KR20020079341A - A game machine - Google Patents

Abstract

PURPOSE: To secure the normal processing operation of a game machine by surely discharging static electricity generated on the rail of a game machine by simple structure. CONSTITUTION: A connection member HB, a connection member UB and a connection member SB are arranged respectively at paths from the shooting rail 30, the inner rail 49 and the outer rail 51 of a pachinko machine 10 to a hinge 170 for an inner frame or hinges for a mechanism plate 190 and 195. These connection members HB, UB and SB consists of metal members formed in a state where the shapes of the paths from the respective rails 30, 49 and 51 to the respective hinges 170, 190 and 195 can be maintained. Static electricity generated at the rail 30, the rail 49 and the rail 51 by friction, etc., with a game ball B is introduced surely to the hinge 170 and the hinges 190 and 195 through the connection members HB, UB and SB and discharged to the outside of the machine 10.

Description

Organic machine {A game machine}

TECHNICAL FIELD This invention relates to an organic group. Specifically, It is related with the organic group which guide | induces the launched organic sphere by the predetermined rail to an organic area | region, and performs predetermined organic.

In general, on the organic panel of the organic group, rails such as a launch rail, an outer rail, and an inner rail are provided as a means for guiding the blown organic sphere (hereinafter referred to as a ball) into an organic region. It is. On such a rail, static electricity is generated by friction between the ball and the rail. If the static electricity is left unattended, the charge of the static electricity may act on the control mechanism that controls the operation of the organic group, which may cause the organic group to malfunction. Therefore, conventionally, the static electricity charged to the outer rail and the inner rail is guided to the earth (ground) processing unit through a metal glass frame and a lead wire connected to the glass frame, and thus the static electricity on the rail. A technique for eliminating the above has been proposed (Japanese Patent Laid-Open No. 5-228257).

However, in the conventional technique, in order to remove the static electricity on the rail, the wiring work for connecting the glass frame and the earth processing part must be performed inside and outside the organic group, and extremely complicated in manufacturing the organic group or the like. did.

In addition, in the above method, when wiring is accidentally left out when assembling, transporting, or inspecting an organic group, static electricity cannot be removed, and it cannot be said that reliability for removing static electricity is sufficient. For example, when a conductive wire is attached to a glass frame or an earth processing part, a portion attached by vibration or the like when the organic group is transported is loosened, or the wire is inadvertently caught when the organic group is inspected. There was a fear that the connection between the glass frame and the earth processing part would be broken. On the other hand, there has been no proposal in the prior art about the method of removing static electricity on a rail without performing such wiring.

Therefore, the present invention has solved the above problems, the static electricity on the rail is reliably removed by a simple structure, and the following configuration has been taken for the purpose of ensuring the normal processing operation of the organic group.

BRIEF DESCRIPTION OF THE DRAWINGS It is explanatory drawing which shows the characteristic of this invention using the pachinko organic group which is an Example.

2 is an explanatory diagram showing a front surface of a pachinko organic group.

3 is an explanatory diagram showing a rear surface of a pachinko organic group.

FIG. 4 is an explanatory diagram showing a state in which a metal plate, a case rail, a product bead / loan bead discharge unit, and a bead base are attached to the instrument plate, and the configuration of the hinge for the instrument plate.

5 is an explanatory view showing the back of the glass frame.

It is explanatory drawing which shows the cross-sectional shape of the bending part of a surrounding plate.

It is explanatory drawing which shows the front surface of the pachinko organic group in the state which removed the glass frame or the upper plate.

FIG. 8 is an explanatory diagram showing a state around the launch rail in FIG. 7; FIG.

It is explanatory drawing which shows the mode of the periphery of sheet metal attached to the outer rail.

It is explanatory drawing which shows the structure of the inner frame hinge and the glass frame hinge with the structure of the instrument plate hinge.

FIG. 11 is an explanatory view showing a state in which a bent portion or a connecting member of the rear surface of the glass frame is accommodated in the recess of the inner frame when the glass frame is closed.

FIG. 12 is an explanatory diagram showing a state around the key unit along a line 12-12 of FIG. 11.

FIG. 13: is explanatory drawing which shows the appearance of the sheet metal periphery when it cut along the 13-13 line of FIG.

FIG. 14: is explanatory drawing which shows the appearance of the sheet metal periphery when it cut along the 14-14 line of FIG.

Fig. 15 is a graph showing the potential difference occurring in the organic organic phase before and after discharge of product beads or rental beads.

<Description of the symbols for the main parts of the drawings>

10: organic pachinko 12: outer frame

15: prefade card unit 16: guide unit

17: card unit power cord 20: inner frame

22: glass frame 23: indicator lamp

24: upper plate 25: lower plate

26: launch operation unit 26a: launch handle

29 key unit 30 launch rail

31: launch mechanism unit 40: organic group

41: special pattern display device 42: normal pattern display device

43: normal mouth 44: starting mouth

45: normal pattern display device operation gate 46: high entrance

54 display lamp 56 liquid crystal display

57: lamp control board 58: voice control board

59: plate for lamp and sound board 60: cover

70: instrument plate 72: bead tank

73: tank rail 74: case rail

75: product bead / loan bead discharge unit 75c: product bead outlet

75d: Rental bead outlet 76a, 76b: Protective cover

77: bead base 78: bead cover

80: power supply and external terminal unit 80b: organic power supply cord

80c: External terminal board for organic panel 80d: External terminal board for frame

81: power supply unit 81a: power supply board

82: launch control unit 82a: launch control board

83: plate for power supply and emission control board 84: main control unit

84a: main substrate 85: main substrate plate

86: discharge control unit 86a: discharge control board

87: plate for discharge control board 90: metal plate

99; Sheet metal 110, 115: Sheet metal

131: foul bead guide unit 132: pedestal (臺 座)

133: bead stopper 134: contact member

140: frame 141, 142: pin axis

143, 147: slide plate 144: lock mechanism

150, 151: flat plate 151i: hanger section

153: enveloping plate 154: connecting member

155, 156: locking piece 170, 175: hinge for the inner frame

170, 190, 195: hinge 171, 176: shaft forming member

173, 178, 188: bearing plate 180, 185: hinge for glass frame

190, 195: hinge for instrument plate 191, 196: protruding piece

B: organic sphere HB, UB, SB: connection member

GS: Guide surface IS: Mounting surface

The organic group of the present invention is an organic group which guides the emitted organic spheres to an organic region by a predetermined rail and performs a predetermined organic phase. The organic group is formed using a conductive material and opens and closes a part of the organic group. A hinge is provided so that it can be supported, and the electroconductive connecting member which connects the said rail and the said hinge is comprised, Comprising: The connection member consists of a member which forms the path shape from the said rail to the hinge as it is.

According to the organic group of the present invention, since the rail and the hinge leading the organic sphere to the organic region are connected to the conductive connecting member which forms the path shape from the rail to the hinge as it is, the path shape from the rail to the hinge is connected to the organic group. It does not change due to the impact from the outside. Therefore, the connection state between the rail and the hinge can be maintained reliably, and the static electricity charged on the rail can be reliably guided to the hinge and removed to the outside of the organic group.

It is also suitable to have an openable door which is closed at the time of execution and a closed connection structure which electrically connects the rail and the hinge via the connecting member when the door is closed. In this way, in the closed state of the door, the hinge and the rail are conducted through the connecting member. Therefore, the static electricity generated by the flow of the organic sphere on the rail during the organic performance can be reliably removed by a simple operation of closing the door.

The connecting member includes a first connecting member that is connected to the rail while the door is opened, and a contact connecting member that contacts the first connecting member when the door is closed, and includes at least one of the contact connecting member and the first connecting member. When one member has an elastic force with respect to the other member and the said contact connecting member contacts the 1st connection member according to the closing of a door, at least one member of the said contact connection member and the 1st connection member is an elastic force. It is good also as a structure which resists and deforms. In this case, by the elastic force of the said one member with respect to the said other member, moderate resistance is given when a door is closed, and the closing of a door can be suppressed.

A first door which is opened and closed at the time of execution of the door, having a front door having an opening for viewing the organic area when the door is closed, and as the connecting member, the first door is connected to the rail with the front door open. A connecting member, a plate body provided on a rear surface of the front door in a predetermined area, and a second connecting member for connecting the plate body and the hinge, wherein the closed connection structure includes at least a plate body when the front door is closed. It is also preferable to set it as the structure which electrically connects a rail and hinge by contacting a 1st connection member. In this way, by closing the front door, the static electricity charged on the rail is guided to the plate through the first connecting member, and is dispersed in the plate provided in the predetermined area. Therefore, the static electricity on the rail can be efficiently discharged out of the rail.

The closed connection structure may have a structure in which the plate body abuts not only the first connecting member but also at least part of the rail when the front door is closed. In this case, the object which contacts a rail becomes a 1st connection member and a board body, and the contact area | region of a rail and an electroconductive member becomes wider. Therefore, the efficiency of removing static electricity on a rail out of a rail can be further improved. For example, if the plate body is in contact with the end of the rail when the front door is closed, the static electricity having the property of being easy to charge to a sharp part such as the end can be effectively removed from the rail.

It is also preferable to provide the plate body discontinuously in the outer circumferential region of the opening. In this way, the static electricity guided from the rail to the plate can be avoided from forming a loop in the plate, and the static electricity in the plate can be reliably discharged to the outside of the organic group through the second connecting member and the hinge. In addition, "mounting a board body discontinuously" specifically means providing the board body provided in the outer periphery area | region of an opening part in which the end surfaces become non-contact. As such a structure, for example, one plate body with a part cut out is provided in the outer periphery area | region of an opening part, or many plate bodies are installed in series, leaving a predetermined gap between one board body and another board body. May be considered.

As a predetermined rail, a plurality of rail members may be provided, and at least two rail members of the plurality of rail members may be provided in a state where conduction is possible between the rail members. This makes it difficult to generate a potential difference between the rail members and prevents the occurrence of local high voltage on one rail.

EXAMPLE

EMBODIMENT OF THE INVENTION In order to make clear the structure and effect | action of this invention demonstrated above, embodiment of this invention is described below based on an Example. 1 is an explanatory view showing the features of the present invention by using the pachinko organic group 10 which is an embodiment of the present invention. In FIG. 1, the left side toward the front surface of the pachinko organic group 10 is shown in the state which the outer frame 12 saw. In addition, in the following description, the surface when viewed from the front direction of the pachinko organic group 10 is called "surface", and the surface when viewed from the backside direction of the pachinko organic group 10 is called "back surface." In FIG. 1, the right side becomes the surface of the pachinko organic group 10, and the left side becomes the back surface of the pachinko organic group 10 from the figure.

As shown in FIG. 1, the pachinko organic group 10 is made of a resin inner frame which is installed in a wooden outer frame 12 so as to be opened and closed via hinges 170 and 175 for metal inner frames. 20 is provided. The organic panel 40 in which the organic region was formed is inserted in the opening formed in the frame of the inner mold 20. On the back side of the organic panel 40, a mechanism plate 70 on which various mechanisms such as a product bead discharge mechanism are mounted is provided. The instrument plate 70 is provided on the outer side of the left side (just in front of FIG. 1) toward the front of the inner frame 20 via openings 190 and 195 made of metal instrument plates so as to be openable and detachable.

On the inner side surface of the left side (just in front of FIG. 1) toward the front of the inner frame 20, a resin glass frame 22 is provided to be opened and closed via the metal hinges 180 and 185. This glass frame 22 is closed at the time of the execution of the organic so that the organic sphere B does not protrude out of the machine while flowing down from the organic region.

In addition, in the area covered with the upper plate 24 below the inner frame 20 surface, the metal sphere for guiding the organic sphere B, which has been fired by the rotation operation of a launch handle (not shown), to the outer rail 51 is formed. The launch rail 30 is mounted. Moreover, the metal outer rail 51 and the inner rail 49 which guide the organic sphere B from the launch rail 30 to the organic region are mounted on the surface of the organic panel 40.

In this embodiment, the connecting member HB is provided in the path from the launch rail 30 to the inner frame hinge 170 to the instrument plate hinges 190 and 195, and the hinge for the inner frame from the inner rail 49. The connection member UB is connected to the path from 170 to the hinges 190 and 195 for the instrument plate, and the path from the outer rail 51 to the hinge 170 and 195 for the instrument plate to the inner frame. Each member SB is provided. In this embodiment, as these connection members HB, UB, and SB, the other member which does not form the shape of the path | route from each rail 30, 49, 51 to each hinge 170, 190, 195 (example) For example, like the conducting wires, the hinges 170 may be formed from the rails 30, 49, and 51 without using a member whose appearance is simply changed by a slight action from the outside such as contact or vibration. Only the metal member which forms the shape of the path | route to 190 and 195 as it is is used. The "conductive connecting member" in the claims corresponds to the connecting members HB, UB, and SB in this embodiment.

That is, according to the present invention, the connecting members HB, UB, and SB are provided at the respective portions of the organic organic group 10, so that the firing rail 30 and the inner rail 49 may be caused by friction with the organic sphere B or the like. ) And the static electricity generated in the outer rail 51 are reliably guided to the inner frame hinge 170 and the instrument plate hinges 190 and 195 through the connecting members HB, UB, and SB. 190, 195 is characterized in that the discharge to the outside of the pachinko organic group (10).

Next, the whole structure of the pachinko organic group 10 of this embodiment is demonstrated with reference to FIG. 2 and FIG. 2 and 3 show the front and rear surfaces of the pachinko organic group 10, respectively. As shown in FIG. 2, the pachinko organic group 10 includes a wooden outer frame 12 and a prefade card unit 15 set on an outer side surface of the outer frame 12.

The prefade card unit 15 is a device for supplying a predetermined number of organic spheres B to the upper plate 24 by inserting a prefade card in which information on the number of rental beads is recorded. (17) (refer FIG. 3) and the guide unit 16 which has the frequency display part 16a, the loan button 16b, the loan button lamp, and the return button 16c. The configuration in which the loan is performed by the prepaid card unit 15 will be described later.

The pachinko organic device 10 includes an inner frame 20 installed on the outer frame 12 so as to be opened and closed through metal hinges 170 and 175. Each component attached to this inner frame 20 is demonstrated below. In the opening formed in the frame of the inner frame 20, an organic plate 40 with a sheet drawn in advance is inserted, and the organic plate 40 is formed of glass using a non-transparent resin. It is covered with a frame 22.

The glass frame 22 is provided to be opened and closed to the inner frame 20 through metal hinges 180 and 185 mounted on the inner surface of one side of the inner frame 20 (left side in FIG. 2). have. The glass frame 22 is comprised from the opening part 22a formed in the vicinity of the center of this glass frame 22, and the frame part 22b around this opening part 22a. The opening 22a is attached to glass to form a glass surface. A display lamp 23 that blinks or lights in accordance with an organic situation is attached to the frame portion 22b around the glass surface. In the state in which the glass frame 22 is closed, the organic region of the organic panel 40 is covered with the glass surface of the glass frame 22. Thereby, an organic region can be seen from the front surface of the pachinko organic group 10 over glass.

In the region below the glass frame 22, an upper plate 24 for storing organic spheres B as rental beads or product beads is provided. The upper plate 24 is provided on the inner side of one side (left side in FIG. 2) of the inner frame 20 so as to be openable and openable through a metal upper plate hinge (not shown).

In addition, at the end of the inner frame 20 on the opposite side of the glass frame hinges 180 and 185 and the upper plate hinge (right side in FIG. 2), the glass frame 22 and the upper plate 24 are opened and closed. The metal key unit 29 which replaces a is attached. The lock 28 which operates the key unit 29 is attached to the keyhole ornament 27 provided in the glass frame 22 near the key unit 29. The details of this key unit 29 will be described later.

On the surface of the inner mold 20 below the upper dish 24, the lower dish 25 for storing the organic spheres B discharged beyond the capacity of the upper dish 24, and the rotation operation of the firing handle 26a. Is attached to a firing operation unit 26 for firing the organic sphere B supplied from the upper dish 24 toward the organic region. In addition, on the surface of the inner mold 20 exposed when the upper dish 24 is opened, a metal launching rail for guiding the organic sphere B projected by the rotation operation of the launching handle 26a to the outer rail 51. 30 is mounted.

On the other hand, as shown in Fig. 3, on the back side of the inner frame 20, a launch mechanism unit made of a firing motor, a batting rod, or the like at a position corresponding to the attachment position of the upper dish 24 and the launch operation unit 26 ( 31) is attached. Moreover, the metal support member 33 for supporting the mechanism plate 70 mentioned later is attached to the side surface of the inner side frame 20 (right side in FIG. 3). Details of this support member 33 will be described later. Moreover, support pieces 32a and 32b which support the organic panel 40 fitted in this opening part on the back side of the inner side frame 20 are provided in the left and right sides of an opening part in the back side of the inner side frame 20. After rotating the left and right support pieces 32a and 32b about the axis, the organic plate 40 can be removed from the back side of the inner frame 20 by pulling out the organic plate 40.

Next, the organic panel 40 will be described. As shown in FIG. 2, on the surface of the organic panel 40, a metal outer rail 51 and an inner rail 49 for guiding the organic sphere B fired by the firing operation unit 26 to the organic region. And the fouling ball stopper 50 formed of a thin metal having elasticity and exiting the organic region to prevent the organic sphere B from returning toward the inner rail 49, the return rubber 52, and the organic region. A number of obstacle nails that change the direction in which the ball flows down, a windmill 47 and a lamp windmill 48 that change the speed or direction in which the ball flows in the organic area, and an organic ball flowing in the organic area can enter. The normal pattern display device which operates as several normal standing mouth 43 and one starting standing mouth 44 and the organic sphere B pass through the normal pattern display operating gate 45 ( 42 and the pattern as the organic sphere B enters the starting mouth 44 The special pattern display device 41 which starts a fluctuation, the entrance table 46 which opens when a specific pattern is displayed by this special pattern display device 41, and the standing situation to each prize box 43, 44, 46 Various components, such as the display lamp 54 which light up or flash in various forms according to this, are attached. Further, an outlet 53, which is a hole into which the organic sphere B which does not granulate in the organic region, is formed in the lower center of the organic panel 40. By each of these parts, an organic region is formed on the organic panel 40 beyond the glass of the glass frame 22.

On the other hand, the back surface of the organic panel 40, as shown in Fig. 3, the lamp control for controlling the display mode of the liquid crystal display 56 and the display lamps 23 and 54, which function as the special pattern display device 41, A substrate 57 and an audio control substrate 58 for controlling the contents of the audio output to the outside in accordance with the operation status of the special pattern display device 41 are attached together with the electrical wiring. In addition, the lamp control board 57 and the audio control board 58 are attached to the organic panel 40 via a metal lamp / voice board plate 59. This liquid crystal display 56. The lamp control board 57 and the audio control board 58 are covered with a resin cover (not shown).

Next, the resin plate 70 made of resin will be described. As shown in FIG. 3, the instrument plate 70 can be opened and detached with or without the organic panel 40 being fitted to the inner frame 20 through the metal instrument plate hinges 190 and 195 provided at two positions on the side. Is fitted. The configuration of the mechanical plate hinges 190 and 195 will be described later.

The rectangular opening 70a is formed in substantially the center of the mechanical plate 70. As shown in FIG. 3, in the state where the mechanism plate 70 is closed, the liquid crystal display 56, the lamp control substrate 57, and the voice control substrate 58 on the back of the organic panel 40 are in the opening 70a. Put in.

On the back of the instrument plate 70, a bead tank 72 for temporarily storing the organic spheres supplied from the bead supply device of the organic field, and from the bead tank 72 to the product bead / loan bead discharge unit 75 are successively connected. A tank rail 73 and a case rail 74 are connected to each other. As shown in FIG. 3, two convex parts 72a and 72b are formed in the lower part of the bead tank 72 attached to the uppermost part. These convex portions 72a and 72b are in contact with the upper end of the tank rail 73. The end of the tank rail 73 is in contact with the front end of the case rail 74.

At the end of the case rail 74, a product bead / loan bead discharge unit 75 with protective covers 76a and 76b and a bead base 77 with a bead cover 78 are successively provided. These case rails 74, the merchandise beads / loan bead discharge unit 75, and the bead cylinder base 77 are formed on a rectangular metal plate 90 attached to the rear surface of the mechanical plate 70, as shown in FIG. Is provided in contact with the metal plate 90. The end of the tank rail 73 in contact with the front end of the case rail 74 is also provided on the metal plate 90 in contact with the metal plate 90. The aspect in which the metal plate 90, the case rail 74, the product beads / loan ball discharge unit 75, and the bead cylinder base 77 are provided in the mechanical plate 70 will be described later.

The power supply / external terminal unit 80 is attached to the upper region of the case rail 74 in the mechanical plate 70. The power supply / external terminal unit 80 has an organic power supply cord 80b for introducing AC 24 volt power into the organic organic device 10 from the island of the organic field, and on / off supply power by operation. A power switch 80a for turning off, an external terminal board 80c for outputting the number of winnings, etc. due to the display of a specific pattern generated in the pachinko organic group 10, and beads rental, bead disconnect, product beads It consists of an external terminal board 80d for a frame which outputs the information concerning to the outside. The power of AC 24 volts introduced from the organic power supply cord 80b is sent to the power supply unit 81 (to be described later) through electrical wiring.

Below the opening 70a, the power supply unit 81 having the power supply board 81a and the launch control unit 82 having the launch control board 82a are connected to the metal power source / launch control board plate 83. It is attached to the back of the instrument plate 70. In addition, the main board plate 85 made of metal is attached to the rear surface of the mechanical plate 70 so as to cover a part of the upper surface of the power supply unit 81 and the launch control unit 82. On the 85 is attached a main control unit 84 having a main substrate 84a. Further, a metal discharge control board plate 87 is attached to the rear surface of the mechanical plate 70 so as to cover the upper surface of the bead cover 78 and a part of the upper surface of the power supply unit 81. An emission control unit 86 having an emission control substrate 86a is attached to the substrate plate 87.

The power supply unit 81 connected to the external terminal unit 80 via electrical wiring converts the AC power sent from the organic power cord 80b into direct current, and converts the converted direct current power through a feed line. It supplies to each control component, such as the liquid crystal display 56, the lamp control board 57, the audio | voice control board 58, the launch control unit 82, the main control unit 84, and the discharge control unit 86. The launch control unit 82 controls the launching operation of the launch control mechanism unit 31, and the main control unit 84 controls the pattern display operation of the special pattern display device 41 or the normal pattern display device 42, and the like. The operation accompanying the induction is controlled, and the discharge control unit 86 controls the discharge operation by the product beads / rental beads discharge unit 75.

As shown by a dashed-dotted line in FIG. 3, various passages for guiding the organic sphere B are provided on the surface of the mechanical plate 70. One is a guide path 70b which is a passage leading to the organic dish B discharged as a product ball or a rental ball to the upper plate 24. Moreover, the organic sphere which entered the branch path 70c which is the path which guide | induces the organic sphere B discharged | emitted beyond the capacity | capacitance of the upper side dish 24 to the lower side dish 25, and the outlet 53 is shown. An out-bead discharge passage 70d, which is a passage for discharging (B) out of the machine as out-beads, is also provided.

The metal plate 90, the case rail 74, the product bead / loan bead discharge unit 75 and the bead base 77 is attached to the instrument plate 70 and the configuration of the hinge (190, 195) for the instrument plate 4 is shown.

As shown in FIG. 4, the hinge 190 for instrument boards has the bearing part 33a which has the shaft hole 33t1 formed in the upper part of the supporting member 33 attached to the side of the inner frame 20, and this shaft hole 33t1. Consists of a protrusion 191 having a shaft (191a) is inserted into the), the hinge for the instrument plate 195 has a bearing portion 33b having a shaft hole (33t2) formed in the lower portion of the support member 33, It is comprised by the protrusion piece 196 which has the shaft 196a inserted into this shaft hole 33t2. The bearing part 33a and the bearing part 33b are formed by bending a part of the supporting member 33 made of metal, and the shaft 191a and the shaft 196a are respectively formed of the metal protrusion 191 and the protrusion 196. It is formed integrally with By inserting the shaft 191a and the shaft 196a into the shaft hole 33t1 of the bearing portion 33a and the shaft hole 33t2 of the bearing portion 33b, respectively, the instrument plate 70 makes the inner frame 20. Is rotatably supported, and the instrument plate 70 is rotatable about the shaft hole 33t1 and the shaft hole 33t2. In this way, the support plate 33 is rotatably supported by the inner frame 20 so that the supporting member 33 is supported by the shafts 191a and 196a of the protruding pieces 191 and 196 in the shaft holes 33t1 and 33t2. It comes in contact.

As shown in FIG. 4, the mechanical plate 70 includes a guide path 70b for guiding the organic spheres B discharged as product beads or rental beads to the upper plate 24 or the lower plate 25. It is provided through 70 in the width direction. The metal plate 90 is affixed slightly above this guide path 70b (z direction shown in FIG. 4).

As shown in FIG. 4, the bending part 90a and the bending part 90b are formed in the side end part of the metal plate 90. As shown in FIG. These bent parts 90a and 90b are attached to the side of the instrument plate 70 together with the protruding pieces 191 and the protruding pieces 196, respectively. As a result, the metal plate 90 is in a state capable of conducting with the metal protrusions 191 and the protrusion pieces 196 through the bent portions 90a and 90b. Of course, even if the metal plate 90, the protrusion piece 191 and the protrusion piece 196 is integrally formed in advance, there is no problem.

In the lower position on the metal plate 90 (the position biased in the -z direction shown in FIG. 4), the bead base 77 overlaps the mounting surface 77g of the bead base 77 and the upper surface of the metal plate 90. Attached. In the bead base 77, a passage 77a of the organic sphere B discharged as product beads or rental beads is formed, and a metal bell 77c is attached to the center of the passage 77a. .

The bell 77c is attached to a metal support shaft 79 that stands vertically through the mounting surface 77g. Therefore, when the bead base 77 is attached on the metal plate 90, the mounting surface 77g and the support shaft 79 will be in contact with the metal plate 90. As shown in FIG. Therefore, the static electricity charged to the bell 77c is led to the hinge plates 190 and 195 (protrusion pieces 191 and 196 and the supporting member 33) for the instrument plate through the bent portions 90a and 90b of the metal plate 90. Then, it is removed from the hinges 190 and 195 for the instrument board to the outside of the pachinko organic group 10.

Further, when the bead base 77 is attached, the organic spheres B in the passage 77a are discharged in the direction of the upper dish 24 at the position facing the guide passage 70b and the branch passage 70c. A first outlet 77b and a second outlet 77f for discharging the organic sphere B in the passage 77a in the lower plate 25 direction are formed. A partition plate 77e is placed upright between the first outlet 77b and the second outlet 77f. The guide plate 77d is provided in the state inclined downward on the partition plate 77e. This guide plate 77d is provided in the range which covers the 2nd outlet 77f.

The merchandise beads / loan ball discharge unit 75 is attached to the upper side (the z direction shown in FIG. 4) of the passage 77a of the bead barrel base 77. The bead cylinder base 77 below the mounting position of the product bead / loan bead discharge unit 75 (-z direction shown in FIG. 4) is covered by the bead cylinder cover 78. A user hole (bottomed hole) 78a is provided in one of the top surfaces of the bead barrel cover 78, and the main substrate plate 85 and the inside of the hole of the user hole 78a are provided. A nut for attaching the plate 87 for the discharge control board is fitted.

The product beads / rental beads discharge unit 75 is provided with two stoppers (not shown) which open and close the motor 75a, 75b as a power source therein. This stopper becomes closed, and the fall of the organic sphere B from the case rail 74 is prevented. In addition, two protective covers 76a and 76b are attached to the top surface of the product bead / loan ball discharge unit 75 so as to cover the motors 75a and 75b, respectively.

At the bottom (in the -z direction shown in Fig. 4) of the product bead / loan ball discharge unit 75, a product bead discharge port 75c and a rental bead discharge port 75d are connected to each other from the position of each stopper. In addition, in the vicinity of the product bead discharge port 75c and the rental bead discharge port 75d in the product bead / rental ball discharge unit 75, the product bead and the rental bead discharged from the product bead discharge port 75c and the rental bead discharge port 75d. A merchandise beads / rental bead sensor (not shown) which detects the number of organic spheres B as a buried is embedded.

In FIG. 4, the case rail 74 has shown the state before the combination divided | segmented up and down. In the case rail 74 attached to the upper position of the metal plate 90, the entrance opening 74a which the organic sphere B which flowed out from the tank rail 73 enters, and the organic opening which entered from this entrance opening 74a A branch wall 74b for branching (B) into a product bead passage 74c and a rental bead passage 74d, and an organic ball through hole for product beads that is an exit of the branched organic sphere B ( 74e) and an organic sphere through hole 74f for the lease beads.

In the pachinko organic device 10 configured as described above, the organic content is executed as follows. When the loan button 16b of the guide unit 16 is pressed after the prepaid card unit 15 is inserted into the prepaid card unit 15, the discharge control unit 86 that detects the information of the number of the leased beads is supplied to the rental bead discharge port 75d. To open the stopper. As a result, the organic sphere B accumulated in the rental bead passage 74d of the case rail 74 is discharged from the rental bead discharge port 75 in the merchandise bead / rental bead discharge unit 75 from the rental bead organic sphere passage opening 74f. Enter the passage 77a of the bead base 77 through 75d. The organic sphere B which entered this passage 77a collides with the bell 77c, flows down toward the first outlet 77b while ringing the bell 77c, and guides from the first outlet 77b. Discharged to 70b. Thereby, the predetermined number of organic spheres B as a rental ball are discharged | emitted through the guide path 70b to the upper dish 24 of the front side of the pachinko organic group 10 front.

Then, when the rotation operation of the launch handle 26a shown in FIG. 2 is performed, the launch operation unit 26 drives the launch motor, the shot rod, etc. of the launch mechanism unit 31, and is discharged | emitted to the upper pan 24. The organic sphere B is fired toward the organic region. The fired organic sphere B passes through the firing rail 30 and then contacts the outer rail 51 or the inner rail 49 along a passage formed between the outer rail 51 and the inner rail 49. To rise. Thereafter, the organic sphere B pushes open the foul bead stopper 50 mounted at one end of the inner rail 49 by the force applied to the organic sphere B. FIG. As a result, the organic sphere B is guided to the organic region.

The organic sphere B guided to the organic region flows down on the organic plate 40 while colliding with the outer rail 51 or the obstacle nail, and is out of the outlet 53, the normal mouth 43, and the large mouth 46. Enter any one. The organic sphere B entering the outlet 53 is discharged out of the machine through the out bead discharge passage 70d. On the other hand, when the organic sphere B enters into the ordinary mouth opening 43 or the large mouth opening 46 during the abandonment, the discharge control unit 86 which detects the entry of this organic sphere B is the product bead outlet ( Indicate the opening of the stopper on the 75c) side. As a result, the organic beads B accumulated in the product beads passage 74c of the case rail 74 are discharged from the product beads / loan bead discharge unit 75 from the product beads organic ball passage opening 74e. Enter the passage 77a of the bead base 77 through 75c. The organic sphere B entering this passage 77a collides with the bell 77c, rings the bell 77c, is guided to the guide plate 77d, and flows toward the first outlet 77b, and the first outlet. It discharges from 77b to the guide path 70b. Thereby, the predetermined number of organic spheres B as product beads are discharged | emitted through the guide path 70b to the upper dish 24 of the front side of the organic group 10.

When the organic sphere B exceeding the capacity of the upper dish 24 is discharged, the organic sphere B cannot flow from the guide path 70b to the upper dish 24. As a result, the guide passage 70b and the first outlet 77b are blocked by the organic sphere B, and the organic sphere B stays in the lower portion near the first outlet 77b in the bead base 77. . When the organic sphere B stays up to the height exceeding the partition plate 77e, the organic sphere B flows over the partition plate 77e toward the second outlet 77f and branches off from the second outlet 77f. It is discharged to the furnace 70c. Thereby, the organic sphere B as a commodity beads is discharged | emitted to the lower dish 25 of the front side of the organic organic group 10 via the branch path 70c.

According to the discharge of the product beads and the rental beads as described above, the organic balls B accumulated in the case rail 74, the tank rail 73, and the bead tank 72 are sequentially in the product bead / rental bead discharge unit 75. Move to the side. When it is detected that the number of stored water in the bead tank 72 is equal to or less than a certain number by the discharge of the product beads or the rental beads, the beads of the organic field are based on the instructions from the frame external terminal board 80d which received this detection result. The organic sphere B is replenished to the bead tank 72 from a supply apparatus.

In addition, the number of discharged product beads or rental beads is detected by a product beads / rental beads sensor (not shown) installed in the product beads / rental beads discharge unit 75. When the product bead / rental bead sensor detects a predetermined number of discharges, the detection result is sent to the discharge control unit 86, and the discharge control unit 86 having received the detection result is discharged from the product bead discharge port 75c to the loan. The stopper on the bead outlet 75d is instructed to close. The closing of the stopper stops the flow of the organic sphere B from the organic sphere passage opening 74e for product beads or the organic sphere passage opening 74f for rental beads. As a result, the inside of the bead tank 72, the tank rail 73, and the case rail 74 returns to the state in which the organic sphere B was stored like granularity or before the ball | bowl loan generation.

Next, the characteristic structure of the pachinko organic group 10 of a present Example is demonstrated with reference to FIGS. 5 is a view showing the back of the glass frame 22. As shown in FIG. 5, in the frame part 22b of the back of the glass frame 22, a thin metal plate like the flat plate 150, the flat plate 151, and the enclosing plate 153 Is equipped.

The enveloping plate 153 is an approximately U-shaped plate mounted in a range from the right side to the lower side and the left side of the opening 22a. The enveloping plate 153 is provided with the bent parts 153a, 153b, and 153c formed in the range which encloses the opening part 22a, bend | folding the enveloping plate 153, and standing to a predetermined height from the plate surface. Among these, between the edge part of the upper part (upper side in FIG. 5) of the bending part 153a, and the upper part (upper side in FIG. 5) of the bending part 153c, as shown in FIG. 5, the metal connecting member 154 is shown. Is laid on. By spanning the connecting member 154, the strength of the bent portions 153a, 153b, and 153c is secured.

6 shows cross-sectional shapes of the bent portions 153a, 153b, and 153c. 6 (A), 6 (B) and 6 (C) are cross-sectional shapes when the enclosing plate 153 is cut along the 6A-6A, 6B-6B and 6C-6C lines of FIG. 5, respectively. Indicates. 6 (A) and 6 (C), fitting grooves 153sa and 153sc into which the connecting member 154 is fitted are formed in the bent portions 153a and 153c of the surrounding plate 153. .

As shown to FIG. 6 (A)-FIG. 6 (C), the fitting groove | channel 153ga, 153gb, 153gc in which glass is fitted is formed in the bending part 153a, 153b, 153c of the surrounding plate 153. FIG. . As shown in Fig. 6 (B), the bent portion 153b is a horizontal direction (the surface direction of the organic panel 40 attached to the inner frame 20) from the portion where the fitting grooves 153gb are formed in these bent portions. The protruding portion 153bt is formed to protrude. This protruding portion 153bt is formed in almost the entire range of the bent portion 153b except for the range of the inner frame 20 facing the outer rail 51. The bent part 153b of the range which opposes the outer rail 51 becomes the notch 153bm which does not protrude horizontally from the part in which the fitting groove 153gb was formed (refer FIG. 9 demonstrated later).

In addition, as shown in FIG. 6 (C), in the bent portion 153c opposite to the fitting groove 153gc, a metal locking piece 155 is placed in the horizontal direction from the bent portion 153c (glass frame 22). In the extended direction). Further, the bent portion 153c is provided with a locking piece 156 having the same shape as the locking piece 155 at a position below the locking piece 155 (see FIG. 5). These locking pieces 155 and 156 are mounted at positions corresponding to the locking portions 143c and 143p provided in two positions above and below the key unit 29 described later.

Returning to FIG. 5, the description will be given. As shown in FIG. 5, the flat plate 150 and the flat plate 151 are attached to the upper (upper FIG. 5) area | region outside the opening part 22a in the aspect which covers the surrounding plate 153 from the top. . Two screws penetrate the range where the flat plate 150 and the surrounding plate 153 overlap each other, whereby the flat plate 150 and the surrounding plate 153 form a frame portion 22b on the rear surface of the glass frame 22. It is fixed to). Similarly to the flat plate 150, the flat plate 151 is fixed through with a screw. Therefore, the flat plate 150 is always in contact with the enveloping plate 153, whereby the conduction between the flat plate 150 and the enveloping plate 153 is possible. In addition, the flat plate 151 is also always in contact with the enveloping plate 153, whereby the conduction between the flat plate 151 and the enveloping plate 153 is possible.

On the other hand, as shown in FIG. 5, the flat plate 150 and the flat plate 151 are attached to the frame part 22b in the state which does not contact each other at the predetermined space | interval d1. That is, the metal plates, such as the flat plates 150 and 151 and the enclosing plate 153, which are provided in the peripheral region outside the opening 22a, are mounted by spreading the flat plates 150 and the flat plate 151 apart from each other. It is installed continuously. In the present embodiment, the flat plate 150, the flat plate 151, and the enveloping plate 153 shown in FIG. 5 are made of metal having an area of about 800 square centimeters on the rear surface of the glass frame 22. Plate area is secured.

In the present embodiment, the "plate body" in the claims corresponds to a metal plate made of the flat plate 150, the flat plate 151, and the surrounding plate 153. Of course, it is also possible to make "plate body" into other forms other than the said flat plate 150, the flat plate 151, and the surrounding plate 153.

In addition, as shown in FIG. 5, the roll part which comprises a part of glass-frame hinge 180 is formed in the side end part (tip part of the right side in FIG. 5) of the flat plate 151 of the glass frame 22 outer direction ( roll) 151g is formed. Moreover, on the surrounding plate 153 which is substantially vertically below this roll part 151g, the metal bearing plate 188 which comprises a part of the hinge 185 for glass frames is in contact with the upper surface of the surrounding plate 153. It is installed. The bearing plate 188 is attached to the rear surface of the glass frame 22 by three screws. Detailed configurations of the glass frame hinge 180 and the glass frame hinge 185 will be described later.

7 shows a front surface of the pachinko organic group 10 in a state where the glass frame 22 to the upper plate 24 are removed. In FIG. 7, the prepaid card unit 15 is not shown. Hereinafter, although FIG. 7 is demonstrated, it demonstrates, referring FIG. 8 thru | or 10 suitably in this description.

As can be seen by comparing FIG. 7 with FIG. 2, the area of the inner frame 20 covered with the glass frame 22 (hereinafter referred to as the glass frame covering area) to the inner plate covered with the upper plate 24. The key unit 29 mentioned above is provided in the area | region (henceforth an upper dish coating area | region) of the 20. As shown in FIG. Further, in the upper dish covering area, a resin foul bead guide unit 131 for guiding foul beads to the lower dish 25 and a metal pedestal mounted on the foul bead guide unit 131 are provided. 132, a launch rail 30 mounted on the pedestal 132, and a metal contact member 134 connecting the pedestal 132 and the key unit 29 are provided. In addition, the sheet metal 110 made of metal circumscribed by the inner side rail 49 is provided in the glass frame covering area | region just a little above the launch rail 30. As shown in FIG.

In addition, as can be seen by comparing FIG. 7 with FIG. 2, the metal sheet metal circumscribed to the outer rail 51 is formed in the glass frame covering region near the outer rail 51 located in the left direction toward FIG. 7. 115) is installed.

As shown in FIG. 7, when the glass frame 22-the upper plate 24 are removed from the pachinko organic machine 10, the hinge for an inner frame (where the glass frame 22-the upper plate 24 was attached) ( A portion of the members constituting the 170 and 175 (the shaft forming members 171 and 176, the shafts 171a and 176a, the bearing plates 173 and 178 shown in FIG. 7) and the hinges 180 and 185 for the glass frame are A part of the member (protruding portion 171b, shaft 186, and pedestal 187 of the shaft forming member 171 shown in FIG. 7) remains.

The appearance around the launch rail 30 and the inner rail 49 in FIG. 7 is shown in FIG. First, the state around the launch rail 30 is demonstrated. As shown in FIG. 8, the pedestal 132 on the foul bead guide unit 131 is fixed to the inner frame 20 using a screw. The launch rail 30 and the bead stopper 133 are mounted on this pedestal 132. The bead stopper 133 is a wall which prevents the organic sphere B on the launch rail 30 from falling to the bottom opening 20y of the inner frame 20 along the inclination of the launch rail 30. . The hitting rod 31a of the launch mechanism unit 31 is disposed between the bead stopper 133 and the front end of the launch rail 30.

In addition, on the foul ball guide unit 131 and the pedestal 132, a contact member 134 is mounted using a screw. As shown in FIG. 8, the contact member 134 has the overlap part 134a which overlaps on the pedestal 132, the extension part 134b extended in the direction bent at substantially right angle from this overlap part 134a, and The fitting portion 134c is bent at an approximately right angle from the extension portion 134b and extends in the opposite direction to the overlap portion 134a. The extension part 134b is arrange | positioned along the guide surface GS formed in the inner frame 20. As shown in FIG. In addition, the fitting portion 134c is sandwiched between the mounting surface IS of the key unit 29 formed in the inner frame 20 and the frame 140 of the key unit 29, and thus the mounting surface IS and the frame 140. ) Is supported.

As shown in FIG. 8, the key unit 29 is equipped with the frame 140 extended in the range of the longitudinal direction (z-axis direction shown in FIG. 8) of a glass frame covering area | region. The frame 140 has a substantially U-shaped cross-sectional shape and is attached to the guide surface GS of the inner frame 20. In addition, illustration of the inner frame 20 and the frame 140 of the upper position of the pachinko organic group 10 is abbreviate | omitted in FIG.

On the outer side surface 141a of the frame 140, the slide plate 143 is provided in the range corresponding to the upper glass frame covering area, and the slide plate 147 is provided in the range corresponding to the upper upper plate covering area, respectively. It is. The slide plate 143 is used to change the open / close state of the glass frame 22, and the slide plate 147 is used to change the open / close state of the upper plate 24. In this embodiment, detailed description of the slide plate 147 is omitted.

In the vicinity of the center of the slide plate 143, long holes 143a and 143m having short side lengths to which the shaft portions of the pin shafts 141 and 142 are movable are formed. The pin shafts 141 and 142 are mounted to the outer side surface 141a of the frame 140 in a state of penetrating the long holes 143a and 143m. Thereby, the slide plate 143 is arrange | positioned so that it may slide up and down along the long side of the long hole 143a, 143m between the head part of the pin shaft 141, 142 and the outer side surface 141a. .

To the slide plate 143, a lock mechanism 144 having a spring (not shown) is connected. In the state shown in FIG. 8, the spring attached to the slide plate 143 is locked by the locking mechanism 144 in the state which tensioned downward, and this slide plate 143 is arrange | positioned at the bottom position by this latch. Such a state is hereinafter referred to as the locking open state of the lock mechanism 144. When the front end portion 144a of the lock mechanism 144 is pressed in the unlocked state, the engagement of the spring by the lock mechanism 144 is released. Thereby, the elastic force of the spring acts on the slide plate 143, and the slide plate 143 moves upward along the long holes 143a and 143m which the pin shafts 141 and 142 can move. By the upward movement, the lock mechanism 144 is locked.

The frame 140, the pin shafts 141 and 142, the slide plate 143 and the lock mechanism 144 are all formed using metal. Moreover, as shown in FIG. 8, a part of upper part rather than each long hole 143a, 143m of the slide plate 143 is formed in the shape cut out. The cut out portions are hereinafter referred to as cutouts 143b and 143n, and the partially cut out portions are hereinafter referred to as locking portions 143c and 143p. The locking portions 143c and 143p of the slide plate 143 are located in front of the notch portions 143b and 143n (the x direction in Fig. 8) where the front end portion 144a of the lock mechanism 144 is located. 8, illustration of the frame 140, the slide plate 143, and the lock mechanism 144 between the notch 143b and the notch 143n is omitted.

If the front end portion 144a of the lock mechanism 144 is pressed while the locking pieces 155 and 156 behind the glass frame 22 enter the cutout portions 143b and 143n, the locking portions 143c and 143p. ) Moves upward to lock the mechanism 144, and the glass frame 22 is kept in the closed state as shown in FIG. The locked state of the lock mechanism 144 is released in accordance with the unlocking operation of the lock 28 provided in the keyhole ornament 27. As a result, the lock mechanism 144 is locked, and the glass frame 22 can be opened by rotation about the hinges 180 and 185 for the glass frame. Moreover, after opening the glass frame 22, a finger is inserted between the back surface of the upper plate 24 and the surface of the inner frame 20, and a part of the slide plate 147 is pressed to move the upper plate 24 and The engagement state with the key unit 29 is released. As a result, the upper plate 24 is rotatable around the upper plate hinge, so that the upper plate 24 can be opened.

In the above, the state around the launch rail 30 was demonstrated. In this way, in the state where the glass frame 22 is removed from the pachinko organic machine 10, the launch rail 30 is connected to the key unit 29 via the pedestal 132 and the contact member 134. The "first connection member" in the claims corresponds to the key unit 29 of the present embodiment with respect to the launch rail 30. Of course, it is also possible to make this "first connection member" into another form.

Next, the state around the inner rail 49 is described. As shown in FIG. 8, the inner side frame 20 in the outer side vicinity of the inner side rail 49 is a shape which was raised more than the surface of the organic panel 40 by the width | variety of the inner side rail 49 generally. The part of this raised shape is hereafter called ridge 20r. A substantially V-shaped sheet metal 110 is mounted along the outer circumferential surface of the ridge 20r. That is, as shown in FIG. 8, the ridge 20r has four front surfaces 20ra, the back surface (not shown) which opposes the organic panel 40, the upper side 20rc, and the lower side 20rd. It has an outer surface. The sheet metal 110 is formed in the space region between the upper surface 20rc and the inner rail 49 through a gap between the rear surface of the ridge 20r and the surface of the organic plate 40 from the lower surface 20rd. It is installed to reach. In the state provided in this way, the sheet metal 110 located between the upper surface 20rc and the inner rail 49 is in contact with the outside of the inner rail 49 by the elastic force of the sheet metal 110.

The sheet metal 110 installed in this way is fixed to the lower surface 20rd of the ridge 20r using the screw 111. Moreover, as shown in FIG. 8, the bending part 110f is formed in the edge part of the sheet metal 110 by making the edge part bent. The sheet metal 110 is fixed such that the bent portion 110f faces the front side (the x direction in FIG. 8) of the pachinko organic group 10.

The "first connecting member" in the claims corresponds to the sheet metal 110 in the present embodiment with respect to the inner rail 49. Of course, it is also possible to make this "first connection member" into another form.

The state around the sheet metal 115 attached to the outer rail 51 is shown in FIG. FIG. 9 shows the shape of the Pachiko organic group 10 in the state in which the glass frame 22 is opened, and has a structure lower than the glass covering area except for the glass frame hinge 185 and the upper dish hinge. It abbreviate | omits and shows.

As shown in FIG. 9, the edges 20d, 20e, and 20f of the shape which protruded in the front (x direction in FIG. 9) are formed in the outermost periphery of the inner frame 20 surface. These tees 20d are located on the outer circumference of the left side (in the -y direction in FIG. 9) toward the front of the pachinko organic group 10, and the te 20e is upward toward the front of the pachinko organic group 10. It is located in the outer periphery (the z direction in FIG. 9). In FIG. 9, illustration is omitted about the frame 20f located at the outer periphery of the pachinko organic group 10 toward the front (y-direction in FIG. 9). When the glass frame 22 is closed, the glass frame 22 is put inside the frames 20d, 20e, and 20f. At this time, a part of the plane 20h of the inner frame 20 formed inside the frames 20d, 20e, and 20f is covered by the flat plate 151 or the surrounding plate 153 on the back of the glass frame 22.

In the center region of the inner frame 20 inside the plane 20h, a recessed portion 20i is formed in the shape which is recessed to a depth from the plane 20h to the surface of the organic panel 40. The outer rail 51 and the inner rail 49 are attached to the surface of the organic panel 40 in the recess 20i. At the front end of the inner rail 49, the above-described metal foul ball stopper 50 is mounted.

In the present embodiment, as shown in FIG. 9, the foul bead stopper 50 is attached to the inner rail 49 with the foul bead stopper 50 slightly in contact with the outer rail 51. Therefore, the foul bead stopper 50 pushed open by the fired organic sphere B is returned to its original position by its elastic force after the passage of the organic sphere B, and weakly contacts the outer rail 51 again. Thereby, the outer rail 51 and the inner rail 49 are conducted through the foul bead stopper 50 except when the organic sphere B passes. Therefore, a potential difference between the outer rail 51 and the inner rail 49 is less likely to occur, so that the occurrence of local high voltage on the outer rail 51 or the inner rail 49 can be prevented.

Among the side surfaces which form the recessed part 20i, the left side is made into the side surface 20j toward the front of the pachinko organic group 10. As shown in FIG. As shown in FIG. 9, the sheet metal 115 is provided in the space area | region between this side surface 20j and the outer rail 51. As shown in FIG. In addition, in FIG. 9, the sheet metal 115 is shown in the state which saw the outer rail 51 for convenience of description.

As shown in FIG. 9, among the two edge parts of the sheet metal 115, one edge part located in the surface side (the -x direction side shown in FIG. 9) of the organic plate | board 40 is bent and bent part 115e. ) Is formed. Moreover, the bending part 115f is formed in the other edge part located in the back surface direction side (x direction side shown in FIG. 9) of the glass frame 22. As shown in FIG.

In the state where the sheet metal 115 is installed in the space area between the side surface 20j and the outer rail 51, the bent portion 115e of the sheet metal 110 is formed by the elastic force of the bent portion 115e. It is in contact with the outside of 51. The sheet metal 115 thus installed is fixed using a screw (not shown) to the side surface 20j such that the bent portion 115f faces the front side (the x-direction side in FIG. 9) of the pachinko organic machine 10. .

The "first connection member" in the claims corresponds to the sheet metal 115 of the present embodiment with respect to the outer rail 51. Of course, it is also possible to make this "first connection member" into another form.

Next, the structures of the inner frame hinges 170 and 175 and the glass frame hinges 180 and 185 will be described with reference to FIGS. 9 and 10. FIG. 10 is an explanatory view showing the structures of the inner frame hinge 170 and the glass frame hinges 180 and 185 together with the structures of the instrument plate hinges 190 and 195. In FIG. 10, the inner frame 20 and the outer frame 12 to which the inner frame hinges 170 and 175 are attached, and the glass frame 22 and the inner frame 20 to which the hinges 180 and 185 for the glass frame are attached. In addition, in the instrument board 70 and the inner frame 20 to which the hinges 190 and 195 for instrument boards are attached, the external shape is shown by the dashed-dotted line.

First, the inner frame hinges 170 and 175 will be described. As shown in FIG. 9 and FIG. 10, the inner frame hinge 170 includes a metal shaft forming member 171 attached to a side surface of the inner frame 20 above (the z-direction side shown in FIG. 10) and the outside. It is comprised by the metal bearing plate 173 attached to the side surface of the frame 12 upper side (z direction side shown in FIG. 10) to the side surface of the frame 12-side side -y direction shown in FIG. The shaft forming member 171 has a mounting portion 171e which is placed on the upper side of the inner mold 20, and the front of the inner mold 20 in succession with the laying portion 171e. The 1st extension part 171f extended in the length beyond the thickness of the inner side frame 20 in the x direction direction shown to 10 is provided. The shaft 171a which extends substantially vertically downward is attached to the front end of this 1st extension part 171f.

The lower part of the shaft formation member 171 is provided with the 2nd extension part 171g extended by the length beyond the thickness of the inner frame 20. As shown in FIG. This second extension portion 171g is inserted into a through hole 20c that penetrates the inside and outside of the inner mold 20 when the shaft forming member 171 is attached to the inner mold 20. When the shaft forming member 171 is attached to the inner frame 20, the protrusion 171b at the end of the second extension portion 171g is ahead of the plane 20h of the inner frame 20 (the x direction shown in FIG. 10). ) Is in a protruding state (see FIG. 9). The protrusion 171b is formed with a shaft hole 171t having a diameter slightly larger than the diameter of the shaft portion 181b of the slide shaft 181 described later.

On the other hand, in the bearing plate 173, as shown in FIG. 10, the extension part 173a extended in the inner frame 20 direction (x direction shown in FIG. 10) is formed, and in this extension part 173a, , The shaft hole 173t having a diameter slightly larger than the diameter of the shaft 171a is drilled.

Similar to the hinge 170 for the inner frame, the inner frame hinge 175 also includes a metal shaft forming member 176 with a shaft 176a and a shaft hole 178t having a diameter slightly larger than the diameter of the shaft 176a. It consists of a bearing metal plate 178 made of perforated metal (see Fig. 7). The shaft forming member 176 and the bearing plate 178 are attached between the side of the lower side of the inner frame 20 (downward direction shown in FIG. 7) and the outer frame 12.

By inserting the shafts 171a and 176a of the shaft forming members 171 and 176 into the shaft holes 173t and 178t of the bearing plates 173 and 178, the inner frame 20 opens and closes with respect to the outer frame 12. It is possibly installed. For example, in the case of the hinge 170 for an inner frame, as shown by the black thick arrow in FIG. 10, the extension part 173a of the bearing plate 173 is rearward of the shaft forming member 171 (FIG. 10). After passing through the notch 171c formed in the -x direction shown in the figure, the shaft 171a is inserted into the shaft hole 173t at the front end of the extended portion 173a.

Next, the glass frame hinges 180 and 185 will be described. 9 and 10, the hinge 180 for a glass frame includes a shaft hole 171t formed in the protrusion 171b of the shaft forming member 171 attached to the inner frame 20 described above, and a glass frame. The roll portion 151g of the flat plate 151 mounted on the back of the 22 and the slide shaft 181 inserted into the roll portion 151g and hung so as to slide up and down outside the roll portion 151g. Consists of.

As shown in FIG. 10, the roll part 151g is formed round the edge of the flat plate 151, and is formed. The shaft insertion hole 151h is formed as a space in this roll part 151g. The shaft portion 181b of the slide shaft 181 is inserted into the shaft insertion hole 151h from the bottom up. Moreover, the hanger part 151i which hangs one end of a spring is welded to the outer side of the roll part 151h. The other end of the spring which hangs on this hanger part 151i is wound around the grip part 181a of the slide shaft 181, and is attached. As a result, the slide shaft 181 receives a force upward (in the arrow K direction shown in FIG. 10) by the elastic force of the spring. As a result, the shaft portion 181b inserted into the shaft insertion hole 151h passes through the shaft insertion hole 151h and protrudes upward of the roll part 151g.

On the other hand, the hinge 185 for glass frames is an axis | shaft fixed to the plane 20h below the inner frame 20 (in the -z direction in FIG. 10) using three screws, as shown to FIG. 9 and FIG. It consists of the pedestal 187 with 186, and the bearing plate 188 attached to the rear surface of the glass frame 22 in the state which overlapped with the surrounding plate 153 mentioned above. The shaft 186 extends downward through the pedestal 187 and is fixed to the inner mold 20 at its end (see FIG. 7). The part of this shaft 186 located above the base 187 functions as the hinge 185 for glass frames, and the part located below the base 187 functions as the hinge for an upper dish.

As shown to FIG. 9 and FIG. 10, one end of the metal thin plate 99 is attached to the base 187 which comprises the hinge 185 for glass frames. The other end of the thin plate 99 is inserted from the outside of the inner frame 20 into a slit 20k (see FIG. 10) penetrating inside and outside of the inner frame 20, so that It is attached to the supporting member 33.

9 and 10, the bearing plate 188 is bent in a direction perpendicular to the plate surface at an outer side of the frame portion 22b at a position perpendicular to the lower side of the roll portion 151g. It has a bent portion (188a) extending in the horizontal direction. The bent portion 188a is formed with a shaft hole 188t having a diameter slightly larger than the diameter of the shaft 186.

After inserting the shaft hole 188t of the bearing plate 188 into the shaft 186 on the pedestal 187, the shaft portion 181b of the slide shaft 181 is inserted into the shaft hole 171t of the protrusion 171b. By inserting, the glass frame 22 is supported by the inner frame 20 so that opening and closing is possible. When inserting the shaft portion 181b into the shaft hole 171t, first, the handle portion 181a is pushed down in the direction of the arrow L shown in FIG. 10 against the elastic force of the spring, so that the shaft portion 181b is a roll portion ( It does not protrude too much to the upper side of 151g). Next, after aligning the shaft portion 181b to the position of the shaft hole 171t, the hand is released from the handle portion 181a. Thereby, the slide shaft 181 is moved upwards (arrow K direction shown in FIG. 10) by the elastic force of a spring, and the shaft part 181b is inserted in the shaft hole 171t. Thereby, the glass frame 22 is rotatably provided in the inner frame 20 in the state shown in FIG.

Thus, when the glass frame 22 is installed in the inner frame 20, the roll part 151g of the flat plate 151 will be in contact with the shaft part 181b of the slide shaft 181, and the slide shaft The shaft portion 181b of 181 is in contact with the protrusion 171b of the shaft forming member 171 at the shaft hole 171t. In addition, when the inner frame 20 is installed in the outer frame 12, the shaft forming member 171 is in contact with the bearing plate 173. That is, in the state in which the inner frame 20 is installed in the outer frame 12 and the glass frame 22 in the inner frame 20, respectively, the flat plate 151 on the back of the glass frame 22 is hinged for the glass frame 180 Conduction to the inner frame hinge 170 (shaft forming member 171 and bearing plate 173) through (roll part 151g, slide shaft 181, protrusion 171b of shaft forming member 171). It is.

On the other hand, when the glass frame 22 is installed in the inner frame 20, the bearing plate 188 superposed on the surrounding plate 153 is in contact with the shaft 186 at the shaft hole 188t, and this shaft ( The pedestal 187 on which the 186 is mounted is connected to the support member 33 through the thin plate 99. 4, when the mechanism plate 70 is installed in the inner frame 20, the supporting member 33 is the shaft 191a of the protruding pieces 191 and 196 at the shaft holes 33t1 and 33t2. 196a). That is, in a state where the glass frame 22 and the instrument plate 70 are respectively installed in the inner frame 20, the enclosing plate 153 on the back of the glass frame 22 is the hinge 185 for the glass frame (bearing plate 188). , The shaft 186 and the pedestal 187) and the thin plate 99 are connected to the hinges 190 and 195 (the supporting member 33 and the protruding pieces 191 and 196) for the instrument plate.

In the present embodiment, the "second connection member" in the claims is the "glass frame hinge 180", the enclosing plate 153 and the instrument plate hinge that connect the flat plate 151 and the inner frame hinge 170 in this embodiment. It corresponds to "the glass frame hinge 185 and the thin plate 99" which connect 190 and 195. Of course, this "second connection member" can also be made into another form.

In the pachinko organic device 10 configured as described above, when the glass frame 22 rotatably installed in the inner frame 20 through the hinges 180 and 185 for the glass frame, the bent portion of the rear of the glass frame 22 ( 153a, 153b, and 153c and the connecting member 154 enter the recessed part 20i of the inner mold 20, and are in the range shown by the dashed-dotted line in FIG. As illustrated in FIG. 11, the engaging pieces 155 to 156 of the bent portion 153c abut against the key unit 29 in the regions P to Q. As shown in FIG. In addition, the protrusion 153bt (not shown in FIG. 11) of the bent portion 153b abuts the sheet metal 110 in the region R, and the bent portion 153a abuts the sheet metal 115 in the region S. FIG. 12 shows a state in which the bent portion 153c and the key unit 29 abut in the regions P to Q, and a state in which the bent portion 153b and the sheet metal 110 abuts in the region R is shown in FIG. 13. In FIG. 14, a state where the bent portion 153a and the sheet metal 115 abut in the region S is shown. Hereinafter, each figure is demonstrated.

First, the region P to region Q will be described. FIG. 12: is explanatory drawing which shows the appearance around the key unit 29 along the 12-12 line of FIG. In FIG. 12, the inner side frame 20 to which the key unit 29 is mounted is abbreviate | omitted and shown. In addition, about the glass frame 22, the locking pieces 155 and 156 are made into cut surfaces, and are shown by hatching hatching, and the parts other than the locking pieces 155 and 156 are made into virtual shapes, and 2 The dashed line and the dotted line are shown by.

12 (A) shows a state in which the glass frame 22 is opened, and the lock mechanism 144 is in the unlocked state of the key unit 29. In this state, as described above in FIG. 8, the launch rail 30 is connected to the key unit 29 via the pedestal 132 and the contact member 134.

When the glass frame 22 is closed from this state, first, as shown in FIG. 12 (B), the locking pieces 155 and 156 pass through the upper portions of the locking portions 143c and 143p and the slide plate 143 is closed. It enters into notches 143b and 143n.

Then, as shown in FIG.12 (B), when the surrounding plate 153 of the back of the glass frame 22 contacts the front-end | tip part 144a of the lock mechanism 144, and closes the glass frame 22 further, The front end 144a of the lock mechanism 144 is pressed by the surrounding plate 153. Thereby, the lock mechanism 144 is locked, and the key unit 29 and the glass frame 22 will be in the state shown to FIG. 12 (C). That is, when the front end portion 144a is pressed while the locking pieces 155 and 156 enter the cutout portions 143b and 143n, the slide plate 143 moves upward along the long holes 143a and 143m. As a result, the slide plate 143 abuts against the lower ends of the engaging pieces 155 and 156.

When the hand is released from the glass frame 22 after the locking mechanism 144 is locked, the glass frame 22 tries to return in the opposite direction to the pressing direction. The pieces 155 and 156 abut on the locking portions 143c and 143p of the slide plate 143 as shown in FIG. 12D, and the locking portions 143c and 143p return the locking pieces 155 and 156. Stops going Therefore, after removing the hand from the glass frame 22, as shown in FIG. 12 (D), the locking parts 143c and 143p and the locking pieces 155 and 156 will be in contact, and the glass frame 22 ) Remains closed.

Thus, in the closed state of the glass frame 22, the engaging parts 143c and 143p of the key unit 29 and the engaging pieces 155 and 156 attached to the bent part 153c of the surrounding plate 153 contact. It is in a state. For this reason, the launch rail 30 is surrounded by the base 132, the contact member 134, the locking portions 143c and 143p of the key unit 29, and the bent portion 153c of the surrounding plate 153. 153 and flat plates 150 and 151 are brought into contact with the metal plate region on the rear surface of the glass frame 22.

9 and 10, among the plates constituting the plate region made of metal, the flat plate 151 has a hinge 180 for a glass frame (roller 151g, a slide shaft 181, and a shaft). It is connected to the hinge 170 for the inner frame (the shaft forming member 171 and the bearing plate 173) through the protrusion 171b of the member 171, and the surrounding plate 153 is the hinge 185 for the glass frame ( The bearing plate 188, the shaft 186, the pedestal 187) and the thin plate 99 are connected to the hinges 190 and 195 (the supporting member 33 and the protruding pieces 191 and 196) for the instrument plate. .

A member (base 132, a contact member 134, a key unit 29, a locking piece 155, 156) that forms a conductive path between the launch rail 30 and the inner frame hinge 170. A member (base 132), a contact constituting a conductive path between the plate 153, the flat plate 151, the hinge 180 for a glass frame, and the launch rail 30 and the hinges 190, 195 for the instrument plate. The member 134, the key unit 29, the engaging pieces 155 and 156, the enclosing plate 153, the hinge 185 for the glass frame, the thin plate 99, and the supporting member 33 are the connecting members in FIG. It corresponds to (HB). The static electricity generated on the launch rail 30 passes through this connecting member HB in turn to guide the inner frame hinge 170 or the instrument plate hinges 190 and 195 and out of the machine from each hinge 170, 190, 195. Discharged.

Next, the region R will be described. FIG. 13 is an explanatory diagram showing a state around the sheet metal 110 when cut along the line 13-13 of FIG. 11. FIG. 13A shows a state in which the glass frame 22 is opened as an image. When the glass frame 22 is closed in this state, the frame portion 22b of the glass frame 22 gradually approaches the plane 20h through the inside of the frames 20d, 20e, and 29f of the inner frame 20, The bent portions 153a, 153b, and 153c of the enclosing plate 153 on the rear of the glass frame 22 and the connecting member 154 enter the recesses 20i of the inner mold 20.

Upon entry of this bent portion 153b into the recess 20i, the protrusion 153bt at the front end of the bent portion 153b secures contact with the inner rail 49 at the ridge 20r of the inner frame 20. By contacting the bent portion 110f of the attached sheet metal 110 and further closing the glass frame 22, the protrusion 153bt resists the elastic force of the bent portion 110f and presses the bent portion 110f. By the elastic force of this sheet metal 110 (bending part 110f) with respect to the surrounding plate 153 (projection part 153bt), appropriate resistance is given when closing the glass frame 22, and the glass frame 22 is provided. The rapid closure of can be suppressed.

When the lock mechanism 144 is locked and the glass frame 22 is in a closed state, as shown in Fig. 13B, the protrusion 153bt is caused by the elastic force of the bent portion 110f in the direction of the protrusion 153bt. ) And the bent portion 110f are kept in contact with each other.

In this way, in the closed state of the glass frame 22, the bent part 110f of the sheet metal 110 circumscribed to the inner rail 49 and the bent part 153b of the surrounding plate 153 are in contact with each other. For this reason, the inner side rail 49 has the sheet metal 110 and the glass frame 22 which overlaps the surrounding plate 153 and the flat plates 150 and 151 through the bending part 153b of the surrounding plate 153. It becomes conductive to the metal plate area on the back side.

9 and 10, among the plates constituting the plate region made of metal, the flat plate 151 includes the hinge 180 for the glass frame (roller 151g, the slide shaft 181, and the shaft formation). It is connected to the hinge 170 for the inner frame (the shaft forming member 171 and the bearing plate 173) through the protrusion 171b of the member 171, and the surrounding plate 153 is the hinge 185 for the glass frame ( The bearing plate 188, the shaft 186, the pedestal 187) and the thin plate 99 are connected to the hinges 190 and 195 (the supporting member 33 and the protruding pieces 191 and 196) for the instrument plate. .

A member (sheet metal 110, enveloping plate 153, flat plate 151, glass frame hinge 180) constituting a conduction path between the inner rail 49 and the inner frame hinge 170, and Member constituting a conduction path between the inner rail 49 and the hinges 190 and 195 for the instrument plate (sheet metal 110, enveloping plate 153, glass frame hinge 185, thin plate 99, support member ( 33) corresponds to the connecting member UB in FIG. The static electricity generated on the inner rail 49 passes through this connecting member UB in turn and is led to the inner frame hinge 170 or the instrument plate hinges 190 and 195, and out of the machine from each of the hinges 170, 190 and 195. Discharged.

Next, the area S will be described. FIG. 14: is explanatory drawing which shows the appearance around the sheet metal 115 at the time of cutting along the 14-14 line of FIG. In this FIG. 14, the enclosing plate 153 of the back of the glass frame 22 is shown by hatching hatching as the cut surface with respect to the glass frame 22, and the parts other than the enclosing plate 153 are virtually shaped. It is shown by the dashed-dotted line.

FIG. 14A shows a state when the glass frame 22 rotatably installed in the inner frame 20 in the protrusion 171b is opened. When the glass frame 22 is closed in this state, the glass frame 22 gradually approaches the plane 20h of the inner frame 20, so that the bent portion 153a of the enclosing plate 153 on the back of the glass frame 22 is formed. Enters the recess 20i of the inner mold 20.

Upon entry of this bent portion 153a into the recessed portion 20i, the front end of the bent portion 153a secures contact with the outer rail 51 at the bent portion 115e, and thus the side surface 20j of the inner frame 20. A bent portion 115f of the sheet metal 115 attached thereto. Further, by closing the glass frame 22, the front end of the bent portion 153a presses the bent portion 115f against the elastic force of the bent portion 115f. By the elastic force of this sheet metal 115 (bending part 115f) with respect to the surrounding plate 153 (front end of the bending part 153a), an appropriate resistance is given when closing the glass frame 22, and the glass Sudden closure of the mold 22 can be suppressed.

When the lock mechanism 144 is locked and the glass frame 22 is in a closed state, as shown in FIG. 14 (B), the bent portion (11) is caused by the elastic force of the bent portion 115f toward the bent portion 153a. The front end part of 153a and the bending part 115f remain in contact.

In this way, in the closed state of the glass frame 22, the bent part 115f of the sheet metal 115 outer-circuited by the outer rail 51 and the bent part 153a of the surrounding plate 153 will be in contact. For this reason, the outer rail 51 is a glass frame 22 formed by overlapping the surrounding plate 153 and the flat plates 150 and 151 through the sheet metal 115 and the bent portion 153a of the surrounding plate 153. It is connected to the metal plate area on the back side.

9 and 10, among the plates constituting the plate region made of metal, the flat plate 151 has a hinge 180 for a glass frame (roller 151g, a slide shaft 181, and a shaft). It is connected to the hinge 170 for the inner frame (the shaft forming member 171 and the bearing plate 173) through the protrusion 171b of the member 171, and the surrounding plate 153 is the hinge 185 for the glass frame ( The bearing plate 188, the shaft 186, the pedestal 187) and the thin plate 99 are connected to the hinges 190 and 195 (the supporting member 33 and the protruding pieces 191 and 196) for the instrument plate. .

A member (sheet metal 115, enveloping plate 153, flat plate 151, glass frame hinge 180) constituting a conductive path between such an outer rail 51 and the inner frame hinge 170, and Member constituting a conduction path between the outer rail 51 and the hinges 190 and 195 for the instrument plate (sheet metal 115, enveloping plate 153, glass frame hinge 185, thin plate 99, support member ( 33) corresponds to the connecting member SB in FIG. The static electricity generated on the outer rail 51 passes through this connecting member SB in turn to the inner frame hinge 170 or the instrument plate hinges 190 and 195, and out of the machine from each hinge 170, 190, 195. Discharged.

In addition, as a method of discharging the static electricity guided to each of the hinges 170, 190, and 195 out of the machine, a method of connecting an earth (ground) line provided on an island of an organic field to each of the hinges 170, 190, and 195 may be considered. have.

As described above, each of the hinges 170, 190, and 195 through the launch rail 30, the inner rail 49, and the outer rail 51 through the connection member HB, the connection member UB, and the connection member SB. By connecting to the static electricity generated in the pachinko organic group 10 is quickly removed out of the machine. As a result, static electricity charged in the organic group 10 is significantly reduced than before. Further, in the pachinko organic device 10, the connecting member HB, the connecting member UB, and the connecting member SB between the rails 30, 49, and 51 and the hinges 170, 190, and 195 described above. In addition to the conduction through the bead, the beads tank 72, the tank rail 73, the case rail 74 and the product bead / loan bead discharge unit 75 may be formed of a conductive material made of resin having different surface resistance. By using a metal plate 90 to remove static electricity charged in the bead tank 72 or the like out of the machine, or a power source / launch control board plate 83 on which various control boards are installed, and a main board. The plate 85, the discharge control substrate plate 87, and the lamp and sound substrate plate 59 are adopted to communicate with each other. The results of measuring the influence of noise due to static electricity in the organic phase in the pachinko organic group 10 are shown in the graph of FIG. 15 (B).

Fig. 15 is a graph showing the potential difference occurring in the organic organic phase before and after discharge of product beads or rental beads. The graph shows the change in the potential difference in the power supply line as data, the vertical axis shows the potential difference, and the horizontal axis shows the elapsed time. 15 (A) shows the measurement result of the conventional pachinko organic group, and FIG. 15 (B) shows the measurement result in the case of the pachinko organic group 10 of the present embodiment. As shown in Fig. 15, the potential difference in the power supply line is stabilized around 5 volts before the discharge of the merchandise beads and the rental beads.

As can be seen by comparing FIG. 15 (A) and FIG. 15 (B), in the conventional pachinko organic group, a potential difference of up to 11 volts and at least -2 volts occurs when product beads or rental beads are discharged. The width W2 at which the voltage changes is 13 volts. On the other hand, in the pachinko organic machine 10 of the present embodiment, when the product beads or the rental beads are discharged, a potential difference of at most 6 volts and at least 4 volts occurs, and the width W1 at which the voltage changes is 2 volts. As described above, in the pachinko organic device 10 of the present embodiment, the width at which the voltage of the power supply line changes during discharge of product beads or rental beads is about ± 1 volt, to about 1/6 of the conventional pachinko organic device. Is reduced. As mentioned above, it turns out that the noise by the static electricity which generate | occur | produced by discharge | emission of goods beads, a rental ball, etc. by the discharge of the organic apparatus 10 of the present Example compared with the conventional apparatus is hard to be provided.

In the pachinko organic device 10 of the present embodiment described above, the firing rail 30, the inner rail 49, the outer rail 51, the inner frame hinge 170, and the guide guide the organic sphere B into the organic region. The spherical hinges 190 and 195 are connected by metal connection members HB, UB, and SB. Since the connecting members HB, UB, and SB form a path shape from each rail 30, 49, 51 to each of the hinges 170, 190, and 195, the hinges from each rail 30, 49, and 51 are intact. The path shape to (170, 190, 195) does not change by the impact from the outside with respect to the paddle organic group 10, etc. Therefore, the connection state between each rail 30, 49, 51 and each hinge 170, 190, 195 can be maintained reliably, and each hinge 30, 49, 51 can be surely hinged to the static electricity charged on each rail 30, 49, 51. Guide 170, 190, and 195 may be removed to the outside of the pachinko organic group 10.

Specifically, in the pachinko organic group 10 of the present embodiment, the connecting members HB, UB, and SB are provided on the surface constituting the organic group 10 (hereinafter referred to as a constituent surface), and each connecting member ( HB, UB, and SB) are attached to the construction surface to prevent movement. Accordingly, when carrying, installing, or inspecting the pachinko organic device 10, the connecting members HB, UB, and SB move unintentionally due to vibration or contact, and thus, each rail 30, 49, 51 and each hinge. The connection state with (170, 190, 195) is not broken.

In addition, in the pachinko organic group 10 of the present embodiment, the connecting members HB, UB, and SB are made of a plurality of metal parts, and the plurality of metal parts are connected in succession, thereby providing the front of the pachinko organic group 10. Each rail 30, 49, 51 is connected to each of the hinges 170, 190, 195 on the rear side of the organic organic device 10. Therefore, each rail 30, 49, 51 and each hinge 170, 190, 195 can be connected, without making a connection member into a complicated shape. In addition, in order to fulfill its basic functions, the pachinko organic machine 10 opens and closes a metal component (for example, a key unit 29 and a mechanism plate 70 used to open and close the glass frame 22). Although the supporting member 33 etc. which are used for this purpose are arrange | positioned, according to the parch oil apparatus 10 of this embodiment, such a metal component can be used as a part of connection member HB, UB, SB.

In the pachinko organic machine 10 of the present embodiment, the rails 30, 49, 51 and the hinges 170, 190, and 195 are normally operated by an operation normally performed before the execution of the glass, called the closing of the glass frame 22. Is conducted through the connecting members HB, UB, and SB. Therefore, it is possible to reliably remove the static electricity generated on the rails 30, 49, and 51 during the execution of the induction.

The pachinko organic group 10 of the present embodiment includes the following components as the connecting members HB, UB, and SB.

(1) Connection member (HB)

(1) a key unit (29) which is electrically connected to the launch rail (30) with the glass frame (22) open;

(2) flat plates (150, 151) and enveloping plates (153) installed on the back of the glass frame (22) with an area of about 800 square centimeters;

③ The glass frame hinge 180 connecting the flat plate 151 and the inner frame hinge 170, the glass frame hinge 185 and the thin plate 99 connecting the enclosing plate 153 and the mechanical plate hinges 190 and 195. ).

(2) Connection member (UB)

① sheet metal 110 that is in contact with the inner rail 49 while the glass frame 22 is opened,

(2) flat plates (150, 151) and enveloping plates (153) installed on the back of the glass frame (22) with an area of about 800 square cm

③ The glass frame hinge 180 connecting the flat plate 151 and the inner frame hinge 170, the glass frame hinge 185 connecting the enclosing plate 153 and the mechanical plate hinges 190, 195, and a thin plate 99. ).

(3) Connection member (SB)

① sheet metal 115 that is electrically connected to the outer rail 51 while the glass frame 22 is opened,

(2) flat plates (150, 151) and enveloping plates (153) installed on the back of the glass frame (22) with an area of about 800 square centimeters;

③ The glass frame hinge 180 connecting the flat plate 151 and the inner frame hinge 170, the glass frame hinge 185 and the thin plate 99 connecting the enclosing plate 153 and the mechanical plate hinges 190 and 195. ).

When the glass frame 22 is closed, the keyingko organic group 10 having the above connecting members HB, UB, and SB is formed by the ① key unit 29, the sheet metal 110, and the sheet metal 115. (22) Each of the rails 30, 49, 51 and the hinges 170, 190, 195 are electrically connected by abutting the flat plates 150, 151 and the surrounding plate 153 on the back surface. Therefore, by closing the glass frame 22, the static electricity charged on each of the rails 30, 49, and 51 is quickly transferred to the large plate area through the key unit 29, the sheet metal 110, and the sheet metal 115. Guided and dispersed in the plate region. Therefore, the static electricity on each rail 30, 49, 51 can be efficiently discharged out of each rail 30, 49, 51. In addition, the connection paths from the plate area to the hinges 170, 190, and 195 are common components (the hinge 180 for the glass frame, the hinge 185 for the glass frame) between the connecting members HB, UB, and SB. Since it is formed of the thin plate 99, it is possible to reduce the number of parts that need to be mounted in order to discharge static electricity.

In addition, in the pachinko organic device 10 of the present embodiment, the flat plate 150 and the flat plate 151 are provided on the back of the glass frame 22 in a state where the flat plate 150 is separated from each other, so that the metal on the back of the glass frame 22 Install the plate area of the discontinuously. Therefore, the static electricity guided from the rails 30, 49, and 51 to the metal plate area can be effectively avoided to form a loop in the plate area, thereby preventing static electricity in the plate area from the hinge 180 for the glass frame. It is possible to reliably discharge to the outside of the pachinko organic device 10 through the inner frame hinge 170, or from the glass frame hinge 185, the thin plate 99 through the hinges for the mechanical plate (190, 195).

As mentioned above, although the Example of this invention was described, this invention is not limited to this Example, It can implement in various aspects within the range which does not deviate from the summary of invention.

For example, in the above embodiment, when the glass frame 22 is closed, the flat plates 150 and 151 and the surrounding plate 153 on the back of the glass frame 22 are ① key unit 29 and sheet metal 110. ), But when the glass frame 22 is closed, each plate 150, 151, 153 is not only ① key unit 29, sheet metal 110, sheet metal 115, It is good also as a structure which contacts the edge part of each rail 30, 49, 51. In this way, the contact area between each rail 30, 49, 51, and a metal part becomes wider, and the efficiency of removing static electricity on a rail out of a rail can be improved further. In particular, the ends of the rails 30, 49, 51 generally have a pointed shape and have a property of being easy to charge, so that the rails 30, 49, 51 are brought into contact with the plates 150, 151, 153 by contact with each plate. The occurrence of local high voltage in the phase can be sufficiently prevented.

In addition, in the above embodiment, a metal plate region was formed on the rear surface of the glass frame 22 by arranging three plates, namely, the flat plates 150 and 151 and the enveloping plate 153, but the rear surface of the glass frame 22 Even if the number of plates is 2 or less or 4 or more, there is no problem.

In the above embodiment, the connecting members HB, UB, and SB are composed of a plurality of components, but the connecting members HB, UB, and SB may be composed of one component.

In addition, in the said Example, although connection member HB, UB, SB was made into the metal member, even if all or one part of this connection member HB, UB, SB is formed from electrically conductive materials other than metal, it does not interfere. For example, when carbon, a conductive resin, or the like is used as the material for forming the connecting members HB, UB, and SB, the same effects as in the above embodiments can be achieved.

The pachinko organic group 10 according to the embodiment of the present invention replenishes the organic sphere B to the upper plate 24 by bead rental or the organic sphere B discharged to the upper plate 24 to the lower plate 25. Although it is comprised so that it can take out of a machine, organic beads are enclosed in a machine, and this invention can be applied also to the other organic group which distribute | circulates and performs this bead. Further, in the pachinko organic group 10 of the above embodiment, the organic sphere B is discharged as a product bead as a predetermined number of organic spheres B enters the granular sphere such as the ordinary granular sphere 43. Instead of the same product beads, the present invention can be applied to other organic groups that discharge a predetermined number of metals, premiums and the like. As such an organic group, an arrangement ball, a pachinko toy, etc. can be considered.

According to the organic group of the present invention, since the rail and the hinge leading the organic sphere to the organic region are connected to the conductive connecting member which forms the path shape from the rail to the hinge as it is, the path shape from the rail to the hinge is connected to the organic group. It does not change due to an impact from the outside. Therefore, the connection state between the rail and the hinge can be reliably maintained, and the static electricity charged on the rail can be reliably guided to the hinge and removed outside the organic group.

Claims (7)

An organic group which guides the emitted organic spheres to an organic region by a predetermined rail and executes predetermined organic, It is formed using a conductive material, and includes a hinge for supporting a part of the organic group so as to be openable and close, and a conductive connecting member for connecting the rail and the hinge. Organic group characterized in that the connecting member is composed of a member to form a path shape from the rail to the hinge as it is The said organic apparatus is equipped with the openable door which is closed at the time of execution of the said organic apparatus, and the closed connection structure which electrically connects the said rail and the said hinge via the said connection member when the door is closed. An organic group characterized by the above. 3. The contacting device according to claim 2, wherein the organic group is, as the connection member, a first connection member that is connected to the rail while the door is opened, and abutment connection that abuts the first connection member upon closing of the door. With a member, At least one of the contact connecting member and the first connecting member has an elastic force with respect to the other member, An organic group characterized in that at least one of the contact connecting member and the first connecting member deforms in response to the elastic force when the contact connecting member contacts the first connecting member due to the closing of the door. . 3. The door of claim 2, wherein the door is a front door having an opening that allows the organic area to be visible when the door is closed, The organic device includes, as the connecting member, a first connecting member that is connected to the rail while the front door is opened, a plate body provided in a predetermined area on a rear surface of the front door, the plate body and the hinge. A second connecting member to be connected, And the closed connection structure is a structure in which the plate and the hinge are electrically connected to each other by contacting at least the first connection member when the front door is closed. The organic device according to claim 4, wherein the closed connection structure is a structure in which the plate body abuts at least part of the first connection member and the rail when the front door is closed. The organic group according to claim 4, wherein the plate body is discontinuously provided in an outer circumferential region of the opening. 7. The organic device according to any one of claims 1 to 6, wherein the organic group includes a plurality of rail members as the predetermined rails, and at least two rail members of the rail members are electrically connected between the rail members. The organic group installed in this possible state.