount increases in the order of (1) symbol parts 101 and 102, (2) symbol part 103, and (3) symbol part 104. In this way, the symbol parts 101 to 104 are formed such that the larger the character size, the larger the amount of protrusion. This creates a three-dimensional visual effect, making the characters more three-dimensionally visible, attracting the player, giving a novel impression, and increasing the interest of the game.

In this embodiment, the tip surfaces of the symbol parts 101 to 104 are perpendicular to the front-rear direction (flat surface); however, the front surfaces of the symbol parts 101 to 104 may have an inclined surface, a curved surface, or an uneven surface. It may be a shape or the like. When the front surfaces of the symbol portions 101 to 104 are shaped other than flat in this way, the amount of protrusion of the symbol portions 101 to 104 is measured at the most forward position (top) on the tip surface. Further, in the present embodiment, the base surface 38a is a surface perpendicular to the front-rear direction, but the base surface 38a is, for example, a surface inclined with respect to the front-rear direction, and the symbol portion 101 is arranged in a direction perpendicular to the slope. ~104 may be made to protrude.

Further, in this embodiment, the front sides of the symbol parts 101 to 104 (design member 38) are covered with the glass unit 8 (see FIG. 5). may be provided on the front frame 10 (see FIG. 5) and configured to be exposed. Furthermore, some or all of the symbol sections 101 to 104 may be configured to be illuminated, and furthermore, the illumination brightness and emitted light color may be changed depending on, for example, the font size of each symbol section.

Further, the design member 38 may be provided on the pressing portion of the effect operation device 26 (see FIG. 5). In this case, for example, four symbol parts are provided, and the shape of the top surface (top surface) of the first symbol part is the letter "P", and the shape of the top surface (top surface) of the second symbol part is the letter "U". , the shape of the tip end surface (top surface) of the third symbol part is the letter "S", and the shape of the tip surface (top surface) of the fourth symbol part is the letter "H". Then, the first to fourth symbol parts are arranged in this order, for example, in the left-right direction (in a row horizontally).

At this time, the first to fourth symbol portions are formed such that, for example, the character size gradually decreases from both ends toward the center. Further, the first to fourth symbol portions are formed such that the amount of protrusion gradually decreases from both ends toward the center. In addition, in order to prevent the first to fourth symbol parts from being directly exposed, a translucent (transparent resin) cover is provided to cover the periphery of the first to fourth symbol parts, and the first to fourth symbol parts are exposed through the cover. The 4-symbol portion may be visually recognized. With this configuration, the first to fourth symbol portions in the effect operation device 26 can be viewed more three-dimensionally, improving the interest of the game.

Next, the sub-board unit 200 will be explained.
FIG. 10A is a diagram (plan view) of the sub-board unit 200 seen from the back side. FIG. 10(b) is a schematic cross-sectional view taken along line AA shown in FIG. 10(a). Further, FIG. 11 is a diagram (plan view) of the sub-board 210 viewed from the back side. Note that FIG. 11 shows a state in which the sub-board case 220 is removed in FIG. 10(a).
The sub-board unit 200 is provided on the back side of the liquid crystal display 113 (see FIG. 1) according to the first embodiment and the liquid crystal display 32 (see FIG. 6) according to the second embodiment. Although the sub-board unit 200 will be described below, the specifications shown in FIG. 10 can be applied to liquid crystal board units, LED board units, and power supply board units other than the main board unit.

As shown in FIGS. 10A and 10B, the sub-board unit 200 includes a sub-board 210, a sub-board case 220 that covers the back side of the sub-board 210, and the like. This sub-board case 220 is made of, for example, transparent resin, and has a substantially concave cross section in the vertical direction.
Further, as shown in FIG. 11, electronic components are mounted (arranged) on the sub-board 210. In this example, an IC 217 and a resistor 218 are mounted as electronic components. Although not shown, capacitors and the like are also mounted on the sub-board 210 as electronic components.
As shown in FIG. 10(a), the sub-board case 220 is provided with a plurality of through holes 221 that penetrate in the front-rear direction. The plurality of through holes 221 include a small diameter through hole 222 and a large diameter through hole 223. The small-diameter through hole 222 is provided inside the sub-board case 220 (on the center side). On the other hand, the large-diameter through hole 223 is provided on the outside (outer peripheral end side) of the sub-board case 220. The large-diameter through-hole 223 is mainly provided at a position facing a location (range) on the sub-board 210 where no electronic components (such as chips) are arranged. Note that a large diameter through hole 223 may be provided at a position facing the capacitor.
Furthermore, in the sub-board case 220, there are places where small-diameter through-holes 222 are provided at positions facing the IC 217 among the electronic components, but there are no places where large-diameter through-holes 223 are provided. Note that FIG. 10A shows an example of how to provide the small-diameter through-holes 222 and the large-diameter through-holes 223, and the number of holes is not limited to this.

As shown in FIG. 10(b), the small diameter through hole 222 is formed in a tapered shape so that the hole diameter gradually decreases from the front side (board side) to the rear side (housing side). The small diameter through hole 222 has a smallest hole diameter (inner diameter) of about 2 mm and a largest hole diameter (outer diameter) of about 3 mm. Further, the distance between the centers of two holes adjacent in the left and right direction is approximately 5 mm (see FIG. 10(a)).
As shown in FIG. 10(b), the large diameter through hole 223 is formed in a reverse tapered shape so that the hole diameter gradually increases from the front side (board side) to the rear side (housing side). The large diameter through hole 223 has a smallest hole diameter (inner diameter) of about 2 mm and a largest hole diameter (outer diameter) of about 4 mm. Further, the distance between the centers of two holes adjacent in the left and right direction is approximately 6 mm (see FIG. 10(a)). Note that the smallest hole diameter (inner diameter) of the large diameter through hole 223 may be about 2.5 mm, which is larger than about 2 mm.

The small-diameter through-hole 222 has a tapered shape in which the hole diameter gradually decreases from the front side toward the rear side. Therefore, air inside the sub-board case 220 is easily released to the outside through the small-diameter through-hole 222. Further, the small diameter through hole 222 is sometimes provided at a position facing the IC on the board, and by making it tapered, it also serves as a measure to prevent unauthorized insertion of instruments etc. from the rear side (back side).
The large-diameter through-hole 223 has a reverse tapered shape in which the hole diameter gradually increases from the front side toward the rear side. Therefore, air outside the sub-board case 220 is easily drawn into the sub-board case 220 through the large-diameter through hole 223.

Next, the volume adjustment switch 300 will be explained. As shown in FIG. 11, the volume adjustment switch 300 is arranged on the sub-board 210 and electrically connected to the sub-board 210. This volume adjustment switch 300 adjusts the volume (volume) of the sound output from the speaker 114 according to the first embodiment (see FIG. 1), the speaker 14 according to the second embodiment (see FIG. 5), etc. ) is provided to adjust. Note that although the following description will be made using the volume adjustment switch 300, the present content can be applied to predetermined adjustment switches (rotary switches) including the volume adjustment switch 300. The predetermined adjustment switch includes the volume adjustment switch 300, the brightness adjustment switch, the production changeover switch, and the like. The brightness adjustment switch is provided to make it possible to adjust the luminance (brightness) of the lighting device (illumination device) of the gaming machine. Further, the performance changeover switch is provided to enable settings related to the performance to be changed on the hall (gaming hall) side. For settings related to presentation, for example, if four types of states (four types of presentation states) with different presentation contents are prepared, one state can be selected from among the four states. Note that the four states may include, for example, a state in which a specific effect appears and a state in which a specific effect does not appear.

12(a) is a view (plan view) of the volume adjustment switch 300 seen from the back side, and FIG. 12(b) is a view (plan view) of the housing 310 of the volume adjustment switch 300 seen from the back side. . Further, FIG. 13 is a schematic cross-sectional view taken along the line BB shown in FIG. 10(a). Note that the housing 310 is not shown in cross section in FIG. Moreover, FIG. 14 is a perspective view of the volume adjustment switch 300 seen from the back side.

As shown in FIG. 13, the volume adjustment switch 300 includes a housing 310, a shaft member 320, a knob 330, and the like. As shown in FIG. 12(b), the housing 310 has a square shape in plan view (rectangular shape in plan view). Planar view refers to viewing the surface of the sub-board 210 on the side where the volume adjustment switch 300 is arranged from a direction perpendicular to the surface. Housing 310 is fixed to sub-board 210 by, for example, soldering. A hole 311 having a circular shape in plan view is provided in a surface (upper surface) 310a of the housing 310 opposite to the substrate side. A shaft member 320 (see FIG. 13) projects from this hole 311. The shaft member 320 has its proximal end housed inside the housing 310, and is rotatable around the axis. As the shaft member 320 rotates, for example, a rotor (not shown) inside the housing 310 rotates.

As shown in FIG. 12(b), a level display section 312 is provided on the upper surface 310a of the housing 310 so as to surround the hole 311. This level display section (predetermined display) 312 is formed by, for example, numbers 0 to 9 indicating the volume (level) of the volume being attached at predetermined intervals in a ring shape. Each number is arranged so that the bottom of the number faces the center of the hole 311 (the center of a knob 330, which will be described later). Note that in this embodiment, the predetermined display is a number indicating the volume (level), but it may be a letter or symbol other than the number. In the case of a brightness adjustment switch, as a predetermined display, for example, numbers indicating the brightness (brightness) in stages are attached in a ring shape. Further, in the case of a performance changeover switch, as a predetermined display, for example, numbers and letters (for example, alphabets) corresponding to each performance state are attached in a ring shape. Here, the diameter of a circle (a circumscribed circle connecting the upper parts of each number) regulating the outer peripheral side (radially outer side) of the range of the level display section 312 is defined as the level diameter 313.

As shown in FIG. 13, the knob 330 has a cylindrical shape with one end closed and the other end open. The knob 330 has an inner diameter that allows it to be placed over the shaft member 320. When the knob 330 is rotated with the knob 330 placed over the shaft member 320, the shaft member 320 rotates in synchronization with the knob 330. Further, at the end of the knob 330 on the opening side (housing 310 side), a flange-shaped flange portion 331 that protrudes radially outward is provided. The knob 330 is made of, for example, transparent resin or black resin.
In addition, in the above description, the case where the shaft member 320 and the knob 330 are separate bodies has been described, but the shaft member 320 and the knob 330 may be integrally configured. In other words, when referring to the knob 330, the shaft member 320 may be included. It can be said that the knob 330 is rotatably supported by the housing 310. Further, the upper surface 310a of the housing 310 can be said to be the surface of the housing 310 on the knob 330 side.

As shown in FIG. 12(a), the collar portion 331 is provided in an annular shape (circular shape in plan view) when viewed from the axial direction of the knob 330, and is provided at one location in a U-shape when viewed from the axial direction. A notch 331a is formed. This notch portion 331a is formed in a size that allows one number (level) of the level display portion 312 to be visually recognized.

Although not shown in FIG. 13, a slight gap of less than 1.0 mm is provided between the bottom surface of the collar portion 331 and the top surface 310a of the housing 310. For this reason, the level display portion 312 printed on the upper surface 310a of the housing 310 is not scratched and the level display (numbers) does not become unclear. In other words, deterioration in the visibility of the level display can be prevented. In addition, since the gap is small, less than 1.0 mm, when the knob 330 is set at the appropriate position (when the level is located approximately in the middle of the notch 331a), the axial direction of the knob 330 Whether viewed from the front or obliquely with respect to the axial direction, the level display next to the level display (number) located inside the notch 331a is not visible. That is, two level displays are not visually recognized at the same time, and the current setting value can be accurately grasped.

Further, as shown in FIG. 15, the width at the upper part (radially outer side) of the notch 331a is defined as the width X, and the width between the centers of adjacent levels (numbers) is defined as the width Y. The width X is less than or equal to the width Y. Therefore, if the notch 331a is located between the center of one number (for example, "1") and the center of the other number (for example, "0"), both numbers (here, "1" and "0") are unrecognizable or difficult to recognize. Thereby, it is possible to more easily recognize a setting error of the knob 330, that is, the knob 330 is not rotated to an appropriate position (the knob 330 is in an inappropriate position).

Further, as shown in FIG. 14, a plurality of longitudinal grooves 332 are provided on the outer peripheral surface of the knob 330 along the axial direction at predetermined intervals along the circumferential direction. By providing a plurality of vertical grooves 332, it is possible to prevent fingers from slipping when rotating the knob 330. Moreover, one horizontal groove 333 is formed on the tip end surface of the knob 330 along a diameter passing through the center. By inserting a flathead screwdriver or the like into this lateral groove 333 and rotating it, the knob 330 can be rotated without having to pinch it directly.

Further, as shown in FIG. 13, a case opening (opening) 224 is provided in the sub-board case (board case) 220 located on the back side (upper side in FIG. 13) of the volume adjustment switch 300. This case opening 224 has a circular shape in plan view (concentric with the knob 330). This case opening 224 is provided at a position corresponding to (opposed to) the position of the knob 330 in order to allow the tip of the knob 330 to protrude (to allow the knob 330 to be inserted therethrough). By rotating a knob 330 protruding from the case opening 224, the loudness (volume) of the sound output from the speaker can be adjusted. For example, if the knob 330 is rotated to increase the number visible through the notch 331a, the volume output from the speaker will increase. Note that the sub-board case 220 is made of, for example, transparent resin. This is to enable the components housed (arranged) inside the sub-board case 220 to be visually recognized.

In this embodiment, the sub-board case 220 has a concave portion 225 that is recessed one step from the back side (top side) toward the substrate side. Case opening 224 is provided approximately at the center of recess 225 . By making the knob 330 protrude inside the recess 225 in this way, it becomes difficult for fingers or the like to come into contact with the knob 330, and it is possible to prevent the knob 330 from rotating due to erroneous contact or the like.

Components arranged (connected) on the sub-board 210 include electronic components, connectors, and a volume adjustment switch 300. ) stands out. Furthermore, the sub-board case 220 is formed to have a concave cross-section so as to cover the sub-board 210 from the back side. The top surface 226a of the back plate portion 226 in the sub-board case 220 is formed to be located further back (on the upper side) than the tip of the volume adjustment switch 300. In other words, the tip of the volume adjustment switch 300 (knob 330) does not protrude beyond the top surface 226a of the sub-board case 220. Note that the protrusion of the knob 330 from the case opening 224 is such that it can be pinched with, for example, fingers.

During the assembly process, the sub-board unit 200 may be placed on a stand or the like with the sub-board case 220 side facing down, but even in that case, the knob 330 is lower than the top surface 226a of the sub-board case 220. Since it does not protrude, no impact is applied to the volume adjustment switch 300. This can prevent damage to the volume adjustment switch 300 due to force (impact) being applied to the tip of the volume adjustment switch 300 when placed on a stand or the like.
In FIG. 13, the top surface 226a of the sub-board case 220 is positioned on the back side (top side) of the tip of the volume adjustment switch 300, and the recess 225 is provided. If the structure is such that no impact is applied, the recess 225 does not necessarily need to be provided. In that case, a case opening 224 may be provided in the back plate portion 226.

Further, as shown in FIG. 13, the length L is the gap between the upper surface of the collar portion 331 and the substrate-side (inside) surface of the sub-board case 220. This length L is approximately 1 to 2 mm. The length L is made narrow from the viewpoint of fraud prevention, and is set to such a length that the flange portion 331 and the sub-board case 220 do not interfere even if the component tolerance becomes the worst. By reducing this length L, fraud can be prevented.

FIG. 31(a) is a diagram of another sub-board unit 600 viewed from the back side. FIG. 31(b) is a schematic cross-sectional view taken along the line U--U shown in FIG. 31(a). On the sub-board 210, electronic components (not shown) such as a capacitor and a resistor, a volume adjustment switch 300, a connector CN, a dip switch DIP, a reset switch RE, and the like are arranged. Here, the position (height) of the top surface 226a of the sub-board case 220 is determined according to tall electronic components (for example, capacitors) placed on the sub-board 210, but switches, connectors, etc. Since it is necessary to expose these areas, a recess 225 is provided and an opening is formed in the recess 225. At this time, the tip of the switch or connector that protrudes from the opening of the recess 225 is designed not to protrude beyond the top surface 226a of the sub-board case 220. Note that the tip of the volume adjustment switch 300 (knob 330) protrudes further toward the top surface 226a than the tip of the connector CN.

During the assembly process, etc., the sub-board unit 600 may be placed on a stand, etc. with the sub-board case 220 side facing down, but even in that case, the switches (including the volume adjustment switch 300) and connector CN may be Since it does not protrude beyond the top surface 226a of the sub-board case 220, no impact is applied to the switch or connector CN. This can prevent the volume adjustment switch 300 and the connector CN from being damaged due to force (impact) being applied to the tips of the volume adjustment switch 300 and the connector CN when placed on a table or the like.

FIG. 32(a) is an enlarged view of section S in FIG. 31(a). FIG. 32(b) is a schematic cross-sectional view taken along the line WW shown in FIG. 32(a). Hereinafter, the dimension of one side of the housing 310 (upper surface 310a) will be referred to as the length of one side of the housing 310 (one side length). Further, the diagonal dimension of the housing 310 (upper surface 310a) is referred to as the diagonal length of the housing 310 (diagonal length). The diagonal length of the housing 310 is longer than the length of one side of the housing 310.

The diagonal length of the housing 310 is greater than or equal to the diameter of the case opening 224 (the diagonal length of the housing 310 is greater than the diameter of the case opening 224). For example, if excessive force (load) is applied to the knob 330 or if the fixation (adhesion) of the volume adjustment switch 300 to the sub-board 210 deteriorates over time, the volume adjustment switch 300 may be removed from the sub-board 210. This is a case where damage occurs that causes it to come off. Even in such a case, since the diagonal length of the housing 310 is greater than or equal to the diameter of the case opening 224, the housing 310 will be caught in the case opening 224. Therefore, the volume adjustment switch 300 can be prevented from popping out (being ejected) from the sub-board case 220 through the case opening 224. Thereby, the volume adjustment switch 300 discharged to the outside of the sub-board case 220 can be prevented from being lost. Further, the volume adjustment switch 300 discharged to the outside of the sub-board case 220 can be prevented from affecting other components. Note that the length of one side of the housing 310 may be greater than or equal to the diameter of the case opening 224.

Further, the length of one side of the housing 310 is greater than or equal to the diameter of the flange 331 (the length of one side of the housing 310 is larger than the diameter of the flange 331). That is, the diameter of the collar portion 331 is equal to or less than the length of one side of the housing 310. In other words, when viewed from the axial direction of the knob 330, the outer circumferential end of the housing 310 is located outside (radially outward) than the outer circumferential end of the collar portion 331. In other words, the outer shape of the housing 310 is larger than the outer shape of the flange 331 when viewed from the axial direction of the knob 330.

If the outer circumferential end of the collar portion 331 is located outside the outer circumferential end of the housing 310, the terminal portion of the housing 310 will be hidden and cannot be seen when viewed from the axial direction of the knob 330, and the terminal portion of the housing 310 will be hidden. Although a problem arises in that adhesion (presence or absence of defects) cannot be confirmed, this example can prevent such a problem from occurring. Furthermore, if the outer circumferential edge of the collar portion 331 were to be located outside the outer circumferential edge of the housing 310, a problem would arise in which the identification code written on the board near the housing 310 would be hidden and cannot be seen. Accordingly, such problems can be prevented from occurring. Further, if the outer circumferential end of the collar portion 331 is located outside the outer circumferential end of the housing 310, a problem arises in that the heat dissipation effect of the heat generated by the volume adjustment switch 300 is reduced. This can prevent such problems from occurring.

Further, the diameter of the flange portion 331 is equal to or smaller than the diameter of the case opening 224. In other words, the diameter of the case opening 224 is greater than or equal to the diameter of the flange 331. When the diameter of the case opening 224 is made larger than the diameter of the flange portion 331 in this way, an effect is produced in that the level (number) becomes easier to see.

Although not shown, the diameter of the flange portion 331 may be greater than or equal to the diameter of the case opening 224. In this case, for example, even if only the knob 330 is removed from the housing 310, the diameter of the flange 331 of the knob 330 is larger than the diameter of the case opening 224, so the knob 330 will be caught in the case opening 224. Therefore, the knob 330 can be prevented from protruding (ejected) to the outside of the sub-board case 220 through the case opening 224. This prevents the knob 330 from being lost. Note that the diameter of the collar portion 331 and the diameter of the case opening 224 may be the same or approximately the same. Even in this case, similar effects can be achieved.

According to this example, since at least the case opening 224 is smaller than the size of the housing 310, even if the volume adjustment switch 300 is damaged and detached from the sub-board 210, the volume adjustment switch 300 will remain intact. This can prevent the liquid from being discharged from the case opening 224.

Further, the diameter of the flange portion 331 and the level diameter 313 (see FIG. 12(b)) (the diameter of the circumscribed circle of a predetermined display) are the same or approximately the same. In other words, the upper part (upper end) of the level display (for example, numbers 0 to 9) is located inside the outer periphery of the collar portion 331. In other words, the level diameter 313 is smaller than the diameter of the collar 331. For this reason, the upper part (upper end) of the level display (number) does not protrude beyond the outer periphery of the collar portion 331. By aligning the outer periphery of the flange 331 with the top of the predetermined display (numbers), the numbers, etc. do not protrude outside the flange 331, preventing misidentification of the set value, and also prevents the numbers, etc., from entering too much inside. Therefore, even when the knob 330 is pinched, numbers and the like can be easily recognized.

Further, the diameter of the case opening 224 is the same or approximately the same as the level diameter 313 (see FIG. 12(b)). In other words, when viewed from the axial direction of the knob 330, the diameter of the case opening 224 is such that the level (number) can be directly viewed without going through the sub-board case 220. Therefore, since the numbers can be directly viewed without going through the sub-board case 220, the level does not become difficult to see due to, for example, reflection of light on the sub-board case 220, and the numbers are easier to see. This can prevent incorrect adjustment. Moreover, the burden of adjustment can be reduced. Note that the diameter of the case opening 224 may be greater than or equal to the level diameter 313.

Further, in this embodiment, the sub-board case 220 is provided with a case opening 224, which is a hole through which the knob 330 is inserted. A gaming machine (for example, a pachinko gaming machine) has a main control board on its back side that performs main processing related to the game, and a sub-control board (for example, sub-board 210) that controls various devices in response to commands from the main control board. , a cover (back cover) attached to the back of the main frame so that it can be opened and closed (rotated) freely so as to cover the sub-board case 220 and the harness all at once, and stores a large number of game balls supplied from the island equipment of the game hall. Some are equipped with storage tanks, etc. Note that the main control board is covered with a cover member and sealed to prevent unauthorized acts.

In such a configuration, in addition to the case opening 224 of the sub-board case 220, the cover (back cover) covering the outside of the sub-board case 220 has a specific position corresponding to (opposed to) the volume adjustment switch 300 (knob 330). Provide an opening. Here, specific openings will be explained. The back cover is provided with a plurality of openings (for example, round holes) of the same shape at predetermined intervals, for example, in order to dissipate heat. The specific opening refers to an opening that is different from those openings (referred to as other openings), and for example, has a different shape from the other openings. The specific opening may be, for example, a long hole that is elongated in the vertical direction and has a width that does not allow a finger to be inserted, but allows a flathead screwdriver to be inserted. Note that the specific opening may have the same shape as other openings, but may have a different size (width, diameter, etc.). The specific opening can also be said to be an opening that is provided in a manner different from other openings. Further, the number of specific openings is not limited to one, and two or more may be provided side by side. The operator can rotate the knob 330 by inserting a flathead screwdriver or the like through a specific opening and inserting it into the horizontal groove 333 (see FIG. 14) of the knob 330. Thereby, the volume can be adjusted from the back side of the gaming machine without opening the back cover (without removing the back cover). Note that the sub-board case 220 may not be provided, only the back cover may be provided, and an opening (specific opening) may be provided at a position corresponding to (opposed to) the knob 330 in the back cover.

FIG. 33 is a schematic cross-sectional view taken along the line TT shown in FIG. 31(a). A connector opening K for inserting the connector CN is provided in the recess 225 of the sub-board case 220 at a position corresponding to (opposed to) the connector CN. When the sub-board case 220 is attached to the sub-board 210, the tip of the connector CN protrudes toward the rear side (upper side) than the connector opening K. However, as described above, the tip of this connector CN is designed not to protrude beyond the top surface 226a of the sub-board case 220.

Further, the gap between the outer circumferential surface of the connector CN and the inner circumferential surface of the connector opening K is formed small (narrow) from the viewpoint of fraud prevention. Note that in this embodiment, the gap is smaller than the gap between the outer peripheral surface of the knob 330 of the volume adjustment switch 300 and the inner peripheral surface of the case opening 224 in FIG. Furthermore, when the sub-board case 220 is placed over the sub-board 210, the connector CN is a component that may come into contact with the end of the connector opening K before other components. Since the strength of the connector CN is low, if the end of the connector opening K contacts and receives force (impact), there is a risk of damage such as chipping.

In consideration of such circumstances, in this embodiment, the connector opening K is provided with a taper. That is, the inner peripheral surface of the connector opening K is made into a tapered surface. Specifically, the inner peripheral surface is tapered so that the diameter of the connector opening K becomes smaller (gradually narrows) toward the top surface 226a (upper side). Thereby, even if the end of the connector opening K comes into contact with the connector CN when attaching the sub-board case 220, the connector CN can be prevented from being damaged because of the tapered surface. Moreover, by making the inner circumferential surface of the connector opening K a tapered surface, even if the wires come into contact with each other, it is possible to prevent the wires from deteriorating or breaking.

Further, FIG. 13 shows that the inner circumferential surface of the case opening 224 is a surface parallel to the axial direction of the knob 330. That is, the case opening 224 is shown without a taper. The reason why the case opening 224 is not tapered is that the gap between the outer circumferential surface of the knob 330 and the inner circumferential surface of the case opening 224 is larger than the gap between the connector CN and the opening. . However, the case opening 224 may also be tapered. That is, the inner circumferential surface of the case opening 224 may be a tapered surface (the end of the case opening 224 may be chamfered). Note that there are two ways to provide the taper to the case opening 224.

FIG. 34A shows an example in which the inner peripheral surface of the case opening 224 is tapered so that the diameter of the case opening 224 becomes smaller toward the substrate side (lower side). By providing the taper in this manner, even if the fingertips come into contact with the sub-board case 220 when the knob 330 is pinched, the tapered surface prevents the user from feeling pain.

FIG. 34(b) shows an example in which the inner circumferential surface of the case opening 224 is tapered so that the diameter of the case opening 224 becomes smaller toward the top (upper side). By providing a taper in this way, even if the tip of the knob 330 comes into contact with the sub-board case 220 when the sub-board case 220 is placed over the sub-board case 210, the tapered surface prevents the sub-board from falling. The position of the case 220 is forced, allowing smooth fitting.

In FIG. 33, a taper is provided in the opening K for the connector, which is likely to come into contact with other parts before other parts, but as shown in FIG. may be provided. Note that the opening for the volume adjustment switch 300 (the case opening 224) may not be tapered, and only the connector opening K may be tapered. Further, without providing a taper in the connector opening K, only the opening for the volume adjustment switch 300 (case opening 224) may be provided with a taper.

In addition, although the case where a taper is provided in the opening for protruding the connector CN and the volume adjustment switch 300 is shown above, the opening provided with a taper is not limited to the opening of the connector CN and the volume adjustment switch 300. That is, if there is a component that protrudes (exposes) from an opening formed in the sub-board case 220, the opening for that component can be provided with a taper. At this time, if the gap between the outer circumferential surface of the component and the inner circumferential surface of the opening is less than a predetermined gap (narrow gap), a taper may be provided.

Next, the liquid crystal unit 500 will be explained.
FIG. 16 is a perspective view of the liquid crystal unit 500 seen from the front.
This liquid crystal unit 500 is located, for example, near the operation section where the MAX bet button 122 and the like shown in FIG. 1 (first embodiment) are provided, or in the vicinity of the operation section shown in FIG. It is provided near the operation section where the performance operation device 26 and the like are provided. The following description will be made using the liquid crystal unit 500, but the present content is not limited to the liquid crystal unit 500, but can be applied to sub-board units other than the main board unit, LED board units, and power supply board units.

FIG. 17 is an exploded perspective view of the liquid crystal unit 500. The liquid crystal unit 500 includes a frame 510, a liquid crystal protective sheet 520, a liquid crystal module 530, a liquid crystal base 540, a liquid crystal control board (board) 550, a liquid crystal cover 560, and the like.

The frame 510 is a rectangular frame-shaped member, and is formed to cover the outer peripheral portion of the front side of the liquid crystal module 530. The frame 510 is made of resin, for example. The frame 510 is fixed to the liquid crystal base 540 by a fixing member so that the liquid crystal protective sheet 520 and the liquid crystal module 530 are sandwiched between the frame 510 and the liquid crystal base 540. Examples of the fixing member include screws and the like.

The liquid crystal protection sheet 520 is a rectangular plate-shaped member placed in front of the liquid crystal module 530. The liquid crystal protection sheet 520 is made of, for example, a PET material or a glass material, and is, for example, colorless and transparent.

The liquid crystal module 530 is, for example, a transmissive type, and is formed into a rectangular plate shape. The liquid crystal module 530 is formed of a liquid crystal layer, a polarizing filter, a color filter, a glass substrate, an alignment film, a transparent electrode, a backlight, and the like, and has a multilayer structure. FIG. 18 is a perspective view of the liquid crystal module 530 viewed from the back side (rear side). The liquid crystal module 530 includes an FPC (wiring means) 531 and is electrically connected to a liquid crystal control board 550 via the FPC 531. In this embodiment, FPC (Flexible Printed Circuits) 531 is used as this wiring means. The material of the FPC 531 is, for example, a PET film or a polyimide film, and an electric circuit is wired to the film. The FPC 531 extends from approximately the center of one long side of the liquid crystal module 530 toward the back side.

Returning to FIG. 17, explanation will be given. The liquid crystal base 540 is a substantially rectangular plate-shaped member, and is formed to hold the liquid crystal module 530 on its front side and to hold the liquid crystal control board 550 on its back side. The liquid crystal base 540 is made of resin, for example. Furthermore, a substantially rectangular through hole 541 is provided in the liquid crystal base 540 at a position facing the FPC 531 . The FPC 531 is guided to the back side of the liquid crystal base 540 (the side of the liquid crystal control board 550) through the through hole 541.

The liquid crystal control board 550 is a plate-shaped member on which a plurality of electronic components are mounted (arranged). FIG. 19 is a diagram (plan view) of the liquid crystal control board 550 viewed from the back side. Electronic components mounted on the liquid crystal control board 550 include resistors (R), ICs, capacitors, coils, diodes, and the like.
As shown in FIG. 17, the liquid crystal cover 560 is a substantially rectangular plate-shaped member, and is formed to cover the back side of the liquid crystal control board 550. The liquid crystal cover 560 is made of resin, for example. The liquid crystal cover 560 is fixed to the liquid crystal base 540 by a fixing member so that the liquid crystal control board 550 is sandwiched between the liquid crystal cover 560 and the liquid crystal base 540. Examples of the fixing member include screws and the like.

As shown in FIG. 19, a connector 551 is mounted on the liquid crystal control board 550. This connector 551 is electrically connected to the liquid crystal control board 550. In this embodiment, an angle type connector is used as the connector 551. This connector 551 is a female connector for FPC that can be fitted with FPC (wiring means) 531 (see FIG. 18). FIG. 20 is a side view of the liquid crystal control board 550, and the angle type refers to the surface E (fitting surface E) that fits (connects) with the FPC 531 when mounted on the liquid crystal control board 550. (Aperture surface E) is perpendicular to the substrate surface. This can be said to mean that the insertion/extraction direction of the FPC 531 is parallel to the board surface.

As shown in FIG. 19, the connector 551 is arranged inside (center side) of the liquid crystal control board 550, not at the outer edge of the liquid crystal control board 550. The reason why the connector 551 is provided at the center of the liquid crystal control board 550 in this way is that, for example, the FPC 531 having a predetermined length is used. If the FPC 531 having a predetermined length is used and the connector 551 is provided at the outer peripheral end of the liquid crystal control board 550, the path of the FPC 531 will protrude outside the liquid crystal control board 550. This leads to an increase in the size of the liquid crystal unit 500, which hinders space saving (downsizing).

FIG. 21 shows a state in which the FPC 531 is fitted into the connector 551, and the FPC 531 is pulled out (extended) from the connector 551. At this time, there is a region (range) where the FPC 531 and the liquid crystal control board 550 face each other, and in that region, the FPC 531 and the liquid crystal control board 550 are in close proximity. If an electronic component such as a resistor or an IC is mounted in that region, that is, a position directly below the path of the FPC 531, the FPC 531 and the electronic component will be close to each other. In this case, problems may occur, such as failure of the FPC 531 due to heat emitted from the electronic components, or failure of electronic components that have become hot.

FIG. 22 shows a state in which the FPC 531 is removed from the connector 551. In this embodiment, mounting is prohibited in a position directly below the path of the FPC 531 on the liquid crystal control board 550, that is, in a region (range) facing the FPC 531 on the liquid crystal control board 550, where no electronic components are placed (no electronic components are mounted). It is set as area G. By providing the prohibited mounting area G in this way, even if the connector 551 is placed at a location other than the outer edge of the liquid crystal control board 550, for example near the center of the liquid crystal control board 550, the FPC 531 and the electronic Parts do not come close to each other. This can prevent problems such as failure of the FPC 531 due to heat emitted from the electronic components and failure of the electronic components due to high temperatures.
No electronic components are placed in the mounting prohibited area G, and no through holes, wiring patterns, etc. are formed therein. In other words, no electronic components are placed in the mounting prohibited area G, and no processing is performed thereon. By forming the mounting prohibited area G in this manner, there is no obstacle when inserting the FPC 531 into the connector 551, and work efficiency is improved. In addition, since no processing is performed, inspection (quality control) is easy, and the time required for manufacturing can be shortened (that is, productivity is improved). Furthermore, since no processing is performed, manufacturing costs can be reduced.

In this embodiment, a case has been described in which the FPC 531 having a predetermined length is used and the connector 551 is arranged on the center side of the liquid crystal control board 550. However, for example, when using the FPC 531 with a shorter length, the connector 551 It is possible to arrange it closer to the outer periphery of the liquid crystal control board 550. In this embodiment, arranging the connector 551 at a location other than the outer edge of the liquid crystal control board 550 means that the mating surface E (see FIG. 20) of the connector 551 is aligned with the outer peripheral side surface of the liquid crystal control board 550. This means that the mating surface E is not on the same plane, and is located inside the outer peripheral side surface (outer peripheral end) of the liquid crystal control board 550, and the prohibited mounting area G is when electronic components are placed. The size is such that at least one electronic component (for example, a chip resistor) can be placed (mounted) thereon. Note that the electronic components include ICs, resistors, capacitors, LEDs, and the like.

The liquid crystal unit 500 according to the present embodiment is provided near the operation unit and may be subject to vibration, but by providing the mounting prohibited area G, the FPC 531 may move (shake) due to vibration. Even in such a case, the FPC 531 does not come into contact with electronic components, and it is possible to prevent, for example, image distortion on the liquid crystal. Further, since the mounting prohibited area G is provided, the FPC 531 and the electronic component do not come into contact with each other, and the electronic component can be prevented from receiving force from the FPC 531 and coming off from the liquid crystal control board 550. In addition, since the mounting prohibited area G is provided and no electronic components are mounted, an operator or the like can smoothly insert the FPC 531 into the connector 551, improving work efficiency.

Note that, as shown in FIG. 23, the connector 551 may include a holding portion 552 that is rotatably supported around an axis. When the FPC 531 is inserted into the connector 551 with the holding part 552 open and the holding part 552 is closed in this state, the fitting between the FPC 531 and the connector 551 is locked.

Further, as shown in FIG. 17, a wall-shaped convex portion 561 may be provided upright on the liquid crystal cover 560 at a position facing the holding portion 552 of the connector 551. The convex portion 561 is provided to prevent the holding portion 552 of the connector 551 from opening. Note that a slight gap is provided between the holding portion 552 and the convex portion 561. By providing this convex portion 561, it is possible to reliably prevent the FPC 531 from coming off from the connector 551.

In addition, in FIG. 23, the connector 551 and the electronic component T1 (for example, an IC) are arranged such that the left end of the connector 551 and the right end of the electronic component T1 are on the same straight line or approximately on the same straight line. There is. At this time, a small gap is provided between the right end of the electronic component T1 and the left end of the FPC 531. Therefore, the electronic component T1 does not become an obstacle when inserting the FPC 531 into the connector 551, improving work efficiency.

In this embodiment, a case is shown in which the FPC 531 is used as an example of wiring means. FPC is a flexible printed circuit board, and a plurality of electric circuits (wirings) are formed on an insulating film. Signals and power can be sent through the plurality of wires.
FIG. 30 is a diagram of the FPC 531 viewed from the substrate surface side. A board (not shown) is located on the front side. In this embodiment, the FPC 531 has a copper foil layer (circuit) adhered to one side of a base film (polyimide), and a cover film (polyimide) is bonded to cover the circuit in the part other than the connection part 531a (that is, the cable part 531b). ) are glued (crimped). The connecting portion 531a is a portion that is connected (inserted) to the connector 551 (see FIG. 23), and has exposed terminals (circuits). Note that the terminal may be subjected to surface treatment (for example, nickel plating). Further, the portion other than the connecting portion 531a is a cable portion 531b, and this cable portion 531b faces the board. Further, the area of the board facing the cable portion 531b is a mounting prohibited area G (see FIG. 22). Note that when the wiring means is the FPC 531, an electronic component such as a resistor may be mounted on the board-side surface of the cable portion 531b in a region that does not face the board (for example, region J in FIG. 30). Further, in this embodiment, the FPC 531 is a single layer (one side) FPC, but it may be a double-sided FPC or a multilayer FPC.
Furthermore, FFC (Flexible Flat Cable) may be used as the wiring means. The FFC is formed by sandwiching a plurality of wires (conductors) between insulating films (for example, polyimide films) from above and below with an adhesive interposed therebetween. In this case, a female connector for FFC may be used as the connector 551. Note that even when FFC is used, a connecting portion 531a (for example, an FFC connector) that is a portion connected to the connector 551 and a cable portion 531b that is a portion other than the connecting portion 531a are provided. This cable portion 531b faces the board.
FPC and FFC can be said to be thin sheet-like (film-like) flat cables. Since the flat cable has a predetermined width, a region facing the liquid crystal control board 550 is likely to be formed. Therefore, it is more effective to provide the mounting prohibited area G.

Further, as the wiring means, a harness (wire harness) in which two or more electric wires (wirings) (cables) are bundled may be used. In the harness, one male connector (connection part 531a) having a predetermined number of poles is provided at the tips of a plurality of electric wires (cable part 531b). In that case, a female connector that can fit into the male connector is used as the connector 551, and the male connector (connection portion 531a) is inserted into the connector 551. At this time, the cable portion 531b faces the board.
The wiring means has at least two wires, more preferably four or more wires, and still more preferably eight or more wires. If it has 8 wires, it is possible to send a 1-byte signal.

Furthermore, in this embodiment, a case where an angle type connector is used as an example of the connector 551 is shown, but a straight type connector, that is, a connector in which the direction of insertion and removal of the FPC 531 is perpendicular to the board surface, in other words, the mating surface E ( A connector in which the connector (see FIG. 20) is parallel to the board surface may also be used.
Note that if the connector 551 is a straight type connector, the amount of bending of the FPC (wiring means) 531 will be larger than in the case of an angle type connector, and the stress applied to the FPC 531 will increase, so there is a risk of wire breakage, etc. . On the other hand, with angle type connectors, such problems do not occur because the load due to bending is small. Further, when a straight type connector is used, the FPC 531 curves in a mountain shape in the direction away from the board. Therefore, the size of the liquid crystal cover 560 must be made larger so as not to interfere with the FPC 531. In other words, it hinders miniaturization (space saving). On the other hand, with an angle type connector, the FPC 531 passes through a position closer to the board, so such a problem does not occur. Furthermore, in the case of an angle type connector, the FPC 531 is closer to the board, so if electronic components are arranged on the board, the distance from the electronic components becomes smaller. Therefore, it is more effective to provide the mounting prohibited area G as in this embodiment. Further, when an angle type connector is used, as described above, a shape (convex portion 561 of liquid crystal cover 560) can be provided to prevent the holding portion 552 of the connector 551 from opening. Therefore, it is possible to prevent the FPC 531 from easily coming off from the connector 551.

Further, although not shown in the drawings, at least one through hole (via hole) can be provided in the mounting prohibited area G. By providing a through hole in the mounting prohibited area G, it is possible to obtain the effect of improving resistance to noise. Furthermore, by providing a through hole in the mounting prohibited area G, an air passage between the space on the front side (player side) of the liquid crystal control board 550 and the space on the rear side (back side) of the liquid crystal control board 550 is created. The two spaces communicate with each other, and a heat dissipation effect can be obtained. For example, electronic components can also be mounted on the front surface (the surface on the liquid crystal base 540 side) of the liquid crystal control board 550 (the surface opposite to the surface on which the connector 551 is mounted). In that case, heat will also be generated on the front side of the liquid crystal control board 550, but by providing the through hole, the heat will be diffused throughout (including the space on the rear side), and the liquid crystal control board 550 will be heated. It is possible to prevent breakdowns of electronic components due to high temperatures only in the space in front of the device.

Further, although not shown, at least one wiring pattern can be provided in the mounting prohibited area G. By providing a wiring pattern in the mounting prohibited area G in this manner, the degree of freedom in circuit design increases and design efficiency improves. Furthermore, if a wiring pattern is not provided in the mounting prohibited area G, there is a risk that the wiring pattern cannot be drawn unless the size of the board is increased, but it is possible to prevent the occurrence of such a problem of increasing the size. can.

Further, in the present embodiment, the mounting prohibited area G is provided on the liquid crystal control board 550, but is not limited thereto and may be provided on other boards. Other substrates include the sub-board 210, an LED board, a liquid crystal board, a power supply board, and a relay board that relays from the sub-board 210 to the LED board.

Next, the configuration of the end portion of the sub-board unit 200 will be described.
24(a) is a schematic diagram (plan view) of the sub-board unit 200 seen from the back side, and FIG. 24(b) is a schematic sectional view taken along the line VV shown in FIG. 24(a). be. FIG. 24(c) is a schematic diagram (plan view) of the sub-board 210 viewed from the back side. Although not shown, electronic components and the like are mounted on the sub-board 210. Examples of electronic components include resistors, ICs, capacitors, coils, diodes, and the like.
The sub-board case 220 (hereinafter referred to as case 220) is made of, for example, transparent resin, and has a substantially concave cross section in the vertical direction. Further, as shown in FIG. 24(c), a connector 211 is mounted on the sub-board 210. The connector 211 is an angle type female connector, and is electrically connected to the sub-board 210.
Hereinafter, one predetermined side among the four sides on the outer periphery of the sub-board 210 will be referred to as an end (outer peripheral end) α. Further, the opening (opening surface) of the connector 211 (the surface into which the male connector is inserted) is defined as an opening β. In this example, the opening β of the connector 211 faces the end α side of the sub-board 210, and the opening β and the end α are parallel to each other. Further, a predetermined distance is ensured between the opening β and the end α. The predetermined distance is, for example, approximately 2 to 3 mm. Further, one side of the case 220 located on the same side as the end α of the sub-board 210 (the side corresponding to the end α) is defined as an end (outer peripheral end) γ.

FIG. 25 is a diagram showing a configuration example of the end α of the sub-board 210, the opening β of the connector 211, and the end γ of the case 220. In FIG. 25A, the opening β of the connector 211 and the end γ of the case 220 overlap and match in plan view. In other words, the end γ of the case 220 is located directly above the opening β of the connector 211. In this state, it can be said that the connector 211 is located inside the end γ of the case 220. In other words, the case 220 exists above the connector 211.

In FIG. 25(a), the case 220 has a straight end γ, but as shown in FIG. 25(b), there is a U-shaped A notch may be formed, and the inside (inner peripheral end) (inner peripheral surface) of the notch may constitute the end γ. Hereinafter, when the case 220 is provided with a U-shaped cutout, the inner end of the cutout and the end parallel to the end α and the opening β will be referred to as the end γ. Even in the case shown in FIG. 25(b), the opening β and the end γ overlap and match in plan view.

FIG. 25(c) shows a state in which the connector (male connector) 250 of the harness is fitted into the connector 211 in the state shown in FIG. 25(b). The connector 250 is located outside the end γ of the case 220. In other words, case 220 is not present over connector 250.

According to this positional relationship of the ends, the connector 211 is located inside the end γ of the case 220, and the case 220 is located above the connector 211, so that the operator etc. Connector 211 cannot be touched from outside. This can prevent damage to the connector 211 due to force (load) being applied to the connector 211 and prevent the connector 211 from coming off from the sub-board 210.
Further, since the connector (male connector) 250 is located outside the end γ of the case 220, an operator or the like can touch the connector 250 from above in plan view. Therefore, the connector 250 can be easily disengaged from the connector 211 by pushing the claw portion (not shown), improving work efficiency. Further, as shown in FIG. 25(c), if the end (end face) on the wiring (cable) side of the connector 250 is an end δ, the end δ protrudes outward from the end α of the sub-board 210. There is. Therefore, the operator or the like can more easily hold the connector 250, making it easier to insert and remove the connector 250.

Next, another configuration example of the end α of the sub-board 210, the opening β of the connector 211, and the end γ of the case 220 will be described with reference to FIG.
In this example, in plan view, the end α of the sub-board 210, the opening β of the connector 211, and the end γ of the case 220 all overlap and match. In other words, the end α of the sub-board 210, the opening β of the connector 211, and the end γ of the case 220 are located on the same straight line.

According to this positional relationship of the ends, the connector 211 is located inside the end γ of the case 220, and the case 220 is located above the connector 211, so that the operator etc. Connector 211 cannot be touched from outside. This can prevent damage to the connector 211 due to force (load) being applied to the connector 211 and prevent the connector 211 from coming off from the sub-board 210. In addition, in plan view, the end α of the sub-board 210 and the end γ of the case 220 match, and since the sub-board 210 is covered by the case 220, foreign matter etc. do not adhere to the sub-board 210. can be prevented.
Further, since the connector (male connector) 250 is located outside the end γ of the case 220, an operator or the like can touch the connector 250 from the upper side in a plan view. Therefore, the connector 250 can be easily disengaged from the connector 211 by pushing the claw portion (not shown), improving work efficiency. Furthermore, since the connector 250 protrudes outward from the end α of the sub-board 210, it becomes easier for an operator or the like to grasp the connector 250, making it easier to insert and remove the connector 250.

Next, another configuration example of the end α of the sub-board 210, the opening β of the connector 211, and the end γ of the case 220 will be described with reference to FIG. In FIG. 27, the wiring side end δ of the connector 250 and the end α of the sub-board 210 overlap and match in plan view. This can be said to mean that the end δ of the connector 250 is in contact with the outer peripheral side surface of the sub-board 210.
If the end δ on the wiring side of the connector 250 protrudes outward from the end α of the sub-board 210, there is no sub-board 210 that functions as a wall, and the connector 250 may be touched by a finger, for example. 250 was susceptible to force (external force) (impact). Therefore, when the connector 250 is subjected to force, problems such as the connector 250 and the connector 211 becoming unfitted or the connector 211 coming off the sub-board 210 may occur. On the other hand, as shown in FIG. 26, when the wiring-side end δ of the connector 250 is aligned with the end α of the sub-board 210, the connector 250 protrudes outward from the end α of the sub-board 210. Because there is no contact with the connector 250, it is difficult for fingers or the like to touch it, and the connector 250 is difficult to receive force. This can prevent the above problem from occurring.

Next, another configuration example of the end α of the sub-board 210, the opening β of the connector 211, and the end γ of the case 220 will be described with reference to FIG.
As shown in FIG. 28(a), the end (end surface) of the connector 211 on the side opposite to the opening β (inside the board) is defined as an end ε. In this example, in plan view, the end γ of the case 220 is located inside the end ε (inside the substrate). That is, the connector 211 is located outside the end γ of the case 220 (outside the board), and the case 220 does not exist above the connector 211. Note that, as shown in FIG. 28(b), the end γ of the case 220 and the end ε of the connector 211 may be aligned in plan view.

According to this positional relationship of the ends, since the connector 211 is located outside the end γ of the case 220 (outside the board), an operator or the like can press the connector 250 while holding the upper part of the connector 211. can be inserted into connector 211. This can prevent the connector 211 from coming off the sub-board 210 due to the force (insertion force) when inserting the connector 250 into the connector 211. In particular, when the connector 211 is surface-mounted rather than insertion-mounted, a configuration like this example is more effective because surface-mounted connectors tend to come off from the board when subjected to force (adhesion strength is low). becomes.

24 to 28 show examples in which one connector 211 is mounted on the sub-board 210, but as shown in FIG. 29, a plurality of connectors 211 may be arranged in parallel on the sub-board 210. It's okay.

(Third embodiment)
Next, a third embodiment will be described. This embodiment will be explained using the main back box board unit 700 of the slot machine 100 shown in FIG. ) can also be applied to the main system board unit used for.
FIG. 35(a) is a front view of the slot machine 100 shown in FIG. 1, with the front door 112 (see FIG. 1) removed. The main back box board unit 700 is located inside the casing (back box) 111 and next to the main board unit 400 (on the right side when viewed from the front). The main board units including the main board unit 400 and the main back box board unit 700 are provided with a main board (main board), and are covered with a case from the viewpoint of fraud prevention.

FIG. 35(b) is an exploded perspective view of the main back box board unit 700 and the bracket 799 that supports the main back box board unit 700 from the back side, viewed from the front side. The main back box board unit 700 includes a board case 710 (hereinafter simply referred to as case 710) and a main back box board 720 (hereinafter simply referred to as board 720). On the board 720, electronic components such as a capacitor, a connector (female connector) 721, etc. are arranged (mounted). Hereinafter, the surface of the board 720 on which electronic components and connectors 721 are arranged will be referred to as a component arrangement surface Z.

The case 710 is formed into a box shape, and the back surface (substrate 720 side) is open. The case 710 includes a top plate part 711 facing the component placement surface Z, and a side plate part 712 provided perpendicularly to the top plate part 711 along the outer periphery of the top plate part 711. The side plate portion 712 faces the side surface (outer peripheral surface) of the substrate 720 when the substrate 720 is placed inside. Further, the end of the side plate 712 on the side opposite to the top plate 711 is a case opening 714 (shown in FIG. 39). The case 710 has a concave cross section and is formed to be able to cover the substrate 720. In other words, case 710 is formed such that substrate 720 can be placed (installed) inside. Furthermore, the case 710 is made of transparent resin, and the internal substrate 720 can be viewed from the front side.

As shown in FIG. 35(b), a connector opening 713 is formed at a position corresponding to (opposed to) the connector 721 in the top plate portion 711. In this embodiment, a case is shown in which a plurality of connectors 721 are arranged on the substrate 720 and a plurality of connector openings 713 are provided corresponding to the plurality of connectors 721. However, at least one connector 721 and at least one connector opening 713 may be provided. Connector opening 713 is provided to allow a male connector (not shown) to fit into connector 721 (ie, to expose connector 721).

FIG. 36 is a diagram of the main rear box board unit 700 viewed from the front side. Further, FIG. 37(a) is a schematic cross-sectional view taken along the line CC shown in FIG. 36. Further, FIG. 37(b) is a schematic cross-sectional view taken along the line DD shown in FIG. 36. Note that in FIGS. 37(a) and 37(b), hatching indicating that they are cross sections is omitted.
As shown in FIG. 37(a), the outer circumferential surface (outer circumferential side surface) of the connector 721 and the surface perpendicular to the component arrangement surface Z of the board 720 is defined as a connector outer circumferential surface 721a. Further, the inner circumferential surface of the connector opening 713 is referred to as a connector opening inner circumferential surface 713a. The connector outer peripheral surface 721a and the connector opening inner peripheral surface 713a are opposed to each other. Note that when the connector opening inner circumferential surface 713a is tapered, the location where the gap with the connector outer circumferential surface 721a is the narrowest (the location closest to the connector) is defined as the connector opening inner circumferential surface 713a. Note that in this embodiment, a case is shown in which the connector 721 and the connector opening 713 are each rectangular, but if the connector 721 is square (in plan view), the connector opening 713 is square. That is, the connector opening 713 may have a shape that follows the outer shape of the connector 721.

As shown in FIG. 37(a), the longitudinal dimension (horizontal dimension) of the outer shape of the connector 721 is defined as dimension AL1. Further, the longitudinal dimension (horizontal dimension) of the connector opening 713 (the dimension between the pair of opposing inner circumferential surfaces 713a of the connector opening) is defined as the dimension BL1. Further, as shown in FIG. 37(b), the width dimension (vertical dimension) of the outer shape of the connector 721 is defined as dimension AL2. Further, the short side dimension (vertical dimension) of the connector opening 713 (the dimension between the pair of opposing inner circumferential surfaces 713a of the connector opening) is defined as the dimension BL2.

In this embodiment, the difference between dimension BL1 and dimension AL1 (dimension BL1-dimension AL1) is approximately 2 mm. Further, the difference between the dimension BL2 and the dimension AL2 (dimension BL2-dimension AL2) is also about 2 mm. That is, the difference M (dimensional difference M) (gap M) (first difference) between the opening dimension of the connector opening 713 in a predetermined direction and the external dimension of the connector 721 in the same direction is approximately 2 mm. . The predetermined direction is a direction along the outer peripheral surface of the connector 721 (a surface perpendicular to the component placement surface Z), and is two directions (a first direction and a second direction) that are orthogonal to each other. In this embodiment, the predetermined directions include a direction along the longitudinal direction of the outer circumferential surface of the connector 721 (direction in FIG. 37(a)) (first direction), and a direction along the transverse direction of the outer circumferential surface of the connector 721 ( (direction shown in FIG. 37(b)) (second direction). When the connector 721 is located at the center of the connector opening 713, a gap of about 1 mm is formed over the entire circumference between the connector outer peripheral surface 721a and the connector opening inner peripheral surface 713a. By forming the gap between the connector outer circumferential surface 721a and the connector opening inner circumferential surface 713a small in this manner, it becomes difficult to insert instruments, etc., and unauthorized access can be prevented.

Furthermore, no electronic components such as resistors or capacitors are arranged on the board 720 at a position corresponding to the gap between the connector outer circumferential surface 721a and the connector opening inner circumferential surface 713a. That is, the electronic component is not visible through the gap between the connector outer peripheral surface 721a and the connector opening inner peripheral surface 713a. Therefore, even if an instrument or the like is inserted through the gap, the instrument or the like will not come into contact with the electronic component because there is no electronic component directly under the gap. This makes it possible to further strengthen countermeasures against fraud.

FIG. 38 is a diagram of the main back box board unit 700 viewed from the back side.
A board 720 is arranged inside the case 710, and the board 720 is first arranged (temporarily placed) inside the case 710. Next, by tightening screws or the like (not shown) into the plurality of mounting holes MH (four locations at the four corners in this embodiment) provided coaxially in both the case 710 and the board 720, the board 720 is is fixed to case 710. Here, as described with reference to FIG. 37, the gap between the connector outer circumferential surface 721a and the connector opening inner circumferential surface 713a is small. Therefore, if the board 720 is simply placed (temporarily placed) inside the case 710 or if the board 720 is misaligned during the screw tightening process, the connector outer circumferential surface 721a and the connector opening inner circumferential surface 713a may There is a risk of contact. If the outer circumferential surface 721a of the connector comes into contact with the inner circumferential surface 713a of the connector opening, problems such as deformation or damage of the connector 721 or detachment of the connector 721 from the board 720 may occur. This leads to a decline in the quality of gaming machines.

Next, a structure for preventing such problems from occurring will be explained. FIG. 39 is a perspective view of the case 710 viewed from the back side. Hereinafter, the inner circumferential surface of the side plate portion 712 of the case 710 will be referred to as an inner circumferential surface 712a. This inner circumferential surface 712a plays a role in regulating the position of the substrate 720 placed inside the case 710 (before screw tightening). In this embodiment, a plurality (seven locations) of position regulating portions 730 are further provided on the inner circumferential surface 712a. When the position regulating section 730 is provided, this position regulating section 730 has a function of regulating the position of the substrate 720.

The position regulating portion 730 is formed into a rib shape. The position regulating section 730 of this embodiment includes position regulating sections 731a, 731b, 732a, and 732b that regulate the movement (movement) of the substrate 720 in the transverse direction (horizontal direction), and There are position regulating portions 733a, 733b, and 733c that regulate the movement (movement) of ). The position regulating portion 730 is formed in an L-shape in which a portion on the top plate portion 711 side protrudes more inward than a portion on the case opening 714 side. The position regulating section 730 includes a supporting section 730A that has a surface that contacts (abuts) the component placement surface Z of the board 720, and a regulating section 730B that has a surface that faces the outer peripheral surface of the board 720 with a predetermined gap therebetween. have.

The dimension between the pair of opposing side plate parts 712, 712 refers to the dimension between the pair of opposing position regulating parts 730, 730 when the position regulating part 730 is provided. If not, it refers to the dimension between the pair of opposing side plate parts 712, 712 (inner peripheral surfaces 712a, 712a).

FIG. 40(a) is a schematic cross-sectional view taken along line HH shown in FIG. 38. FIG. 40(b) is a schematic cross-sectional view taken along line II shown in FIG. 38. Note that in FIGS. 40(a) and 40(b), hatching indicating that they are cross sections is omitted.
As shown in FIG. 40(a), the dimension between the pair of opposing side plate portions 712, 712, that is, the dimension between the pair of position regulating portions 731a, 731b is defined as dimension CL1. Although not shown, the dimension between the pair of position regulating portions 732a and 732b is also the dimension CL1. Further, the dimension of the substrate 720 in the left-right direction (short direction) is defined as dimension DL1. As shown in FIG. 40(b), the dimension between the pair of opposing side plate portions 712, 712, that is, the dimension (straight line distance, shortest distance) between the pair of position regulating portions 733a, 733b is defined as dimension CL2. Although not shown, the dimension between the pair of position regulating portions 733a and 733c is also dimension CL2. Further, the dimension of the substrate 720 in the vertical direction (longitudinal direction) is defined as dimension DL2.

In this embodiment, the difference between dimension CL1 and dimension DL1 (dimension CL1-dimension DL1) is approximately 1 mm. Further, the difference between the dimension CL2 and the dimension DL2 (dimension CL2-dimension DL2) is also about 1 mm. That is, the difference (dimensional difference N) (gap N) (second difference) between the case inner dimension between the pair of opposing side plate parts 712 in a predetermined direction and the outer dimension of the board 720 in the same direction is about 1 mm. It becomes. The predetermined directions are two mutually orthogonal directions (plan view) along the outer shape (outer peripheral surface) of the substrate 720. In this embodiment, there is a direction along the lateral direction of the outer shape of the substrate 720 (direction in FIG. 40(a)) and a direction along the longitudinal direction of the outer shape of the substrate 720 (direction in FIG. 40(b)). When the board 720 is placed in the center of the case 710, the gap between the outer peripheral surface of the board 720 and the side plate part 712 (position regulating part 730) of the case 710 is approximately 0.5 mm. In this embodiment, the dimensional difference N is about 1 mm, but this dimensional difference N can be set within the range of about 0.4 mm to about 1 mm. If the dimensional difference N is approximately 0.4 mm, the gap between the outer peripheral surface of the substrate 720 and the side plate portion 712 (position regulating portion 730) of the case 710 is approximately 0.2 mm.

In this embodiment, the case 710 includes a top plate part 711 facing the surface of the board 720 on which the connector 721 is arranged, a side plate part 712 formed along the outer periphery of the top plate part 711, A connector opening 713 is formed at a position corresponding to the connector 721 of the top plate part 711, and the difference between the opening dimension of the connector opening 713 in a predetermined direction and the external dimension of the connector 721 in the same direction is determined by a first (dimensional difference M), and the difference between the inner dimension of the case between the pair of side plate parts 712, 712 that face each other in a predetermined direction (in a predetermined direction) and the outer dimension of the board 720 in the same direction is defined as a second difference. (dimensional difference N), the first difference is larger than the second difference. Therefore, when the board 720 is placed inside the case 710 (before screws are tightened) (when assembling the case 710 and the board 720), or if the position of the board 720 is shifted during the screw tightening process, Even if the connector outer circumferential surface 721a and the connector opening inner circumferential surface 713a come into contact (abutment) (interference), the outer circumferential surface of the board 720 and the side plate portion 712 (inner circumferential surface 712a) of the case 710 may contact each other. come into contact (abut). Therefore, stress (load) is not applied to the connector 721, and problems such as deformation and damage of the connector 721 and detachment of the connector 721 from the board 720 can be prevented. Thereby, it is possible to prevent the quality of the gaming machine from deteriorating.

In this embodiment, the case where the dimensional difference M is about 2 mm is shown, but the dimensional difference M may have a value larger than the dimensional difference N. Further, in this embodiment, a case where a rib-shaped position regulating portion 730 is provided is shown. When the position regulating portion 730 is provided, it is only necessary to manage the dimensions between ribs, and therefore, dimension management is easier than when managing the dimensions between surfaces. Further, if the substrate 720 has a large wobbling, the mold for the position regulating portion 730 may be adjusted (corrected), and the countermeasure can be easily taken and the construction period can be shortened. Note that providing the position regulating portion 730 is particularly effective when the size of the substrate 720 is larger than a predetermined size. This is because it becomes difficult to manage the dimensions between the surfaces. On the other hand, if the size of the substrate 720 is smaller than a predetermined size, or if the precision can be ensured sufficiently by controlling the dimensions between the surfaces, it is not necessary to provide the position regulating section 730. That is, the dimensions between the pair of opposing side plate portions 712, 712 may be set to dimensions CL1, CL2.

Further, in this embodiment, the substrate 720 is surrounded on all sides by the side plate portions 712 of the case 710. That is, all the outer peripheral side surfaces of the board 720 are shown facing the side plate portion 712 of the case 710. However, the present invention is not limited to this, and at least one side plate part 712 among the four side plate parts 712 of the case 710 may not be provided. That is, at least one of the four side plate parts 712 of the case 710 may not be provided and may be open. In that case, for example, a positioning boss is provided on the top plate portion 711 of the case 710, and a boss hole is provided on the substrate 720 at a position facing the positioning boss. Then, when placing the board 720 inside the case 710, the positioning bosses are inserted into the boss holes. As a result, the position of the substrate 720 is also regulated by the relationship between the positioning boss and the boss hole. In this case, the difference (dimensional difference N) between the diameter of the positioning boss and the inner diameter of the boss hole is, for example, 1 mm, which is smaller than the dimensional difference M (2 mm). Therefore, the outer circumferential surface of the positioning boss and the inner circumferential surface of the boss hole come into contact before the connector outer circumferential surface 721a and the connector opening inner circumferential surface 713a come into contact.

Further, when a plurality of connectors 721 having different external shapes (sizes) are arranged on the board 720, the dimensional difference M may be the same (equivalent) for all the connectors 721. In this case, even if the connector outer circumferential surface 721a and the connector opening inner circumferential surface 713a contact each other, the connector outer circumferential surface 721a and the connector opening inner circumferential surface 713a may contact each other at multiple locations (all connectors 721). will come into contact with each other at the same time. Therefore, the load (impact) at the time of contact is distributed to the plurality of connectors 721 without being concentrated on one connector 721. This can prevent deformation and damage of the connector 721, and has the effect that the connector 721 is difficult to come off from the board 720.

Furthermore, as shown in the lower right corner of FIG. 36, a plurality of (two in this embodiment) connectors 721 may be arranged side by side inside one connector opening 713. The connector opening 713 has unevenness in a plan view, but this is because the connector opening 713 has a shape that follows the outer shapes of the two connectors 721. When the two connectors 721 are located at the center of the connector opening 713, the gap between the connector outer circumferential surface 721a and the connector opening inner circumferential surface 713a is approximately 1 mm over the entire circumference (approximately 2 mm on both sides, that is, a dimensional difference). M). Note that in this embodiment, two connectors 721 having different external shapes (sizes) are arranged inside one connector opening 713, but they may have the same shape. Further, two or more connectors 721 may be arranged inside one connector opening 713. Further, the gap between two adjacent connectors 721 is 2 mm or less. In this way, by forming the gap between the connectors to be small, it becomes difficult to insert an instrument or the like between the connectors, and countermeasures against fraud can be strengthened.

In the above description, the main system board unit (main back box board unit 700) has been described. Next, the sub-system board unit will be explained using the sub-board unit 600 shown in FIG. 31. Note that this content can also be applied to a sub-system board unit used in the pachinko gaming machine 1 (second embodiment).
As shown in FIG. 31(b), the sub-board unit 600 includes a sub-board 210 and a case 220 that covers the sub-board 210. Further, the case 220 is provided with an opening (referred to as a connector opening) for exposing the connector CN. That is, a gap is formed between the outer peripheral surface of the connector CN and the inner peripheral surface of the connector opening.

In the sub-board unit 600, the difference M between the dimension of the connector opening in a predetermined direction and the external dimension of the connector CN in the same direction (dimensional difference M) is about 4 mm. That is, when the connector CN is located at the center of the connector opening, a gap of about 2 mm is formed over the entire circumference between the outer peripheral surface of the connector CN and the inner peripheral surface of the connector opening. Furthermore, although the case 220 has side plate portions, the difference N between the inner dimension of the case between a pair of opposing side plate portions in a predetermined direction and the outer dimension of the sub-board 210 in the same direction (dimensional difference N) is , approximately 1 mm. That is, when the sub-board 210 is placed at the center of the case 220, the gap between the outer peripheral surface of the sub-board 210 and the inner peripheral surface of the case 220 is approximately 0.5 mm. Although FIG. 31 only shows the dimensional difference M and the dimensional difference N in one direction (the longitudinal direction of the sub-board unit 600), the relationship between the dimensional difference M and the dimensional difference N is also shown in the direction perpendicular to that direction. It has become.

Since the dimensional difference M is larger than the dimensional difference N in this way, even if the sub-board 210 is displaced, the outer circumferential surface of the connector CN and the inner circumferential surface of the connector opening will come into contact with each other. The outer circumferential surface of the sub-board 210 and the inner circumferential surface (side plate portion) of the case 220 come into contact before this. Therefore, no stress (load) is applied to the connector CN, and problems such as deformation and damage of the connector CN and detachment of the connector CN from the board 210 can be prevented.

Further, as shown in FIG. 13, in the sub-board unit, a knob 330 of the volume adjustment switch 300 protrudes through a case opening (volume adjustment opening) 224 formed in the case 220. At this time, the difference M (dimensional difference M) between the diameter of the knob 330 and the inner diameter of the volume adjustment opening 224 is about 4 mm. That is, when the knob 330 is located at the center of the volume adjustment opening 224, a gap of about 2 mm is formed over the entire circumference between the outer peripheral surface of the knob 330 and the inner peripheral surface of the volume adjustment opening 224. There is. Also, at this time, depending on the position (height) of the case 220, etc., the inner circumferential surface of the volume adjustment opening 224 may not be opposed to the outer circumferential surface of the knob 330, but to the outer circumferential surface (outer circumferential side surface) of the housing 310. It may happen. In that case, the housing 310 is square (in plan view), and the volume adjustment opening 224 is also square (in plan view). Also in this case, the difference M between the opening size of the volume adjustment opening and the outer size of the housing 310 (dimensional difference M) is about 4 mm. That is, when the housing 310 is located at the center of the volume adjustment opening 224, a gap of approximately 2 mm is formed over the entire circumference between the outer peripheral surface of the housing 310 and the inner peripheral surface of the volume adjustment opening 224. ing.

Further, a reset switch RE having a rectangular shape in plan view is arranged on the sub-board 210. A reset switch opening having a rectangular shape in plan view is formed in the case 220 at a position corresponding to the reset switch RE. At this time, the outer circumferential surface (outer circumferential side surface) of the reset switch RE and the inner circumferential surface of the reset switch opening may face each other. Also in this case, the difference M (dimensional difference M) between the opening size of the reset switch opening and the external size of the reset switch RE is approximately 4 mm. That is, when the reset switch RE is located at the center of the reset switch opening, a gap of approximately 2 mm is formed over the entire circumference between the outer peripheral surface of the reset switch RE and the inner peripheral surface of the reset switch opening. ing.

In this manner, in the sub-board unit, the dimensional difference M (approximately 4 mm) is larger than the dimensional difference N (approximately 1 mm) in the volume adjustment switch 300 and the reset switch RE. Therefore, even if the position of the sub-board 210 is shifted, the outer circumferential surface of the sub-board 210 is and the inner circumferential surface (side plate portion) of the case 220 come into contact with each other. Furthermore, even if the position of the sub-board 210 is shifted, the outer circumferential surface of the sub-board 210 and the inner circumferential surface of the case 220 are connected to each other before the reset switch RE and the inner circumferential surface of the reset switch opening come into contact with each other. The surface (side plate part) comes into contact. This can prevent the volume adjustment switch 300 and the reset switch RE from being deformed or damaged. Further, it is possible to prevent the volume adjustment switch 300 and the reset switch RE from coming off the sub-board 210.

Note that the reset switch opening may further be provided with a lid portion that covers the reset switch opening. The lid is a rectangular plate-like member, and a rotating shaft (one side) is rotatably supported by a lid support near the reset switch opening (above the opening). By pinching the lower side of the lid (the side opposite to the rotating shaft side) and pulling it toward you, the lid rotates and opens, exposing the reset switch RE. By providing the lid portion that covers the reset switch RE in this manner, it is impossible to insert an instrument or the like unless the lid portion is opened, and countermeasures against fraud can be further strengthened. Furthermore, a rib may be further provided that protrudes from the case 220 toward the sub-board 210 and is formed so as to surround the periphery (outside) of the reset switch RE. By providing the ribs in this manner, even if the lid is opened and an instrument is inserted, the presence of the rib prevents the instrument from entering, and the instrument, etc. does not come into contact with the reset switch RE. This will further strengthen countermeasures against fraud.

Next, the sub-back box slave board unit 610, which is another sub-system board unit, will be explained. As shown in FIG. 35, the sub-back box slave board unit 610 is arranged on the left side inside the casing (back box) 111. Although not shown, the sub-back box slave board unit 610 includes a board on which a connector is arranged and a case that covers the board, and the case is provided with a connector opening for exposing the connector. There is. The difference M between the opening dimension of the connector opening in a predetermined direction and the external dimension of the connector in the same direction (dimensional difference M) is about 6 mm. That is, when the connector is located at the center of the connector opening, a gap of about 3 mm is formed over the entire circumference between the outer peripheral surface of the connector and the inner peripheral surface of the connector opening. In addition, the case has side plates, and the difference N between the inner dimension of the case between a pair of opposing side plates in a predetermined direction and the outer dimension of the board in the same direction (dimensional difference N) is approximately 1 mm. It has become. That is, when the board is placed in the center of the case, the gap between the outer peripheral surface of the board and the inner peripheral surface of the case is about 0.5 mm. In this way, the sub-back box slave board unit 610 is also formed so that the dimensional difference M (approximately 6 mm) is larger than the dimensional difference N (approximately 1 mm). Therefore, the outer circumferential surface of the board and the inner circumferential surface of the case come into contact before the outer circumferential surface of the connector and the inner circumferential surface of the connector opening come into contact. This can prevent problems such as deformation and damage of the connector, and problems such as the connector coming off from the board.

Here, when comparing the dimensional difference M between the main system board unit and the sub system board unit, the dimensional difference M (approximately 4 mm or approximately 6 mm) of the sub system board unit is equal to the dimensional difference M of the main system board unit. It is larger than M (approximately 2 mm). The maximum value of the dimensional difference M of the sub-system board units is 2X, where the connector width (shorter width) is X mm. For example, when the connector width is 5 mm, the maximum value of the dimensional difference M is 10 mm. At this time, the gap between the outer circumferential surface of the connector and the inner circumferential surface of the connector opening is 5 mm over the entire circumference, making it difficult to arrange another connector in the gap.

In the main system, when placing the board inside the case, it is necessary to have a structure in which the board is lowered from a direction perpendicular to the top plate of the case. On the other hand, in the sub-system, when placing the board inside the case, hook one side of the board onto the claws of the case (insert it diagonally), then push the other side of the board ( It can be arranged in a case (in an arc). When such a structure is adopted, interference between the connector and the case is avoided by securing a larger gap between the outer peripheral surface of the connector and the inner peripheral surface of the connector opening in the sub system than in the main system.

In this embodiment, the board is screwed to the board case, but a structure in which the board case is screwed to the board may also be used. Furthermore, although screws are used as fixing members for fixing the board to the board case, pins or the like may also be used. For example, when a pin passes through a hole (through-hole provided in the board and board case), its diameter becomes smaller, but after passing through the hole, the diameter at both ends becomes larger, and there is a stopper at both ends. In some cases, a section is formed. When such a pin is used, the board and the board case will not come off the pin unless the retaining portion is pinched to reduce the diameter.

A power switch is provided at the lower left inside the PO section shown in FIG. 35, that is, the housing (back box) 111. Note that FIG. 35 shows a state in which the power switch is covered with a lid. Here, we will explain the case where the power switch is mounted on a board and the board is covered by a case. The case is provided with a power supply opening for exposing the power switch. The difference M (dimensional difference M) between the opening dimension of the power supply opening in a predetermined direction and the external dimension of the power switch in the same direction is about 6 mm. That is, when the power switch is located at the center of the power supply opening, a gap of approximately 3 mm is formed over the entire circumference between the outer peripheral surface of the power switch and the inner peripheral surface of the power supply opening. In addition, the case has side plates, and the difference N between the inner dimension of the case between a pair of opposing side plates in a predetermined direction and the outer dimension of the board in the same direction (dimensional difference N) is approximately 1 mm. It has become. That is, when the board is placed in the center of the case, the gap between the outer peripheral surface of the board and the inner peripheral surface (side plate part) of the case is approximately 0.5 mm. In this way, the power supply unit is also formed so that the dimensional difference M (approximately 6 mm) is larger than the dimensional difference N (approximately 1 mm). Therefore, the outer circumferential surface of the board and the inner circumferential surface of the case come into contact before the outer circumferential surface of the power switch and the inner circumferential surface of the power source opening come into contact. This can prevent the power switch from being deformed, damaged, or coming off the board.

(Fourth embodiment)
Next, a fourth embodiment will be described.
This embodiment will be described using the reel lighting board unit of the slot machine 100 shown in FIG. The present invention can also be applied to a lighting device (for example, a lighting device for the upper door 112a). Furthermore, it can be applied to each lighting device in the pachinko gaming machine 1 (second embodiment).

FIG. 41(a) is a perspective view of the integrated liquid crystal display device LCD and reel unit RU as seen from the front side, and FIG. 41(b) is a perspective view of the same as seen from the back side. An illumination board unit (details will be described later) for irradiating light to the reels 131 to 133 shown in FIG. 1 is provided between the liquid crystal display device LCD and the reel unit RU. The liquid crystal display device LCD includes a transmissive liquid crystal module. That is, images such as effects are displayed in front of the reels, and the reels in the back are visible. When a transparent liquid crystal is provided in front of the reel in this way, it is necessary to brightly illuminate the reel in order to make the reel at the back visible. That is, it is necessary to increase the number of LEDs arranged on the LED board of the lighting board unit within a defined space. However, as the number of LEDs increases (as the number of LEDs is densely arranged on a board), the amount of heat generated by the LED light emission increases, and there is a risk that the LEDs may be damaged. Therefore, in this embodiment, even when a large number of LEDs are arranged on an LED board, the structure is such that the LEDs will not be damaged.

As shown in FIG. 42, the lighting board unit 80 of this embodiment includes an LED board (substrate) 81, a heat radiation sheet 82, a heat radiation plate 83, and the like. The lighting board unit 80 is fixed to the side (lower side) of the base portion 84 by screwing from below. The lighting board unit 80 fixed below the base part 84 will be described below, but a lighting board unit having the same configuration is also arranged above the base part 84. That is, the reels are irradiated with light from above and below, respectively.

The lighting board unit 80 includes a pair of (two) LED boards 81, 81 formed laterally symmetrically. The LED board 81 is formed into a long plate shape extending in the left-right direction. Further, the LED board 81 includes a plurality of LEDs (light sources) 81a arranged at predetermined intervals along the left-right direction. Furthermore, the LED board 81 includes a connector 81b arranged at the outer end in the left-right direction. One LED board 81 includes, for example, 21 to 42 LEDs 81a. The light from this LED 81a is irradiated onto the reels. Note that in this embodiment, two LED boards 81 are provided side by side, but it may be one, or two or more.

Further, the lighting board unit 80 includes a pair (two) of heat dissipation sheets 82, 82 formed symmetrically. The heat dissipation sheet 82 has an outer shape corresponding to the LED board 81, and is formed into a thin sheet shape (for example, about 1 mm thick). Note that in this embodiment, the heat dissipation sheet 82 has an outer shape corresponding to the LED board 81, but the heat dissipation sheet 82 is arranged so as to face (correspond to) at least the position where the plurality of LEDs 81a of the LED board 81 are arranged. It suffices if it is installed in a position where This heat dissipation sheet 82 is in contact with a surface (back surface of the substrate) of the LED board 81 opposite to the LED arrangement surface (front surface of the board). The heat dissipation sheet 82 is made of a material that is both thermally conductive and insulative, and in this embodiment is made of silicon. The heat dissipation sheet 82 can also be called a heat conduction sheet. The heat dissipation sheet 82 is held between the heat dissipation plate 83 and the LED board 81. In this embodiment, two heat dissipation sheets 82 are provided side by side, but it may be one, or two or more heat dissipation sheets 82 may be provided.

Next, the heat sink 83 will be explained using FIG. 43. FIG. 43 is a perspective view of the heat sink (sheet metal) 83 seen from the front. The heat dissipation plate 83 is formed in a long shape extending in the left-right direction, and has a flat part 83a that contacts the heat dissipation sheet 82, and a side opposite to the heat dissipation sheet 82 from the end of the flat part 83a (lower side in this example). It includes a side surface portion 83b extending toward the side surface portion 83b. This heat sink 83 is made of metal, and in this embodiment, it is made of aluminum. As the metal, a material with high thermal conductivity is more preferable. The plane part 83a and the side part 83b are formed by bending a metal plate. By allowing the heat sink 83 to be formed only by bending a metal plate, the time required for manufacturing can be shortened and costs can be reduced. Further, in this embodiment, a convex portion 83c is further provided extending forward from both sides of the side surface portion 83b. Since the heat sink 83 includes the side surface portions 83b and the convex portions 83c, the area (surface area) of the heat sink 83 is increased. By increasing the area of the heat sink 83 that functions as a heat sink, the heat radiation effect of the heat sink 83 to the outside can be further enhanced.

The flow of heat will be explained using FIG. 44. (1) Heat is generated as the LED 81a of the LED board 81 emits light. (2) The heat dissipation sheet 82 receives heat from the LED board 81 side and releases (conducts) the heat to the heat dissipation plate 83 side. (3) The heat sink 83 receives heat from the heat sink sheet 82 and releases the heat to the outside. The amount of heat dissipation varies depending on the materials and areas of the heat dissipation sheet 82 and the heat dissipation plate 83.

According to the lighting board unit 80 of the present embodiment, the LED board 81 on which a plurality of LEDs 81a are arranged contacts the surface of the LED board 81 opposite to the surface on which the LEDs 81a are arranged, and conducts heat. and a metal heat sink 83 that contacts the surface of the heat sink sheet 82 opposite to the surface that contacts the LED board 81. Therefore, even if a plurality of LEDs 81a are arranged on the LED board 81 and the amount of heat generated from the LEDs 81a increases, the heat can be dissipated quickly. Thereby, damage to the LED 81a can be prevented.

In this embodiment, as shown in FIG. 43, the side surface portion 83b of the heat sink 83 is provided only on one side (rear side) of the flat surface portion 83a. However, the present invention is not limited to this, and the side surfaces 83b may be provided to face both sides (ie, the front side and the rear side) of the plane section 83a. That is, when the heat dissipation plate 83 is viewed from the side, it may have a substantially U-shape. Even in this case, the heat sink 83 can be formed only by bending the metal plate. By forming the heat sink 83 in a U-shape when viewed from the side, the area of the heat sink 83 can be made larger and the heat radiation effect can be further enhanced. Note that when viewed from the side, a plurality of ribs connecting the opposing side surfaces 83b, 83b may be provided at predetermined intervals along the left-right direction. In this case, although it is difficult to form the heat sink 83 only by bending, the area of the heat sink 83 can be made larger, and the heat radiation effect can be further enhanced.

Further, a plurality of through holes (through-hole vias, via holes) may be further provided in the LED board 81. The through hole has a function of passing heat from the LED 81a arrangement surface side (the front side of the board) to the back side of the board (the heat dissipation sheet 82 side). For example, the number of through holes is greater than the number of LEDs 81a. Further, the position where the through hole is provided is more preferably near the LED 81a (around the LED 81a) from the viewpoint of dissipating heat. For example, four through holes may be provided around one LED (four times the number of one LED). When a through hole is provided, the heat dissipation sheet 82 is provided at least at a position corresponding to (opposed to) the position where the through hole is formed. By interposing an insulating heat dissipating sheet 82 between the LED board 81 and the metal heat dissipation plate 83, short circuits due to direct contact between the LED board 81 (with through holes) and the heat dissipation plate 83 are avoided. It is possible to provide through holes.

In this way, the LED board 81 has a plurality of through holes, and the heat dissipation sheet 82 is arranged at a position corresponding to the plurality of through holes. Therefore, the heat of the LED 81a on the front surface of the board can be more easily transferred to the back side of the board (toward the heat radiation sheet 82 side) while avoiding direct contact between the LED board 81 and the heat sink 83 to cause a short circuit. . This further enhances the heat dissipation effect and further reduces the risk of damage to the LED 81a.

Further, when providing through holes, they may all have the same diameter, but through holes with different diameters, that is, large diameter through holes and small diameter through holes may be provided. For example, the through holes around the LED 81a may be small diameter through holes, and priority may be given to increasing the number of through holes. However, even in that case, the identification code printed near the LED (for example, the characters "LED10") does not overlap with the through hole, and the visibility of the identification code is ensured. Further, for example, the large diameter through hole may be used mainly for the ground line, and the small diameter through hole may be used mainly for the signal line.

Further, for example, in the case of reel lighting, the LEDs 81a are all white and are controlled so that they are all turned on or all turned off. However, the specifications of the LED 81a are not limited to this, and the emitted light color and number of lights may be set as appropriate for each lighting device.

(Fifth embodiment)
Next, a fifth embodiment of the present invention will be described. In the fifth embodiment, a slot machine, which is one of the gaming machines, will be described, but other gaming machines may be used. Note that in the slot machine of this embodiment, descriptions of the same configurations as those of the first embodiment will be omitted or simplified.

FIG. 45 shows the upper door 112a portion of the gaming machine of this embodiment. A liquid crystal display 813 and design members 150, 150 are provided on the upper door 112a.

The liquid crystal display (display device) 813 is configured to display various presentation images (moving images, still images) in its display area (display surface) 814. Further, the display area 814 has a first display area 814a and a second display area 814b. The first display area 814a is formed in a horizontally elongated rectangular shape approximately in the lower half when the liquid crystal display 813 is viewed from the front. The liquid crystal display 813 is a transmissive liquid crystal display, and is capable of making the members behind the first display area 814a visible.

Behind the first display area 814a, the reel unit 130 is arranged so that a part of the reel unit 130 is visible through the first display area 814a. Then, when the reels 131, 132, and 133 stop, three consecutive symbols per reel are displayed via the first display area 814a. In addition, the first display area 814a is provided with an upper stage, a middle stage, and a lower stage as display positions for visually recognizing the symbols of each reel 131, 132, 133. An effective line is set depending on the combination.

The first display area 814a has a plurality of states including a transparent state and a state in which an effect image is displayed. When the first display area 814a is transparent, the symbols on the reels 131, 132, and 133 are visible. In addition, when the first display area 814a displays the effect image, the effect image is displayed in front of the reels 131, 132, 133.In addition, when the first display area 201 displays the effect image, the reel 131 , 132, and 133 may be visible (easily visible) or may be invisible (hard to see). In this way, the first display area 814a is an area where the symbols of the reels 131, 132, and 133 can be visually recognized, and where images for presentation can be displayed.

The second display area 814b is a portion of the display area 814 of the liquid crystal display 813 excluding the first display area 814a. It is constituted by a narrow horizontally long rectangular area below the first display area 814a and a narrow vertically long rectangular area on the left and right sides of the first display area 814a. That is, the second display area 814b is arranged to surround the first display area 814a. The second display area 814b can display an image for presentation, and can also display one unified image across the second display area 814b and the first display area 814a. Furthermore, the second display area 814b does not have a transparent state, and is configured such that it cannot transmit a member behind it and make it visible. However, the second display area 814b may also have a transparent state. In other words, the entire display area 814 may be the first display area 814a.

45 and 46 show the positional relationship between the liquid crystal display 813 and the design members 150, 150. Here, FIG. 46 is a sectional view of the liquid crystal display 813 and the design members 150, 150 viewed from above. The design members 150, 150 are arranged on both the left and right sides of the upper door 112a with the liquid crystal display 813 in between. Further, the design members 150, 150 have a substantially rectangular box shape that is vertically elongated. Further, the design members 150, 150 have substantially the same length in the vertical direction as the liquid crystal display 813, and are arranged along the left and right sides of the liquid crystal display 813, respectively. Further, the design members 150, 150 are arranged so as to protrude forward so that the front surfaces thereof are located in front of the liquid crystal display 813. The display area 814 is visible from between the left and right design members 150, 150. In other words, the display area 814 is visible through the opening whose width is defined by the design members 150, 150. Further, the left and right design members 150, 150 have a structure that is substantially symmetrical to each other, and their arrangement is also substantially symmetrical.

The design member is a member that decorates the appearance of the gaming machine. In the game machine of this embodiment, the design member 150 is a lighting device (side lamp), but it may be one that does not emit light.

The design member 150 has a side surface (inner wall 820) on the inside in the left-right direction that bulges inward in the left-right direction. Specifically, the inner wall 820 has a swollen shape such that the center portion in the front-rear direction is positioned innermost, thereby forming a protrusion 822. The design member 150 includes two types of speakers 830 and an LED board for illumination (not shown) provided therein, and an exterior member 832 that covers these, and has a protrusion 822 formed therein. This ensures a space to accommodate the speaker and LED board.

The protruding portion 822 is located in front of the liquid crystal display 813 and protrudes inward in the left-right direction from the outer edge of the display area 814. The distance W1 from the apex of the protrusion 822 of one design member 150 to the other design member 150 (the shortest distance from one design member 150 to the other design member 159 in a plane parallel to the display surface of the liquid crystal display 813 distance) is shorter than the width W2 of the display area 814 of the liquid crystal display 813 in the left-right direction. When viewing the liquid crystal display 813 from the front side, the protruding portion 822 is in a state that it extends closer to the display area 814 than the outer edge of the display area 814.

Note that the protrusion 822 does not need to be formed at the center of the design member 150 in the front-rear direction, and may be formed, for example, on the front side in the front-rear direction. In other words, the front surface of the design member 150 may protrude innermost in the left-right direction. In this case, the front surface of the design member 150 can be enlarged, and the presence of the design member 150 can be increased.

Furthermore, the inner wall 820 of the design member 150 has a shape that extends toward the outside of the display area 814 as it goes rearward from the protrusion 822 (the apex of the protrusion 822). In other words, the inner wall 820 of the design member 150 has a shape in which the rear side of the protrusion 822 gradually moves outward in the left-right direction as it goes rearward. Specifically, the inner wall 820 has an inclined surface 824 behind the apex of the protrusion 822 that extends outward in the left-right direction toward the rear.

Further, the rear end of the inner wall 820 of the design member 150 is in contact with or close to the front surface of the liquid crystal display 813. Further, a contact portion (proximate portion) P between the design member 150 (inner wall 820) and the front surface of the liquid crystal display 813 is located outside the display area 814 of the liquid crystal display 813. In the game machine of this embodiment, the contact portion P is substantially flush with the outer edge of the display area 814, and the distance between the contact portions P of the left and right design members 150, 150 is approximately the width W2. They are the same.

As is clear from the above, a part of the design member 150 overlaps a part of the display area 814 in the front-rear direction (direction perpendicular to the display area 814), and a part of the design member 150 overlaps with a part of the display area 814. It is covered. In addition, the design member 150 is configured so that the rear end of the inner wall 820 (the part that comes into contact with the front surface of the liquid crystal display 813) does not overlap the display area 814 in the front-rear direction (direction perpendicular to the display area 814). The area 814 is not covered. That is, a space is formed between the portion (protrusion 822) of the design member 150 that covers the display area 814 and the liquid crystal display 813 so that the end of the display area 814 can be viewed.

The visible range (visible range) of the display area 814 from the player's viewpoint changes depending on the player's standing position. Specifically, as described above, a portion of the design member 150 overlaps a portion of the display area 814 in the front-rear direction, so when viewed from an infinite distance from the front side of the gaming machine (direction perpendicular to the display area 814). In this case (in other words, in the front view (vertical projection view) of the gaming machine), the display area 814 is partially covered by the design member 150 and cannot be seen by the player (see FIG. 45). On the other hand, from a predetermined position, specifically, from the player's eye point Q, the player can view the entire display area 814 without moving his or her face up, down, left or right. Here, the player's eye point Q means the position of the player's eyes when sitting on a chair and playing a game. That is, while the entire display area 814 can be viewed near the gaming machine, the entire display area 814 cannot be viewed far from the gaming machine. In other words, whether the entire display area 814 can be viewed without moving your face depends on whether the distance between the gaming machine and the player's eyes in the front-back direction (direction perpendicular to the display surface) is less than a predetermined distance or greater than a predetermined distance. It changes depending on the situation. It is desirable that this distance is such that the player can see the entire display area 814 while playing the game, and specifically, for example, the distance between the liquid crystal display 813 (display area 814) and When the distance between the player's eyes is less than 50 to 90 cm, it is preferable that the player be able to view the entire display area 814 without moving his or her face up, down, left or right. In other words, it is preferable that the inner wall 820 of the design member 150 does not overlap a straight line from the predetermined point Q, which is less than 50 to 90 cm away from the liquid crystal display 813, to the outer edge of the display area 814.

Further, even when viewed from an infinite distance on the front side of the gaming machine, the specific display is not covered by the design member 150. Here, the specific display includes a display that instructs (suggests) the order of operation of the plurality of stop buttons 124 (so-called batting order navigation displayed during assist time), a display of the manufacturer's name or logo of the gaming machine, and a display of the player's This includes displays to prevent players from becoming too absorbed in the game (addiction prevention displays: warning displays). Note that the addictive prevention display is a text display that alerts players, such as ``Pachinko and slots are games that can be enjoyed in moderation. Be careful not to get addicted.'' The manufacturer's name or logo of the gaming machine and the addictive prevention display are displayed on a demo screen, etc. that is displayed when no games are played for a predetermined period of time.
Note that not all of the specific displays listed here need to be visible even when viewed from an infinite distance. Further, the display of the numerical values related to the game may be such that a part or the whole of each numerical value is covered by the design member 150 when viewed from an infinite distance. Here, the display of numerical values related to games refers to the display of the number of games played by a player in a specific section (specific period), or the number of medals paid out in one game or in a specific section (specific period). display regarding the number of games that can be executed in a predetermined gaming state or performance state, display regarding the number of medals that can be obtained in a predetermined gaming state or performance state, display regarding the number of navigation operations mentioned above, display regarding the number of games that can be executed in a predetermined gaming state or performance state, This includes displaying the count value of the counter related to the display.

Furthermore, even when viewed from an infinite distance on the front side of the gaming machine, the first display area 814a is not covered by the design member 150. In other words, even when viewed from an infinite distance in a direction perpendicular to the display area 814, the reels 131, 132, 133 are not covered by the design member 150; The design is visible.

As described above, the gaming machine of the present embodiment includes the liquid crystal display 813 that displays an effect image in the display area 814 and the design member 150. It has a protrusion 822 that protrudes inward from the outer edge of the display area 814, and has a shape that extends toward the outside of the display area 814 as it goes rearward from the protrusion 822, so that the entire display area 814 is visible. Therefore, the visible range of the player can be widened, and the player's motivation to play can be improved. Furthermore, since the design member 150 can be made larger while ensuring an area that is visible to the player, it is possible to enhance the decorativeness of the gaming machine, and to place large speakers with excellent sound inside the design member. This can improve the player's desire to play.

Note that in this embodiment, the design member 150 having the protrusion 822 and making the entire display area 814 visible is placed next to the liquid crystal display 813; It may be arranged. Further, in this embodiment, the relationship between the liquid crystal display and the design member 150 has been explained using the case of the transmissive liquid crystal display 813 as an example, but the liquid crystal display 113, etc., which is not a transmissive type as shown in the first embodiment, etc. The present invention may be applied to.

(Sixth embodiment)
Next, a sixth embodiment of the present invention will be described. The fifth embodiment stipulates the relationship between the liquid crystal display 813 and the design member 150, and ensures the visibility of the liquid crystal display while enlarging the design member. The visibility of the game media moving in the game area is ensured while increasing the size of the members. Further, the sixth embodiment describes a pachinko game machine. In the pachinko game machine of this embodiment, descriptions of the same configurations as those of the second embodiment will be omitted or simplified.

In the gaming machine of this embodiment, as shown in FIG. 47, the gaming area 4 is divided into a left-handed hitting area 4a located on the left side and a right-handed hitting area 4b located on the right side. By changing the strength, the game ball can be dropped in different areas.

Further, at the upper end of the game area 4, a game ball passage 840 is provided that connects the left-handed hitting area 4a and the right-handed hitting area 4b. A game ball fired from the firing device with a predetermined firing intensity or higher passes through the game ball passage 840 and advances to the right-handed hitting area 4b, whereas a game ball fired from the firing device with a firing strength lower than a predetermined firing intensity is a game ball. The ball does not pass through the passage 840 and proceeds to the left-handed hitting area 4a.

The game ball passage 840 is formed by the outer rail 28 and a rail 841 provided below the outer rail 28 along the outer rail 28. Moreover, the game ball passage 840 is formed including the upper end of the outer rail 28. Further, the width of the game ball passage 840 is longer than the diameter of one game ball and shorter than the diameter of two game balls at the narrowest part. In addition, the narrowest part of the game ball passage 840 is the top of the game ball passage 840, in other words, the part formed by the upper end (top) of the outer rail 28 and the part of the rail 841 opposite to the upper end, and In other words, it is a portion located at the upper end of the gaming area 4.

Further, in the gaming machine of this embodiment, as shown in FIGS. 48 and 49, a substantially rectangular box-shaped design member 850 that is elongated in the left-right direction is provided at the top of the front frame 10. Further, the length of the design member 850 in the left-right direction is more than half the length of the front frame 10 in the left-right direction. Further, the design member 850 is arranged so as to protrude forward so that its front surface is located in front of the game area 4 and the glass unit 8.
In the gaming machine of this embodiment, the glass unit 8 includes two transparent plates (glass plates) 8a and 8b arranged in the front-rear direction with their plate surfaces parallel to each other.

The design member 850 includes an LED board for illumination (not shown) provided inside the design member 850 and an exterior member 851 that covers this, and a space is secured inside the exterior member 851 to accommodate the LED board. has been done. Further, a logo representing the model name, etc. is attached to a portion of the exterior member 851 constituting the front surface of the design member 850, and the logo is illuminated by an LED board provided inside.
Note that a speaker or the like may be provided inside the design member 850.

The front portion of the lower surface 852 of the design member 850 is located at the lowest position. Further, the front portion has a plane 853 that is substantially parallel to the horizontal plane. Further, the lower surface 852 of the design member 850 has an inclined surface 854 that is inclined with respect to the horizontal surface at the rear side of the rear end of the flat surface 853. The lower surface 852 of the design member 850 has a shape in which the rear portion (the inclined surface 854 portion) points upward toward the rear. That is, the front part of the design member 850 protrudes more downward than the rear part, and a protrusion 856 is formed. Further, the rear end of the lower surface 852 (slope surface 854) of the design member 850 is in contact with or close to the glass unit 8.
Note that the shape of the rear end of the lower surface 852 of the design member 850 may be formed along the shape of the outer rail 28. That is, the rear end of the lower surface 852 may be curved upwardly when viewed from the front. Further, in accordance with this, the shape of the lower surface 852 (slanted surface 854) may be shaped like a mortar concave toward the upper side.

FIG. 49 is a schematic diagram of the main parts taken along the line AA in FIG. This shows that. The cross section shown in FIG. 49 also passes through the upper end (top) of the rail 841 and the upper end (top) of the rear end of the lower surface 852 of the decorative member 850.

The rear end of the lower surface 852 of the design member 850 is located below the upper end of the game area 4 in a portion corresponding to the upper end of the game area 4 (the front portion of the upper end of the game area 4). In other words, the rear end of the lower surface 852 of the design member 850 is located below the upper end of the upper surface 840a of the game ball passage 840. Further, the rear end of the lower surface 852 of the design member 850 is located above the upper end of the lower surface 840b of the game ball passage 840. Further, the rear end of the lower surface 852 of the design member 850 is located above the lower end of the game ball B located at the upper end of the game area 4 (the game ball that is in contact with the upper end of the upper surface 840a of the game ball passage 840). positioned. More specifically, it is located above the center of the game ball B in this state (indicated by the dashed line C in FIG. 49).

Further, the protruding portion 856 protrudes downward from the center of the game ball B located at the upper end of the game area 4. In other words, the lower end of the protrusion 856 is located below the center of the game ball B in this state. More specifically, the lower end of the protrusion 856 is located below the lower end of the game ball B in this state. Further, the protruding portion 856 protrudes below the upper end of the lower surface 840b of the game ball passage 840.

As is clear from the above, the design member 850 overlaps the game ball B located at the upper end of the game area 4 in the front-rear direction (direction perpendicular to the game board 6 and the glass unit 8). It is designed to cover the entire game ball B in this state. In addition, the design member 850 has a portion corresponding to the upper end of the gaming area 4 at the rear end of the lower surface 852 (a front portion of the upper end of the gaming area 4) in the front-rear direction (direction perpendicular to the gaming board 6 and the glass unit 8). It does not overlap with at least the lower half of the game ball B located at the upper end of the game area 4, and does not cover at least the lower half of the game ball B in the state. Further, the rear portion of the lower surface 852 is an inclined surface 854. Therefore, even if the game ball is located at the upper end of the game area 4, the player can easily see the game ball rolling in the game area 4. Here, from a predetermined position, specifically, from the player's eye point, it is preferable that at least the lower half of the game ball in this state can be seen without the player moving his or her face up, down, left or right. A player's eye point refers to the position of the player's eyes when sitting on a chair and playing a game. Specifically, for example, when the distance between the glass unit 8 and the player's eyes in the front-rear direction is less than 50 to 90 cm, at least a portion of the game ball in this state can be removed without the player moving his or her face vertically or horizontally. (lower half) should be visible. In other words, the design member is placed on a straight line from a predetermined point that is less than 50 to 90 cm away from the glass unit 8 to the game ball B located at the upper end of the game area 4 (the part below the center of the game ball B). It would be good if it does not cost 850 yen.

(Seventh embodiment)
Next, a seventh embodiment of the present invention will be described. This embodiment relates to an invention related to a board 900 of a gaming machine such as a slot machine or a pachinko gaming machine. The board 900 may be any board including a main board, a sub board, a game machine terminal board (an external terminal board, a terminal board for connecting rental equipment such as game balls, etc.), or various boards shown in other embodiments. Good too.
The external terminal board is for connecting the gaming machine to external electronic equipment (data display device, hall computer, etc.). Information signals are output to external electronic equipment. In addition, the game ball rental device connection terminal board is for connecting the gaming machine to the rental device that rents game media, and information can be sent and received to and from the rental device via this game ball rental device connection terminal board. It is possible.

As shown in FIG. 50, a plurality of electronic components 901 are mounted on the board 900. Here, the electronic components include, for example, an IC, a resistor, a capacitor, a coil, a diode, or a connector. Further, the substrate 900 is provided with a plurality of through holes (via holes) 902.

Further, the board 900 has two board identification marks, a first board identification mark 911 and a second board identification mark 912. Here, the board identification display indicates information regarding the board, specifically, a display that allows each board to be identified, and is represented by a plurality of letters, numbers, symbols, etc.

The first board identification display 911 and the second board identification display 912 display the same content (information). Specifically, the first board identification display 911 and the second board identification display 912 display the same character string "ABC01".

Further, the first substrate identification display 911 is an etched character formed by etching. In other words, the first board identification display 911 is a copper foil character formed of copper foil. On the other hand, the second board identification display 912 is a silk letter formed by silk printing. Since the first board identification mark 911 and the second board identification mark 912 are different between etched letters and silk letters, the reflectance of light, the way of scattering, etc. are different, and the appearance is different.

The substrate 900 is a green substrate. Further, the first board identification display 911 is an etched character and is formed in the same manner as the wiring pattern of the board 900, so it is the same color (similar color) as the wiring pattern, specifically green. Further, the second board identification display 912 is a different color (a color that is not similar) to the first board identification display 911 and the wiring pattern, specifically, white.
Note that the second board identification display 912 may be of a similar color to the first board identification display 911 and the wiring pattern.

Further, the first board identification display 911 and the second board identification display 912 have the same display size. That is, the character string "ABC01" of the first board identification display 911 and the character string "ABC01" of the second board identification display 912 have the same size. Note that these display sizes do not have to be completely the same, but must be within a range that can be considered to be approximately the same when visually recognized (for example, a difference in length and width of one display within ±10%). is preferred.

Further, the second board identification display 912 is located at a position where the first board identification display 911 is moved parallel to the short sides (the left and right sides in FIG. 50) of the board 900. Note that the second board identification display 922 may be placed at a position where the first board identification display 911 is moved parallel to the long sides of the board 900 (the upper and lower sides in FIG. 50). In this way, by arranging the second board identification mark 912 at a position where the first board identification mark 911 is moved in-plane parallel to either side of the board 900, an observer can see the identification mark. The identification markings can be easily found if you wish to check them.

Further, the first board identification display 911 and the second board identification display 912 are arranged at the peripheral edge within the plane of the board 900. In other words, the first board identification display 911 and the second board identification display 912 are arranged near one of the sides of the board 900 and along that side.

Furthermore, the first board identification display 911 and the second board identification display 912 have the same display direction, that is, the direction of the character strings. Specifically, the first board identification display 911 and the second board identification display 912 are arranged so as to be read from left to right in FIG. 50, and the top and bottom of the character strings are aligned with the top and bottom of FIG. We are doing so.

Further, the through hole 902 is not provided in the display range of the first board identification display 911 and the display range of the second board identification display 912. Specifically, no through hole 902 exists between the character strings "ABC01".

Further, the board 900 has an identification display 904 near each electronic component 901 that allows each electronic component 901 to be identified. Specifically, six resistors 901 are mounted on the board 900, and "R1" to "R6" are labeled near each resistor 901 as an identification mark 904 for identifying each resistor 901. A string is written. Furthermore, four capacitors 901 are mounted on the board 900, and near each capacitor 901, a character string of "C1" to "C4" is displayed as an identification display 904 for identifying each capacitor 901. It is written. Further, two ICs 901 are mounted on the board 900, and character strings “IC1” to “IC2” are written near each IC 901 as an identification display 904 for identifying each IC 901. There is. Furthermore, two connectors 901 are mounted on the board 900, and near each connector 901, a character string of "CN1" to "CN2" is displayed as an identification display 904 for identifying each connector 901. It is written.

The identification display 904 is entirely in silk letters. However, part or all of the identification display 904 may be etched characters.

The first board identification display 911 and the second board identification display 912 are larger in display size than other identification displays displayed on the board 900. Specifically, the first board identification display 911 and the second board identification display 912 are larger in display size than any of the identification displays 904.

According to the game machine of this embodiment, a predetermined board 900 provided in the game machine has a first board identification display 911 and a second board identification display 912, and the first board identification display 911 has etched characters. Since the second board identification display 912 is in silk letters, even if one board identification display becomes difficult to see, the other board identification display can be made easy to see. In other words, etched letters and silk letters have different reflectance and scattering of light, so it may be difficult to see one board identification display depending on the environment (conditions of lighting, etc.) of the gaming parlor where the gaming machine is installed. Even if the visibility is reduced, the visibility of the other board identification display is prevented from decreasing, and the identification display can be easily confirmed. In addition, especially regarding the board provided on the side plate (inner surface) of the gaming machine casing (such as the casing 111 in the gaming machine of the first embodiment), it is necessary to look into the board and check the board identification display. Since the board identification display may be located behind components on the board, it may be difficult to see the board identification display, but the gaming machine of this embodiment has two board identification displays. This makes it easy to visually recognize the board identification display.

1,100 Gaming machine 81 LED board (board)
81a LED
82 Heat dissipation sheet 83 Heat dissipation plate

Claims (1)

comprising a board on which a connector is arranged, and a case that protects the board,
A first gap is defined as a gap between an end surface of the substrate and an inner surface of the side wall of the case,
If the gap where the side surface of the connector and the inner surface of the connector opening of the case face each other is defined as a second gap,
In the gaming machine , the second gap is larger than the first gap .

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