KR20020082735A - A game machine - Google Patents

Abstract

PURPOSE: A game machine is provided, which is protected from static electricity, and at the same time achieves safe handling of the game machines and secures fine appearance or cleanliness of the game machines. CONSTITUTION: A pachinko game machine(10) is provided with a circulation route(R1) and a circulation route(R2) for circulation routes of game balls(B), wherein the circulation route(R1) comprises a ball tank, a tank rail, a case rail and a prize ball/lent ball putting out unit, and the circulation route(R2) comprises a bell pail base, a tray part of an upper tray and a tray part of a lower tray. In the periphery of the circulation routes(R1,R2), a cover for each substrate, a protective cover, a bell pail cover, a mechanism plate, an inner frame, a glass frame, a projecting part of the upper plate, an overflow ball guiding unit(130), a projecting part of the lower plate, shooting handle, and a foul ball guiding unit(131) are arranged. Each component comprising the circulation routes(R1,R2) are formed of a conductive polymer material, and each component arranged in the periphery of the circulation routes(R1,R2) is formed of an antistatic material.

Description

Organic machine {A game machine}

TECHNICAL FIELD This invention relates to an organic group. Specifically, It is related with the organic group which performs organic by distributing organic beads.

Conventionally, in order to prevent the influence of the static electricity charged to the organic beads on the organic group, various techniques for forming a portion of the organic group with a conductive material have been proposed. For example, there is a method of forming a saucer from a conductive material such as carbon and removing static electricity charged on the beads on the dish out of the organic group from the dish (Japanese Patent Application Laid-Open No. 2-136684).

Here, in order to more fully prevent the influence of static electricity on the organic group, it is considered to form not only the saucer but also the bead flow path other than the dish and all parts around the flow path with the conductive material. This is because the static electricity is not easily accumulated in the bead flow path or in all parts around the flow path, thereby effectively preventing the occurrence of local high voltage at such a part.

However, when all the portions around the distribution path are formed of a conductive material, electricity can also flow to the portions where people around the distribution path frequently come into contact with each other, which is not preferable for the handling of organic groups.

In view of the light weight, when a conductive polymer material (hereinafter referred to as a conductive synthetic polymer material) having conductivity such as conductive plastic is used as the conductive material, the conductive synthetic polymer material mainly has a black property. There is a problem that aesthetics is impaired by forming all the portions around the distribution path with a conductive synthetic polymer material.

This problem can be solved in an organic group by forming an area in which a person easily contacts or an area that emphasizes aesthetics with an insulating material and forming another part with a conductive material. However, in the case where the insulating material is used in this way, the charging of the static electricity on the surface of the portion formed of the insulating material is allowed, and the influence of the static organic group on the static electricity cannot be completely prevented. In addition, since static electricity attracts dust in the air, contaminants tend to adhere to the surface of the portion formed of the insulating material, which may cause another problem that the cleanliness of the surface of the organic group is impaired.

Accordingly, the present invention has the following configuration in order to solve the above problems and to realize the protection of organic groups from static electricity while ensuring the safe handling of organic groups and the aesthetics or cleanliness of organic groups.

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.

4 is an explanatory view showing an embodiment in which a metal plate, a case rail, a product bead / loan bead discharge unit, and a bead base are mounted on a mechanical plate.

FIG. 5 is an explanatory diagram showing the molding materials and properties thereof for each part, each part constituting the distribution path, and a part or part disposed around the distribution path.

It is explanatory drawing which shows the external appearance of an upper plate.

It is explanatory drawing which shows the external appearance of a lower dish.

Fig. 8 is a graph showing the potential difference occurring in the organic organic group before and after discharge of product beads or rental beads.

9 is an explanatory view showing a selectable combination of a part or a part formed of a conductive plastic and a part formed of an antistatic material.

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

10: organic pachinko 12: outer frame

13: hinge for inner frame 15: pre-fade card unit

16: guide unit 17: card unit power cord

20: inner frame 21: hinge for the glass frame

22: glass frame 23: indicator lamp

24: upper plate 25: lower plate

26: launch operation unit 26a: launch handle

30 launch rail 31 launch mechanism unit

40: organic panel 41: special pattern display device

42: normal pattern display device 43: ordinary mouth

44: starting mouth 45: normal pattern display operation gate

46: charging stand 49: inner rail

51: outer rail 54: indicator lamp

56 liquid crystal display 57a lamp control board

58a: sound control board 59: plates for lamps and sound boards

70: instrument plate 71: hinge for the instrument plate

72: bead tank 73: tank rail

74: case rail 75: product beads / rental beads discharge unit

75c: product bead outlet 75d: rental bead outlet

76a, 76b: Protective cover 77: Bead base

78: bead barrel cover 79: hinge for instrument plate

80: power supply and external terminal unit 80a: power switch

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

130: overflow bead guide unit 131: foul bead guide unit

B: organic spheres R1, R2, R3, R4: distribution channel

The organic group according to the first embodiment of the present invention is an organic group which conducts organic matter by circulating organic beads, and includes a control board for controlling the operation relating to the organic matter and a path forming part that forms a distribution path of the beads. And a peripheral part that is a part located around the path forming part, wherein at least one of the path forming parts is formed by using a conductive polymer material, and at least one of the peripheral parts is formed. Formed using an antistatic material, the main point is.

Here, the conductive polymer material means that, among the conductive polymer materials having conductivity, the whole composition has conductivity and the electrical resistance per unit volume of the composition (hereinafter referred to as volume resistivity) is 10 ⁶ Ω or less. The conductive polymer material is generally formed by blending fine particles having conductivity in a matrix (matrix) as a filler (filler). Examples of the kind of the conductive polymer material include conductive plastics in which synthetic resins are used as the base material, and metals such as carbon black, silver, and copper as fillers, and conductive rubbers having synthetic rubbers as base materials. In this conductive polymer material, electric charges are transferred within the composition by the charge being moved by direct contact between the fillers in the composition.

On the other hand, an antistatic material means that only the surface to which the antistatic treatment was carried out in a composition has electroconductivity, and electric resistance per unit area on this surface (henceforth surface resistivity) exceeds 10 <^6> ohm. The antistatic material is generally formed by performing an antistatic treatment (treating the surface resistivity of a certain material) on the surface of an insulator. Examples of the antistatic treatment include a treatment of applying an antistatic agent to the surface of an insulator, a kneading treatment of mixing an antistatic agent in a molding material of the insulator and forming a conductive layer on the surface thereof. As an example of such an insulator or an antistatic agent, various surfactants (antistatic agent), such as synthetic polymer materials (insulation material), such as synthetic resin, and carotene, can be considered. In this antistatic material, when static electricity is generated on the surface of the insulator, the surface on which the antistatic treatment is applied absorbs moisture in the air and discharges static electricity generated on the surface of the insulator to the air, thereby preventing charging on the surface of the insulator.

According to the organic group of the first embodiment of the present invention, the static electricity generated on the path forming part by friction with organic beads or the like is dispersed into the path forming part formed by using the conductive polymer material. Therefore, the probability of generating a local high voltage on the path forming part is lowered, and it is possible to prevent static electricity discharged from the path forming part from acting on the controller board as noise.

On the other hand, since the parts (hereinafter referred to as peripheral parts) located around the path forming parts are formed using an antistatic material, static electricity generated on the path forming parts or in the path forming parts is less likely to reach the peripheral parts. Even if the static electricity is charged, its surface remains uncharged. Therefore, when the peripheral parts are in contact with each other, the discomfort caused by the discharge from the peripheral parts surface is not felt. In addition, since the antistatic material has a wider selection range of material colors as compared with the conductive polymer material, the aesthetics of the entire organic group can be enhanced by appropriately coloring peripheral components. In addition, dust is not adsorbed by the static electricity on the surface of the peripheral parts, and the surface of the peripheral parts is not contaminated.

As described above, according to the organic group of the first embodiment of the present invention, the organic group can be protected from static electricity without sacrificing convenience or aesthetics of the organic group.

As the path forming part in the organic group of the first embodiment, a bead tank for temporarily storing beads supplied from an island (where a bead supply device is located) of an organic field, an organic sphere stored in this bead tank ( A discharge device for discharging the ball when the predetermined conditions are provided, a first passage-forming part for forming a bead passage from the bead tank to the discharge device, and collecting beads discharged by the discharge device from the discharge device. Second passage forming parts forming a bead passage to the plate body, rail parts for guiding the beads collected in the plate body to the organic region, and the like can be considered. In addition, the peripheral parts include a plate for collecting beads discharged by the discharge device, a cover for the discharge device attached to the discharge device, a cover for the first passage forming part mounted to the first passage forming part, and a controller plate. A cover for a substrate, a control plate, a discharge device, a mechanical plate that is a plate body to which at least one of the first passage forming part and the second passage forming part is attached, a glass frame covering the organic region, and the glass frame The framework may be considered.

It is also preferable to arrange the path forming part and the peripheral part in contact with each other. In this way, static electricity generated on the path forming part is actively induced to the path forming part having a lower resistivity, and is not induced to the peripheral part side. Therefore, the static electricity can be reliably dispersed in the path forming part, so that the charging of the peripheral parts can be effectively prevented.

The organic group according to the second embodiment of the present invention is an organic group that conducts organic matter by distributing organic beads, and includes a distribution path forming part that is a part that forms a distribution path of the beads. The contact portion in contact with the beads in the distribution of the beads is formed of a conductive polymer material, at least a portion of the non-contact portion that does not contact with the beads in the distribution of the beads is made of an antistatic material.

According to the organic group of the second embodiment of the present invention, the static electricity generated at the contact portion in contact with the beads in the distribution process of the beads in the distribution path forming part by friction with the organic beads is formed using a conductive polymer material. It is dispersed into the contact portion of the flow path forming part. Therefore, the probability of generating a local high voltage at the contact portion of the flow path forming part is low, and it is possible to prevent static electricity discharged from the flow path forming part from acting as noise on the control board.

On the other hand, at least some of the non-contact parts which do not contact the beads in the distribution path of the distribution path forming part are formed by using an antistatic material, so that the distribution path formation on or in contact with the distribution path forming part is formed. The static electricity in the part becomes less likely to reach the non-contact portion, and even if the non-contact portion has static electricity, its surface remains uncharged. Therefore, when it comes in contact with the non-contact portion of the flow path forming part, the discomfort caused by the discharge from the surface of the non-contact portion is not felt. In addition, since the antistatic material has a wider selection range of material colors than the conductive polymer material, it is possible to appropriately color the non-contact portion of the flow path forming part to enhance the aesthetics of the entire organic group. In addition, dust or the like is adsorbed by the static electricity on the surface of the non-contact portion of the flow path forming part, and the surface of the non-contact portion is not contaminated.

Thus, according to the organic group of 2nd Embodiment of this invention, an organic group can be protected from static electricity, without sacrificing the convenience of using a distribution path forming part, or the aesthetics of the whole distribution path forming part.

The flow path forming part in the organic phase of the second embodiment includes a bead tank for temporarily storing beads supplied from an island of an organic field, and a discharge discharged when the organic spheres stored in the bead tank have a predetermined condition. Device, a first passage forming part for forming a bead passage from a bead tank to a discharge device, a plate body for collecting beads discharged by the discharge device, and a second passage forming part for forming a bead passage from a discharge device to a plate body Etc. may be considered.

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 based on the pachinko organic group 10 which is an embodiment of the present invention. In FIG. 1, the state in which the pachinko organic group 10 was seen from the back surface and the front surface is shown. In addition, in the following description, the surface when viewed from the front direction of the pachinko organic group 10 is called "a surface", and the surface when viewed from the backside direction of the pachinko organic group 10 is called "a back surface."

In Fig. 1, the flow path of the organic sphere B in the pachinko organic group 10 is indicated by a black thick arrow, and the place where the organic sphere B can be stored in this flow path is indicated by a black triangle. It is shown. Also, original characters 1 to 3 shown in FIG. 1 indicate a connection relationship between the flow paths of the organic spheres B between the front and the back of the pachinko organic group 10, and 1 and 2 in FIG. 1 (B) of FIG. 1 (B), and ③ of FIG. 1 (B) indicate that it is connected to ③ of FIG. 1 (A). In addition, in the following description regarding FIG. 1, the part name and the part name are represented by the code | symbol by two digits, The part or part to which these code | symbols are attached is shown in more detail in FIGS. have.

On the back side of the pachinko organic machine 10, as shown in FIG. 1 (A), a mechanism plate 70 is provided in the inner frame 20 attached to the outer frame 12. This instrument board 70 is attached in the state overlapped with the back surface of the organic panel 40. The bead tank 72 is attached to the upper position of the back surface of the mechanism plate 70, and below the bead tank 72, a tank rail 73, a case rail 74, a product bead / loan bead discharge unit ( 75), the bead base 77 is mounted in this order. The guide plate 70b and the branch path 70c which penetrate the front and back of the instrument board 70 are formed in the instrument board 70 in the downward position of the bead base 77. An overflow bead guide unit 130 is attached to the back of the inner frame 20 located below the branch path 70c. Moreover, in the downward position of the surface of the instrument board 70, the groove | channel is formed in the surface of the instrument board 70, and the bead discharge passage 70d is formed.

On the other hand, in the front surface of the pachinko organic group 10, as shown in FIG. 1 (B), the glass frame 22 and the upper plate which cover the organic region YE on the surface of the organic panel 40 so that the eye can see it visually ( 24 and the lower plate 25 are mounted with respect to the inner frame 20. In addition, the firing rail 30 and the fouling bead guide unit 131 are attached to the inner frame 20 of the range covered with the upper dish 24, and the organic panel 40 of the range covered with the glass frame 22 is provided. Various granular devices, such as the outer rail 51, the inner rail 49, the ordinary standing mouth 43, and the large mouth opening 46, are mounted, and the outward opening is provided below the large mouth opening 46. 53) is formed.

As shown by the black thick arrow in FIG. 1, the organic sphere B supplied from the bead supply device of the organic field is a tank rail 73 downstream from the bead tank 72 mounted on the back of the instrument plate 70. Then, flows to the case rail 74, the product beads / rental beads discharge unit 75 in order. The organic spheres B in the product beads / rental beads discharge unit 75 are stopped by a stopper (not shown) except at the time of loaning and standing. The distribution path of the organic sphere B from this bead tank 72 to the stopper in the product bead / loan bead discharge unit 75 is hereinafter referred to as distribution path R1. As shown in FIG. 1, a cover for a substrate and a product bead / lathered bead discharge unit that cover various control plates for controlling organic operation, in addition to the mechanical plate 70 and the inner frame 20, are shown around the flow path R1. Protective covers 76a and 76b covering a part of 75, a bead cover 78 covering a bead base 77, an overflow bead guide unit 130 and the like are disposed. In addition, the organic sphere B is blocked by the stopper and stopped, so that the organic sphere B is disposed in the bead tank 72, the tank rail 73, the case rail 74, and the product bead / loan bead discharge unit 75. Is temporarily stored.

At the time of loaning and winning a prize, the stopper in the product bead / rental bead discharge unit 75 is opened, whereby the organic sphere B from the product bead / rental bead discharge unit 75 is released from the bead base 77 Flows into). As shown in FIG. 1, the organic sphere B which flowed in into the bead base 77 flows into the dish part of the upper dish 24 through the guide path 70b (refer to ① of FIG. 1). Among the organic spheres B introduced into the upper dish 24, the organic spheres B nearest to the firing rails 30 are disposed on the firing rails 30 in a strikeable manner. In addition, the organic sphere B discharged beyond the capacity of the plate portion of the upper plate 24 flows from the branch path 70c to the plate portion of the lower plate 25 via the overflow bead guide unit 130 (FIG. See ② of 1). The distribution path of the organic sphere B from the stopper in the product beads / loan ball discharge unit 75 to the plate portion of the launch rail 30 to the lower plate 25 is hereinafter referred to as distribution path R2. Around this flow path R2, as shown in FIG. 1, the mechanism board 70 and the inner frame 20, the cover for each board | substrate, the protective covers 76a and 76b, the bead cover 78, and the overflow In addition to the bead guide unit 130, a glass frame 22, an extension of the upper dish 24, an extension of the lower dish 25, a launch handle 26a, and the like are disposed. In addition, by discharging the organic sphere B, the plate portion of the upper plate 24 and the plate portion of the lower plate 25 are in a state where the oil mechanism B is stored.

The organic sphere B is guided to the launch rail 30, the outer rail 51, and the inner rail 49 by the operation of the launch handle 26a and guided to the organic region YE. Thereafter, the organic sphere B flows down between the surface of the organic plate 40 and the glass frame 22 and enters one of the ordinary granular sphere 43, the large granular sphere 46, and the outlet 53. The distribution path of the organic sphere B from the launch rail 30 to any one of the ordinary winning prize mouth 43, the large mouth prize mouth 46, and the outlet mouth 53 is hereinafter referred to as the distribution path R3. As shown in FIG. 1, in addition to the glass frame 22, the inner frame 20, the fouling bead guide unit 131, and the organic panel 40, the special pattern display device is described later around the flow path R3. Various role objects, such as 41 and the windmill 47, are arrange | positioned. In addition, the organic sphere B returned from the outer rail 51 and the inner rail 49 to the firing rail 30 without reaching the organic region YE is disposed between the outer rail 51 and the firing rail 30. The fouling bead guide unit 131 enters the lower dish 25 from the void of the air.

The organic sphere (B) entering the ordinary standing mouth (43), the standing mouth (46), the outlet (53) flows into the bead discharge passage (70d) (see ③ in Fig. 1), and then, the pachinko organic group It is discharged to the outside of the (10). The distribution path of the organic sphere B from the ordinary standing mouth 43, the large mouth mouth 46, and the outlet 53 to the outside of the pachinko organic group 10 is hereinafter referred to as distribution path R4. As shown in FIG. 1, in addition to the inner frame 20, the mechanism plate 70, and the organic panel 40, the cover for the substrate, the protective covers 76a and 76b, and the bead barrel are surrounded by the flow path R4. The cover 78, the overflow bead guide unit 130, and the like are disposed.

In the present embodiment, the parts and parts constituting the distribution paths R1 and R2 (in FIG. 1, the bead tank 72, the tank rail 73, the case rail 74, the product beads / loan ball discharge unit 75). ), Bead base 77, plate portion of upper plate 24, plate portion of lower plate 25) are formed using a conductive polymer material and are arranged around the circulation paths R1 and R2. Parts and parts (in FIG. 1), the instrument plate 70, the inner frame 20, the cover for each substrate, the protective covers 76a and 76b, the bead barrel cover 78, the glass frame 22, and the upper plate ( An extension of 24, an extension of the lower dish 25, a launch handle 26a, a foul bead guide unit 131, and an overflow bead guide unit 130 are formed using an antistatic material. The path forming parts referred to in the claims correspond to the respective parts constituting the distribution paths R1 and R2 in the present embodiment, and the peripheral parts referred to in the claims refer to the distribution paths R1 and R2 in the present embodiment. It corresponds to each said component arrange | positioned at the periphery. As described above, the present invention forms the parts constituting the distribution paths R1 and R2 by using a conductive polymer material, and forms the parts and portions disposed around the distribution paths R1 and R2 with an antistatic material, thereby making it difficult to obtain the oil. It is characterized by increasing the convenience and aesthetics of the use of the device 10 and at the same time effectively protecting the organic organic group 10 from the static electricity charged in the organic sphere (B).

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 dish 24 by inserting a prefade card in which information on the number of rental beads is recorded. A guide unit 16 having a code 17 (see FIG. 3), a frequency display section 16a, a loan button 16b, a loan button lamp and a return button 16c is provided. The configuration in which beads are borrowed by the prepaid card unit 15 will be described later.

The pachinko organic machine 10 is provided with the inner frame 20 which can be opened and closed to the wooden outer frame 12 via the hinge 13 for inner frame. 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 fitted, and the organic plate 40 is covered with the glass surface of the glass frame 22. The glass frame 22 is provided with the display lamp 23 which flashes or lights according to organic conditions around a glass surface. The glass frame 22 is provided to be opened and closed through the glass frame hinge 21 mounted on the inner side of one side (left side in FIG. 2) of the inner frame 20.

Below the glass frame 22, the upper plate 24 which stores the organic sphere B as a rental beads and a 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 opened and closed via an upper plate hinge (not shown).

Rotating operation of the lower dish 25 and the firing handle 26a on the inner frame 20 surface lower than the upper dish 24 to store the organic spheres B discharged in excess of the capacity of the upper dish 24. And 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 shot rail 30 for guiding the organic spheres released by the rotation operation of the shot handle 26a to the outer rail 51. Is equipped. Further, under the gap formed between the launch rail 30 and the outer rail 51, a foul bead guide unit 131 is provided, in which a passage to the lower dish 25 is formed.

On the other hand, as shown in FIG. 3, on the back side of the inner frame 20, the launch mechanism unit 31 which consists of a launch motor, a batting rod, etc. in the position corresponding to the mounting position of the upper pan 24 and the launch operation unit 26. ) Is mounted. Moreover, the metal support member 33 for supporting the mechanism plate 70 mentioned later is attached to the side surface of one side (right side in FIG. 3) of the inner frame 20 with a screw. Moreover, the overflow bead guide unit 130 in which the path | route to the lower side dish 25 was formed in the back of the inner side frame 20 located below the branch path 70c formed in the surface of the instrument board 70 is attached. .

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. , Foul bead stopper 50, return rubber 52, barrier nails, windmills 47 and lamp windmills 48, several ordinary granular openings 43 and one entry of organic spheres flowing from the organic zone The normal pattern display device 42 and the organic sphere B, which operate as the starting mouth 44 and the organic sphere B pass through the normal pattern display operating gate 45, are the starting mouth 44. ), The special pattern display device 41 which starts pattern change as it enters, and the entrance mouth 46 which opens when a specific pattern is displayed by this special pattern display device 41, and each prize mouth 43, 44, 46 Various components, such as the display lamp 54 which light up or flash in various forms according to the state of granularity of the present invention, are mounted. Further, an outlet port 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. As shown in FIG. By each of these parts, an organic region is formed on the organic panel 40 over the glass frame 22.

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

Next, the mechanical plate 70 will be described. As shown in FIG. 3, metal instrument plate hinges 71 and 79 are attached to two places on the side surface of the instrument plate 70 with screws. By setting the mechanism plate hinges 71 and 79 to the supporting member 33 attached to the inner frame 20, the instrument plate 70 is mounted to be opened and detached while the organic plate 40 is fitted.

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

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 a tank connected in succession from the bead tank 72 to the product bead / loan bead discharge unit 75. The rail 73 and the case rail 74 are attached. 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, and these convex parts 72a and 72b are the upper end of the tank rail 73, and I'm in contact. The end of the tank rail 73 is in contact with the front end of the case rail 74.

The end of the case rail 74 is connected in series with the product beads / rental beads discharge unit 75 with the protective covers 76a and 76b and the bead base 77 with the bead cover 78 attached thereto. . As shown in FIG. 3, these case rails 74, the product bead / loan bead discharge unit 75, and the bead base 77 are formed on a rectangular metal plate 90 attached to the rear surface of the mechanical plate 70. 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 which attaches such a metal plate 90, the case rail 74, the goods beads / ligation ball discharge unit 75, and the bead base 77 to the instrument board 70 is demonstrated later.

The power supply / external terminal unit 80 is mounted in the region above the case rail 74 in the mechanical plate 70. This power supply / external terminal unit 80 is 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 a power supply for turning on / off the power supply by operation. The external terminal board 80c for outputting the switch 80a, the number of winnings due to the display of the specific pattern generated on the pachinko organic device 10, the information on the bead rental or the bead disconnection, product beads, etc. It consists of the external terminal board | substrate 80d for outputting into a frame, and each of these components is covered by the cover 80w. The power of AC 24 volts introduced through the organic group power cord 80b is sent to a power supply unit 81 described later via an electrical wiring.

Below the opening 70a, a cover covering the power supply unit 81, the launch control board 82a, and the launch control board 82a, which has a power supply board 81a and a cover 81w covering the power supply board 81a. A launch control unit 82 having a 82w is attached to the back surface of the instrument plate 70 via a metal plate 83 for power supply and emission control substrate. Further, the main plate plate 85 made of metal is attached to the back of the mechanical plate 70 so as to cover a part of the upper surface of the cover 81w and the cover 82w with a screw. The main control unit 84 which has the main board | substrate 84a and the cover 84w which covers this main board | substrate 84a is attached. 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 barrel cover 78 and a part of the upper surface of the power supply unit 81 with a screw. On the board plate 87, an emission control unit 86 having an emission control substrate 86a and a cover 86w covering the emission control substrate 86a is mounted.

The power supply unit 81 connected to the external terminal unit 80 through electrical wiring converts the AC power sent from the organic power cord 80b into direct current, and converts the converted direct current power through the supply wire to the liquid crystal display 56. ), The lamp control board 57a, the voice control board 58a, the launch control unit 82, the main control unit 84, and the discharge control unit 86, and the like. The launch control unit 82 controls the firing operation of the launch 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. Control the operation accompanying the discharge control unit 86, 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 of them is a guideway 70b which is a passage for guiding the organic sphere B discharged as product beads or rental beads to the upper dish 24. In addition, the branching path 70c which is a passage for inducing the organic bulb B discharged beyond the capacity of the upper dish 24 to the lower dish 25 and the organic sphere B entering the outlet 53. A bead discharge passage 70d, which is a passage for discharging the lamp and the like, is also provided. These passages are formed integrally with the instrument plate 70 by forming through holes penetrating the front and rear of the instrument plate 70 or by forming grooves in the surface of the instrument plate 70.

4 illustrates a shape in which the metal plate 90, the case rail 74, the product bead / loan bead discharge unit 75, and the bead barrel base 77 are mounted to the instrument plate 70. As shown in FIG. 4, the metal plate in which the bending part 90a, 90b was formed in the side end part in the position slightly upward (z direction of FIG. 4) rather than the guide path 70b formed through the front and back of the mechanism board 70 is shown. 90 is attached. The bent portions 90a and 90b are attached to the hinge plates 71 and 79 with screws, respectively. As a result, the metal plate 90 is in a state capable of conducting with the mechanical plate hinges 71 and 79 through the bent portions 90a and 90b. Of course, even if the metal plate 90 and the mechanism plate hinges 71 and 79 are previously formed integrally, there is no problem.

The bead base 77 is attached to the downward position (position biased in the -z direction of FIG. 4) on the metal plate 90. As shown in FIG. In this bead base 77, a passage 77a of the organic sphere B discharged as product beads or rental beads is formed, and a bell 77c is attached to the center of the passage 77a.

Moreover, when the bead base 77 is mounted, it is for discharging the organic sphere B in the passage 77a 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 direction of the lower plate 25 are formed. A partition plate 77e is placed upright between these first outlet 77b and the second outlet 77f, and a guide plate 77d is inclined downward above this 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 mounted above the passage 77a of the bead base 77 (z direction in FIG. 4). The bead base 77 below the mounting position of the merchandise bead / loan bead discharge unit 75 (-z direction in FIG. 4) is covered by the bead cover 78. At one of the top surfaces of the bead barrel cover 78, a user hole (bottomed hole) 78a into which a nut for mounting the main board plate 85 and the discharge control board plate 87 is fitted. Is formed.

The product bead / loan ball discharge unit 75 is provided with two stoppers (not shown) which are opened and closed by using the motors 75a and 75b as power sources. By this stopper being closed, the flow 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 side shown in Fig. 4) of the product bead / loan bead 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 discharged from the product bead discharge port 75c and the rental bead discharge port 75d is rented. A merchandise beads / lending beads sensor (not shown) which detects the number of organic spheres B as beads is embedded.

The case rail 74 of FIG. 4 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 from the tank rail 73 enters, and the organic opening which entered from this entrance opening 74a ( Branch wall 74b for dividing B) into the product bead passage 74c and the rental bead passage 74d, and the organic bead passage port 74e which is the exit of the branched organic sphere B. ) And an organic sphere through hole 74f for a rental bead is formed.

Bead tank 72, tank rail 73, case rail 74, commodity beads / loan bead discharge unit 75 described above, bead cylinder base 77, bead cylinder cover 78, guide path 70b And a passage through which the organic sphere B is discharged to the upper dish 24 or the lower dish 25 by the branch path 70c and the overflow bead guide unit 130 as product beads or rental beads (shown in FIG. 1). Distribution path R1 and distribution path R2) are formed.

That is, in the pachinko organic group 10, when there is no granularity or beads rental, the flow of the organic sphere B is stopped by closing the two stoppers in the product beads / rental beads discharge unit 75, whereby The organic spheres B are stored in the bead tank 72, the tank rail 73, the case rail 74, and the product beads / loan beads discharge unit 75. 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 ( The opening of the stopper on the 75c) side is instructed. As a result, the organic spheres B that have stayed in the product beads passage 74c of the case rail 74 are from the product beads / carousel discharge unit 75 from the organic beads passage opening 74e for product beads. It enters the passage 77a of the bead base 77 through the outlet 75c. The organic sphere B which entered this passage 77a collides with the bell 77c, rings the bell 77c, is guided to the guide plate 77d, and flows down toward the first outlet 77b to flow to the first outlet 77b. 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 path 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. Going back When the organic sphere B stays to the height exceeding the partition plate 77e, the organic sphere B flows over the partition plate 77e to the second outlet 77f side and branches off from the second outlet 77f. 70c). Thereby, the organic sphere B as a commodity beads is discharged | emitted to the lower dish 25 of the front side of the pachinko organic group 10 through the branch path 70c thru | or the overflow bead guide unit 130. FIG.

In addition, when the loan button 16b of the guide unit 16 is pressed after the prefade 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 lease beads is discharged to the lease bead outlet ( The opening of the stopper on the 75d) side is instructed. As a result, the organic sphere B which stayed in the rental bead passage 74d of the case rail 74 is leased bead in the product beads / rental bead discharge unit 75 from the rental bead organic sphere passage opening 74f. It enters the passage 77a of the bead base 77 through the discharge port 75d. The organic sphere B entering this passage 77a collides with the bell 77c and flows down toward the first outlet 77b while ringing the bell 77c to guide the path 70b from the first outlet 77b. Is discharged. 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.

In accordance with the discharge of the product beads or the rental beads, the organic beads B stayed in the case rail 74, the tank rail 73, and the bead tank 72 are sequentially in the product beads / loan beads discharge unit 75. Move towards. When it is detected that the number of stored water in the bead tank 72 is below a certain number by discharge of the merchandise bead or the rental bead, the bead of organic field is supplied according to the instruction from the external terminal board 80d for receiving the detection result. The organic sphere B is replenished to the bead tank 72 from an 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. The product bead / rental bead sensor sends a detection result to the discharge control unit 86 when a predetermined number of discharges are detected, and the discharge control unit 86 that receives the detection result is from the product bead discharge port 75c side to the rental bead discharge port. The stopper on the 75d side is instructed. 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 return to the state in which the organic sphere B was stored like granularity or before the ball loan generation.

Fig. 5 shows the molding materials and the characteristics of the parts and the parts constituting the distribution paths R1, R2, R3, and R4, and the parts and parts arranged around the distribution paths R1, R2, R3, and R4. Shown in In Fig. 5, in the "Function" column for each part, the characters "ro", "low" and "Chou" are indicated by a rectangle along with distribution path names such as "(R1)". It is surrounded and displayed. "Ro" indicates that the part is a part constituting any one of the distribution paths R1 to R4, and the following distribution path name indicates which distribution path among the distribution paths R1 to R4. have. In addition, "low" has shown that the organic sphere B is a component which can be stored. "Note" indicates that the part is a part disposed around one of the distribution paths R1 to R4, and the following distribution path name indicates that the part is disposed around a distribution path among the distribution paths R1 to R4. It shows whether or not.

As shown in FIG. 5, the bead tank 72, the tank rail 73, the case rail 74, and the product bead / loan bead discharge unit 75, which are components forming the flow path R1, are made of ABS (acryl). It is formed of a conductive plastic made of nitrile butadiene styrene) or PC (polycarbonate). On the other hand, the instrument plate 70, the inner frame 20, which are parts arranged around the distribution path R1, the covers 57w, 58w, 80w, 81w, 82w, 84w, 86w for each substrate, and the protective cover 76a, 76b), the bead cover 78 and the overflow bead guide unit 130 are formed of an antistatic material made of ABS. In this embodiment, those having a volume resistivity of 10 ⁶ Ω or less are classified as conductive plastics, and those having a surface resistivity of 10 ⁶ Ω or more as antistatic materials. Conductive plastic (10 ⁰ Ω) having the smallest volume resistivity is used for the bead tank 72 and the tank rail 73 among the components constituting the distribution path R1, and the product beads / loan beads discharge unit 75, Conductive plastics having volume resistivities of 10 ² Ω and 10 ^3.8 Ω, respectively, are used for the case rails 74.

The volume resistivity of the bead base 77, the parts 24b of the upper plate 24, and the plate 25b of the lower plate 25, which are the parts or portions constituting the distribution path R2, is 10 ^3.8 Ω, respectively. And 10 ⁰ Ω and 10 ⁰ Ω are formed of conductive plastic made of ABS. On the other hand, the instrument plate 70 or the inner frame 20, which are parts or parts arranged around the circulation path R2, covers 57w, 58w, 80w, 81w, 82w, 84w, 86w for each substrate, and a protective cover ( 76a, 76b, bead cover 78, and overflow bead guide unit 130, glass frame 22, extension 24a of upper dish 24, extension 25a of lower dish 25 ), The launch handle 26a is formed of an antistatic material made of ABS.

The appearance of the upper plate 24 and the lower plate 25 is shown in Figs. 6 and 7, respectively. As shown in FIG. 6, the upper dish 24 is provided with the extension part 24a extended forward of the pachinko organic group 10, and the dish part 24b which is a recessed part formed in the upper surface of this extension part 24a. do. In the dish portion 24b, a guide path of the mechanical plate 70 is provided on the circumferential wall of the side (-x direction side in Fig. 6) where the frequency display portion 16a, the loan button 16b, and the return button 16c are provided. The opening part 24c which connects to 70b) is formed.

The organic sphere B from the bead base 77 and the guide path 70b is discharged into the dish portion 24b of the upper dish 24 through the opening 24c and stored in the dish portion 24b. . At this time, the organic sphere B is in contact with the bottom surface or the circumferential wall of the dish portion 24b, and is not in contact with the extension portion 24a. In this embodiment, the dish portion 24b in contact with the organic sphere B is made of conductive plastic, and the extension portion 24a not in contact with the organic sphere B is formed of an antistatic material. The range formed using the conductive plastic is shown by hatched hatching in FIG. 6. In addition, the part shown by hatched hatch in FIG. 6 is an area | region formed from a metal plate.

As shown in FIG. 7, the lower dish 25 is provided with the extension part 25a extended forward of the pachinko organic group 10, and the dish part 25b which is a recess formed in the upper surface of this extension part 25a. do. An ashtray 25f is mounted near the dish portion 25b. In the dish portion 25b, an opening 25c communicating with the overflow bead guide unit 130 on the circumferential wall of the front plate portion 25e side (the -x direction side in FIG. 7) attached to the inner frame 20 is connected. Formed.

The organic spheres B from the bead base 77, the branch furnace 70c and the overflow bead guide unit 130 are discharged into the dish portion 25b of the lower dish 25 through the opening 25c. It is stored in this dish part 25b. At this time, the organic sphere B is in contact with the bottom surface and the circumferential wall of the dish portion 25b, and is not in contact with the extension portion 25a. In the present embodiment, the plate portion 25b in contact with the organic sphere B is made of conductive plastic, and the extension portion 25a not in contact with the organic sphere B is formed of an antistatic material. In addition, the range formed using the electroconductive plastics is shown by the hatching of a dot in FIG.

Returning to FIG. 5 again, the distribution route R3 will be described. As mentioned above, the launch rail 30, the outer rail 51, and the inner rail 49 which are components which comprise the flow path R3 are formed of metal. On the other hand, the glass frame 22, the inner frame 20, and the fouling bead guide unit 131, which are parts or parts arranged around the flow path R3, are made of an antistatic material made of ABS, as shown in FIG. Formed.

As shown in Fig. 5, the bead discharge passage 70d, which is a portion constituting the flow path R4, is formed of an antistatic material made of ABS, which is the same material as the mechanical plate 70. The non-conductive plastic is not used in the bead discharge passage 70d. The bead discharge passage 70d has a small number of organic spheres B distributed at one time, and the contact frequency and organic spheres of the organic spheres B at the time of distribution. This is because the frequency of contact between (B) and the bead discharge passage 70d is small and high voltage is hardly generated in the bead discharge passage 70d. In addition, the inner frame 20, which is a component disposed around the distribution path R4, is also formed of an antistatic material made of ABS.

By forming the parts or parts constituting the distribution paths R1, R2, and R3 and the parts or parts disposed around the distribution paths R1, R2, and R3 as described above, the respective distribution paths R1, R2, and R3 are formed. The static electricity generated in is treated as follows.

First, the distribution route R1 will be described. Static electricity generated on path forming parts such as the bead tank 72, the tank rail 73, the case rail 74, and the product bead / rental ball discharge unit 75 due to friction with the organic sphere B is formed of a conductive plastic. Guided into the respective path forming parts. Here, the protective cover (76a, 76b), bead cover 78, each substrate cover (57w, 58w, 80w, 81w, 82w, 84w, 86w) disposed in the periphery of each path forming part, overflow beads Since peripheral parts such as the guide unit 130, the instrument plate 70, and the inner frame 20 are formed by using an antistatic material having a higher resistivity than the conductive plastic, the static electricity generated on the respective path forming parts may be There is no effect on the part, and the resistivity is reliably guided and dispersed into the path forming part such as the smaller bead tank 72. Even if static electricity is applied to the peripheral parts, the surface of the peripheral parts is maintained without static electricity being charged.

In addition, in the distribution path R1, as shown in FIG. 4, the product bead / loan bead discharge unit 75 formed from electroconductive plastic and the protective covers 76a and 76b formed using the antistatic material contact each other. Are placed in a state. For this reason, the static electricity generated on the product bead / loan bead discharge unit 75 is actively induced to the product bead / loan bead discharge unit 75 with a lower resistivity, and hardly induced to the cover 76a, 76b side.

In this way, the static electricity dispersed in the path forming parts such as the bead tank 72 is discharged in the bead tank 72 through the convex portions 72a and 72b and the tank rail 73, and in the tank rail 73 and the case. The inside of the rail 74 has a large area, respectively, directly from the tank rail 73, the case rail 74, and through the bead base 77 formed of a conductive plastic. It flows out to the metal plate 90. In this way, the static electricity generated in each portion is guided to the metal plate 90 having a large area, whereby the generation of high voltage near the circulation path R1 is more completely prevented. The static electricity leaked to the metal plate 90 is discharged to the instrument plate hinges 71 and 79 through the bent portions 90a and 90b and removed out of the machine.

Next, the distribution route R2 will be described. In the flow path R2 on the back of the pachinko organic group 10, the static electricity generated on the bead base 77 by friction with the organic sphere B or the like is induced into the bead base 77 made of conductive plastic. Here, the bead cover 78, protective cover (76a, 76b) disposed around the bead base 77, cover for each substrate (57w, 58w, 80w, 81w, 82w, 84w, 86w), overflow beads Since peripheral parts such as the guide unit 130, the instrument plate 70, and the inner frame 20 are formed using an antistatic material having a higher resistivity than the conductive plastic, the static electricity generated on the bead base 77 Regardless of the peripheral parts, the resistivity is reliably guided and dispersed into the smaller barrel base 77. Even if static electricity is applied to the peripheral parts, the surface of the peripheral parts is maintained without static electricity being charged.

Further, in the distribution path R2 on the back of the pachinko organic group 10, as shown in Fig. 4, the bead base 77 formed of the conductive plastic and the bead cover 78 formed using the antistatic material are mutually different. It is arrange | positioned in the state to contact. For this reason, the static electricity generated on the bead base 77 is actively induced to the side of the bead base 77 having a lower resistivity, and hardly induced to the bead cover 78 side.

In this way, the static electricity reliably dispersed into the bead base 77 is discharged to the large-area metal plate 90 and then flows out through the bent portions 90a and 90b to the instrument plate hinges 71 and 79 to be removed out of the machine. .

On the other hand, in the flow path R2 of the front surface of the pachinko organic group 10, on the plate portion 24b of the upper plate 24 or the plate portion 25b of the lower plate 25 due to friction with the organic sphere B or the like. The generated static electricity is induced into the dish portions 24b to 25b formed of the conductive plastic. Here, the extension part 24a of the upper plate 24 and the extension part 25a of the lower plate 25 which are not in contact with the organic sphere B are formed using an antistatic material having a higher resistivity than the conductive plastic. Peripheral parts such as the launch handle 26a, the glass frame 22, the inner frame 20, and the like disposed around the dish portions 24b and 25b may also be made of the same antistatic material as the extension portions 24a and 25a. Since it is formed, the static electricity generated on the plate portions 24b and 25b does not reach the extension portions 24a and 25a and the peripheral parts thereof, and is reliably guided and dispersed into the plate portions 24b and 25b having a lower resistivity. . Even if static electricity is applied to each of the peripheral parts such as the extensions 24a and 25a and the launch handle 26, the surfaces of the extensions 24a and 25a and the peripheral parts remain uncharged.

Next, the distribution route R3 will be described. Static electricity generated on path forming parts such as the firing rail 30, the outer rail 51, the inner rail 49, and the like by friction with the organic sphere B is dispersed into the respective path forming parts made of metal. At this time, the peripheral parts such as the glass frame 22, the inner frame 20 and the fouling bead guide unit 131 disposed around each path forming part are formed using an antistatic material having a higher resistivity than the metal. As a result, the static electricity generated on each of the path forming parts does not reach the peripheral parts, and is reliably guided and dispersed into the path forming parts such as the launch rail 30 having a lower resistivity. Even if the static electricity is applied to the path parts such as the glass frame 22, the surface of the peripheral parts is maintained without the static electricity being charged.

As described above, the parts or parts constituting the distribution paths R1, R2, and R3 are formed of a conductive material such as conductive plastic or metal, and the parts or parts disposed around the distribution paths R1, R2, and R3 are charged. By forming the barrier member, the static electricity generated on each component constituting the distribution paths R1, R2, and R3 can be reliably dispersed in each component. As a result, a local high voltage is not generated on the parts constituting the distribution paths R1, R2, and R3 and around the parts, and the influence of noise due to static electricity is greatly reduced than before. In addition, in the pachinko organic machine 10, in addition to the use of the above-mentioned conductive material and antistatic material, a plate for power supply and emission control board 83 and a main board plate 85 in which various control boards are provided. ), The discharge control board plate 87 and the lamp / sound board plate 59 and the like, which are in contact with each other, or the launch rail 30, the inner rail 49, the outer rail 51, and the like. Adopt a configuration to remove the static electricity outside the machine. The results of measuring the influence of noise caused by static electricity in organic matter in the Pacchinko organic group 10 are shown in the graph of FIG. 8 (B).

Fig. 8 is a graph showing the potential difference generated in the organic organic group before and after discharge of product beads or rental beads. The graph shows the change in the potential difference on the power supply line as data, with the vertical axis representing the potential difference and the horizontal axis representing the elapsed time. 8 (A) shows the measurement result of the conventional pachinko organic group, and FIG. 8 (B) shows the measurement result of the pachinko organic group 10 of the present embodiment. As shown in Fig. 8, 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. 8 (A) with FIG. 8 (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, a potential difference of up to 6 volts and at least 4 volts occurs when product beads or rental beads are discharged, 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 voltage change of the power supply line when discharging product beads or rental beads is only about 1 volt, and is reduced to about 1/6 of the conventional pachinko organic device. . From the above, it can be seen that in the pachinko organic machine 10 of the present embodiment, noise caused by static electricity generated by discharge of product beads, rental beads, or the like does not act on the power supply line as compared with the conventional apparatus.

In the pachinko organic group 10 of the present embodiment described above, the parts or parts constituting the distribution paths R1 and R2 are formed using conductive plastics, and the parts and parts arranged around the distribution paths R1 and R2 are formed. Form using antistatic material. For this reason, the static electricity generated on the parts or parts constituting the distribution paths R1 and R2 is reliably dispersed in the distribution paths R1 and R2 due to the difference in resistivity, and the parts arranged around the distribution paths R1 and R2. It does not reach the area. Accordingly, the static electricity discharged from the parts or parts constituting the distribution paths R1 and R2 is prevented from acting on the control boards 57a, 58a, 81a, 82a, 84a, 86a as noise and at the same time, the distribution path ( Unpleasant feelings such as paralysis due to discharge from the surface of the part or part can be effectively prevented when the part or part is placed in contact with R1 and R2). As described above, according to the pachinko organic group 10 of the present embodiment, the pachinko organic group 10 can be conveniently used and the pachinko organic group 10 can be protected from static electricity. In addition, the dust is adsorbed by the static electricity on the surface of the parts or parts disposed around the circulation paths R1 and R2, whereby the situation of contamination of each part or part surface can be effectively prevented.

In addition, since the antistatic material has a wider selection range of material colors than the conductive materials such as conductive plastics and metals, it is possible to appropriately color parts and parts arranged around the distribution paths R1 and R2, thereby providing a pachinko organic group 10 ) Can enhance the overall aesthetics. In the pachinko organic group 10 of the present embodiment, portions made of black, which is the material color of the conductive plastic, are shown by hatched in FIGS. 2 and 3. As shown in Fig. 2, when the pachinko organic group 10 of the present embodiment is viewed from the front side, except for the plate portion 25b of the lower plate 25, there is no exposed portion of the black material color. Can be secured. In addition, even when the pachinko organic group 10 is seen from the back side, as shown in FIG. 3, the range which the black material color is exposed is small with respect to the total area of the back of the pachinko organic group 10, and a preferable aesthetic sense is ensured. do. Moreover, there are few black parts, and it is easy to visually confirm the arrangement | positioning of each component in the back of the pachinko organic group 10, and the coupling relationship of components.

Further, in the pachinko organic group 10 of the present embodiment, the product bead / rental bead discharge unit 75 made of conductive plastic and the protective covers 76a and 76b formed by using the antistatic material in the distribution path R1 are mutually connected. Since it is arranged in contact, the static electricity generated on the product bead / loan bead discharge unit 75 is actively induced to the product bead / loan bead discharge unit 75 having a lower resistivity, and toward the cover 76a, 76b. Rarely induced. Therefore, the static electricity can be reliably dispersed in the product beads / loan ball discharge unit 75, and the charging of the covers 76a and 76b can be reliably prevented. This effect can also be obtained between the bead base 77 and the bead cover 78 in the flow path R2.

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, the parts or parts formed of the conductive plastics are used, and in the distribution path R1, the bead tank 72, the tank rail 73, the case rail 74, and the product beads / loan ball discharge unit In the flow path R2, the bead base 77, the dish portion 24b of the upper dish 24, and the dish portion 25b of the lower dish portion 25 were used. Even if only a part of is formed of the conductive member, there is no problem. For example, only the bead tank 72 may be formed of conductive plastic in the distribution path R1. In addition, the bead tank 72, the tank rail 73, the case rail 74, the product beads / rental bead discharge unit 75, the plate portion 24b of the upper plate 24, the plate of the lower plate 25 Like the portion 25b, only portions where the organic spheres B can be stored in each distribution path may be formed of a conductive plastic.

Moreover, even if it forms a conductive member and parts other than the above, there is no problem. For example, in the flow path R2, the guide path 70b, the branch path 70c, and the overflow bead guide unit 130 may be formed of conductive plastic. Specifically, in the case of the guide path 70b and the branch path 70c, the parts having a passage shape of the guide path 70b and the branch path 70c (hereinafter referred to as guide path forming parts and branch path forming parts, respectively). The conductive plate may be formed using a conductive plastic separately from the mechanical plate 70, and the guide plate may be formed by attaching the formed part or branching formed part to the mechanical plate 70. Similarly, in the distribution path R4, a part having a passage shape of the bead discharge passage 70d (hereinafter referred to as a bead discharge passage forming part) is formed by using a conductive plastic separately from the mechanical plate 70, The bead discharge passage forming part may be attached to the mechanism plate 70. In addition, even if the launch rail 30, the outer rail 51, and the inner rail 49 are formed of electroconductive plastic in the flow path R3, it does not interfere.

In the above embodiment, the protective cover 76a, 76b, the bead barrel 78, the substrate covers 57w, 58w, 80w, 81w, 82w as the parts or parts disposed around the circulation paths R1 to R4. 84w, 86w), instrument plate 70, overflow bead guide unit 130, extension 24a of upper dish 24, extension 25a of lower dish 25, launch handle 26a The foul bead guide unit 131, the glass frame 22, the inner frame 20 is formed of an antistatic material, but only a part of the parts or parts thereof may be formed of the antistatic material. For example, only the cover 57w, 58w, 80w, 81w, 82w, 84w, 86w for each board | substrate may be formed with antistatic material in distribution path | route R1.

Moreover, even if it forms the parts and parts of that excepting the above by an antistatic material, it does not interfere. For example, various roles such as the organic panel 40, the special pattern display device 41, the ordinary standing mouth 43, the large mouth mouth 46, the windmill 47, and the like disposed around the distribution path R3. May be formed of an antistatic material.

In this manner, which part or part of the parts or parts constituting the distribution paths R1 to R4 is formed of conductive plastic, and which part or part is regarded as a part disposed around the distribution paths R1 to R4. It can select suitably about whether it forms with a prevention material. A list of these selectable combinations is shown in FIG. 9.

In FIG. 9, the part and site | part which comprise distribution path | route R1-R4 are made into the "path formation part", and the name of the path formation part formed from electroconductive plastic is described in the vertical axis direction. In addition, the part and the part arrange | positioned around the distribution path | route R1-R4 are made into the "peripheral part", and the name of the peripheral part formed with antistatic material is described in the horizontal axis direction. In addition, in the table of Fig. 9,? Indicates that it is judged to be optimal as a combination of a path forming part formed of a conductive plastic and a peripheral part formed of an antistatic material, and a? Mark indicates a path forming part formed of a conductive plastic. And what is considered to be suitable as a combination of peripheral components formed from an antistatic material. In addition, when △ mark is changed to the peripheral position of the path forming part, the parts or parts listed as peripheral parts are installed in the periphery organic group 10, the peripheral parts formed of the path forming part made of conductive plastic and the antistatic material It shows that it becomes applicable as a combination of components.

With reference to FIG. 9, the case where the path forming part formed from the conductive plastic in the distribution path R1 is selected as the bead tank 72 will be described. When the bead tank 72 is formed with electroconductive plastic, as shown in FIG. 9, the protective covers 76a and 76b, the bead barrel cover 78, and the board | substrate covers 57w, 58w, 80w, 81w, 82w. , 84w, 86w), the instrument plate 70, the inner frame 20, and the outer frame 12 are peripheral components, and a combination formed of an antistatic material is optimal. It is because these peripheral parts are arrange | positioned in the position close to the bead tank 72, and are the parts which a human contact is easy.

In addition, when the bead tank 72 is formed from electroconductive plastic, as shown in FIG. 9, the tank rail 73, the case rail 74, the goods bead / loan bead discharge unit 75, etc. are connected to the bead tank ( As a peripheral part of 72), a combination formed of an antistatic material is suitable. In this case, the static electricity generated in the distribution path R1 is guided and dispersed into the bead tank 72 and is removed to the outside of the machine through the metal plate 90 and the hinges 71 and 79 for the instrument plate.

On the other hand, the combination in which the bead tank 72 is formed of a conductive plastic and the upper plate 24 or the lower plate 25 is formed of an antistatic material is used to change the installation position of the upper plate 24 or the lower plate 25. Applicable by the. Since the upper dish 24 and the lower dish 25 are located on the front side of the pachinko organic group 10 of the present embodiment, the possibility of static electricity from the bead tank 72 on the back side of the pachinko organic group 10 is low. Because it is judged. As an example of changing the installation position of the upper plate 24 or the lower plate 25, when the shape of the upper plate 24 or the lower plate 25 is formed so that a part thereof extends toward the back of the pachinko organic device 10. May be considered. In this case, the upper dish 24 or the lower dish 25 and the bead tank 72 are arranged together on the rear side of the pachinko organic machine 10. Thus, by adopting a combination of forming the bead tank 72 from the conductive plastic and forming the upper dish 24 or the lower dish 25 from the antistatic material, static electricity from the bead tank 72 is discharged from the upper dish 24. The charging of the lower plate 25 to the surface can be effectively prevented.

In the above embodiment, portions of the upper plate 24 and the lower plate 25 (plate portions 24b and 25b) are formed of conductive plastic, and portions other than the plate portions 24b and 25b (extension portion 24a). , 25a)) is formed of an antistatic material, but for parts other than the upper plate 24 and the lower plate 25, a part of the part is formed of a conductive plastic and a part other than the part is formed of an antistatic material. It is also possible to set it as a structure. As such a part, a bead tank 72, a tank rail 73, a case rail 74, a product bead / rental bead discharge unit 75, a bead cylinder base 77, a guideway forming part, a branch path forming part, The instrument plate 70, the organic panel 40, the glass frame 22, the inner frame 20, and the like may be considered.

In addition, in the above embodiment, the parts and portions constituting the distribution paths R1 to R4 are formed of conductive plastic, but they are not interfered even if they are formed by using a conductive polymer material (for example, conductive rubber) other than the conductive plastic. Of course. Also in this case, the same effects as in the above embodiment can be obtained.

The pachinko organic group 10 according to the embodiment of the present invention is the replenishment of the organic sphere B to the upper plate 24 by bead rental or the like, or the organic sphere B discharged to the upper plate 24 or the lower plate portion 25. ) Can be taken out of the machine, but organic beads are enclosed inside the machine, and the present invention can also be applied to other types of organic groups that conduct organic matter by circulating the beads. Further, in the pachinko organic group 10 of the above embodiment, a predetermined number of organic spheres B are discharged as product beads as the organic sphere B enters a granular sphere such as the ordinary granular sphere 43. The present invention can also be applied to other organic groups that discharge a predetermined number of medals, prizes, and the like instead of product beads. Such organic groups include an arrangement ball, a pachinko toy, and the like.

According to the present invention, the organic group can be protected from static electricity while ensuring the safe handling of the organic group and the aesthetics and cleanliness of the organic group.

Claims (5)

As an organic group which organically distributes by distribute | circulating organic beads, A control board for controlling the operation relating to the induction, a path forming part that is a part that forms a flow path of the bead, and a peripheral part that is a part located around the path forming part, At least one of the path forming parts is formed using a conductive polymer material, and at least one of the peripheral parts is formed using an antistatic material. The method of claim 1, wherein at least one of the path forming parts, A bead tank for temporarily storing beads supplied from an island of an organic field, a discharging device for discharging the organic spheres stored in the bead tank when a predetermined condition is provided, and the bead from the bead tank to the discharging device. A first passage-forming part forming a passage, a second passage-forming part forming a passage of the beads from the discharge device to a plate body collecting the beads discharged by the discharge device, and collecting the beads collected in the plate body One of the rail parts leading into the area, At least one of the peripheral parts, Dish to collect the beads discharged by the discharge device, the cover for the discharge device mounted to the discharge device, the cover for the first passage forming part mounted to the first passage forming part, for the substrate mounted on the control board A cover plate, the control plate, the bead tank, the discharge device, a plate body on which at least one of the first passage forming part and the second passage forming part is mounted, a glass frame covering the organic region, the glass frame Organic group, characterized in that any one of the frame to be mounted. The organic group according to claim 1 or 2, wherein the path forming part and the peripheral part are disposed in contact with each other. As an organic group which organically distributes by distribute | circulating organic beads, And a distribution path forming part, which is a part forming a distribution path of the beads, In the distribution path forming part, a contact portion in contact with the beads in the distribution of the beads is formed using a conductive polymer material, and at least a portion of the non-contact parts not in contact with the beads in the distribution of the beads are antistatic An organic group formed using ash. The method of claim 4, wherein the flow path forming component, A bead tank for temporarily storing beads supplied from an island of an organic field, a discharge device for discharging the organic spheres stored in the bead tank when a predetermined condition is provided, and forming a passage of the beads from the bead tank to the discharge device; Any one of a first passage forming part, a dish body collecting beads discharged by the discharge device, and a second passage forming part forming a passage of the beads from the discharge device to the dish body. device.