JP2018033814A - Game machine - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a game machine capable of easily changing a prescribed display.SOLUTION: A pachinko game machine 1 is provided with a presentation unit 27 at a prescribed position, the presentation unit 27 having: a body part 82 of which inside an LED 90 is disposed; and a display part 83 which is attached to the body part 82 and which can cause a visual recognition of a prescribed display by transmitting the light from the LED 90. The display part 83 is attachable/detachable to and from the body part 82 through a fitting or engagement by an engaging member 95 of a lock part 93 being engaged with an engaged member 94.SELECTED DRAWING: Figure 10

Description

  The present invention provides an effect unit having a main body portion having a light source disposed therein and a display unit that is attached to the main body portion and that allows a predetermined display to be seen by transmitting light from the light source. The present invention relates to a gaming machine provided.

  2. Description of the Related Art Conventionally, there has been proposed an effect unit in which a light source is disposed inside a glass frame of a gaming machine such as a pachinko machine or a slot machine, and a predetermined display can be visually recognized by transmitting light from the light source. Such a production unit has, for example, a moving rotator that moves and rotates in accordance with the gaming state of the gaming machine, and is configured to enhance the effect by emitting light from the inside of the moving rotator. In addition, since this prior art is not related to the literature known invention, there is no prior art document information to be described.

  However, in the above-described prior art, for example, when it is desired to change the predetermined display by replacing the gaming machine, it is necessary to replace the entire effect unit.

  The present invention has been made in view of such circumstances, and an object thereof is to provide a gaming machine capable of easily changing a predetermined display.

  The invention according to claim 1 includes a main body portion in which a light source is disposed, and a display portion that is attached to the main body portion and transmits a light from the light source so that a predetermined display can be visually recognized. A gaming machine provided with a production unit at a predetermined site, wherein the display unit is detachable by fitting or locking to the main body unit.

  According to a second aspect of the present invention, in the gaming machine according to the first aspect, the main body is attached to a frame member of the gaming machine, and the display unit can visually recognize a predetermined display relating to the gaming machine. It is characterized by.

  According to a third aspect of the present invention, in the gaming machine according to the first or second aspect, the display unit has a lock part that can be fixed to the main body part, and the lock part is the gaming machine. It is characterized in that it is formed at a position where it is difficult for a player to visually recognize the game.

  According to the present invention, it is possible to provide a gaming machine capable of easily changing a predetermined display.

The front schematic diagram which shows the game machine of the state in which the production unit which concerns on embodiment of this invention was attached to the glass frame. Block diagram showing the components of the gaming machine It is a schematic diagram which shows the state of the electric tulip in the same game machine, Comprising: (a) Closed state, (b) The figure which shows an open state A perspective view showing frame members (glass frame, outer frame and inner frame) in the same gaming machine Overall view (front side) showing an effect unit when the moving rotating body according to the present embodiment is located at the advance position Overall view (back side) showing a production unit when the moving rotator according to the present embodiment is located at the advance position. Overall view showing the effect unit when the moving rotator according to the present embodiment is located at the origin position The side view which shows the production | presentation unit in case the moving rotary body which concerns on this embodiment is located in the advance position The top view which shows the internal structure of the moving rotary body which concerns on this embodiment Cross-sectional view showing the internal configuration of the moving rotating body according to the present embodiment The perspective view which shows the state by which the display part was attached to the main-body part of the moving rotary body which concerns on this embodiment. The perspective view which shows the state by which the display part was attached to the main-body part of the moving rotary body which concerns on this embodiment. The rear view which shows the attachment structure (before lock) of the display part with respect to the main-body part of the moving rotary body which concerns on this embodiment. The rear view which shows the attachment structure (after locking) of the display part with respect to the main-body part of the moving rotary body which concerns on this embodiment.

Hereinafter, embodiments of the present invention will be specifically described with reference to the drawings.
The gaming machine according to the present embodiment is composed of a pachinko gaming machine 1 and is configured so that a player can visually observe the gaming board 4 from the glass plate 2 as shown in FIG. Various types of accessories, a plurality of nails, a windmill, and the like are formed. Further, the game board 4 is formed with an electric tulip 7 having a first start port 6, a second start port 7a (see FIG. 3), a prize winning port 8, a gate 9, and the like. A handle 14 is provided at the lower right corner of the pachinko gaming machine 1 and is configured to launch a game ball in the tray 13 to the game board 4 by rotating the handle 14. Accordingly, an operation button 3 that can be arbitrarily pressed by the player is attached.

  The first start port 6 and the electric tulip 7 are arranged side by side in the vertical direction below the symbol display unit 5 (specifically, a liquid crystal image display device) on the game board 4. Game balls can be won. Among these, the first starting port 6 is for acquiring numerical data (specifically, a random number for jackpot and a random number for presentation) that can be determined whether or not the game ball wins, and is directed upward. The game is open and the game ball is always allowed to win.

  The second start opening 7a in the electric tulip 7 is called a variable winning opening. As shown in FIG. 3, the electric tulip 7 is in a closed state in which the winning of the game ball is restricted (see FIG. 3A). The game ball can be won by operating up to an open state (see FIG. 5B) that allows winning of the game ball. Thus, the second start port 7a is numerical data (specifically, a jackpot random number value and an effect random number value) that can be determined whether or not the jackpot is won when the electric tulip 7 is opened and the game ball is won. To get.

  Further, in the pachinko gaming machine 1 according to the present embodiment, a first special symbol display means 10 and a second special symbol display means 11 made of, for example, 7 segments are formed. The first special symbol display means 10 displays a special symbol (first special symbol) in a variable manner when a game ball wins at the first starting port 6, and the random number value (big jackpot) acquired at the time of winning the first starting port 6 The special symbol corresponding to the random number) is stopped and displayed. The second special symbol display means 11 is configured to display the special symbol (second special symbol) when the game ball is won by the electric tulip 7 being opened. Is displayed in a variable manner, and a special symbol corresponding to the random value (big value for jackpot) acquired at the time of winning the electric tulip 7 is stopped and displayed.

  In other words, the winning for the first starting port 6 and the winning for the second starting port 7a of the electric tulip 7 are controlled independently of each other. When winning the first starting port 6, the first special symbol display means 10 is used. The variation display of the first special symbol is started, and when the electric tulip 7 wins the second start port 7a, the variation display of the second special symbol by the second special symbol display means 11 is started.

  The gate 9 is configured to allow game balls to pass therethrough, and unlike other winning holes, no prize balls are paid out by passing. Further, a normal symbol display means 12 is disposed in the vicinity of the first special symbol display means 10 and the second special symbol display means 11. When the game ball passes through the gate 9, the normal symbol display means 12 displays the normal symbol in a variable manner (in this embodiment, the circle mark and the cross mark are alternately lit), and a predetermined normal symbol (this embodiment). When a circle is displayed in a stopped state, it becomes a “win” and the electric tulip 7 is opened for a predetermined time.

  In the present embodiment, it is set so that the player can be more advantageous when winning the electric tulip 7 (second starting port) than when winning the first starting port 6. For example, in the high probability gaming state, when winning the second starting port 7a of the electric tulip 7, the probability of winning short is set very low (or not short winning), while the high probability gaming state is also the same. Even so, when the first starting port 6 is won, the probability that the gaming state is short hit is set to be relatively high.

  Here, “short win” means that the right to execute the short win game was acquired in the lottery in the big hit state performed on condition that the game ball entered the first start port 6 or the second start port 7a. A game state executed in a case. In such a “short win game state”, the round game in which the big winning opening 8 is opened is performed two times less than the “long win”, but in each round game, the big winning opening 8 is once. Only the opening time is set to 0.1 seconds.

  On the other hand, “long winning” means that a long winning game is obtained in a jackpot lottery performed on condition that a game ball has entered the first starting port 6 or the second starting port 7a. A game state executed in a case. In such a “long game state”, the round game in which the grand prize opening 8 is opened is performed 15 times in total, and the total opening time of the big prize opening 8 in each round game is set to a maximum of 30 seconds. During this time, when a predetermined number of game balls (for example, 9 balls) enter the grand prize winning opening 8, one round game is set to end.

  The symbol display unit 5 is composed of a liquid crystal image display device or the like disposed substantially at the center of the game board 4 and can display a predetermined symbol or background on the screen, and corresponds to the first special symbol display means 10. A symbol (decorative symbol) corresponding to the symbol (decorative symbol) or the second special symbol display means 11 can be variably displayed or stopped. Then, when a predetermined symbol is stopped and displayed (for example, the same symbol is stopped and displayed), a “hit state” occurs, and the big winning opening 8 is opened at a predetermined time and timing, so that a large number of game balls can be obtained. It is configured as follows.

  In the present invention (including this embodiment), the decorative symbol corresponding to the first special symbol that is displayed in a variable manner or stopped on the symbol display unit 5 is also referred to as a “first special symbol” and is displayed on the symbol display unit 5. The decorative symbol corresponding to the second special symbol displayed in a variable manner or stopped is also referred to as a “second special symbol”. That is, the first special symbol that is changed or stopped by the first special symbol display means 10 and the second special symbol that is changed or stopped by the second special symbol display means 11 are displayed on the symbol display unit 5. Since there is a relationship that always corresponds to the decorative symbols that are changed or stopped, the names of the symbols are the same.

  In addition, when the symbol stopped and displayed on the symbol display unit 5 is a predetermined specific symbol (that is, the random value acquired when winning the first starting port 6 or the second starting port 7a of the electric tulip 7) When a special symbol predetermined according to (a jackpot random value) is stopped and displayed by the first special symbol display means 10 or the second special symbol display means 11), the probability of the jackpot occurrence is increased than usual. Benefits are given to players. That is, at the end of the jackpot state, the player is given a privilege that the next jackpot will occur with a high probability on the condition that the stop symbol that caused the jackpot state is a specific symbol. Thus, a gaming state in which a jackpot state occurs with a normal probability is referred to as a normal probability gaming state, and a gaming state in which a jackpot state occurs with a higher probability than the normal probability is referred to as a high probability gaming state.

  The first special symbol holding lamp 15 is variably displayed with symbols (first special symbol or second special symbol) on the symbol display section 5 (the same applies to the first special symbol display means 10 and the second special symbol display means 11). In the meantime, when a game ball wins at the first start opening 6, the predetermined number (four in this embodiment) is limited and the winning game balls are held as holding balls. Similarly, the second special symbol holding lamp 16 has a symbol (first special symbol or second special symbol) in the symbol display section 5 (the first special symbol display means 10 and the second special symbol display means 11 are also the same). When a game ball wins at the first start port 6 while the display is variably displayed, the winning game ball is held as a holding ball up to a predetermined number (four in this embodiment). .

  Further, as shown in FIG. 2, a main control board 17 and a sub control board 18 are disposed on the back surface of the pachinko gaming machine 1 according to the present embodiment. Among these, the sub control board 18 performs various controls based on the control signal transmitted from the main control board 17, and the effect control board 19 electrically connected to the symbol display unit 5, the speaker, etc. The lamp control board 20 is electrically connected to a lamp, a movable accessory, and the like, and the payout control board 21 is electrically connected to a payout drive motor and the like.

  The main control board 17 controls game contents throughout the pachinko gaming machine 1 and includes a CPU, a ROM, a RAM, and the like. The main control board 17 includes the first special symbol display means 10, the second special symbol display means 11, the normal symbol display means 12, the first special symbol hold lamp 15 and the second special symbol hold lamp 16 described above. , A start port SW for detecting a winning of a game ball to the first start port 6 and the second start port 7a, a solenoid of the electric tulip 7 for driving the electric tulip 7, and a passage of the game ball of the gate 9 are detected. A gate SW for performing the game, a large winning port SW for detecting the winning of the game ball to the large winning port 8, a large winning port solenoid for driving the large winning port 8, and the like are electrically connected.

  The main control board 17 according to the present embodiment is a jackpot for determining a jackpot state or a loss that is advantageous to the player in response to a winning of a game ball at the starting port (the first starting port 6 and the second starting port 7a). Lottery means 22 for obtaining numerical value data (random value) and production numerical data (random value) for determining the production mode, and a game ball at the start port (first start port 6 and second start port 7a) There is a storage means 23 for storing numerical data (numerical data for jackpots and numerical data for effects) acquired as a result of winning a prize as reserved data. In particular, the storage means 23 according to the present embodiment stores numerical data (numerical data for jackpots and numerical data for effects) acquired as a first hold data when a game ball wins a prize at the first start port 6. In addition, numerical data (numerical data for jackpots and numerical data for performance) acquired in response to the winning of a game ball at the second starting port 7a is stored as second reserved data.

  The effect control board 19 is configured to include a CPU, a ROM, a RAM, and the like, and performs various controls mainly related to effects based on a control signal transmitted from the main control board 17. The effect control board 19 is also electrically connected to the lamp control board 20 and, based on the control signal transmitted from the main control board 17, the decorative lamp, the movable accessory, etc. are transmitted via the lamp control board 20. It is configured to perform a predetermined effect by controlling.

  By the way, as shown in FIG. 4, the pachinko gaming machine 1 according to the present embodiment has an outer frame 25 attached to an island facility of a game shop, and an inner frame 26 supported to be rotatable with respect to the outer frame 25. And a glass frame 24 supported to be rotatable with respect to the inner frame 26 on the front side of the inner frame 26. In the glass frame 24, the glass plate 2 is detachably provided from the back side. A glass frame opening switch (not shown) for detecting that the glass frame 24 has been opened is provided at a predetermined position of the glass frame 24, and the inner frame 26 is provided at a predetermined position of the inner frame 26. An inner frame opening switch (not shown) for detecting the opening is provided. The inner frame 26 is provided with main mechanisms constituting the pachinko gaming machine 1, various components, a substrate, and the like, and a game board 4 is detachably provided.

  Here, on the upper part of the glass frame 24 (frame member) of the pachinko gaming machine 1 according to the present embodiment, a production unit 27 is attached to a predetermined part (upper part in the present embodiment) as shown in FIGS. It has been. The effect unit 27 includes a moving rotator 28 that is displaceable between an origin position (position in FIG. 7) and an advanced position (positions in FIGS. 5 and 6), and a support member 29 that supports the moving rotator 28. have. The support member 29 is formed on the periphery of the base 30 so as to stand on the front side (outside) of the glass frame 24 and the base 30 fixed to the front side (outside) of the glass frame 24. It has standing part 31a, 31b which supports.

  As shown in FIGS. 5 and 6, the base 30 is provided with a movement control mechanism for controlling the movement of the moving rotator 28 (movement between the origin position and the advance position). Includes a motor mechanism 32 provided in the base 30 and wire tension adjusting mechanisms 33a and 33b provided on the left and right sides of the motor mechanism 32. The specific configurations of the motor mechanism 32 and the wire tension adjusting mechanisms 33a and 33b will be described later.

  In addition, the base 30 is electrically connected to the lamp control board 20 (see FIG. 2) and inputs the game information of the pachinko gaming machine 1 to control the movement of the moving rotator 28 in a predetermined manner. The moving rotator control board 34 provided with the board 34 is provided in the effect unit 27 so as to substantially cover the left wire tension adjusting mechanism 33b. Therefore, in FIGS. The wire tension adjusting mechanism 33b is substantially hidden by the movable rotating body control board 34.

  5 and 6, cylindrical fastening members 36a and 36b to which the lower ends (ends on the origin side) of the basic coil springs 35a and 35b are fastened are provided on both the left and right ends of the base 30 so as to be fastened. On the front side of the members 36a and 36b in the drawing, restriction plates 38a and 38b for restricting the movement of the auxiliary coil springs 37a and 37b to the origin side are provided. The fastening members 36 a and 36 b and the regulation plates 38 a and 38 b are formed on the advance position side by a predetermined distance with respect to the base 30.

  Further, buffer members 39a and 39b made of rubber or the like are provided at substantially the center of the surface of the regulating plates 38a and 38b. The basic coil springs 35a and 35b and the auxiliary coil springs 37a and 37b are formed in parallel with a slight gap so as to overlap in the front and rear, the auxiliary coil springs 37a and 37b are located on the front side, and the basic coil on the rear side. The springs 35a and 35b are provided so as to be positioned.

  As shown in FIG. 8, a groove 40a is bored in the standing portion 31a in parallel with the direction in which the movable rotating body 28 advances. FIG. 8 is a right side view of the effect unit 27 in FIGS. 5 and 6 (when the moving rotator 28 is located at the advanced position). Further, although the left side view of the effect unit 27 is omitted, a groove 40b similar to the groove 40a is also formed in the standing portion 31b. Further, in the standing portions 31a and 31b, second grooves parallel to the grooves 40a and 40b, that is, parallel to the direction in which the moving rotating body 28 advances, are formed on the inner surfaces of the grooves 40a and 40b in FIGS. Guide members 41a and 41b are attached.

  A first guide member 42a that is parallel to the groove 40a, that is, parallel to the direction in which the moving rotator 28 advances, is attached to the standing portion 31a that is the right end portion of the moving rotator 28. Further, as shown in FIG. 8, a covering member 46a having a first stopper portion 44a and a second stopper portion 45a in a stepped shape (a position where the first stopper portion 44a is high) from the upper side of the side cover 43a to the lower side on the back side. Is provided. A first storage groove 49a for storing a first slide member 47a (described later) is provided below the first stopper portion 44a, and a second slide member 48a for storing a second slide member 48a (described later) is stored below the second stopper portion 45a. Two storage grooves 50a are respectively formed.

  Further, a fastening portion 54a having a hollow inside for fastening the upper end portion of the auxiliary coil spring 37a is provided below the side cover 43a. Similarly, the side cover 43b, which is the left end portion of the movable rotating body 28, includes a first storage groove 49b, a second storage groove 50b, a first guide member 42b, a first stopper portion 44b, and a second stopper portion 45b. A covering member 46b and a fastening portion 54b are provided.

  In the drawing, reference numerals 51a and 51b denote slide mechanisms, and the slide mechanisms 51a and 51b connect the movable rotating body 28 and the support member 29 (the base 30 and the standing portions 31a and 31b). That is, the slide mechanisms 51a and 51b have a function for defining the advancing direction of the moving rotator 28 and its moving range. The slide mechanisms 51a and 51b include first slide members 47a and 47b that engage with the first guide members 42a and 42b provided on the movable rotating body 28, and a second guide member 41a that is provided on the standing portions 31a and 31b. , 41b and second slide members 48a, 48b.

  As shown in FIG. 8, the first slide members 47a and 47b and the second slide members 48a and 48b are integrally formed in a step shape (a position where the first slide members 47a and 47b are high). 47a and 47b are located in front of the second slide members 48a and 48b. The surfaces of the first slide members 47a and 47b that engage with the first guide members 42a and 42b face inward, and the surfaces of the second slide members 48a and 48b that engage with the second guide members 41a and 41b. Is facing the outside.

  Further, a cylindrical shape that protrudes outwardly and slidably fits in the grooves 40a and 40b at the origin side end of the first slide members 47a and 47b opposite to the engagement surface with the first guide members 42a and 42b. The slide projections 52a and 52b are projected. The slide protrusions 52a and 52b have a function for defining the movement range of the first slide members 47a and 47b and the second slide members 48a and 48b in the advancing direction, that is, a function for defining the movement range of the moving rotating body 28. Have

  Plate-shaped fastening members 53a and 53b projecting inward to fasten the lower ends of the auxiliary coil springs 37a and 37b are provided at the lower ends (the end portions on the origin side) of the first slide members 47a and 47b. Accordingly, both ends of the auxiliary coil springs 37a and 37b are fixed by the fastening portions 54a and 54b and the fastening members 53a and 53b, and are spanned between the side covers 43a and 43b and the slide mechanisms 51a and 51b of the movable rotating body 28. It is.

  In addition, between the fastening parts 54a and 54b and the fastening members 53a and 53b, round bar-like connecting members 55a and 55b that connect the fastening parts 54a and 54b and the fastening members 53a and 53b are moved by the moving rotator 28. The connecting members 55a and 55b are loosely inserted into the auxiliary coil springs 37a and 37b. That is, the connecting members 55a and 55b have a function of extending and contracting the auxiliary coil springs 37a and 37b by stably guiding the auxiliary coil springs 37a and 37b in the advancing direction of the movable rotating body 28.

  Plate-shaped fastening members 56a and 56b projecting inward to fasten the upper ends of the basic coil springs 35a and 35b are provided at the upper ends (end portions on the advancing side) of the second slide members 48a and 48b. Therefore, both ends of the basic coil springs 35a and 35b are fixed by the fastening members 36a and 36b and the fastening members 56a and 56b, and are spanned between the left and right ends of the base 30 and the slide mechanisms 51a and 51b.

  In addition, between the fastening members 36a and 36b and the fastening members 56a and 56b, round bar-like connecting members 57a and 57b that connect the fastening members 36a and 36b and the fastening members 56a and 56b are movable rotors 28. The connecting members 57a and 57b are loosely inserted into the basic coil springs 35a and 35b. That is, the connecting members 57a and 57b have a function of extending and contracting the basic coil springs 35a and 35b by stably guiding them in the advancing direction of the movable rotating body 28.

  In the figure, reference numerals 58a and 58b denote wires, and one end (advance side end) of the wires 58a and 58b is fixed to the lower side (origin side part) of the side cover 43a and 43b of the movable rotating body 28. Fastening members 59a and 59b to be worn are provided. Further, the other ends (origin side ends) of the wires 58a and 58b are fixed to the motor mechanism 32 provided in the base portion 30. Further, wire tension adjusting mechanisms 33 a and 33 b are provided between the fastening members 59 a and 59 b and the motor mechanism 32. That is, the wires 58a and 58b are fixed to the left and right ends of the movable rotating body 28 and the motor mechanism 32 via the wire tension adjusting mechanisms 33a and 33b.

  Here, the configuration of the motor mechanism 32 will be described with reference to FIG. The motor mechanism 32 includes a motor 60, a worm gear 63 including a worm 61 and a worm gear 62, and a wire winding unit 64. The motor 60 is a stepping motor, and is connected to the moving rotator control board 34 by a harness 65. Based on a command from the moving rotator control board 34, the motor 60 rotates in a predetermined number of steps in both directions (forward rotation and reverse rotation). Control possible. The moving rotating body control board 34 is connected to the lamp control board 20 by a harness 65 and inputs game information of the pachinko gaming machine 1 and issues a command to the motor 60 based on the input game information. ing.

  The worm 61 is a helically toothed screw gear attached to the motor shaft of the motor 60, and rotates in both directions (forward rotation and reverse rotation) in conjunction with the rotation of the motor shaft. The worm 61 meshes with the worm gear 62 to form a worm gear 63, and the worm gear 62 is rotated by its own rotation. The worm gear 62 is a disc-shaped gear having a large number of teeth meshing with the worm 61 and rotates in both directions (forward rotation and reverse rotation) in conjunction with the rotation of the worm 61. Note that the shaft angle between the motor shaft of the motor 60 (the shaft of the worm 61) and the shaft of the worm gear 62 is set to approximately 90 degrees.

  In FIG. 5, the wire take-up portion 64 is provided below the worm gear 62 and normally rotates in both directions (forward rotation and reverse rotation) in conjunction with the rotation of the worm gear 62. The wire take-up portion 64 is formed in two upper and lower stages, and in this embodiment, the right wire 58a is taken up at the upper stage and the left wire 58b is taken up at the lower stage. That is, the other end (origin side end) of the wire 58 a is fixed to the upper stage side of the wire winding portion 64, and the other end (origin side end) of the wire 58 b is fixed to the lower stage side of the wire winding portion 64.

  Here, a torque limiter (not shown) is provided between the worm gear 62 and the wire take-up portion 64. When the torque limiter is operated, the worm gear 62 rotates from the worm gear 62 even if it further rotates. Further torque transmission to the winding unit 64 is cut off, and the wire winding unit 64 does not rotate and maintains a stopped state. Further, a clutch mechanism (not shown) is provided between the worm gear 62 and the wire take-up portion 64, and this clutch mechanism controls the intermittent transmission of power from the worm gear 62 to the wire take-up portion 64. .

  Next, the configuration of the wire tension adjusting mechanisms 33a and 33b will be described with reference to FIG. Since the wire tension adjusting mechanism 33a and the wire tension adjusting mechanism 33b have the same configuration, here, the wire tension adjusting mechanism 33a will be described as a representative. The wire tension adjusting mechanism 33a includes a vertical pulley 66 and a horizontal pulley 67 as two fixed pulleys, and a first pulley 68 and a second pulley 69 as two moving pulleys.

  In FIG. 5, a vertical pulley 66 is a pulley provided so as to be rotatable in the vertical direction, and is disposed on the left side of a fastening member 36a to which a lower end of a basic coil spring 35a is fastened. A wire 58a extending from the landing member 59a is locked on the lower side of the vertical pulley 66, and is guided to the horizontal pulley 67 by changing the direction by approximately 90 degrees. Note that the wire 58a positioned between the vertical pulley 66 and the fastening member 59a is stretched in substantially the same direction as the advancing direction of the movable rotating body 28.

  The horizontal pulley 67 is a pulley that is rotatably provided in the horizontal direction. The horizontal pulley 67 is disposed on the rear side of the vertical pulley 66, and locks a wire 58a extending from the vertical pulley 66 on the rear side of the horizontal pulley 67. The direction is changed by 180 degrees and guided to the first pulley 68. The first pulley 68 is a pulley provided so as to be capable of rotating in the lateral direction. The first pulley 68 is disposed on the left side of the horizontal pulley 67 and locks a wire 58a extending from the horizontal pulley 67 on the front side of the first pulley 68. It is guided to 2 pulleys 69. The second pulley 69 is a pulley that is rotatably provided in the lateral direction, and is disposed on the left side of the first pulley 68, that is, on the right side of the wire winding portion 64, and the wire 58 a extending from the first pulley 68 is connected to the first pulley 68. The two pulleys 69 are engaged at the rear side, and are guided from the front side of the wire winding portion 64 to the upper stage side of the wire winding portion 64.

  With the above configuration, the wire 58a extending from the fastening member 59a of the movable rotating body 28 passes through the vertical pulley 66, the horizontal pulley 67, the first pulley 68, and the second pulley 69 to the upper stage side of the wire winding portion 64. Be guided. The vertical pulley 66, the horizontal pulley 67, the first pulley 68, and the second pulley 69 are provided with insertion holes for inserting the wires 58a. Therefore, even when the wires 58a are loosened, The wire 58a is not separated from the vertical pulley 66, the horizontal pulley 67, the first pulley 68, and the second pulley 69.

  Here, in FIG. 5 and FIG. 6, two round bar-shaped first slide shafts 70 and second slide shafts 71 laid in the front-rear direction in FIG. Is arranged on the right side, and the second slide shaft 71 is arranged on the left side. Thus, the first slide shaft 70 is loosely fitted with the first pulley 68 and the first coil spring 72 that constantly urges the first pulley 68 forward, and the second slide shaft 71 has the second slide. A pulley 69 and a second coil spring 73 that constantly biases the second pulley 69 to the rear side are loosely fitted.

  Accordingly, the first pulley 68 is provided so as to be movable on the first slide shaft 70, and the second pulley 69 is provided so as to be movable on the second slide shaft 71. In other words, the first slide shaft 68 and the second slide shaft 69 extend and contract the first coil spring 72 and the second coil spring 73 by stably guiding the first and second coil springs 72 and 73 in the axial direction of the base 30. It has a function of moving 69 with respect to the base 30 stably.

  The wire tension adjusting mechanism 33b provided on the left side of the motor mechanism 32 is further provided with one horizontal pulley 74 (fixed pulley) in addition to the above four pulleys. The horizontal pulley 74 is for winding the wire 58b from the rear side of the wire winding portion 64, and the horizontal pulley 74 allows the wire 58b to obtain a sufficient tension.

  The standing portion 31b is provided with an origin position detection sensor (not shown) for detecting whether or not the moving rotator 28 is at the origin position. The origin position detection sensor is a second guide member 41b. It is arranged on the rear side and in the vicinity of the fastening member 36b to which the lower end of the basic coil spring 35b is fastened. The origin position detection sensor is composed of an optical sensor, and when the moving rotator 28 is located at the origin position, a light shielding member (not shown) provided at the lower end of the cover member 46b is provided between the light emitting part and the light receiving part of the optical sensor. By entering between and blocking the light, it is detected whether or not the moving rotating body 28 is at the origin position. The origin position detection sensor is connected to the moving rotator control board 34 via the harness 75 and outputs a detection result, that is, a signal indicating whether or not the moving rotator 28 is at the origin position to the moving rotator control board 34. . The origin position detection sensor may be composed of other sensors such as a magnetic sensor, or may be provided in the standing portion 31a.

  Further, one end of a flexible flat cable (FFC) 76 is connected to the moving rotator control board 34, and the other end is connected to a relay board 77 shown in FIG. ing. In the figure, reference numeral 78 denotes a protective member for protecting the flexible flat cable 76. The protective member 78 is formed in a thin hollow shape from a material such as a resin, and the flexible flat cable 76 is idled therein. It is inserted.

  The protection member 78 includes a lower hinge 79 formed at the lower end (the end on the origin side) connected to the base 30 and an upper hinge 80 formed at the upper end (the end on the advancing side) connected to the moving rotator 28. And a middle hinge 81 formed between the lower hinge 79 and the upper hinge 80. These three hinges 79 are moved in accordance with the movement of the movable rotating body 28 (movement between the origin position and the advanced position). , 80, 81 rotate, the protective member 78 bends or extends in the shape of a "<" at the 81 position of the middle hinge so as to expand and contract. Moreover, between the hinges, that is, between the lower hinge 79 and the middle hinge 81 and between the upper hinge 80 and the middle hinge 81, the flexible flat cable 76 is also included in the protective member 78. Similarly, it is fixed in a wave shape. The protective member 78 configured in this way can prevent the flexible flat cable 76 from being damaged as the moving rotating body 28 moves.

Next, the rendering unit 27 according to the present embodiment will be described with reference to FIGS.
The production unit 27 includes a moving rotator 28. The moving rotator 28 is attached to the main body 82 having an LED 90 (light source) disposed therein, and the main body 82, and from the LED 90 (light source). A display unit 83 that can transmit a predetermined amount of light and visually recognize a predetermined display (in this embodiment, the display is “AAA”, which is a display related to the pachinko gaming machine 1), and the side cover 43a described above. 43b.

  The main body 82 is attached to the frame member of the pachinko gaming machine 1 (in this embodiment, the glass frame 24), and has a cover member K, an outer 84, and a drive mechanism 85. Each of the outer 84 and the cover member K is made of a resin member formed in a football shape (an elliptical shape with a central diameter larger than both ends), and the outer 84 is rotatable in the cover member K. The outer 84 is formed in a hollow shape so as to accommodate the drive mechanism 85 and the like.

  That is, the outer 84 and the cover member K can transmit the light of the LED 90, and the outer 84 is configured to rotate within the cover member K. The drive mechanism portion 85 is provided inside the outer 84, and a base plate 86 is provided at the approximate center thereof. The left and right ends of the base plate 86 are fixed to the side covers 43a and 43b. 9 is a diagram in which the configuration of the front half of the cover member K, the configuration of the front half of the display unit 83 and the outer 84, and the reflector lens R are removed from the movable rotating body 28.

  A motor 87 and a relay board 77 are attached to the base plate 86. The motor 87 has a motor shaft 88 that rotates by driving, and rotating wheels 89 a and 89 b are attached to both ends of the motor shaft 88. The peripheral edges of the rotating wheels 89 a and 89 b are attached along the peripheral walls at both ends of the outer 84. Accordingly, when the motor shaft 88 is rotated by driving the motor 87, the rotating wheels 89a and 89b are rotated in conjunction with the rotation, so that the outer 84 rotates (swings) around the motor shaft 88. ing. The motor 87 is a stepping motor, and is connected to the movable rotating body control board 34 via the relay board 77 by the flexible flat cable 76. Therefore, the motor 87 is bidirectional based on a command from the movable rotating body control board 34. It is controlled to be able to rotate a predetermined number of steps (forward rotation, reverse rotation).

  A plurality of LEDs 90 (for example, full color LEDs) are provided on the front surface side of the relay board 77, and these LEDs 90 are connected to the movable rotating body control board 34 via the relay board 77 by the flexible flat cable 76, Based on a command from the moving rotator control board 34, lighting control is performed in a predetermined manner. As shown in FIG. 10, a reflector lens R is provided between the relay substrate 77 and the outer 84, and the reflector lens R enables efficient light emission.

  Further, the base plate 86 is provided with a rotational position detection sensor (not shown) for detecting whether or not the outer 84 is in a predetermined position. Is located at a predetermined position, a light shielding member (not shown) provided on the rotating wheel 89b enters between the light emitting part and the light receiving part of the optical sensor to block the light, so that the outer 84 is in the predetermined position. It is comprised so that it may detect whether it exists in.

  The display portion 83 is attached along the outer peripheral surface of the main body portion 82, covers the main body portion 82, is made of a transparent or translucent resin material, and includes an LED 90 (light source) disposed inside the main body portion 82. Is transmitted so that a predetermined display (display “AAA”) can be visually recognized. In the present embodiment, the predetermined display “AAA” is a display related to the pachinko gaming machine 1 and can be visually recognized by the player. In addition, it may replace with this predetermined | prescribed display and may be a display different from the display regarding the pachinko gaming machine 1, and the display form may be a predetermined pattern or a photograph in addition to characters.

  Further, as shown in FIGS. 11 and 12, the display unit 83 includes a plurality (three in the present embodiment) of arcuate plate members (83a, 83b, 83c), and the arcuate plate member 83a and the arcuate plate member The plate member 83 b is rotatably connected by a hinge 91, and the arc-shaped plate member 83 a and the arc-shaped plate member 83 c are rotatably connected by a hinge 92. These arc-shaped plate members (83a, 83b, 83c) have an arc shape that follows the shape of the side surface of the main body portion 82, and can cover the entire outer periphery of the main body portion 82 while bending the hinges 91, 92. ing.

  Here, the display portion 83 according to the present embodiment is detachable by fitting or locking to the main body portion 82 and can be fixed to the main body portion 82 as shown in FIGS. The lock portion 93 is configured. The lock portion 93 includes a locking member 95 provided at an end portion of the arc-shaped plate member 83b of the display portion 83, and a locked member 94 provided at an end portion of the arc-shaped plate member 83c of the display portion 83. It is configured. The locking member 95 is made of a frame-shaped part formed in a square shape, and can be slid while being guided in the left-right direction in the figure by inserting a guide portion 96 such as a screw into the central opening. It is said that.

  When the arc-shaped plate members (83a, 83b, 83c) are covered over the entire outer periphery of the main body portion 82, as shown in FIGS. 10 and 14, the end portions of the arc-shaped plate member 83b and the end portions of the arc-shaped plate member 83c Therefore, by sliding the right locking member 95 to the left and the left locking member 95 to the right, the pair of left and right locking members 95 are engaged with the locked member 94, respectively. Can be stopped.

  Furthermore, the lock part 93 according to the present embodiment is formed at a position that is difficult to visually recognize from a player who plays with the pachinko gaming machine 1. That is, the lock portion 93 is formed at a position on the back side of the arc-shaped plate member 83a having a predetermined display (display “AAA”) (a position where the end portion of the arc-shaped plate member 83b and the end portion of the arc-shaped plate member 83c are close to each other). Therefore, it is difficult for the player to see. This can prevent the player from intentionally unlocking the lock portion 93.

  Furthermore, the display unit 83 according to the present embodiment is detachable by locking with respect to the main body part 82 by the lock part 93, but is fitted by another type of lock part and is attached to the main body part 82. It may be made removable. The lock by the lock portion 93 is sufficient if the display portion 83 is detachable from the main body portion 82 by fitting or locking. For example, the display portion 83 is connected by screwing means such as screws or fastening means, or It may be a snap fit or the like connected by the elastic force of the elastic body.

Next, main operations of the moving rotator 28 according to the present embodiment will be described with reference to FIGS.
As shown in FIG. 7, the movable rotating body 28 is normally located at the origin position, and the wires 58 a and 58 b are connected to the wire winding portion 64 by the torque of the motor 60 and the worm gear 63 (worm 61 and worm gear 62). Is wound up to the maximum. In a state where the moving rotating body 28 is located at the origin position, the slide protrusions 52a and 52b are in contact with the lower ends of the grooves 40a and 40b, and the basic coil springs 35a and 35b and the auxiliary coil springs 37a and 37b are most contracted. ing.

  In this state, the lower end portions of the auxiliary coil springs 37a and 37b are in contact with the restricting plates 38a and 38b (buffer members 39a and 39b), and the first stopper portions 44a and 44b are in contact with the upper ends of the first slide members 47a and 47b. The second stopper portions 45a and 45b are in contact with the upper ends of the second slide members 48a and 48b, and the first slide members 47a and 47b and the second slide members 48a and 48b are connected to the first storage grooves 49a and 49b and the second storage. It is substantially stored in the grooves 50a and 50b. Thereby, the further movement to the origin side of the moving rotary body 28 is regulated.

  Further, in the state where the movable rotating body 28 is located at the origin position, the first coil spring 72 and the second coil spring 73 are reduced in the right wire tension adjusting mechanism 33a as shown in FIG. 68 is located on the rear side of the second pulley 69 against the biasing force of the first coil spring 72, and the second pulley 69 is on the front side of the first pulley 68 against the biasing force of the second coil spring 73. Is located. That is, the wire 58 a extending from the horizontal pulley 74 is guided to the upper stage side of the wire winding portion 64 in a substantially “<” shape through the first pulley 68 and the second pulley 69 at the shortest distance. The same applies to the left wire tension adjusting mechanism 33b.

  Further, in a state where the moving rotator 28 is located at the origin position, the protection member 78 is in the most contracted (bent) state, and the origin position detection sensor is turned on by the light shielding member of the moving rotator 28, It is detected that the moving rotator 28 is located at the origin position. Thus, when the motor 60 rotates in the reverse direction with the moving rotating body 28 positioned at the origin position, the worm gear 63 (worm 61 and worm gear 62) rotates in reverse with the reverse rotation of the motor 60, and in conjunction with it. The wire winding unit 64 also rotates in the reverse direction.

  As a result, the wires 58a and 58b, the basic coil springs 35a and 35b, and the auxiliary coil springs 37a and 37b are extended by the amount of the reverse rotation of the wire winding unit 64, and the moving rotating body 28 is moved from the origin position to the basic coil spring 35a, 35b and auxiliary coil springs 37a and 37b move toward the advanced position (hereinafter also referred to as the first position) by the amount of extension. When the motor 60 rotates forward in this state, the moving rotating body 28 moves again to the origin position side by the reverse action. When this operation is repeated in a short time, the moving rotator 28 repeatedly moves (swings) between the origin position and the first position, so-called “rattling effect” is executed, and the origin position detection sensor repeatedly turns on and off. .

  Next, when the motor 60 further rotates in the reverse direction with the moving rotator 28 positioned at the first position, that is, when the moving rotator 28 rotates reversely a predetermined number of steps from the state where the moving rotator 28 is positioned at the origin position, the clutch mechanism The power transmission from the worm gear 62 to the wire take-up portion 64 is interrupted, and the wire take-up portion 64 becomes free to rotate. Then, the wires 58a and 58b are released, and the movable rotating body 28 is moved forward from the first position by the urging force of the basic coil springs 35a and 35b and the auxiliary coil springs 37a and 37b as shown in FIGS. Move up. At this time, the first pulley 68 and the second pulley 69 are moved most forward by the urging force of the first coil spring 72 and the second coil spring 73, and the second pulley 69 is the rearmost. Move to the side.

  That is, when the moving rotating body 28 moves from the origin position to the advanced position, first, the slide mechanisms 51a and 51b (the first slide members 47a and 47b and the second slide members 48a and 48b) move without moving. Only the rotating body 28 is slid in the advancing direction on the first slide members 47a and 47b by the biasing force of the basic coil springs 35a and 35b and the auxiliary coil springs 37a and 37b. It moves to the advance position side (hereinafter also referred to as the second position), and the wires 58a and 58b extend accordingly.

  The second position is on the advance position side than the first position, and the auxiliary coil springs 37a and 37b are in the state in which the urging force toward the advance position side is lost most of the time, The basic coil springs 35a and 35b maintain an urging force toward the advanced position by extending about half. In the second position, the slide protrusions 52a and 52b are in contact with the lower ends of the grooves 40a and 40b, and the lower ends of the auxiliary coil springs 37a and 37b are in contact with the restricting plates 38a and 38b (buffer members 39a and 39b). However, the first stopper portions 44a and 44b are separated from the first slide members 47a and 47b, the second stopper portions 45a and 45b are separated from the second slide members 48a and 48b, and the first slide members 47a and 47b are separated. 47b and the second slide members 48a and 48b are not stored in the first storage grooves 49a and 49b and the second storage grooves 50a and 50b.

  Then, from this second position, the slide mechanisms 51a and 51b cause the second slide members 48a and 48b to slide on the second guide members 41a and 41b in the advancing direction by the biasing force of the basic coil springs 35a and 35b. Then, move to the advance position side. Due to the movement of the slide mechanisms 51a and 51b to the advance position side, the moving rotator 28 moves to the advance position side. Further, the slide protrusions 52a and 52b are separated from the lower ends of the grooves 40a and 40b and the auxiliary coil springs 37a and 37b are separated from the regulating plates 38a and 38b by the movement of the movable rotating body 28 from the second position to the advance position side. To do.

  When the slide protrusions 52a and 52b come into contact with the upper ends of the grooves 40a and 40b, the moving rotator 28 stops moving to the advance position side. Thereby, the moving rotator 28 is completely moved to the advanced position, and the wires 58a and 58b are in the most extended state. In this advanced position, in addition to the auxiliary coil springs 37a and 37b that have already been extended most, the basic coil springs 35a and 35b are also extended to the maximum and the biasing force toward the advanced position is almost lost. Yes.

  Furthermore, almost simultaneously with the completion of the movement of the moving rotating body 28 to the advanced position, the first coil spring 72 and the second coil spring 73 are most extended, and the first pulley 68 is moved by the urging force of the first coil spring 72. The second pulley 69 is located on the foremost side by the urging force of the second coil spring 73. That is, the wire 58a extending from the horizontal pulley 67 is guided to the upper stage side of the wire winding portion 64 in a substantially “N” shape via the first pulley 68 and the second pulley 69 at the longest distance.

  The same applies to the left wire tension adjusting mechanism 33b. Thereby, even if it is a case where the wire winding part 64 will be in a rotation free state with the movement to the advancing position of the movement rotary body 28, the wires 58a and 58b do not loosen. Furthermore, in this state, the protection member 78 is in the most extended state, and the origin position detection sensor is turned off.

  When the moving rotator 28 moves from the advanced position to the origin position, the operation is substantially the reverse of the above-described movement of the movable rotator 28 from the origin position to the advanced position. In other words, when the motor 60 rotates forward with the moving rotating body 28 positioned at the advanced position, the worm gear 63 (worm 61 and worm gear 62) rotates forward in conjunction with the forward rotation of the motor 60, and the wire rotates in conjunction with it. The winding unit 64 also rotates forward. When the motor 60 rotates in the forward direction, the clutch mechanism always executes power transmission from the worm gear 62 to the wire winding unit 64.

  When the wire winding unit 64 rotates forward at the advanced position, first, the wires 58a and 58b are wound, and accordingly, the first coil spring 72 and the second coil spring 73 are contracted. Then, the first pulley 68 and the second pulley 69 are moved to the rear side and the front side, and the wires 58a and 58b are reduced from the substantially “N” shape to the substantially “<” shape.

  After the wires 58a and 58b are reduced to a substantially “<” shape, when the wire take-up portion 64 further rotates forward, the moving rotator 28 moves from the advanced position to the second position. In this case, the wires 58a and 58b are wound by the torque of the motor 60 (worm gear 62), the basic coil springs 35a and 35b are contracted, and the slide mechanisms 51a and 51b are the second slide members 48a and 48b are the second. It moves to the second position side by sliding on the guide members 41a and 41b in the direction of the origin. Due to the movement of the slide mechanisms 51a and 51b toward the second position, the movable rotating body 28 moves toward the second position. Note that the moving speed of the moving rotating body 28 may be changed by changing the rotating speed of the motor 60.

  Further, the slide protrusions 52a and 52b are separated from the upper ends of the grooves 40a and 40b by the movement of the movable rotating body 28 from the advanced position to the second position side. When the slide protrusions 52a and 52b come into contact with the lower ends of the grooves 40a and 40b, the slide mechanisms 51a and 51b stop moving to the origin position side. Thereby, the moving rotator 28 is moved to the second position.

  Here, at the second position when the motor 60 is rotating forward, the state of the rendering unit 27 is apparently the same as when the above-described moving rotator 28 has reached the second position from the origin position. However, due to the torque of the motor 60 (worm gear 62), a force that moves the movable rotating body 28 to the origin position side acts against the biasing force of the basic coil springs 35a, 35b to the advance position side.

  Next, when the motor 60 further rotates forward in the state where the movable rotating body 28 is located at the second position, the slide mechanisms 51a and 51b do not move, and the first guide is generated by the torque of the motor 60 (worm gear 62). When the members 42a and 42b slide on the first slide members 47a and 47b in the direction of the origin, the wires 58a and 58b are wound, and the basic coil springs 35a and 35b and the auxiliary coil springs 37a and 37b are reduced. Only the moving rotator 28 moves to the origin position side. Then, when the lower end portions of the auxiliary coil springs 37a and 37b reach the regulating plates 38a and 38b (buffer members 39a and 39b), the movement of the moving rotator 28 toward the origin position side is stopped, and the moving rotator 28 The movement to the home position is completed.

  When the moving rotator 28 reaches the origin position, the origin position detection sensor is turned on to stop the normal rotation of the motor 60. However, if the moving rotator 28 is located at the origin position, the motor 60 further moves. In the case of normal rotation, the worm gear 63 (the worm 61 and the worm gear 62) rotates in the direction of winding the wires 58a and 58b. Torque transmission to is interrupted, and the wire winding portion 64 does not rotate.

  As apparent from the above, in the effect unit 27, when the moving rotator 28 moves from the origin position to the advanced position, the initial operation of the moving rotator 28 with a large load is performed by a plurality of elastic members, that is, basic coil springs. 35a and 35b and auxiliary coil springs 37a and 37b are used. Then, when the moving rotator 28 advances from the origin position to the predetermined position (second position), the operation after the movement starts with a small load, that is, the moving operation of the moving rotator 28 from the second position to the advanced position is single. This is performed only by the elastic member, that is, the basic coil springs 35a and 35b.

  On the contrary, when the moving rotator 28 moves from the advanced position to the origin position, the initial operation of the moving rotator 28 with a large load is resisted only by the urging force of a single elastic member, that is, the basic coil springs 35a and 35b. Thus, the motor 60 is driven to perform the operation. When the moving rotator 28 moves backward from the advanced position to a predetermined position (second position), there are a plurality of operations after the movement starts with a small load, that is, the moving rotator 28 moves from the second position to the origin position. This is performed by driving the motor 60 against the urging force of the elastic members, that is, the basic coil springs 35a and 35b and the auxiliary coil springs 37a and 37b.

  Thereby, in the production unit 27 according to the present embodiment, it is possible to move the moving rotator 28 between the origin position and the advanced position with a smaller power, and as a result, a motor with a smaller driving force. 60 can be used to reduce costs. The wire tension adjusting mechanisms 33a and 33b are used to stop the moving rotating body 28 at a predetermined position by the torque of the motor 60, rotate the wire winding unit 64 to wind the wires 58a and 58b, and move. When the wire take-up portion 64 is free to rotate as the rotating body 28 moves to the advanced position and the wires 58a and 58b are released and extended, the elastic members, that is, the first coil spring 72 and the second coil spring 73 are Due to the urging force, a predetermined tension is always applied to the wires 58a and 58b via the first pulley 68 and the second pulley 69 as tension rollers.

  Therefore, the moving rotator 28 can be smoothly moved by the wires 58a and 58b. As a result, the wires 58a and 58b are not loosened, and the movement of the moving rotator 28 is not hindered. In addition, it is possible to prevent troubles and troubles caused by the wires 58a and 58b being caught by other parts. The motor 60 uses a stepping motor that can be controlled to rotate by a predetermined number of steps, and further includes an origin position detection sensor that detects the origin position of the moving rotator 28. Based on the number of steps and the detection signal of the origin position detection sensor, it is detected whether or not the moving rotator 28 has moved to the origin position.

  Therefore, the movement of the moving rotator 28 to the origin position can be detected with higher accuracy by the number of steps of the motor 60 and the detection signal of the origin position detection sensor. This effect can be performed more reliably. For example, when the motor 60 is rotated a predetermined number of steps to move the moving rotator 28 to the origin position, the origin position detection sensor is turned off when the origin position detection sensor is off even if the rotation number of rotations is rotated a predetermined number of steps. Until the power is turned on, control for further adjusting the step of the motor 60 can be performed. The same applies to the motor 87 and the rotation position detection sensor for controlling the rotation of the outer 84 to a predetermined position.

  In addition, the exchange of control signals and the like between the moving rotator control board 34 and the moving rotator 28 is performed by a flexible flat cable 76, and the flexible flat cable 76 includes three hinges 79, 80, 81. It is inserted into a wave-shaped protective member 78 and protected.

  Thereby, it is possible to prevent the flexible flat cable 76 from coming into contact with the player or other components, and as a result, it is possible to prevent the flexible flat cable 76 from being damaged. Further, the protective member 78 is expanded or contracted by bending or extending in the shape of a “<” as the moving rotating body 28 moves, and the hinges are formed in a wave shape. Therefore, the flexible flat cable 76 is formed. Is kept in a wavy posture in the protective member 78 against the movement of the movable rotating body 28, and excessive expansion and contraction is suppressed. As a result, the durability of the flexible flat cable 76 is improved. That is, by protecting the flexible flat cable 76 with the protection member 78, it is possible to more reliably perform an effect related to the movement of the movable rotating body 28.

  By the way, as described above, the moving rotator control board 34 inputs the game information of the pachinko gaming machine 1 and controls the motor 87 and the LED 90 based on the input game information, so that the origin of the moving rotator 28 is obtained. In relation to the movement between the position and the advance position, the outer 84 is rotationally controlled in a predetermined manner or the light emission is controlled in a predetermined manner. Therefore, the rotating mode of the movable rotating body 28 is such that only the outer 84 rotates in conjunction with the rotation of the motor shaft 88 of the motor 87. That is, even if the outer 84 rotates, the base plate 86 located inside the outer 84 does not rotate, so that the relay board 77 provided on the base board 86 and the LED 90 provided on the relay board 77 do not rotate. ing.

  In other words, inside the movable rotating body 28, an LED 90 is provided as a light emitting means that is disposed on one side of the relay substrate 77 provided so as not to rotate and can irradiate the outer 84. As a result, the outer 84 (and the outer cover member K) whose rotation is controlled can be easily and reliably caused to emit light, and as a result, the effect relating to the light emission of the movable rotating body 28 can be more reliably performed. It becomes possible. Furthermore, since the relay board 77 is fixed without rotating, the wiring of the driving mechanism 85 can be easily performed, and troubles and troubles associated with the rotation can be avoided.

  Various rotation modes of the movable rotating body 28 (outer 84) are conceivable. For example, the rotation speed and range, the rotation direction, the rotation time, and the like can be changed. Similarly, various light emission modes of the moving rotator 28 (outer 84) are conceivable. For example, the lighting type such as lighting, flashing, and extinguishing, the time, the flashing speed, the lighting color, and the luminance (illuminance) can be changed. is there. In other words, the moving rotator 28 changes the movement mode, the rotation mode, and the light emission mode in relation to the gaming state in relation to the swing between the origin position and the advance position and the stop position. Various effects can be performed by changing the sound.

  According to the present embodiment, a main body 82 having a light source disposed therein and attached to the main body 82 and transmitting light from the LED 90 (light source) for a predetermined display (display “AAA”) The display unit 83 includes a display unit 83 that can visually recognize the display unit 83. The display unit 83 is detachable by fitting or locking to the main body unit 82, so that the pachinko gaming machine 1 can be replaced. In addition, since the predetermined display can be easily changed, it is possible to suppress the cost when replacing the new base.

  Moreover, while the main-body part 82 is attached to the frame member (glass frame 24) of the pachinko gaming machine 1, and the display part 83 can make the predetermined display regarding the pachinko gaming machine 1 visible, the frame member (glass frame 24). When the pachinko gaming machine 1 is replaced while diverting it, the predetermined display can be easily changed, so that the cost for replacing the new machine can be suppressed. Further, the display unit 83 has a lock part 93 that can be fixed to the main body part 82, and the lock part 93 is formed at a position that is difficult to see from a player who plays with the pachinko gaming machine 1. It is possible to prevent the lock part 93 from being unlocked carelessly by a person.

  Although the present embodiment has been described above, the present invention is not limited to this, and a main body portion in which a light source is disposed, and a main body portion that is attached to the main body portion and transmits light from the light source to perform a predetermined display. If the display unit has a display unit having a display unit that can be visually recognized in a predetermined part, and the display unit is detachable by fitting or locking to the main body unit, for example, What was attached other than the glass frame 24, or an operation means such as an operation button may have a main body portion and a display portion.

  In the present embodiment, the light source in the main body portion 82 is configured by the LED 90, but other light sources such as a lamp may be used. Further, in the above embodiment, the moving rotator 28 is movable between the origin position and the advanced position, but it may be applied to those that do not move or that the main body does not rotate. May be. In addition, in this embodiment, although applied to the pachinko game machine 1, you may apply to other game machines (for example, pachislot etc.).

  As long as the display unit is a gaming machine provided with a production unit that is detachable by fitting or locking to the main body unit at a predetermined site, the display unit may be different in appearance shape or added with other functions. Can be applied.

DESCRIPTION OF SYMBOLS 1 Pachinko machine 2 Glass board 3 Operation button 4 Game board 5 Symbol display part 6 1st starting port 7 Electric tulip 7a 2nd starting port 8 Big winning port 9 Gate 10 1st special symbol display means 11 2nd special symbol display means 12 normal symbol display means 13 saucer 14 handle 15 first special symbol holding lamp 16 second special symbol holding lamp 17 main control board 18 sub control board 19 effect control board 20 lamp control board 21 payout control board 22 lottery means 23 storage means 24 Glass frame (frame member)
25 Outer frame 26 Inner frame 27 Production unit 28 Moving rotator 29 Support member 30 Base portions 31a, 31b Standing portion 32 Motor mechanisms 33a, 33b Wire tension adjusting mechanism 34 Moving rotator control boards 35a, 35b Basic coil springs 36a, 36b Stop Attachment members 37a, 37b Auxiliary coil springs 38a, 38b Restriction plates 39a, 39b Buffer members 40a, 40b Grooves 41a, 41b Second guide members 42a, 42b First guide members 43a, 43b Side covers 44a, 44b First stopper portions 45a, 45b Second stopper portions 46a, 46b Cover members 47a, 47b First slide members 48a, 48b Second slide members 49a, 49b First storage grooves 50a, 50b Second storage grooves 51a, 51b Slide mechanisms 52a, 52b Slide protrusions 53a, 53b Fastening member 5 a, 54b Fastening portion 55a, 55b Connecting member 56a, 56b Fastening member 57a, 57b Connecting member 58a, 58b Wire 59a, 59b Fastening member 60 Motor 61 Worm 62 Worm gear 63 Worm gear 64 Wire winding portion 65 Harness 66 Vertical Pulley 67 Horizontal pulley 68 First pulley 69 Second pulley 70 First slide shaft 71 Second slide shaft 72 First coil spring 73 Second coil spring 74 Horizontal pulley 75 Harness 76 Flexible flat cable 77 Relay board 78 Protection member 79 Lower hinge 80 Upper hinge 81 Middle hinge 82 Body 83 Display 84 Outer 85 Drive mechanism 86 Base plate 87 Motor 88 Motor shaft 89a, 89b Rotating wheel 90 LED (light source)
91, 92 Hinge 93 Locking portion 94 Locked member 95 Locking member 96 Guide portion K Cover member

The invention according to claim 1 includes a main body portion having a light source disposed therein, a display portion that is attached to the main body portion, transmits a light from the light source, and allows a predetermined display to be visually recognized, and the main body. A display device having a display unit and a display unit having a rotatable moving rotator at a predetermined site, wherein the display unit is attached to or detached from the main body unit by fitting or locking. It is characterized by being made free.

Claims (3)

A main body having a light source disposed therein;
A display unit that is attached to the main body unit and transmits a light from the light source to make a predetermined display visible;
A gaming machine equipped with a production unit having
The game machine according to claim 1, wherein the display unit is detachable from the main body unit by fitting or locking.   The gaming machine according to claim 1, wherein the main body is attached to a frame member of the gaming machine, and the display unit can visually recognize a predetermined display related to the gaming machine.   2. The display unit according to claim 1, wherein the display unit includes a lock unit that can be fixed to the main body unit, and the lock unit is formed at a position that is difficult for a player to play with the gaming machine to view. Or the game machine of Claim 2.

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