JP4828224B2 - Game rotation display device - Google Patents

Description

  The present invention relates to a game rotation display device in which illumination of a rotation display structure is appropriate.

A game rotation display device having the following structure is known. That is, a display lamp is installed outside the spherical rotating display structure, and the display lamp illuminates the rotating display structure from the outside of the rotary display structure. However, since the structure that is rotatably supported is disposed between the indicator lamp and the rotary display structure, the light that illuminates the rotary display structure from the indicator lamp is blocked by the structure that rotatably supports. There is a drawback that shadows can be made.
JP-A-8-191936

  The problem to be solved by the invention is that the illumination of the rotating display structure is inappropriate.

Game rotating display device according to the present invention, the symbol display member that displays a plurality of symbols is provided on the outer surface of the rotating display structure spherical shape, rotating display structure is rotated by the rotation drive mechanism, to illuminate the Figure Pattern In a game rotation display device in which a plurality of indicator lights are arranged outside the rotation display structure , the rotation display structure passes through the center of the rotation display structure, and both ends are formed in the rotation display structure. A display shaft that protrudes outward from the portion, a reflective surface formed in a conical shape, and a reflector that is attached to the display shaft inside the rotary display structure, and the display shaft is fixed so as not to rotate, and is driven to rotate Synthetic resin having a support structure fitted into the mechanism and an indicator lamp structure that covers the rotary display structure and a plurality of indicator lamps are attached along the circumferential direction, and the rotary display structure transmits light Formed and rotated by Introduced into the irradiation light gap is emitted from the indicator between the shown structure rotating flat portion provided in the display axis constituting the center and the symbol display body by the rotation drive mechanism from the outside of the rotating display structure is configured as a light introducing part for, it reflected as reflection light reflecting surface toward the symbol display member irradiated light introduced therein is provided on the rotating display structure of the rotating display structure from the light introducing portion of the reflector the most important feature and this.

In the game rotation display device according to the present invention, the illumination light from the indicator lamp is introduced into the inside from the outside of the rotation drive mechanism via the light introducing portion, and the irradiation light introduced into the inside of the rotation display structure is reflected. There is an advantage in that the reflected light is reflected by the body as reflected light toward the symbol display body, and the reflected light is transmitted through the rotary display structure so that a plurality of symbols in the symbol display body can be appropriately illuminated from the inside of the rotary display structure. . Since the reflector is configured in a conical shape, there is also an advantage that the reflector can be easily formed so as to illuminate the symbol display body more uniformly than when the reflector is configured in a pyramid shape. .

  1 to 13 show the best mode for carrying out the invention. 1 shows a cross section of the game rotation display device 1 cut in the lateral direction. FIG. 1b shows a cross-section taken along line BB of FIG. 1a. FIG. 2 shows a cross section of a structure in which the game rotation display device 1 is attached to a game board 120 of a pachinko machine, cut in a vertical direction parallel to the display shaft 12. FIG. 3 shows a cross section in which the structure in which the game rotation display device 1 is attached to the game board 120 of the pachinko machine is cut in the vertical direction perpendicular to the display shaft 12. FIG. 4 shows the game rotation display device 1 in an exploded manner. FIG. 5 shows the rotary display structure 3 in an exploded manner. FIG. 6 shows a process of assembling the rotary display structure 3. FIG. 7 shows an initial form in which the rotary display structure 3 and the symbol display body 6 are assembled. FIG. 8 shows a final form in which the rotary display structure 3 and the symbol display body 6 are assembled. FIG. 9 shows the rotary display structure 3 and the planetary gear 13 in an exploded manner. FIG. 10 shows the reflector 9 and the display shaft 12 in an exploded manner. FIG. 11 a shows an exploded view of the rotating display structure 3 and the support structure 14. FIG. 11b shows the support piece 53 from the inside. FIG. 12A shows a form in which the support piece 53 is inserted into the arm portion 16. FIG. 12 b shows a form in which the support piece 53 is engaged with the arm portion 16. FIG. 13 shows the indicator light structure 7 in an exploded manner. In this specification, the direction of “front”, “front”, “rear”, “back”, “left”, “right”, “up”, “down” is the game rotation display device 1 in the state of FIG. And the direction specified when the game board 120 is placed and viewed from the front side indicated by the arrow A. “Previous” and “table” are in the same direction. “Back” and “back” are in the same direction.

  The structure of the game rotation display device 1 will be described with reference to FIG. In the game rotation display device 1, the rotation display structure 3 is rotated on the front side of the device housing 2 by the rotation drive mechanism 4 and the revolution drive mechanism 5, and the rotation display structure 3 rotates in the direction indicated by the arrow W1 and revolves in the direction indicated by the arrow W2. A plurality of symbols displayed on the symbol display body 6 provided in the rotary display structure 3 are variably displayed, while light emitted from the indicator lamp 8 of the indicator lamp structure 7 is outside the rotary display structure 3. In this structure, the light introduced into the interior of the rotary display structure 3 is reflected by the reflector 9, and a plurality of symbols in the symbol display body 6 are illuminated from the inside of the rotary display structure 3. The rotation drive mechanism 4 and the revolution drive mechanism 5 constitute a rotation drive mechanism that rotates the rotation display structure 3. The device housing 2 includes a rotation driving mechanism 4, a revolution driving mechanism 5, a display body accommodating portion 10, and a bearing hole portion 11. The rotation drive mechanism 4 and the revolution drive mechanism 5 will be described later with reference to FIG. The display body accommodating portion 10 is configured as a recess that opens in a circular shape forward and is recessed in a circular shape from the front surface of the device housing 2 to the inside. The bearing hole portion 11 is provided at the center of the circular bottom surface of the display body housing portion 10.

  The rotating display structure 3 is provided with a reflector 9, a display shaft 12, a planetary gear 13, and a support structure 14. The reflector 9 is fixed to the display shaft 12. A structure for attaching the reflector 9 to the display shaft 12 will be described later with reference to FIG. The display shaft 12 passes through the center of the rotary display structure 3 and is rotatably fitted in the rotary display structure 3 and is fixed to the support structure 14 so as not to rotate. The planetary gear 13 is rotatably fitted to one end portion of the display shaft 12 that protrudes outward from the rotation display structure 3 and is fixed to the rotation display structure 3. A structure for attaching the planetary gear 13 to the rotation display structure 3 will be described later with reference to FIG. The support structure 14 includes a support base 15, arm portions 16; 17, a support shaft 18, a sun gear 19, and an intermediate gear 20. The support base 15 has a hemispherical shape that is recessed downward from above. The arm portions 16 and 17 are relatively bent on the diameter line of the support base 15 and protrude upward from the circular peripheral wall of the support base 15. The arm portion 16 supports the display shaft 12 so as not to rotate. The support shaft 18 protrudes in a cylindrical shape from the center of the bottom of the support base 15 to the back side. Then, the rotation display structure 3 is attached to the support structure 14, and the support shaft 18 is rotatably fitted into the bearing hole 11 from the front side of the device housing 2, thereby being supported by the arms 16; 17. The shaft 12 is arranged in parallel with the bottom surface of the display body accommodating portion 10.

  The sun gear 19 is disposed on the front side of the support base 15 and includes a sun shaft 21. The sun shaft 21 protrudes from the center of the sun gear 19 to the back side, is rotatably fitted into the inner hole of the support shaft 18 from the front side of the support base 15, and penetrates the back side of the support shaft 18. The intermediate gear 20 is disposed on the front side of the support base 15 and includes an intermediate shaft 22. The intermediate shaft 22 protrudes from the center of the intermediate gear 20 to the back side, and is rotatably attached to the mortar-shaped peripheral wall of the support base 15. The planetary gear 13, the sun gear 19, and the intermediate gear 20 are constituted by bevel gears. The tooth portion formed on the outer peripheral portion of the intermediate gear 20 is meshed with the tooth portion formed on the outer peripheral portion of the sun gear 19 and the tooth portion formed on the outer peripheral portion of the planetary gear 13. That is, when the sun gear 19 rotates, the intermediate gear 20 and the planetary gear 13 rotate, and the rotation display structure 3 is indicated by the arrow W1 of the display shaft 12 around the center line L1 extending in the lateral direction of the display shaft 12. Rotates in the circumferential direction. Further, when the support shaft 18 of the support structure 14 is rotated, the rotation display structure 3 is displayed in the circumferential direction indicated by the arrow W2 around the center line L2 extending in the front-rear direction of the support shaft 18 of the support structure 14. Revolves in a direction parallel to the bottom surface of the body accommodating portion 10.

  The structure of the rotation display structure 3 will be described with reference to FIG. The rotating display structure 3 includes a pair of hemispheres 25 and 26 made of a synthetic resin having a property of transmitting light. The hemisphere 25 includes a flat portion 27, a bearing hole portion 28, a gear engaging portion 29, and a mating portion 30. The flat portion 27 is provided in the center of the hemisphere 25 in a circle that is parallel to the circular opening of the hemisphere 25 and centered on the center line L1. The bearing hole portion 28 is provided in the center portion of the flat portion 27 as a through hole in a direction parallel to the center line L1. The gear engaging portion 29 is located around the bearing hole portion 28 and provided in the flat portion 27 as a through hole in a direction parallel to the center line L1. The mating portion 30 is provided in an uneven shape in the circular opening of the hemisphere 25. The hemisphere 26 includes a flat portion 31, a bearing hole portion 32, a bearing accommodating portion 33, and a matching portion 34. The flat portion 31 is provided in the center of the hemisphere 26 in a circle that is parallel to the circular opening of the hemisphere 26 and centered on the center line L1. The bearing hole 32 is formed as a hole provided at the center of the flat portion 31. The bearing accommodating portion 33 is formed as a hole provided in the central portion of the flat portion 31. With respect to the flat part 31, the bearing hole part 32 is arrange | positioned inside, and the bearing accommodating part 33 is arrange | positioned outside. The diameter of the bearing hole portion 32 is smaller than the diameter of the bearing accommodating portion 33. The bearing hole portion 32 and the bearing accommodating portion 33 are coaxial with the center line L1 and pass through each other. The mating portion 34 is provided in a concavo-convex shape in the circular opening of the hemisphere 26. The diameter S1 centered on the center line L1 of the flat portion 27 and the diameter S2 centered on the center line L1 of the flat portion 31 have the same dimensions.

  With reference to FIG. 6, the assembly method of the rotation display structure 3 is demonstrated. The mating portion 30 of the hemisphere 25 and the mating portion 34 of the hemisphere 26 face each other, and the display shaft 12 on which the reflector 9 is mounted is disposed inside the two hemispheres 25; The two hemispheres 25; 26 are brought close to each other, one end of the display shaft 12 is inserted into the bearing hole 28 of the hemisphere 25, and the other end of the display shaft 12 is inserted into the bearing hole 32 of the hemisphere 26. Inserted. Next, the convex portion of the mating portion 30 and the concave portion of the mating portion 34 are aligned with each other, the concave portion of the mating portion 30 and the convex portion of the mating portion 34 are aligned with each other, and the mating portions 30; Is done. In this way, after the display shaft 12 on which the reflector 9 is mounted is disposed inside the two hemispheres 25; 26, the two hemispheres 25; 26 are combined as a single body, thereby rotating the display structure. 3 is formed in a hollow sphere shape.

  The structure of the symbol display body 6 will be described with reference to FIG. The symbol display body 6 includes a display sheet, a milky white base layer, and a plurality of different types of symbols. The display sheet is made of a colorless synthetic resin having a property of transmitting heat and contracting light. A base layer is provided on the back surface of the display sheet. A plurality of symbols are displayed in a color other than white on the back surface of the base layer. The base layer and the design are printed on the back surface of the design display body 6. The plurality of symbols are, for example, “3”, “4”, “5”, “6”, “7”, “8”. “3”, “5”, and “7” are red. “4”, “6”, and “8” are blue. The symbol display body 6 is formed in a cylindrical shape so that the base layer and the symbol are on the outside. When the symbol display body 6 is formed in a cylindrical shape, the plurality of symbols are arranged in a column form arranged in a line in the circumferential direction of the symbol display body 6. The symbol display body 6 formed in a cylindrical shape is covered on the outer surface of the rotary display structure 3 from the direction of one end of the display shaft 12. The base layer may be provided on the surface of the display sheet, and the design may be provided on the surface of the base layer. However, if the base layer is provided on the back surface of the display sheet and the design is provided on the back surface of the base layer, two design displays 6 are provided. When attached to the outer surface of the rotating display structure 3 composed of hemispheres 25; 26, the symbol is sandwiched between the display sheet and the rotating display structure 3, so that a person cannot touch the symbol. The durability of the pattern is improved.

  With reference to FIG. 8, the assembly method to the rotation display structure 3 of the symbol display body 6 is demonstrated. After the symbol-shaped display body 6 formed in a cylindrical shape is put on the rotary display structure 3, heat is applied to the symbol display body 6 from the outside, the symbol display body 6 is thermally contracted, and the symbol display body 6 is rotated. Provided integrally on the outer surface of the display structure 3. When the symbol display body 6 is integrally provided on the outer surface of the rotation display structure 3 as described above, the plurality of symbols are arranged apart from each other in the direction of rotation indicated by the arrow W <b> 1 of the rotation display structure 3. When the symbol display body 6 is assembled to the rotary display structure 3, the gap S <b> 3 between the flat portion 27 and the symbol display body 6 constitutes a light introducing portion 35, and between the flat portion 31 and the symbol display body 6. The gap S4 constitutes the light introducing part 36. The gap S3 and the gap S4 have the same dimensions. The light introducing sections 35 and 36 introduce the light emitted from the indicator lamp 8 in FIG. 4 from the outside to the inside of the rotating display structure 3. The flat portions 27 and 31 are portions where the display shaft 12 that constitutes the center of rotation by the rotation drive mechanism of the rotary display structure 3 is provided.

  With reference to FIG. 9, the structure which attaches the planetary gear 13 to the rotation display structure 3 is demonstrated. The planetary gear 13 is provided with a shaft insertion hole portion 38, a bearing housing portion 39, an engagement portion 40, a receiving portion 41, and a residue hole 42. The shaft insertion hole 38 is a hole for inserting the display shaft 12 of FIG. 10 and is provided at the center of the planetary gear 13. The bearing housing portion 39 is a hole into which the bearing 51 of FIG. 11 is inserted, and is provided at the center of the planetary gear 13. The shaft insertion hole 38 is disposed on the inner side with respect to the planetary gear 13, and the bearing housing portion 39 is disposed on the outer side. The diameter of the shaft insertion hole 38 is smaller than the diameter of the bearing housing 39. The shaft insertion hole 38 and the bearing accommodating portion 39 are coaxial with the center line L1 and pass through each other. The engaging portions 40 are a pair of elastic pieces that are opposed to each other on the diameter line of the planetary gear 13, and are elastic pieces that protrude toward the rotation display structure 3 from the surface of the planetary gear 13 that is located on the rotation display structure 3 side. This is a form having a hook at the tip. The receiving part 41 is located between the shaft insertion hole 38 and the engaging part 40, and protrudes from the inner surface of the planetary gear 13 on the side of the rotating display structure 3 to the side of the rotating display structure 3. It is a difficult wall. The residue hole 42 has a shaft insertion hole 38, an engaging portion 40, and a receiving portion 41. In the molding die in which the planetary gear 13 is formed of synthetic resin, a hook is provided on an elastic piece in the engaging portion 40. It is the hole formed as the trace from which the mold element for was extracted.

  Then, as the engaging portion 40 is directed toward the rotation display structure 3 and inserted into the gear engaging portion 29, the shaft insertion hole 38 is taken into the bearing hole 28, and the receiving portion When 41 is disposed outside the bearing hole portion 28 and the hook of the engaging portion 40 passes through the gear engaging portion 29 in the direction of the inside of the rotary display structure 3, the elastic piece of the engaging portion 40 is elastically outward. The hook of the engaging portion 40 faces the inner surface of the flat portion 27, and the receiving portion 41 contacts the outer surface of the flat portion 27. Accordingly, the flat portion 27 is sandwiched between the hook of the engaging portion 40 and the receiving portion 41, and the planetary gear 13 is fixedly attached to the rotation display structure 3. For this reason, the planetary gear 13 can be easily attached to the rotation display structure 3, and the planetary gear 13 can be easily detached from the rotation display structure 3. See FIG. 2 for the configuration in which the planetary gear 13 is attached to the rotary display structure 3.

  A structure for attaching the reflector 9 to the display shaft 12 will be described with reference to FIG. The reflector 9 has a conical shape and has a conical reflecting surface 43 and protrudes from the back side to the front side. Inside the reflector 9, a shaft mounting portion 44 is provided as a recess from the top to the bottom of the reflector 9. A screw fastening hole 45 is provided at the bottom of the shaft attachment portion 44 as a recess from the bottom to the inside. A shaft housing portion 46 is provided on the peripheral portion of the reflecting surface 43 so as to be positioned on the bottom side of the reflector 9. The shaft accommodating portion 46 has a shape that is recessed from the bottom of the reflector 9 toward the top and surrounds a groove that opens in the lateral direction and the bottom of the reflector 9. The display shaft 12 includes a screw insertion hole 47 and a rotation blocking portion 48. The screw insertion hole 47 is provided as a through hole in the front-rear direction at the center of the display shaft 12 in the direction in which the center line L1 extends. The rotation blocking portion 48 is a variant in which a part of the outer peripheral surface of the display shaft 12 is formed as a flat surface at one end portion of the display shaft 12.

  The opening on the bottom side of the shaft accommodating portion 46 is directed to the display shaft 12 side, the screw fastening hole 45 and the screw insertion hole 47 face each other in the front-rear direction, and the direction in which the center line L1 of the display shaft 12 extends is extended. A set screw 49 such as a tapping screw is taken in over the shaft accommodating portion 46 and fastened to the screw fastening hole 45 of the reflector 9 from the bottom side of the reflector 9 via the screw insertion hole 47 of the display shaft 12. Thus, the outer peripheral surface of the display shaft 12 comes into contact with the back surface of the shaft mounting portion 44 and the inner peripheral surface of the shaft housing portion 46, and the display shaft 12 and the reflector 9 are integrated with each other. When the display shaft 12 and the reflector 9 are integrated with each other, since the display shaft 12 is taken into the shaft housing portion 46, the posture of the reflector 9 is stabilized. For the form in which the display shaft 12 and the reflector 9 are integrated with each other, see FIG.

  With reference to FIG. 11, the structure which attaches the rotation display structure 3 to the support structure 14 with the bearing 51; 52 and the support piece 53; 54 is demonstrated. The bearings 51 and 52 are constituted by ball bearings having the same structure. The support piece 53 is fixedly attached to the arm portion 16 of the support structure 14 so that the display shaft 12 protruding outward from the rotation display structure 3 is not rotated, and includes a rotation prevention hole 55, a cylindrical portion 56, A bearing housing portion 57, a first partition wall 58, a second partition wall 59, and an engagement portion 60 are provided. The rotation prevention hole 55 is provided at the center of the support piece 53 as a deformed hole into which the rotation prevention portion 48 of the display shaft 12 is fitted. The cylindrical portion 56 is provided at the central portion of the support piece 53 so as to protrude from the support piece 53 to the inside which is the support structure 14 side. The bearing accommodating portion 57 is configured as a hole provided in the central portion of the cylindrical portion 56. With respect to the support piece 53, the rotation prevention hole 55 is disposed on the outside, and the bearing housing portion 57 is disposed on the inside. The rotation prevention hole 55 and the bearing housing portion 57 are coaxial and penetrate each other. The first partition wall 58 projects radially outward from the inner side in the same direction as the center line L1 (see FIG. 4) of the cylindrical part 56. The second partition wall 59 protrudes radially outward from the inner part of the cylindrical part 56. A position where the first partition wall 58 protrudes from the cylindrical portion 56 such that the first partition wall 58 and the second partition wall 59 are positioned on the diameter line of the cylindrical portion 56, and a position where the second partition wall 59 protrudes from the cylindrical portion 56. Are different from each other. The engaging portion 60 includes a vertical wall 66, a connecting wall 67, an elastic piece 68, and a hook 69. The vertical wall 66 protrudes radially outward from the support piece 53 so as to face the first partition wall 58 in the horizontal direction as the left-right direction. The connecting wall 67 connects the protruding end of the vertical wall 66 to the protruding end of the first partition wall 58. The elastic piece 68 projects linearly from the connecting wall 67 in one direction orthogonal to the horizontal direction as the left-right direction of the support piece 53. The hook 69 is provided so as to protrude from the protruding end of the elastic piece 68 toward the cylindrical portion 56.

  The support piece 54 attaches the display shaft 12 protruding outward from the rotary display structure 3 to the arm portion 17 of the support structure 14. The support piece 54 includes a cylindrical portion 61, a bearing accommodating portion 62, a first partition wall 63, a second partition 63. A partition wall 64 and an engaging portion 65 are provided. The cylindrical portion 61 is provided at the center of the support piece 54 so as to protrude from the support piece 54 to the inside which is the support structure 14 side. The bearing housing portion 62 is provided as a through hole in the lateral direction as the left-right direction at the center of the cylindrical portion 61. The first partition wall 63 projects radially outward from the inner side in the same direction as the center line L1 (see FIG. 4) of the cylindrical part 61. The second partition wall 64 protrudes radially outward from the inner part of the cylindrical part 61. A position where the first partition wall 63 protrudes from the cylindrical portion 61 such that the first partition wall 63 and the second partition wall 64 are located on the diameter line of the cylindrical portion 61, and a position where the second partition wall 64 protrudes from the cylindrical portion 61. Are different from each other. The engaging portion 65 includes a vertical wall 70, a connecting wall 71, an elastic piece 72, and a hook 73. The vertical wall 70 protrudes radially outward from the support piece 54 so as to face the first partition wall 63 in the horizontal direction as the left-right direction. The connecting wall 71 connects the protruding end of the vertical wall to the protruding end of the first partition wall 63. The elastic piece 72 projects linearly from the connecting wall in one direction orthogonal to the lateral direction as the left-right direction of the support piece 54. The hook 73 is provided at the protruding end of the elastic piece so as to protrude toward the cylindrical portion 56.

  The arm portion 16 of the support structure 14 is provided with a piece accommodating portion 75, a split 76, an escape portion 77, and an engaging portion 78. The piece accommodating part 75 is provided in the arm part 16 as a through hole in the lateral direction as the left-right direction. A front portion of the arm portion 16 surrounding the piece accommodating portion 75 on the rotation display structure 3 side has an arc shape with the center of the piece accommodating portion 75 as the center. The split 76 is provided at the front part of the arm part 16 for inserting the first partition wall 58 of the support piece 53, reaches the outside of the arm part 16 and the piece accommodating part 75, and opens in the lateral direction and the front-rear direction. Then, the front part of the arm part 16 is divided. The escape part 77 is provided in the rear part of the arm part 16 for inserting the second partition wall 59 of the support piece 53, and is recessed from the piece accommodating part 75 to the arm part 16, and is open in the lateral direction and the front-rear direction. To do. The engaging portion 78 engages with the hook 69 of the support piece 53 and is provided on one side of the arm portion 16 divided by the split 76, and has a diameter from the boundary between the front portion and the rear portion of the arm portion 16. Projects outward in the direction.

  The arm portion 17 of the support structure 14 is provided with a piece accommodating portion 79, a split 80, an escape portion 81, and an engaging portion 82. The piece accommodating portion 79 is provided in the arm portion 17 as a through hole in the lateral direction as the left-right direction. A front portion of the arm portion 17 surrounding the piece accommodating portion 79 on the side of the rotation display structure 3 has an arc shape centered on the center of the piece accommodating portion 79. The split 80 is provided at the front part of the arm part 17 for inserting the first partition wall 63 of the support piece 54, reaches the outside of the arm part 17 and the piece accommodating part 79, and opens in the lateral direction and the front-rear direction. Then, the front part of the arm part 17 is divided. The escape portion 81 is provided in the rear portion of the arm portion 17 for inserting the second partition wall 64 of the support piece 54, and is recessed from the piece accommodating portion 79 to the arm portion 17, and is open in the lateral direction and the front-rear direction. To do. The engaging portion 82 engages the hook 73 of the support piece 54 and is provided on one side of the arm portion 17 divided by the split 80, and has a diameter from the boundary between the front portion and the rear portion of the arm portion 17. Projects outward in the direction.

  In order to attach the rotation display structure 3 to the support structure 14, the bearing 51 is inserted into the bearing housing portion 39 from the outside of the planetary gear 13, and the bearing 52 is inserted into the bearing housing portion 33 from the outside of the rotation display structure 3. The rotary display structure 3 is inserted into a space opened from the front side of the support structure 14 to the front side surrounded by the support base 15, and both end portions of the display shaft 12 protruding in the lateral direction of the rotary display structure 3 are housed in the frame. Part 75; 79. In that case, after the display shaft 12 is moved from the one end side to the other end side by the operator, the display shaft 12 is inserted into the piece housing portion 75 from the inside of the arm portion 16, and the display shaft 12 is inserted into the other end portion by the operator. After being moved from the side to the one end side, it is inserted into the piece accommodating portion 79 from the inside of the arm portion 17.

  Next, the cylindrical portion 56 of the support piece 53 is inserted into the piece accommodating portion 75 from the outside of the rotation display structure 3, and the first partition wall 58 of the support piece 53 penetrates the split 76 from the outside of the rotation display structure 3. The second partition wall 59 of the support piece 53 penetrates the escape portion 77 from the outside of the rotary display structure 3 and is arranged inside the arm portion 16. Accordingly, the rotation prevention portion 48 of the display shaft 12 is fitted into the bearing housing portion 57 of the support piece 53 in the rotation prevention hole 55 of the support piece 53, and the cylindrical portion 56 comes into contact with the inner ring of the bearing 51. Is fixed to the display shaft 12 so as not to rotate in the circumferential direction (see FIG. 12a). Then, as the support piece 53 is rotated so that the hook 69 approaches the engagement portion 78 side, the display shaft 12 rotates together with the support piece 53, and the cylindrical portion 56 moves the piece receiving portion 75. Rotating about the center, the engaging portion 60 of the support piece 53 engages with the engaging portion 78 of the support structure 14, and the support piece 53 is fixed to the arm portion 16 as shown in FIG. 12 b).

  As the cylindrical portion 61 of the support piece 54 is inserted into the piece accommodating portion 79 from the outside of the rotary display structure 3, the other end portion of the display shaft 12 is fitted into the bearing accommodating portion 62 of the support piece 54. 61 is in contact with the inner ring of the bearing 52, and the support piece 54 is mounted on the display shaft 12 so as to be rotatable in the circumferential direction. Then, as the support piece 54 is rotated so that the hook 73 approaches the engagement portion 82 side, the cylindrical portion 61 rotates around the piece accommodation portion 79, and the engagement portion 65 of the support piece 54. Engages with the engaging portion 82 of the support structure 14, and the support piece 54 is fixed to the arm portion 17. As described above, the support piece 53 is fixed to the arm portion 16 and the support piece 54 is fixed to the arm portion 17, whereby the reflector 9 is fixedly supported in the form shown in FIG. 2.

  The structure of the indicator light structure 7 will be described with reference to FIG. The indicator lamp structure 7 includes an indicator lamp 8, a post-display base 84, a display base 85, a pre-display base 86, a lens 87, and a circuit board 88. The indicator lamp 8 is configured by an LED mounted on the circuit board 88. The indicator lamp 8 penetrates the through hole 99 (see FIG. 2) formed in the post-display base 84 from the outside to the inside of the post-display base 84, and the circuit board 88 is set on the outer surface of the post-display base 84 with the set screw 100 (FIG. 2). Attached). In the case of the best mode, the number of the indicator lamps 8 is six, and when the post-display base 84 is viewed from the front side, one post-display base 84 is arranged for each position divided into six equal parts in the circumferential direction. The

  The post-display base 84 is formed in a cylindrical shape surrounding a space in which the rotating display structure 3 and the support structure 14 shown in FIG. 4 can be accommodated by a colored synthetic resin having a property of blocking light. The inner surface of the post-display base 84 can be used as a light reflecting surface by mixing a diffusion material with the synthetic resin that is the material of the post-display base 84 or by forming a reflective layer by painting or plating on the inner surface of the post-display base 84. Composed. A mounting portion 89 is provided on the rear portion of the display base 84. The attachment portion 89 protrudes from the post-display base 84 to the inside. A screw coupling hole 90 is provided in the attachment portion 89 as a through hole in the front-rear direction. The display base 85 is formed in a cylindrical shape having the same diameter as the post-display base 84 by a colored synthetic resin having a property of blocking light. The inner surface of the display base 85 is formed as a light reflecting surface by mixing a diffusion material with the synthetic resin that is the material of the display base 85 or by forming a reflective layer by painting or plating on the inner surface of the display base 85. Composed. A flange 91 is provided at the front portion of the display base 85. The inner diameter of the flange 91 is smaller than the inner diameter of the display base 85. The outer diameter of the flange 91 is larger than the outer diameter of the display base 85. Therefore, the flange 91 has an annular shape that protrudes inward and outward from the display base 85. The flange 91 is provided with an inner screw insertion hole 92 and an outer attachment hole 93 as through holes in the front-rear direction. The pre-display base 86 is formed in a cylindrical shape having the same inner diameter as that of the display-in-progress base 85 by a colored synthetic resin having a property of blocking light. A screw coupling hole 94 is provided in the back surface of the pre-display base 86 as a recess from the back surface of the pre-display base 86 to the inside. The lens 87 is formed in a hemispherical shape protruding from the back side to the front side by a colorless synthetic resin having a property of transmitting light. A cylindrical partition wall 95 is provided at the front portion of the lens 87. The cylindrical partition wall 95 projects forward from the front portion of the lens 87. A flange 96 is provided at the front portion of the cylindrical partition wall 95. The flange 96 is provided with a screw insertion hole 97 as a through hole in the front-rear direction.

  The flange 96 of the lens 87 is inserted into the inside from the back side of the display base 85, the base 86 before display is superimposed on the flange 91 from the front side of the display base 85, and a set screw 98 such as a tapping screw is provided in the screw insertion hole. The flange 91 of the display base 85 is sandwiched between the lens 87 and the pre-display base 86 by being fastened to the screw coupling hole 94 via 97; 92, and the display base 85 and the pre-display base 86 and The lenses 87 are assembled together. Further, the rear part of the display base 85 and the front part of the display base 84 are overlapped with each other and bonded with an adhesive. Thereby, the indicator light structure 7 is comprised in the form shown in FIG.

  In FIG. 4, the support shaft 18 of the support structure 14 assembled with the rotation display structure 3 is inserted into the bearing hole 11 from the front side of the device housing 2, and the rotation display structure 3 and the support structure 14 have the indicator lamp structure. The indicator lamp structure 7 is placed on the device housing 2 from the front side of the rotary display structure 3 so that it is taken into the body 7, and a set screw 101 such as a tapping screw is placed on the device housing 2 from the back side of the device housing 2. The game rotation display device 1 is configured in the form shown in FIGS. 1 to 3 by being fastened to the screw coupling hole 90 of the indicator lamp structure 7 via the formed screw insertion hole 102.

  With reference to FIG. 2 and FIG. 3, the structure of the rotation drive mechanism 4, the structure of the revolution drive mechanism 5, and the structure where the game rotation display apparatus 1 is attached to the game board 120 in the pachinko machine will be described. The rotation driving mechanism 4 includes a rotation motor 105, a rotation driving wheel body 106, a rotation driven wheel body 107, and a rotation belt 108. The rotation motor 105 is constituted by a step motor, and the rotation motor shaft 109 constituting the output shaft of the rotation motor 105 is directed from the apparatus housing 2 to the back side, and the motor case of the rotation motor 105 is arranged from the back side of the device housing 2 to the motor storage chamber. It is housed in 110 and fixedly attached to the apparatus housing 2. The center portion of the rotation driving wheel body 106 is fitted into the rotation motor shaft 109 and fixedly attached. The center portion of the rotation driven wheel body 107 is fixedly attached by being fitted to the sun shaft 21 protruding from the device housing 2 to the back side. The rotation belt 108 is wound around the rotation driving wheel body 106 and the rotation driven wheel body 107. Then, when the rotation motor shaft 109 is rotationally driven, the rotation driving wheel body 106, the rotation belt 108, the rotation driven wheel body 107, the sun gear 19, the intermediate gear 20, and the planetary gear 13 are rotated, and the rotation display structure 3 is formed. It rotates in the direction shown by arrow W1. The rotation drive mechanism 4 includes a rotation motor 105, a rotation drive wheel body 106, a rotation driven wheel body 107, a rotation belt 108, a sun gear 19, an intermediate gear 20, and a planetary gear 13.

  The revolution drive mechanism 5 includes a revolution motor 112, a revolution drive wheel body 113, a revolution driven wheel body 114, and a revolution belt 115. The revolution motor 112 is constituted by a step motor, the revolution motor shaft 116 constituting the output shaft of the revolution motor 112 is directed from the apparatus housing 2 to the back side, and the motor case of the revolution motor 112 from the back side of the device housing 2 to the motor housing chamber. It is housed in 117 and fixedly attached to the device housing 2. The center part of the revolution drive wheel body 113 is fitted into the revolution motor shaft 116 and fixedly attached. The center portion of the revolving driven wheel body 114 is fixedly attached by being fitted to the support shaft 18 protruding rearward from the device housing 2. The revolution belt 115 is looped over the revolution driving wheel body 113 and the revolution driven wheel body 114. Then, when the revolution motor shaft 116 is driven to rotate, the revolution driving wheel body 113, the revolution belt 115, the revolution driven wheel body 114, and the support structure 14 rotate, and the rotation display structure 3 rotates in the direction indicated by the arrow W2. To do. The revolution drive mechanism 5 includes a revolution motor 112, a revolution drive wheel body 113, a revolution belt 115, a revolution driven wheel body 114, and a support structure 14.

  A structure in which the game rotation display device 1 is attached to the game board 120 will be described. In the best mode, in the game rotation display device 1, the rotation display escape hole formed in the game board 120 from the front side of the game board 120 with the post-display base 84 in a state where the device housing 2 is detached from the indicator light structure 7. The flange 91 is brought into contact with the front surface of the game board 120, and a set screw 122 such as a wood screw penetrates the mounting hole 93 (see FIG. 4) from the front side of the flange 91 to the game board 120. The indicator light structure 7 is attached to the game board 120 after being fastened. As a result, the base 86 before display protrudes forward from the front surface of the game board 120, the lens 87 is disposed away from the front side of the rotary display structure 3, and the lens 87 is disposed parallel to the front side from the symbol display body 6. Is done. Although not shown, game parts such as winning parts, a large number of game nails, and decorative parts are attached to the front surface of the game board 120.

  And the game board 120 is attached to a gaming machine frame (not shown) attached to a gaming machine installation structure called an island of a pachinko store, and the front door called a panel frame in the gaming machine frame is closed, so that the front and rear of the front door A colorless front panel 123 having a property of transmitting light such as glass covering a window as a through hole in a direction is disposed on the front side of the front surface of the game board 120. The front panel 123 is separated from the front surface of the game board 120 and the base 86 before display. A space 124 formed between the front panel 123 and the front surface of the game board 120 is located along the front surface of the game board 120 with a ball 125 called a pachinko ball that the player has launched to win the winning component. A region that flows downward from the bottom is formed. A gap 126 between the front panel 123 and the pre-display base 86 is a size through which the sphere 125 cannot pass. Therefore, the sphere 125 flowing down the space 124 is blocked by the pre-display base 86 and does not reach the front surface of the lens 87.

  After the indicator light structure 7 is attached to the game board 120 as described above, the device housing 2 in which the rotation drive mechanism 4 and the revolution drive mechanism 5 are assembled is attached to the indicator light structure 7 from the back side of the game board 120. . For this purpose, the display body accommodating portion 10 is directed toward the game board 120 and is covered on the back side of the indicator light structure 7, and the support shaft 18 is joined together with the center portion of the revolution driven wheel body 114 via the bearing hole portion 11. The sun shaft 21 is fixedly mounted so as to rotate together with a set screw 127 at the center of the rotation driven wheel body 107, and the set screw 101 is attached from the back side of the device housing 2. The device housing 2 is attached to the indicator lamp structure 7 by being fastened to the screw coupling hole 90 (see FIG. 4) of the attachment portion 89 via the screw insertion hole 102 (see FIG. 4).

  In the state where the game rotation display device 1 is attached to the game board 120 as described above, when the rotation motor 105 is driven by electric power, the power of the rotation motor 105 is transferred from the rotation motor shaft 109 to the rotation driving wheel body 106, the rotation belt 108, This is transmitted to the rotation display structure 3 via the rotation driven wheel body 107, the sun gear 19, the intermediate gear 20, and the planetary gear 13, and the rotation display structure 3 rotates about the display shaft 12 in the direction indicated by the arrow W1. . When the revolution motor 112 is driven by electric power, the power of the revolution motor 112 is transmitted from the revolution motor shaft 116 to the support structure 14 via the revolution driving wheel body 113, the revolution belt 115, and the revolution driven wheel body 114, and the rotation display structure. The body 3 revolves around the support shaft 18 in the direction indicated by the arrow W2. As shown in FIG. 3, the irradiation light X1 emitted from the indicator lamp 8 enters the inside of the rotating display structure 3 from the outside of the rotating display structure 3 via the light introducing portions 35 and 36 and is reflected by the reflector 9. The reflection surface 43 reflects the light. The reflected light X2 reflected by the reflecting surface 43 travels to the front side in parallel with the center line L2, and illuminates the symbol display body 6 from the inside of the rotation display structure 3 via the rotation display structure 3. Since the reflector 9 is configured in a conical shape having a conical reflection surface 43, the reflector 9 is illuminated more uniformly than when the reflector 9 is configured in a pyramid shape. There is an advantage that can be formed easily.

  With reference to FIG. 1, the structure in which the irradiation light X1 emitted from the indicator lamp 8 illuminates the symbol display body 6 from the inside of the rotary display structure 3 will be described. The rotation display structure 3 is stopped by the revolution drive mechanism 5 so that the four indicator lamps 8 are arranged at an angle of 30 degrees in the circumferential direction of the center line L1 of the display shaft 12 and the support structure 14, and the rotation display In a state where the structure 3 is rotated by the rotation driving mechanism 4, when the four indicator lamps 8 are turned on with electric power, the irradiation light X1 emitted from the four indicator lamps 8 passes through the light introducing sections 35 and 36. Then, the light enters the inside of the rotating display structure 3 and is individually reflected toward the front side by the reflecting surface 43 corresponding to the four indicator lamps 8 in the reflector 9. Therefore, the reflected light X2 reflected by the four reflecting surfaces 43 is diffused inside the rotating display structure 3 while being transmitted from the inside of the rotating display structure 3, and illuminates the symbol display body 6. Therefore, there is an advantage that the rotating display structure 3 and the symbol display body 6 are illuminated brightly and clearly as a whole, and a plurality of symbols displayed on the symbol display body 6 are easy to see.

  As described above, the rotation display structure 3 is rotated by the revolution drive mechanism 5 so that the four indicator lamps 8 are arranged at an angle of 30 degrees in the circumferential direction of the center line L1 of the display shaft 12 and the support structure 14. In the state where the rotation display structure 3 is rotated by the rotation drive mechanism 4, the light emitted from the two indicator lamps 8 arranged on the center line L3 orthogonal to the center line L1 in the plane is Since it is not possible to enter the inside of the rotating display structure 3 from the outside of the rotating display structure 3 via the light introducing portions 35; 36, the two indicator lamps 8 arranged on the center line L3 are turned off. . On the other hand, when the rotation display structure 3 is stopped from rotating by the rotation driving mechanism 4 and the rotation display structure 3 performs rotation by the revolution driving mechanism 5, all of the six indicator lamps 8 are the light introducing portions 35; Illuminating light from each of the four indicator lamps 8 from the outside of the rotating display structure 3 via the light introducing part 35; 3, the symbol display body 6 is entirely brightly and clearly illuminated by the reflected light from the reflector 9 inside the rotary display structure 3.

  As shown in FIGS. 2 and 3, a display base 85 made of a colored synthetic resin having a property of blocking light around the lens 87 and a pre-display base 86 made of a colored synthetic resin having a property of blocking light. In the state where the game rotation display device 1 is attached to the game board 120 as shown in FIG. 2, when the player views the game rotation display device 1 from the front side, the indicator lamp 8 is being displayed. There is an advantage that it cannot be hidden by the base 85 or the base 86 before display.

  A rotation position specimen (not shown) is integrally provided on the rotation driven wheel body 107. The rotation position specimen is a disk-like shape protruding radially outward from the rotation driven wheel body 107, and a plurality of slits for rotation position detectors outside the figure and rotation origin position detectors outside the figure are provided in the circumferential direction, etc. Have in minute position. A revolution position specimen (not shown) is integrally provided on the revolution driven wheel body 114. The revolution position specimen has a disk shape projecting radially outward from the revolution driven wheel body 114, and a plurality of slits for a revolution position detector outside the figure and a revolution origin position detector outside the figure are arranged in the circumferential direction, etc. Have in minute position. The rotation position detector, the rotation origin position detector, the revolution position detector, and the revolution origin position detector are attached to the device housing 2. The rotation position detector, the rotation origin position detector, the revolution position detector, and the revolution origin position detector are configured by a light transmission non-contact type detector that receives the detection light from the light emitting element by the light receiving element.

  The rotation driving wheel body 106, the rotation driven wheel body 107, and the rotation belt 108 may be constituted by a gear train including separate spur gears. In this case, the rotation driving wheel body 106 is considered as a rotation driving gear, the rotation driven wheel body 107 is considered as a rotation driven gear, and the rotation belt 108 is considered as a rotation intermediate gear meshing with the rotation driving gear and the rotation driven gear. The revolution driving wheel body 113, the revolution driven wheel body 114, and the revolution belt 115 may be constituted by a gear train composed of separate spur gears. In this case, the revolution driving wheel body 113 is considered as a revolution driving gear, the revolution driven wheel body 114 is considered as a revolution driven gear, and the revolution belt 115 is considered as a revolution intermediate gear meshing with the revolution driving gear and the revolution driven gear.

a figure is a cross-sectional view of a game rotation display device, b figure is a BB line sectional view (best form). The longitudinal cross-sectional view of the direction parallel to the display axis attached to the game board of a game rotation display apparatus (best form). The longitudinal cross-sectional view of the direction orthogonal to the display axis attached to the game board of a game rotation display apparatus (best form). The exploded perspective view of the game rotation display device (best mode). The exploded sectional view of the rotation display structure (best form). Sectional drawing of the assembly process of a rotation display structure (best form). Sectional drawing (best form) of the assembly initial stage of a rotation display structure and a symbol display body. Sectional drawing of the assembly | attachment final stage of a rotation display structure and a symbol display body (best form). The exploded perspective view of a rotation display structure and a planetary gear (best form). The disassembled perspective view of a display axis | shaft and a reflector (best form). a figure is an exploded perspective view of a rotation display structure and a support structure, and b figure is a perspective view showing the support piece from the inside (best mode). FIG. 4A is a side view of the support piece inserted into the arm, and FIG. b is a side view of the support piece engaged with the arm (best mode). The exploded perspective view of the indicator light structure (best form).

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Game rotation display apparatus 3 Rotation display structure 4 Autorotation drive mechanism 5 Revolution drive mechanism 6 Symbol display body 7 Indicator light structure 8 Indicator lamp 9 Reflector 12 Display axis 35 Light introduction part 36 Light introduction part

Claims (1)

A symbol display body displaying a plurality of symbols is provided on the outer surface of the spherical rotation display structure,
The rotation display structure is rotated by a rotation drive mechanism ,
A plurality of indicator lamps for illuminating the symbols, in the gaming rotating display device disposed outside the rotating display structure,
The rotating display structure has a display shaft that penetrates the center of the rotating display structure and has both ends projecting outward from a flat portion formed in the rotating display structure;
A reflector having a reflective surface formed in a conical shape and attached to the display shaft inside the rotating display structure;
A support structure that fixes the display shaft so as not to rotate, and is fitted into the rotation drive mechanism;
An indicator lamp structure that covers the rotating display structure and the plurality of indicator lamps are attached along a circumferential direction;
The rotating display structure is formed of a synthetic resin having the property of transmitting light,
The gap between the flat portion provided in the display axis constituting the center of rotation by the rotary drive mechanism and a symbol display member is introduced into the illumination light emitted from the indicator from the outside of the rotating display structure Configured as a light introduction part
The reflecting surface of the reflector, and wherein the benzalkonium be reflected as reflected light toward the symbol display member irradiated light introduced therein is provided on the rotating display structure of the rotating display structure from the light introducing portion Game rotation display device.

Images