JP5500306B1 - Revolving light device - Google Patents

Abstract

An object of the present invention is to efficiently collect light emitted from a light source on a first reflecting surface in a rotating lamp device having a first reflecting surface and a second reflecting surface.
A rotating lamp device 100 reflects light emitted from an LED 70 toward a first reflecting surface 130a and light reflected by the second reflecting surface by the first reflecting surface 130a and the first reflecting wall 130. The rotating lamp device emits from the inside to the outside of the second reflecting wall 140, and the second reflecting surface is convex to the opposite side of the first reflecting surface 130a in the front view with respect to the rotating opening 64 and the first reflecting surface. An arc-shaped third reflecting surface 150a that is smaller than the surface 130a and an outer side along the chord length direction of the third reflecting surface 150a from both side ends of the third reflecting surface 150a in a front view with respect to the rotary opening 64 And fourth linear reflecting surfaces 160a and 160a extending in a straight line.
[Selection] Figure 13

Description

  The present invention relates to a technology of a rotating lamp device.

  Conventionally, the technology of the rotating lamp device has been publicly known. Such a rotating lamp device includes a light source and a reflecting surface (reflecting member) that is configured to be rotatable around the light source and reflects light to the outside of the rotating lamp device. For example, as described in Patent Document 1.

  In the technique described in Patent Document 1, the rotating lamp device includes a light source, a first reflecting surface (first reflecting member) configured to be rotatable around the light source and reflecting light to the outside of the rotating lamp device. In addition, a second reflecting surface (second reflecting member) configured to be rotatable around the light source together with the first reflecting surface is disposed at a position facing the first reflecting surface across the light source. Has been established.

  With such a configuration, light traveling from the light source toward the opposite direction to the first reflecting surface is reflected by the second reflecting surface toward the first reflecting surface.

JP 2010-240060 A

  In the rotating lamp device described in Patent Document 1, in order to make the device emit light brightly, it is desirable to efficiently collect the light emitted from the light source onto the first reflecting surface.

  Then, this invention aims at condensing the light irradiated from the light source to a 1st reflective surface efficiently in the rotary lamp apparatus provided with the 1st reflective surface and the 2nd reflective surface.

  The problem to be solved by the present invention is as described above. Next, means for solving the problem will be described.

  That is, in claim 1, a light source for irradiating light, a rotary plate portion provided with an opening corresponding to the light source, and the opening provided on the rotary plate portion in front view with respect to the opening. A first reflecting wall having an arc-shaped first reflecting surface which is convex on the opposite side of the portion, and is provided on the rotating plate portion so as to face the first reflecting wall across the opening, and from the light source A second reflecting wall that has a second reflecting surface that reflects the irradiated light toward the first reflecting surface and that is shorter in the standing direction than the first reflecting wall, and rotates the rotating plate portion. A driving device for driving, the light reflected from the light source toward the first reflecting surface and the light reflected by the second reflecting surface reflected by the first reflecting surface and the first reflecting wall And the second reflecting wall, the second reflecting surface is a rotating lamp device that emits from the inside to the outside. An arcuate arc surface that is convex on the opposite side of the first reflecting surface in front view with respect to the opening and smaller than the first reflecting surface, and both ends of the arc surface in front view with respect to the opening And a linear extending surface extending outward along the chord length direction of the arc surface.

  As effects of the present invention, the following effects can be obtained.

  In the present invention, the rotating lamp device can efficiently collect the light emitted from the light source onto the first reflecting surface.

The front view which showed the whole structure of the game machine provided with the rotating light apparatus which concerns on one Embodiment of this invention. Similarly, the front perspective view which showed the state by which the window frame of the gaming machine was opened. Similarly, the front view which showed the game board. The rear perspective view which showed the rotating lamp apparatus which concerns on one Embodiment of this invention. Similarly, a rear view. Similarly, side view. Similarly, the AA arrow side surface sectional drawing in FIG. Similarly, a plan view. Similarly, the BB line arrow plane sectional view in FIG. Similarly, the plane cross-sectional schematic diagram which showed the arrangement configuration of a 1st reflective surface and a 2nd reflective surface (a 3rd reflective surface and a 4th reflective surface). Similarly, the side surface cross-section schematic diagram which showed the reflective path | route by the 1st reflective surface, the 3rd reflective surface, and the 4th reflective surface of the light irradiated from the light source. Similarly, the plane cross-sectional schematic diagram which showed the reflection path | route by the 3rd reflective surface of the light irradiated from the light source. Similarly, the plane cross-section schematic diagram which showed the reflective path | route by the 4th reflective surface of the light irradiated from the light source. The side surface cross-section schematic diagram which showed the reflective path | route of the light irradiated from the light source in the case of not having a 3rd reflective surface and a 4th reflective surface.

First, an overall configuration of a gaming machine 1 that is an embodiment of a gaming machine according to the present invention will be described with reference to FIGS.
In the following description, when the gaming machine 1 is viewed from the player, the front side is defined as the front side of the gaming machine 1 and the back side is defined as the rear side of the gaming machine 1 to define the front-rear direction. Further, when the gaming machine 1 is viewed from the player, the left and right directions are defined with the left hand side as the left side of the gaming machine 1 and the right hand side as the right side of the gaming machine 1.

  As shown in FIGS. 1 to 3, the gaming machine 1 is mainly formed by attaching various gaming parts to a frame constituted by an outer frame 2, an inner frame 3, and a window frame 4. The

  The outer frame 2 is a frame that forms an outline of the gaming machine 1 and is formed in a substantially rectangular tube shape with front and rear surfaces opened. The outer frame 2 is installed in Taijima provided in a game hall such as a pachinko hall. The outer frame 2 is provided with an intermediate frame 3.

  The middle frame 3 is a frame formed in a substantially rectangular tube shape with front and rear surfaces opened. The middle frame 3 is rotatably supported by a front opening of the outer frame 2 via a shaft support member such as a hinge. The middle frame 3 is provided with a window frame 4, a lower tray unit 5, and a game board 6.

  The window frame 4 is a frame formed in a substantially flat plate shape with an opening at the center. The window frame 4 is arranged over substantially the entire surface except for the lower part of the middle frame 3 in a front view. The window frame 4 is rotatably supported by a front opening of the middle frame 3 via a hinge member. A substantially circular window frame opening 7 is formed in the center of the window frame 4 in front view. The window frame opening 7 is covered with a transparent plate 19. In the lower part of the window frame opening 7, an upper plate 8 for storing game balls before launching is disposed. Speakers 9 are disposed above and to the left and right of the window frame opening 7.

  The lower dish unit 5 is attached to the lower part of the middle frame 3 and below the window frame 4. In the center of the lower plate unit 5, a lower plate 17 in which game balls overflowing from the upper plate 8 are stored is disposed. A firing handle 18 is disposed on the right side of the lower plate 17 on the right side of the lower plate unit 5. The launch handle 18 is configured to be able to launch game balls stored in the upper plate 8.

  The game board 6 is a member in which a game area 25 that is an area in which a game ball rolls is formed. The game board 6 is arranged behind the window frame 4 and over substantially the entire surface excluding the lower part of the middle frame 3 in a front view. The game board 6 is detachably attached to the middle frame 3. The game area 25 of the game board 6 is arranged behind the window frame opening 7 of the window frame 4 and is configured to be visible through the transparent plate 19 from the front.

  Next, the configuration of the game board 6 will be described in more detail with reference to FIG.

  As shown in FIG. 3, the game board 6 includes a game board 10, a guide rail 11, a center accessory 12, a symbol display device 13, a variable winning device 14, a big winning device 15, and an out port 16. The rotating lamp device 100 is configured.

  The game board 10 is a member formed in a substantially flat plate shape with four corners appropriately cut out. Various game parts constituting the game board 6 are attached to the game board 10.

  The guide rail 11 is a member formed in a substantially arc belt shape. The guide rail 11 is attached to the game board 10 in a rising shape toward the front. The guide rail 11 is disposed so as to form a substantially circular shape when viewed from the front. Note that an inner area formed in a substantially circular shape by the guide rail 11 in the game board 10 is configured as a game area 25 in which the game ball rolls.

  The center accessory 12 is a member that decorates the game board 10 by its appearance. The center accessory 12 is substantially annular when viewed from the front, and a center opening 27 is formed through the center in the front-rear direction. The center accessory 12 is inserted from the front into a hole formed from the center to the top of the game board 10 so as to penetrate the game board 10 in the front-rear direction, and is attached by a bolt or the like.

  The symbol display device 13 is a device configured to display changes (symbol game) such as symbols and numbers on the liquid crystal screen 26 arranged to face the front. The symbol display device 13 is disposed behind the game board 10. More specifically, the liquid crystal screen 26 of the symbol display device 13 is disposed behind the center opening 27 of the center accessory 12 attached to the game board 10. Thereby, the symbol game displayed on the liquid crystal screen 26 can be visually recognized from the front through the center opening 27.

  The variable winning device 14 opens and closes a pair of left and right movable pieces 28 in accordance with a predetermined operating condition, and an open state in which a game ball can enter (win) and a block that cannot enter (win) a winning. It is a device that can be switched to a state. The variable winning device 14 is arranged on the right side of the game area 25 and below the center accessory 12. The variable winning device 14 is configured such that a predetermined number of gaming balls (prize balls) are paid out by a winning ball payout device (not shown) when a game ball enters (wins) the start winning port 14a in the open state. The

  The big prize device 15 is an apparatus configured to open a big prize opening 15a and to allow a game ball to enter (win) when a big prize is selected by a predetermined lottery lottery. The big winning device 15 is arranged in the lower right portion of the game area 25 and in the lower left portion of the variable winning device 14. The big prize device 15 is configured such that when a game ball enters the opened big prize opening 15a, a predetermined number of game balls (prize balls) are paid out by a prize ball payout device (not shown).

  The out port 16 is an opening through which the game ball that rolls in the game area 25 will finally flow when the game ball that has rolled does not enter (win) each winning port such as the big winning port 15a and the starting winning port 14a. is there. The out port 16 is arranged at the lowermost part of the game area 25. Note that the game balls that have flowed into the out port 16 are collected at a game hall such as a pachinko hall in which the gaming machine 1 is installed.

  Next, the configuration of the rotating lamp device 100 will be described in detail.

  A rotating lamp device 100 shown in FIGS. 3 to 9 is a device for driving according to a symbol game displayed on the liquid crystal screen 26 and rotating the light to give a visual impression (impact) to the player. . As shown in FIG. 3, the rotating lamp device 100 is disposed at the center lower part of the game area 25 in front view and between the center accessory 12 and the out port 16. The rotating lamp device 100 mainly includes a base member 30, a driving device 40, a gear member 50, a rotating member 60, an LED 70, and a reflecting member 110.

  The base member 30 shown in FIGS. 4 to 9 is a member that is a main structure of the rotating lamp device 100. The base member 30 is provided with members constituting the rotating lamp device 100, such as the gear member 50, the rotating member 60, the reflecting member 110, and the like. The base member 30 mainly includes an outer peripheral wall portion 31 and a center support portion 32.

  The outer peripheral wall portion 31 of the base member 30 constitutes an outer wall (outer peripheral portion) of the base member 30. The outer peripheral wall part 31 is formed in a substantially cylindrical shape with the axial direction of the outer peripheral wall part being the vertical direction. A mounting plate portion 33 is disposed at the front lower portion of the outer peripheral wall portion 31. The mounting plate portion 33 is formed in a substantially flat plate shape with its plate surface directed in the vertical direction, and protrudes forward from the lower front portion of the outer peripheral wall portion 31. A plurality of attachment holes 36 are formed in the attachment plate portion 33 so as to penetrate in the vertical direction. The outer peripheral wall portion 31 (and thus the rotating lamp device 100) is attached to an appropriate attachment position of the game board 6 via screws (not shown) screwed into the plurality of attachment holes 36.

  A rear cutout 34 is formed in the outer peripheral wall 31 of the base member 30. As shown in FIG. 5, the rear notch 34 is formed by cutting the rear side surface of the outer peripheral wall portion 31 upward from the lower end portion into a substantially rectangular shape that is elongated in the left-right direction in the rear view.

  As shown in FIG. 7, the center support portion 32 of the base member 30 is disposed inside the outer peripheral wall portion 31 and substantially at the center in the vertical direction. The central support portion 32 extends from the inner peripheral surface of the outer peripheral wall portion 31 toward the center. A central opening 35 is formed in the center of the central support 32 so as to penetrate therethrough in the vertical direction. The central opening 35 is formed in a substantially cylindrical shape with a peripheral edge projecting in the vertical direction and having the axial direction as the vertical direction.

  A driving device 40 shown in FIG. 4 is a device for rotating the reflecting member 110. The drive device 40 is mainly composed of a motor 41 and a drive gear 42.

  The motor 41 of the driving device 40 is a driving source for rotating the reflecting member 110. The motor 41 is disposed below the base member 30. The driving force of the motor 41 is transmitted to the outside through the output shaft 43. The output shaft 43 protrudes upward from the upper side surface of the motor 41 with its axial direction as the vertical direction.

  The driving gear 42 of the driving device 40 is a spur gear to which the driving force from the motor 41 is transmitted. A gear is formed on the outer periphery of the drive gear 42. The drive gear 42 is disposed above the motor 41 with its plate surface directed in the vertical direction. At the center of the drive gear 42, the upper end portion of the output shaft 43 is fixed so as not to be relatively rotatable. The drive gear 42 is configured to be rotatable in the horizontal direction around the output shaft 43. The front gear of the drive gear 42 is arranged inside the outer peripheral wall portion 31 through the rear notch 34 of the outer peripheral wall portion 31 of the base member 30.

  The gear member 50 shown in FIGS. 4, 5, and 7 is a member to which the driving force from the driving device 40 is transmitted from the driving gear 42. The gear member 50 is mainly composed of a gear part 51 and a gear cylinder part 52.

  The gear part 51 of the gear member 50 is formed in a spur gear shape. A gear is formed on the outer periphery of the gear portion 51. The gear portion 51 is disposed on the inner side of the outer peripheral wall portion 31 and below the central support portion 32 with its plate surface directed in the vertical direction. In the center of the gear portion 51, a gear opening portion 54 is formed which is opened through in the vertical direction. The rear gear of the gear unit 51 is meshed with the front gear of the drive gear 42.

  The gear tube portion 52 of the gear member 50 is formed in a substantially cylindrical shape with the axial direction of the shaft member being the vertical direction. The gear cylinder portion 52 extends upward from the peripheral edge portion of the gear opening 54 of the gear portion 51. The gear cylinder portion 52 is formed so as not to rotate relative to the gear portion 51. The outer diameter of the gear tube portion 52 is formed slightly smaller than the inner diameter of the central opening 35 of the central support portion 32.

  Thus, the gear member 50 is formed in a convex shape that protrudes upward in a side view as a whole. Further, the gear member 50 has a gear through hole 53 (FIG. 7) that is provided with an inner peripheral surface of the gear tube portion 52 and a gear opening portion 54 of the gear portion 51 that are connected in the vertical direction and penetrates in a substantially cylindrical shape in the vertical direction. Reference) is formed.

  The rotating member 60 shown in FIG. 7 is a member to which the driving force from the driving device 40 is transmitted from the gear member 50. The rotating member 60 mainly includes a rotating plate part 61 and a rotating cylinder part 62.

  The rotating plate portion 61 of the rotating member 60 has a substantially flat plate shape whose plate surface is directed in the vertical direction, and is formed in a substantially annular shape. The rotating plate portion 61 is disposed inside the outer peripheral wall portion 31 and above the central support portion 32. More specifically, the rotating plate portion 61 is slidably mounted on the upper side surface of the peripheral edge portion of the central opening 35 of the central support portion 32. In the center of the rotating plate portion 61, a rotating opening portion 64 is formed that penetrates and opens in the vertical direction.

  The rotating cylinder portion 62 of the rotating member 60 is formed in a substantially cylindrical shape with the axial direction as the vertical direction. The rotary cylinder 62 extends downward from the peripheral edge of the rotary opening 64 of the rotary plate 61. The rotating cylinder portion 62 is formed so as not to rotate relative to the rotating plate portion 61. The outer diameter of the rotating cylinder portion 62 is formed slightly smaller than the inner diameter of the gear through hole 53 of the gear member 50.

  Thus, the rotating member 60 is formed in a convex shape that protrudes downward in a side view as a whole. Further, the rotary member 60 is provided with a rotary through hole 63 that is formed by connecting the rotary opening 64 of the rotary member 60 and the inner peripheral surface of the rotary cylinder portion 62 in the vertical direction and penetrating in a substantially cylindrical shape in the vertical direction. The

  Further, the rotating cylinder portion 62 of the rotating member 60 is inserted into the gear through hole 53 of the gear member 50 from above. The gear member 50 and the rotating member 60 are engaged with each other so that the shaft centers of the gear through hole 53 of the gear member 50 and the rotating through hole 63 of the rotating member 60 overlap with each other so that they cannot rotate relative to each other. Thus, the rotating member 60 and the gear member 50 are formed in a substantially H-shape that is opened in the lateral direction as viewed from the side.

  Further, a central support portion 32 (more specifically, a peripheral edge portion of the central opening 35) is interposed between the rotary plate portion 61 of the rotary member 60 and the gear portion 51 of the gear member 50. As described above, the rotating plate portion 61 of the rotating member 60 is slidably mounted on the upper side surface of the peripheral edge portion of the central opening 35. Therefore, the rotating member 60 and the gear member 50 are supported so as to be slidable (relatively rotatable) with respect to the central support portion 32.

  The LED 70 shown in FIGS. 5 to 9 is a member that serves as a light source of the rotating lamp device 100. LED70 is comprised so that light can be irradiated from the light emission surface 71. FIG. The LED 70 is disposed on the extension line of the axis of the rotation through hole 63 of the rotating member 60 below the gear member 50 with the light emitting surface 71 facing upward. The LEDs 70 are all housed inside the rotary through-hole 63 in plan view. With such a configuration, when light is irradiated from the LED 70 (more specifically, the light emitting surface 71 of the LED 70), the irradiated light is disposed above the rotating member 60 through the rotating through hole 63 of the rotating member 60. The reflecting member 110 can be irradiated.

The reflecting member 110 shown in FIGS. 4 to 9 is a member for reflecting the light emitted from the LED 70. The front side surface of the reflecting member 110 is subjected to metal plating such as aluminum, silver, or nickel. The reflecting member 110 is mainly composed of a reflecting wall base 120, a first reflecting wall 130, and a second reflecting wall 140.
The reflecting member 110 is configured to be rotatable in the horizontal direction. The arrangement configuration will be described based on the state shown in the drawing.

  The reflection wall base 120 is a member (base) that supports the first reflection wall 130 and the second reflection wall 140 from below. The reflection wall 120 is a substantially flat plate with its plate surface directed in the vertical direction, and is formed in a substantially annular shape. The reflecting wall base 120 covers the upper surface of the rotating plate portion 61 of the rotating member 60 and is engaged with the rotating plate portion 61 so as not to be relatively rotatable. At the center of the reflection wall base 120, a wall base opening 121 that is opened through in the vertical direction is formed. The wall opening 121 is formed so as to accommodate the entire rotation through hole 63 of the rotation member 60 in the plan view.

The first reflecting wall 130 includes an upper member formed in a substantially hemispherical shape whose lower side is open, and a lower member that is disposed below the upper member and is formed in a substantially cylindrical shape with the axial direction as the vertical direction. The upper half and the lower half are cut off from each other. The upper member with the rear half cut off is referred to as the upper member 131, and the lower member with the rear half cut off is referred to as the lower member 132.
The first reflecting wall 130 is erected upward (vertical direction) from the upper side surface of the reflecting wall base 120. The first reflecting wall 130 is disposed at the approximate center in the radial direction of the reflecting wall base 120 in plan view. The first reflecting wall 130 is arranged such that the axis of the lower member 132 is an extension line of the axis of the rotation through-hole 63 of the rotating member 60. The first reflecting wall 130 is connected to the reflecting wall base 120 so as not to be relatively rotatable.

  The first reflecting wall 130 has a first reflecting surface 130 a that reflects the light emitted from the LED 70. The first reflecting surface 130a is formed by the inner side surface (the rear side surface in the drawing) of the first reflecting wall 130. As shown in FIGS. 7 and 8, the first reflecting surface 130a (formed on the upper member 131) is formed so as to cover the LED 70 (more specifically, the front half of the LED 70). Further, as described above, the first reflecting wall 130 has the axis of the lower member 132 disposed on the extension line of the axis of the rotating through hole 63 of the rotating member 60, so that the first reflecting surface from the center of the LED 70 in plan view. The length up to 130a is a constant length. As a result, the amount of light emitted from the LED 70 to the first reflecting surface 130a is uniform in plan view.

  The second reflecting wall 140 is mainly composed of a third reflecting wall 150 and fourth reflecting walls 160 and 160.

  The third reflecting wall 150 is formed in a shape in which a substantially front half on the first reflecting surface 130a side of a member formed in a substantially cylindrical shape with its axial direction as the vertical direction is cut off. The third reflecting wall 150 is erected from the upper side surface of the reflecting wall base 120 upward (vertical direction). The height (length in the standing direction) of the third reflecting wall 150 is formed lower (shorter) than the height (length in the standing direction) of the first reflecting wall 130. More specifically, the height of the third reflecting wall 150 is formed lower (shorter) than the height of the lower member 132 of the first reflecting wall 130. The third reflecting wall 150 is disposed near the radial center of the reflecting wall base 120 in plan view. Further, the third reflecting wall 150 has the axis of the third reflecting wall 150 (the axis of the member formed in a substantially cylindrical shape before the front half is cut off) of the rotating through hole 63 of the rotating member 60. It is arranged on the extension line of the shaft center. The third reflecting wall 150 is connected to the reflecting wall base 120 so as not to be relatively rotatable.

  The third reflecting wall 150 has a third reflecting surface 150 a that reflects the light emitted from the LED 70. The third reflecting surface 150a is formed by the inner side surface (the front side surface in the drawing) of the third reflecting wall 150, and is disposed to face the first reflecting surface 130a with the LED 70 in plan view. The third reflecting surface 150a is formed in a substantially arc shape in which the first reflecting surface 130a side (front side) is opened (projects outward) in plan view (projection view in the standing direction). In addition, as described above, the third reflecting wall 150 has the axial center of the third reflecting wall 150 arranged on an extension line of the axial center of the rotation through-hole 63 of the rotating member 60. The length from the center to the third reflecting surface 150a is a constant length. As a result, the amount of light emitted from the LED 70 to the third reflecting surface 150a in a plan view is uniform.

  The fourth reflection walls 160 and 160 are formed in a substantially flat plate shape with its plate surface directed in the front-rear direction. The fourth reflection walls 160 and 160 are erected upward (vertical direction) from the upper side surface of the reflection wall base 120. Two fourth reflection walls 160 and 160 are provided, and are respectively disposed on the left and right sides of the third reflection wall 150 in the center in plan view. In addition, the height (length in the standing direction) of the fourth reflecting walls 160 and 160 is formed to be lower (shorter) than the height (length in the standing direction) of the first reflecting wall 130. More specifically, the height of the fourth reflection walls 160 and 160 is lower (shorter) than the height of the lower member 132 of the first reflection wall 130 and is formed to be the same as the height of the third reflection wall 150. The fourth reflecting walls 160 and 160 extend from the left and right ends of the third reflecting wall 150 in the left-right direction, and are connected to the left and right ends of the first reflecting wall 130, respectively. The fourth reflecting walls 160 and 160 are connected to the reflecting wall base 120 so as not to be relatively rotatable.

  The fourth reflection walls 160 and 160 have fourth reflection surfaces 160a and 160a that reflect the light emitted from the LEDs 70. The fourth reflective surfaces 160a and 160a are formed by the side surfaces (front side surfaces in the drawing) of the first reflective surfaces 130a of the fourth reflective walls 160 and 160. The fourth reflecting surfaces 160a and 160a are formed in a straight line in a plan view (projection view in the standing direction). Further, as shown in FIG. 10, the fourth reflecting surfaces 160 a and 160 a are arranged behind the LED 70. The fourth reflecting surfaces 160a and 160a are desirably arranged behind the center of the LED 70.

  As described above, the first reflecting wall 130, the third reflecting wall 150, and the fourth reflecting walls 160 and 160 are connected to each other, and are formed in a substantially cylindrical shape having upper and lower side surfaces opened in the vertical direction. Is done. Further, the lower opening is connected to the wall base opening 121 of the reflection wall base 120. In other words, the first reflecting wall 130, the third reflecting wall 150, and the fourth reflecting walls 160 and 160 are erected upward (perpendicular direction) from the peripheral edge of the wall base opening 121 of the reflecting wall base 120. Is done. As described above, all of the LEDs 70 are accommodated inside the rotary through hole 63 in plan view. That is, the first reflecting wall 130, the third reflecting wall 150, and the fourth reflecting walls 160 and 160 are continuously formed in a plan view to form an endless annular shape as a whole, and the rotating opening 64 of the rotating plate portion 61. (Around LED 70) is surrounded without a gap.

  Further, as shown in FIGS. 5 to 7, above the third reflecting wall 150 and the fourth reflecting walls 160 and 160, the height of the first reflecting wall 130 and the third reflecting wall 150 and the fourth reflecting wall are provided. The opening 133 is formed by the difference between the heights 160 and 160. The opening 133 is open at the rear end portion of the first reflecting wall 130 so as to face the rear. Then, the light irradiated by the LED 70 above the rotating member through the rotating through-hole 63 of the rotating member 60 passes through the wall base opening 121 of the reflecting wall base 120, the first reflecting wall 130, the third reflecting wall 150, and the fourth. After irradiating the inside of the reflecting walls 160 and 160, it is configured to be irradiated to the outside through the opening 133.

  Next, an operation mode of the rotating lamp device 100 will be described.

  First, when the motor 41 of the driving device 40 is driven, the driving force from the motor 41 is transmitted to the driving gear 42 via the output shaft 43. When the driving force is transmitted to the driving gear 42, the driving gear 42 rotates in the horizontal direction around the axis of the output shaft 43. The driving force transmitted to the driving gear 42 is then transmitted to the gear member 50 (see FIG. 4). The gear member 50 rotates in the horizontal direction around the axis of the gear through hole 53. The driving force transmitted to the gear member 50 is then transmitted to the rotating member 60. The rotating member 60 rotates in the horizontal direction around the axis of the rotating through hole 63. In addition, since the gear member 50 and the rotation member 60 are engaged so as not to be relatively rotatable, the gear member 50 and the rotation member 60 rotate integrally. The driving force transmitted to the rotating member 60 is then transmitted to the reflecting member 110. The reflecting member 110 has a reflecting wall 120 that is engaged with the rotating plate portion 61 of the rotating member 60 in a relatively non-rotatable manner, and rotates in the horizontal direction around the axis of the rotating through hole 63 of the rotating member 60.

  Thus, when the driving force from the motor 41 is transmitted, the reflecting member 110 rotates in the horizontal direction around the axis of the rotation through-hole 63 of the rotating member 60. That is, when the driving force of the motor 41 is transmitted, the first reflecting wall 130, the third reflecting wall 150, and the fourth reflecting walls 160 and 160 rotate around the LED 70 in plan view, and according to the rotation. Thus, the opening 133 is configured to rotate around the LED 70. When the LED 70 is irradiated while the motor 41 of the driving device 40 is driven, the light irradiated to the outside through the opening 133 can be rotated in the horizontal direction by the rotation of the opening 133.

  Next, the reflection path of the light irradiated from the LED 70 by the reflection surfaces 130a, 150a, and 160a will be described in detail.

  First, the arrangement configuration of the first reflecting surface 130a, the third reflecting surface 150a, and the fourth reflecting surfaces 160a and 160a will be described in more detail with reference to FIG.

The third reflecting surface 150a is disposed to face the first reflecting surface 130a with the LED 70 interposed therebetween in plan view. More specifically, the third reflecting surface 150a is a first reflecting surface that extends on a straight line connecting the left end 151 of the third reflecting surface 150a and the center point C of the LED 70 in plan view. A surface between point X of the reflective surface 130a and point Y of the first reflective surface 130a that is an extension of a straight line connecting the right end 152 of the third reflective surface 150a and the center point C of the LED 70 in plan view. The LED 70 is disposed opposite to the LED 70.
In the following description, a region of the first reflecting surface 130a where the surface disposed opposite to the third reflecting surface 150a with the LED 70 in plan view is disposed is referred to as a first reflecting surface central region α1.

  Unlike the third reflection surface 150a, the fourth reflection surfaces 160a and 160a are not arranged to face the first reflection surface 130a with the LED 70 in plan view. Therefore, the first reflective surface 130a is a surface facing the third reflective surface 150a and the fourth reflective surfaces 160a and 160a across the LED 70 (that is, the first reflective surface 130a shown in FIG. X and the inner surface of the point Y) and non-opposing surfaces (that is, the surface on the left side of the point Y and the surface on the right side of the point X in the first reflecting surface 130a shown in FIG. 10). It becomes. In the following, in the first reflecting surface 130a shown in FIG. 10, the region where the surface on the left side from the point Y and the surface on the right side from the point X are arranged are referred to as first reflecting surface edge side regions β1 and β1. That is, the first reflecting surface edge side regions β1 and β1 are regions disposed on both the left and right sides of the first reflecting surface central region α1, respectively.

  Next, with reference to FIG. 11, a detailed description will be given of a reflection path of the light irradiated from the LED 70 in the side view by the reflection surfaces 130a, 150a, and 160a.

  When light is irradiated from the LED 70, the irradiated light travels upward while expanding (diffusing) the irradiation range (length in the left-right direction in the drawing). In the following description, as shown in FIG. 11, with respect to the irradiation range of the LED 70, the front side range (region) from the center of the LED 70 is the front side irradiation region F, and the rear side range (region) from the center of the LED 70 is the rear side. This is referred to as an irradiation area B.

  The irradiated light in the front irradiation region F (for example, the irradiation light A2 shown in FIG. 11) is reflected by the first reflecting surface 130a of the first reflecting wall 130 and passes through the opening 133 and the first reflecting wall 130 and the first reflecting wall 130a. The light is emitted from the inside of the third reflection wall 150 and the fourth reflection walls 160 and 160 to the outside.

  On the other hand, the light irradiated in the rear irradiation region B (for example, the irradiation light A1 shown in FIG. 11) is first moved to the first reflection surface 130a side by the third reflection surface 150a or the fourth reflection surfaces 160a and 160a. Reflected towards. The light reflected toward the first reflecting surface 130a is reflected by the first reflecting surface 130a of the first reflecting wall 130, and the first reflecting wall 130, the third reflecting wall 150, and the fourth through the opening 133. The light is emitted from the inside of the reflection walls 160 and 160 to the outside.

  With such a configuration, the first reflecting surface 130a is reflected not only by the light directly irradiated from the LED 70 but also by indirectly irradiated light (the third reflecting surface 150a and the fourth reflecting surfaces 160a and 160a). Light) can be collected and reflected through the opening 133 from the inside of the first reflecting wall 130, the third reflecting wall 150, and the fourth reflecting walls 160 and 160 outward. Therefore, as shown in FIG. 14, for example, the amount of light reflected from the first reflecting surface 130a to the outside may be increased as compared with a case where the third reflecting surface 150a and the fourth reflecting surfaces 160a and 160a are not provided. Yes (can emit bright light).

Next, with reference to FIG. 12 and FIG. 13, the reflection path of the light irradiated from the LED 70 in plan view by the reflection surfaces 150a and 160a will be described in detail.
12 and 13 are diagrams mainly illustrating the reflection path by the third reflection surface 150a or the fourth reflection surfaces 160a and 160a, omitting the reflection path by the first reflection surface 130a.

  First, as shown in FIG. 12, when light is irradiated onto the third reflecting surface 150a by the LED 70, the light reflected by the third reflecting surface 150a (for example, the irradiated light B1, B2,. B3) is reflected toward the first reflecting surface 130a disposed opposite to the third reflecting surface 150a with the LED 70 interposed therebetween, that is, toward the first reflecting surface central region α1 side.

  With such a configuration, in the first reflecting surface central region α1, not only the light directly irradiated from the LED 70 but also the indirectly irradiated light (light reflected by the third reflecting surface 150a) is collected. The light can be reflected from the inside of the first reflecting wall 130, the third reflecting wall 150, and the fourth reflecting walls 160 and 160 from the inside through the opening 133 toward the outside. In other words, if there is no third reflecting surface 150a, light that is not reflected toward the first reflecting surface 130a but leaks to the outside, specifically, light that is irradiated to the region α2 side shown in FIG. Can be efficiently condensed on the first reflecting surface 130a (more specifically, the first reflecting surface central region α1) to increase the amount of light reflected from the first reflecting surface 130a to the outside (brighter). Can emit light).

  Next, as shown in FIG. 13, when the LED 70 irradiates the fourth reflective surfaces 160a and 160a with light, the light reflected by the fourth reflective surfaces 160a and 160a (as an example, the irradiation shown in FIG. 13). The light C1 and C2) is reflected toward the first reflecting surface 130a side that is not disposed to face the fourth reflecting surfaces 160a and 160a with the LED 70 interposed therebetween, that is, toward the first reflecting surface edge side region β1 and β1 side. The

  With such a configuration, in the first reflecting surface edge side regions β1 and β1, not only light directly irradiated from the LED 70 but also indirectly irradiated light (reflected by the fourth reflecting surfaces 160a and 160a). Light) can be collected and reflected through the opening 133 from the inside of the first reflecting wall 130, the third reflecting wall 150, and the fourth reflecting walls 160 and 160 outward. In other words, if there are no fourth reflecting surfaces 160a and 160a, the light that is not reflected toward the first reflecting surface 130a but leaks to the outside, specifically, the region β2 shown in FIG. 13 is irradiated. The collected light is efficiently condensed on the first reflecting surface 130a (more specifically, the first reflecting surface edge side regions β1 and β1), and the amount of light reflected from the first reflecting surface 130a to the outside is increased. (Can emit light brightly).

  In addition, with this configuration, light other than the light irradiated on the first reflecting surface 130a out of the light irradiated from the LED 70 is not leaked first by the third reflecting surface 150a and the fourth reflecting surfaces 160a and 160a. It can reflect toward the reflective surface 130a. Therefore, the light emitted from the LED 70 is not reflected by the first reflecting surface 130a, and it is difficult for the light to escape from the inside of the first reflecting wall 130, the third reflecting wall 150, and the fourth reflecting walls 160 and 160 outward. Thus, the amount of light that is efficiently condensed on the first reflective surface 130a and reflected from the first reflective surface 130a to the outside can be increased (light can be emitted brightly).

  Also, with such a configuration, not only the central portion (first reflective surface central region α1) of the first reflective surface 130a but also the edge portion (first first surface of the first reflective surface 130a) of the first reflective surface 130a. Even in the reflection surface edge side regions β1 and β1), the light reflected by the third reflection surface 150a and the fourth reflection surfaces 160a and 160a can be collected. That is, the light reflected from the third reflecting surface 150a and the fourth reflecting surfaces 160a and 160a can be collected over the entire first reflecting surface 130a, and the light reflected by the first reflecting surface 130a (the bright part). The difference between the dark portion and the dark portion is unlikely to occur.

  The rotating lamp device 100 is an embodiment of the “rotating lamp device” according to the present invention. The LED 70 is an embodiment of a “light source” according to the present invention. The rotating plate 61 is an embodiment of the “rotating plate” according to the present invention. The rotary opening 64 is an embodiment of the “opening” according to the present invention. The first reflecting wall 130 is an embodiment of the “first reflecting wall” according to the present invention. The first reflecting surface 130a is an embodiment of the “first reflecting surface” according to the present invention. The second reflecting wall 140 is an embodiment of the “second reflecting wall” according to the present invention. The third reflecting wall 150 is an embodiment of the “third reflecting wall” according to the present invention. The fourth reflection walls 160 and 160 are an embodiment of the “fourth reflection wall” according to the present invention. The third reflecting surface 150a and the fourth reflecting surfaces 160a and 160a are embodiments of the “second reflecting surface”, the “third reflecting surface”, and the “fourth reflecting surface” according to the present invention.

  In the present embodiment, the second reflecting wall 140 (the third reflecting wall 150 and the fourth reflecting wall 160, 160) is erected in the vertical direction, but is not limited to the vertical direction. That is, the second reflecting wall 140 (the third reflecting wall 150 and the fourth reflecting wall 160, 160) may be inclined in the front-rear direction.

As described above, the rotating lamp device 100 is
LED 70 (light source) that emits light;
A rotating plate 61 provided with a rotating opening 64 corresponding to the LED 70 (light source);
A first reflecting wall 130 that has a first reflecting surface 130a that reflects light emitted from the LED 70 (light source) and is erected on the rotating plate 61;
A third reflecting surface 150a and a fourth reflecting surface 160a, 160a (second) are arranged opposite to the first reflecting wall 130 with the LED 70 (light source) interposed therebetween, and reflect light emitted from the LED 70 (light source). A second reflecting wall that has a reflecting surface and is erected on the rotating plate portion 61 and is shorter than the first reflecting wall 130 in the standing direction from the LED 70 (light source). 140,
A driving device 40 for rotating the rotating plate portion 61,
The first reflecting wall 130 and the second reflecting wall 140 surround the rotary opening 64 without any gaps,
The light applied to the first reflecting surface 130a is reflected by the first reflecting surface 130a and is formed by a difference in length between the first reflecting wall 130 and the second reflecting wall 140 in the standing direction. Exiting from the inside of the first reflecting wall 130 and the second reflecting wall 140 through the opening 133,
The light applied to the third reflecting surface 150a and the fourth reflecting surface (second reflecting surface) is reflected toward the first reflecting surface 130a.

The rotating lamp device 100 is
The light applied to the third reflecting surface 150a is reflected toward the first reflecting surface central region α1 that faces the third reflecting surface 150a and the LED 70 (light source) across the first reflecting surface 130a. ,
The light applied to the fourth reflection surfaces 160a and 160a is the first reflection surface other than the first reflection surface central region α1 that faces the third reflection surface 150a and the LED 70 (light source) across the first reflection surface 130a. It is reflected toward the one reflecting surface edge side region β1 · β1.

The rotating lamp device 100 is
The third reflecting surface 150a is disposed facing the first reflecting surface 130a with the LED 70 (light source) interposed therebetween, and has an arc shape that is convex outward in a projected view in the standing direction.
The fourth reflecting surfaces 160a and 160a are arranged on both sides of the third reflecting surface 150a in the center in a projected view in the standing direction and are linear.

  With such a configuration, the rotating lamp device 100 can efficiently collect light emitted from the LED 70 onto the first reflecting surface 130a and emit light more brightly.

  1: gaming machine, 61: rotating plate, 64: rotating opening, 70: LED, 100: rotating lamp device, 130: first reflecting wall, 130a: first reflecting surface, 133: opening, 140: second Reflecting wall, 150: third reflecting wall, 150a: third reflecting surface, 160: fourth reflecting wall, 160a: fourth reflecting surface, α1: first reflecting surface central region, β1: first reflecting surface edge side region

Claims (1)

A light source that emits light;
A rotating plate portion provided with an opening corresponding to the light source;
A first reflecting wall that is erected on the rotating plate and has an arc-shaped first reflecting surface that is convex on the opposite side of the opening in front view with respect to the opening;
While having a second reflection surface that is erected on the rotating plate portion so as to face the first reflection wall across the opening and reflects light emitted from the light source toward the first reflection surface, A second reflecting wall having a shorter length in the standing direction than the first reflecting wall;
A driving device for rotating the rotating plate portion,
The light irradiated from the light source toward the first reflecting surface and the light reflected by the second reflecting surface are reflected by the first reflecting surface to be inside the first reflecting wall and the second reflecting wall. A rotating lamp device that emits from the outside,
The second reflecting surface is convex on the opposite side to the first reflecting surface when viewed from the front with respect to the opening, and is smaller than the first reflecting surface, and a front view with respect to the opening. And a linearly extending surface extending outwardly from both end portions of the arc surface along the chord length direction of the arc surface.

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