JP2010003708A - False rotating light - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a false rotating light capable of rotating display without using a motor. <P>SOLUTION: The false rotating light (1) is provided with a support body (7) formed in a cylindrical shape having a convex surface of its front face side and its axis nearly perpendicular, light emitting groups (12) consisting of a plurality of light-emitting bodies (11) arrayed in nearly parallel with the axis of the support body (7) and installed at prescribed spacings along a circular circumference of the support body (7) on the convex surface of that (7), and a control device (14) to control lighting and turning-off of each light-emitting body (11). Each light-emitting group (12) is formed so that luminance of the light-emitting body (11) arranged at a center part is higher than those arranged at end parts. The control device (14) carries out control of lighting and turning-off of each light-emitting body (11) for one light-emitting group (12) sequentially to another light-emitting group (12). <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  In the present invention, a plurality of light emitting groups are provided on the outer peripheral surface of the support body at predetermined intervals along the circumference of the support body, and the light emitting group includes a plurality of light emitting bodies arranged substantially parallel to the axis of the support body. More specifically, the present invention relates to a pseudo-rotating lamp that can be rotated and displayed without using a motor by sequentially performing control for turning on and off each light emitter for each light emitting group on adjacent light emitting groups. Is.

  A conventional rotating lamp includes a light emitter fixedly installed, a reflector for reflecting light from the light emitter to be emitted to the surroundings, a motor for rotating the reflector, a light emitter and a reflector. What is provided with the colored transparent cover to cover is known.

JP-A-6-314509

However, since the rotating lamp as described above requires a motor for rotating the reflecting plate, it has been difficult to reduce the size. Further, since the motor is driven, there is a problem that power consumption is large. Further, there has been a problem that a motor and a rotating part for rotating the reflecting plate are broken due to long-term use.
Therefore, the present invention has been made in view of the above-described problems, and an object of the present invention is to provide a rotating lamp that does not use a motor.

(First invention)
(Feature point)
The first invention relates to a pseudo rotating lamp (1), which is a cylindrical support (7) and a predetermined interval along the circumference of the support (7) on the outer peripheral surface of the support (7). A plurality of light emitting groups (12) provided with a plurality of light emitters (11) arranged in parallel with the axis of the support (7), and adjacent light emitting groups on the outer peripheral surface of the support (7) (12), each provided between the partition (13) formed in a plate-like shape extending substantially parallel to the axis of the support (7), and control for controlling the lighting and extinction of each light emitter (11) A control device (14), and the control device (14) sequentially controls the adjacent light emitting groups (12) to turn on and off each light emitter (11) for each light emitting group (12). It is formed.

The “pseudo rotating lamp (1)” is used for notifying the operation state of the machine and the like.
The “support (7)” is for supporting a plurality of light emitters (11) in an arrayed state. The support (7) is formed in a cylindrical shape. Specifically, for example, a flexible substrate bent into a cylindrical shape can be used.
Examples of the “light emitter (11)” include a light bulb and a light emitting diode.
The “light emitting group (12)” is composed of a plurality of light emitters (11) arranged on the outer peripheral surface of the support (7) substantially in parallel with the axis of the support (7). A plurality of light emitting groups (12) are provided on the outer peripheral surface of the support (7) at predetermined intervals along the circumference of the support (7).

The “partition plate (13)” is provided between adjacent light emitting groups (12) on the outer peripheral surface of the support (7). The partition plate (13) is formed in a plate shape extending substantially parallel to the axis of the support (7).
The “control device (14)” is configured to sequentially perform control for turning on and off each light emitter (11) for each light emitting group (12) on the adjacent light emitting group (12).
Specifically, for example, after a predetermined time has elapsed since the light emitters (11) of the set of light emitting groups (12) are turned on, the light emitters (11 of the light emitting groups (12) that are turned on are turned on. ) Is turned off, and the light emitters (11) of the light emitting group (12) on the left side of the light emitting group (12) are turned on. Then, after a lapse of a predetermined time after lighting each light emitter (11) of the left light emitting group (12), each light emitter (11) of the light emitting group (12) adjacent to the left lighted Is turned off, and each light emitter (11) of the light emitting group (12) on the left side of the light emitting group (12) is turned on. In this way, by sequentially blinking the light emitters (11) of the light emitting group (12) on the left on the left side, the reflector, like a conventional rotating lamp, rotates around the light emitter, An illusion can be given to the viewer as if the light from the illuminant is reflected.

  Further, each light emitter (11) of the adjacent light emitting group (12) may be blinked sequentially so that each light emitter (11) of one set of light emitting group (12) is turned on, or a plurality of sets of light emitting devices (11) The light emitters (11) of the adjacent light emitting groups (12) may be sequentially blinked so that the light emitters (11) of the group (12) are turned on simultaneously. Specifically, for example, after a predetermined time has elapsed since the light emitters (11) of the set of light emitting groups (12) are turned on, the light emitting group (12) on the left side of the light emitting group (12) Each light emitter (11) is turned on. Then, after a predetermined time has elapsed since the light emitters (11) of the light emitting group (12) on the left are turned on, the light emitters (11) of the light emitting groups (12) that were initially turned on are turned off. In addition, the light emitters (11) of the light emitting group (12) on the left side of the light emitting group (12) on the left side are turned on. In this way, the light emitters (11) of the two sets of light emitting groups (12) can be turned on at the same time and can be blinked so as to flow sequentially.

Note that the light emitters (11) of the light emitting group (12) on the left side may be blinked sequentially, or the light emitters (11) of the light emitting group (12) on the right side may be blinked sequentially.
(Second invention)
(Feature point)
In the second invention, in addition to the features of the first invention, the support (7) is provided so that the axis is substantially vertical, and the light emitter (11) located on the back side of the support (7). ) Is smaller than the number of light emitters (11) located on the front side of the support (7).
Here, the “front side” means the front side of the pseudo rotating lamp (1) as viewed from the viewer facing the front of the pseudo rotating lamp (1). Further, the “back side” means the back side of the pseudo rotating lamp (1) viewed from the viewer facing the front of the pseudo rotating lamp (1).

Further, a smaller number of light emitters (11) are provided on the back side of the support (7) than on the front side of the support (7).
Specifically, for example, the number of light emitters (11) of each light emitting group (12) located on the back side of the support (7) is equal to the number of light emitting groups (12) located on the front side of the support (7). ) May be formed to be smaller than the number of light emitters (11). Further, the number of light emitting groups (12) located on the back side of the support (7) is set to be smaller than the number of light emitting groups (12) located on the front side of the support (7). May be.
As described above, the number of light emitters (11) located on the back side of the support (7) is smaller than the number of light emitters (11) located on the front side of the support (7). When the light emitter (11) located on the back side of the support (7) is turned on, it appears darker than when the light emitter (11) located on the front side of the body (7) is turned on. become. Therefore, an illusion can be given to the viewer as if the reflecting mirror is reflecting the light of the light emitter to the back side like a conventional rotating lamp.

(Third invention)
(Feature point)
The third invention relates to a pseudo-rotating lamp (1), which has a convex surface on the front side, a support body (7) formed in a semi-cylindrical shape with a substantially vertical axis, and a convex surface of the support body (7). A plurality of light emitting groups (12) each including a plurality of light emitters (11) arranged at a predetermined interval along the circumference of the support (7) and arranged substantially parallel to the axis of the support (7); A partition plate (13) formed between the adjacent light emitting groups (12) on the convex surface of the support (7) and extending substantially parallel to the axis of the support (7); and And a control device (14) for controlling the lighting and extinguishing of the light emitters (11), and the control device (14) supports the control of turning on and off each of the light emitters (11) for each light emitting group (12). From the first light emitting group located on one side end side of the body (7) to the last light emitting group located on the other side end side, it was formed so as to be sequentially performed on the adjacent light emitting group (12). Features.

The “support (7)” is for supporting a plurality of light emitters (11) in an arrayed state. The support (7) is formed in a semi-cylindrical shape. Specifically, for example, a flexible substrate bent into a semicylindrical shape can be used.
The pseudo-rotating lamp (1) is installed such that the convex surface of the support (7) faces the front side.
The “light emitting group (12)” is composed of a plurality of light emitters (11) arranged on the convex surface of the support (7) in parallel with the axis of the support (7). In addition, a plurality of light emitting groups (12) are provided on the convex surface of the support at predetermined intervals along the circumference of the support.

The “first emission group” is the emission group (12) on the side where one side end of the support (7) is located and the lighting of the light emitter (11) is started.
The “final light emission group” is the light emission group (12) located on the side end side of the support (7) opposite to the first light emission group. That is, when the light emitting group (12) located on the right end side is the first light emitting group, the left light emitting group (12) is the final light emitting group, and the left light emitting group (12) is the first light emitting group. In this case, the light emitting group (12) on the right end side is the final light emitting group.
The `` control device (14) '' controls each light emitter (11) to be turned on and off for each light emitting group (12) from the first light emitting group located on one side end side of the support (7) to the other. These are formed so as to be sequentially performed on the adjacent light emitting groups (12) up to the final light emitting group located on the side end side.

  Specifically, for example, after a predetermined time has elapsed since the light emitters (11) of the first light emission group located on the right end side are turned on, the light emitters (11) of the first light emission group that are turned on Is turned off, and the light emitters (11) of the light emitting group (12) adjacent to the left of the first light emitting group are turned on. Next, after a predetermined time has elapsed since the light emitters (11) of the left adjacent light emitting group (12) are turned on, the light emitters (11) of the left adjacent light emitting group (12) are turned on. Is turned off, and each light emitter (11) of the light emitting group (12) on the left side of the light emitting group (12) is turned on. In this way, from the first light emission group to the last light emission group, by sequentially flashing each light emitter (11) of the light emission group (12) on the left side so as to flow, a reflector such as a conventional rotating lamp can be obtained. An illusion can be given to the viewer as if the light from the light emitter is reflected while rotating around the light emitter.

(Fourth invention)
(Feature point)
In the fourth aspect of the invention, in addition to the features of the third aspect of the invention, the control device (14) allows the first emission group after the predetermined period of time has elapsed since the light emitters (11) of the final emission group were turned off. Each of the light emitters (11) is formed to start lighting.
When the `` control device (14) '' blinks each light emitter (11) of the next light emission group (12) sequentially from the first light emission group and blinks each light emitter (11) of the last light emission group, the first light emission group again. It is formed so as to blink from each light emitter (11) of the light emitting group. At this time, there is a predetermined time lag between the time when each light emitter (11) of the last light emitting group is turned off and the time when each light emitter (11) of the first light emitting group is turned on.

Specifically, the `` predetermined time after turning off each light emitter (11) of the last light emitting group '' means, for example, after turning on each light emitter (11) of the first light emitting group, The time required to turn off each light emitter (11) can be set to substantially the same time.
In this way, by providing a predetermined time lag from the time when each light emitter (11) of the last light emitting group is turned off to the time when each light emitter (11) of the first light emitting group is turned on, it is like a conventional rotating lamp. In addition, it is possible to make the viewer have an illusion as if the reflecting mirror reflects the light of the light emitter to the back side.
(Fifth invention)
(Feature point)
In the fifth invention, in addition to the features of any one of the first to fourth inventions, each light emitting group (12) is arranged such that the luminance of the light emitter (11) arranged at the center is arranged at the end. It is characterized by being formed so as to be larger than the luminance of the luminous body (11).

Here, the light emitting group (12) is provided with a high-luminance light emitter (11) in the central portion, and the light emitting body (11) having a lower luminance than the light emitter (11) disposed in the central portion at the end portion. May be formed so that the luminances of the respective light emitters (11) are different.
Also, using the same type of illuminant (11), the luminance of the illuminant (11) disposed at the center of the luminescent group (12) is greater than the luminance of the illuminant (11) disposed at the end. As such, the control device (14) may be configured to adjust the light emission of each light emitter (11).
Thus, by increasing the luminance of the light emitter (11) disposed in the center of each light emitting group (12) and lowering the luminance of the light emitter (11) disposed at the end, a pseudo rotating lamp When the luminous body (11) of (1) is turned on, the central portion of the pseudo rotating lamp (1) appears brighter than the end portion. Therefore, it is possible to make an illusion of the viewer as if the reflecting mirror is reflecting the light of the light emitter while rotating around the single light emitter, such as a conventional rotating lamp.

(Sixth invention)
(Feature point)
In the sixth invention, in addition to the features of any one of the first to fifth inventions, each light emitting group (12) is arranged such that the density of the light emitter (11) arranged at the center is arranged at the end. It is characterized by being formed so as to be higher than the density of the luminous body (11).
In other words, in the central portion of the light emitting group (12), the interval between the light emitters (11) adjacent in the axial direction of the support body is arranged to be narrow, and at the end portion, the light emitter adjacent in the axial direction of the support body. It is arranged so that the interval of (11) is wide.

Thus, by increasing the density of the light emitters (11) arranged at the center of each light emitting group (12) and lowering the density of the light emitters (11) arranged at the ends, the pseudo rotating lamp When the luminous body (11) of (1) is turned on, the central portion of the pseudo rotating lamp (1) appears brighter than the end portion. Therefore, it is possible to make an illusion of the viewer as if the reflecting mirror is reflecting the light of the light emitter while rotating around the single light emitter, such as a conventional rotating lamp.
(Seventh invention)
(Feature point)
The seventh invention is characterized in that, in addition to the features of any one of the first to sixth inventions, the partition plate (13) is formed so as to be light-transmissive but not transparent.

Specifically, for example, a semi-transparent material formed into a plate shape, a transparent material formed into a plate shape, and the surface of which is matted can be used for the partition plate (13). .
In this way, the partition plate (13) transmits the light from the light emitter (11), so that a reflector like the conventional rotating lamp reflects the light from the light emitter while rotating around the light emitter. It can make the viewers have the illusion.
(Eighth invention)
(Feature point)
The eighth invention is characterized in that, in addition to the features of the seventh invention, the partition plate (13) is formed so as to have the highest light transmittance at the center.

In this way, by making the light transmittance at the center of the partition plate (13) the highest, a reflector such as a conventional rotating lamp rotates around the single light emitter, and the light of the light emitter It is possible to make an illusion of the viewer as if it were reflecting.
(9th invention)
In the ninth aspect of the invention, in addition to the features of any of the first to eighth aspects, the periphery of the support (7), the light emitting group (12), and the partition plate (13) is transparent but transparent. It is characterized by being covered with a non-covered cylindrical cover (4).
`` Light-transmissive but not transparent cover (4) '' means that the light of the light emitter (11) is transmitted, but the support (7) inside the cover (4), the light emitting group (12) and the partition plate ( The cover (4) is formed so that the structure of (13) cannot be seen.

Specific examples of the “covered cylindrical cover (4)” include a hemispherical cover and a cylindrical cover.
Thus, the light of the light emitter (11) is transmitted, but the cover (4) so that the structure of the support (7), the light emitting group (12), and the partition plate (13) inside the cover (4) cannot be seen. By forming the illusion, the viewer can have an illusion as if the reflecting mirror is reflecting the light of the light emitter while rotating around the light emitter, like a conventional rotating lamp.

(First invention)
According to the first invention, the pseudo-rotating lamp includes a plurality of light emitting groups provided at predetermined intervals along the circumference of the support body on the outer peripheral surface of the cylindrical support body. Each light emitter blinks. Thereby, the pseudo revolving light can make an illusion to the viewer as if the reflecting mirror is reflecting the light of the light emitter while rotating around the light emitter, like a conventional revolving light. Therefore, since the pseudo rotating lamp does not require a motor for rotating the reflecting plate, it can be reduced in size and power consumption can be reduced. Moreover, since the pseudo-rotating lamp does not have a motor or a rotating part for rotating the reflecting plate, the malfunction can be reduced even if it is used for a long time.

(Second invention)
According to the second invention, in the pseudo rotating lamp, the number of light emitters located on the back side of the support is smaller than the number of light emitters located on the front side of the support. Thereby, since the number of the light-emitting bodies provided in the back side of a support body can be reduced, while being able to reduce a number of parts, power consumption can further be reduced. In addition, since it looks darker when the light emitter located on the back side of the support is turned on than when the light emitter located on the front side of the support is turned on, like a conventional rotating lamp, An illusion can be given to the viewer as if the reflecting mirror is reflecting the light of the illuminant to the back side, and the pseudo-rotation lamp can be enhanced.

(Third invention)
According to the third invention, the pseudo rotating lamp includes a plurality of light emitting groups provided at predetermined intervals along the circumference of the support on the convex surface of the support, and is sequentially adjacent from the first light emitting group to the last light emitting group. Each light emitter of the light emitting group blinks. Thereby, the pseudo revolving light can make an illusion to the viewer as if the reflecting mirror is reflecting the light of the light emitter while rotating around the light emitter, like a conventional revolving light. Therefore, since the pseudo rotating lamp does not require a motor for rotating the reflecting plate, it can be reduced in size and power consumption can be reduced. Moreover, since the pseudo-rotating lamp does not have a motor or a rotating part for rotating the reflecting plate, the malfunction can be reduced even if it is used for a long time.

In addition, a plurality of light emitters are provided on the convex surface of the support so that the convex surface of the support faces the front side, and no light emitter is provided on the back side of the support. Thereby, since it is not necessary to provide a light-emitting body in the back side of a support body, while being able to reduce a number of parts, power consumption can be reduced.
(Fourth invention)
According to the fourth invention, the pseudo rotating lamp is provided with a predetermined time lag from when the light emitters of the final light emitting group are turned off until when the light emitters of the first light emitting group are turned on. As a result, it is possible to make an illusion of the viewer as if the reflecting mirror is reflecting the light of the illuminant to the back side like a conventional rotating lamp, and the pseudo-simulation of the pseudo rotating lamp can be enhanced. .

(Fifth invention)
According to the fifth aspect of the invention, the luminous body of the pseudo rotating lamp is turned on by increasing the luminance of the luminous body arranged at the center of each luminous group and lowering the luminance of the luminous body arranged at the end. Then, the central part of the pseudo-rotating lamp looks brightest. This makes it possible to create an illusion of the viewer as if the reflector is reflecting the light of the light emitter while rotating around a single light emitter, like a conventional rotating lamp, and a pseudo rotation. It is possible to increase the simulation of the lamp.
(Sixth invention)
According to the sixth aspect of the invention, the luminous body of the pseudo rotating lamp is turned on by increasing the density of the luminous body disposed at the center of each light emitting group and decreasing the density of the luminous body disposed at the end. Then, the central part of the pseudo-rotating lamp looks brightest. This makes it possible to create an illusion of the viewer as if the reflector is reflecting the light of the light emitter while rotating around a single light emitter, like a conventional rotating lamp, and a pseudo rotation. It is possible to increase the simulation of the lamp.

(Seventh invention)
According to the seventh aspect of the invention, the partition plate is not transparent but transmits light from the light emitter. This makes it possible to create an illusion of the viewer as if the reflecting mirror is rotating around the light emitter and reflecting the light from the light emitter, as in a conventional revolving light. Can increase the sex.
(Eighth invention)
According to the eighth invention, the partition plate has the highest light transmittance at the center. This makes it possible to create an illusion of the viewer as if the reflector is reflecting the light of the light emitter while rotating around a single light emitter, like a conventional rotating lamp, and a pseudo rotation. It is possible to increase the simulation of the lamp.

(9th invention)
According to the ninth invention, the cover transmits the light of the light emitter, but the structure of the support, the light emitting group, and the partition plate inside the cover cannot be visually recognized. This makes it possible to create an illusion of the viewer as if the reflecting mirror is rotating around the light emitter and reflecting the light from the light emitter, as in a conventional revolving light. Can increase the sex.

It is a perspective view of the front side of the pseudo | simulation rotary lamp which concerns on 1st Embodiment. It is a perspective view which shows the state which removed the cover in the pseudo | simulation rotary lamp which concerns on 1st Embodiment from the front side. It is a perspective view which shows the attachment structure of the light emission unit which concerns on 1st Embodiment from the back side. It is a top view of the light emitting unit concerning a 1st embodiment. It is a partial front view of the light emitting unit which concerns on 1st Embodiment. It is an external appearance front view of the slot machine provided with the pseudo | simulation rotary lamp which concerns on 1st Embodiment. It is a partial rear view of the light emitting unit which concerns on 2nd Embodiment. It is a top view of the light emitting unit concerning a 3rd embodiment. It is a partial front view of the light emitting unit which concerns on 5th Embodiment.

DESCRIPTION OF EMBODIMENTS Embodiments for carrying out the present invention will be described with reference to the drawings.
(First embodiment)
(Explanation of drawings)
1 to 6 show a first embodiment. FIG. 1 is a front perspective view of the pseudo rotating lamp 1. FIG. 2 is a perspective view showing the state in which the cover 4 is removed from the pseudo rotating lamp 1 from the front side. FIG. 3 is a perspective view showing the mounting structure of the light emitting unit 3 from the back side. FIG. 4 is a plan view of the light emitting unit 3. FIG. 5 is a partial front view of the light emitting unit 3. FIG. 6 is an external front view of the slot machine 20 provided with the pseudo rotating lamp 1.

The “front side” means the front side of the pseudo rotating lamp 1 as viewed from the viewer facing the front of the pseudo rotating lamp 1, and the “rear side” means the viewer facing the front of the pseudo rotating lamp 1. This means the back side of the pseudo rotating lamp 1 as seen from above.
(Pseudo rotating light 1)
As shown in FIGS. 1 to 5, the pseudo rotary lamp 1 according to the first embodiment includes a base 2 that is a base of the pseudo rotary lamp 1 and a plurality of light emitters on the outer peripheral surface of a cylindrical support 7. 11 and a light emitting unit 3 provided with a partition plate 13, a control device 14 for controlling the lighting and extinction of each light emitter 11, and a cover 4 provided on the base 2 so as to cover the light emitting unit 3 from above. I have.

(Base 2)
As shown in FIG. 3, the base 2 includes a disk-shaped bottom plate 5 and side walls 6 that protrude vertically upward from the periphery of the bottom plate 5. The base 2 can be integrally formed by injection molding using plastic. A control device 14 is provided inside the base 2, and the light emitting unit 3 is fixed to a female connector 15 provided in the control device 14.
(Light-emitting unit 3)
As shown in FIGS. 1 to 3, the light emitting unit 3 is provided with a cylindrical support 7 and a plurality of light emitting units 3 provided on the outer peripheral surface of the support 7 along the circumference of the support 7 with a predetermined interval. 7 includes a light emitting group 12 composed of a plurality of light emitting bodies 11 arranged substantially parallel to the axis 7 and a partition plate 13 provided between the adjacent light emitting groups 12 on the outer peripheral surface of the support 7.

The support 7 is for arranging the light emitters 11 at predetermined positions and electrically connecting them, and a flexible substrate is used. As shown in FIG. 3, the support body 7 includes a substrate body 8 bent in a cylindrical shape and a male connector 9 that protrudes downward from the lower end of the substrate body 8. Further, the male connector 9 is provided with a pin 10 that protrudes substantially horizontally inward in the radial direction of the substrate body 8.
On the outer peripheral surface of the support 7, as shown in FIGS. 1 to 4, 13 sets of light emitting groups 12 composed of nine light emitters 11 arranged substantially parallel to the axis of the support 7 are provided. Is provided. Specifically, 13 sets of light emitting groups 12 from the first light emitting group 12a to the 13th light emitting group 12m are provided on the outer peripheral surface of the support body 7 at substantially equal intervals along the circumference of the support body 7. ing. In each light emitting group 12, as shown in FIG. 5, the light emitters 11 from the first light emitter 11a to the ninth light emitter 11i are arranged at substantially equal intervals. A light emitting diode is used as the light emitter 11.

In addition, between the adjacent light emitting groups 12 on the outer peripheral surface of the support 7, partition plates 13 are provided as shown in FIGS. Specifically, 13 partition plates 13 from the first partition plate 13a to the 13th partition plate 13m are provided on the outer peripheral surface of the support 7. Each partition plate 13 is formed in a plate shape extending substantially parallel to the axis of the support 7. Each partition plate 13 is formed by injection molding using translucent plastic.
In the present embodiment, a translucent plastic is used for the partition plate 13. However, the present invention is not limited to this, and the partition plate 13 is formed so as not to be transparent although it has optical transparency. Just do it. Specifically, for example, a material obtained by matting a transparent plastic surface may be used for the partition plate 13. Further, a partition plate 13 may be formed by pasting a translucent plastic film on a transparent plastic surface.

(Control device 14)
The control device 14 is for controlling lighting and extinguishing of each light emitter 11. As the control device 14, a printed board including a microcomputer (including a CPU, ROM, RAM, I / O, etc.) is used. Moreover, the control apparatus 14 is installed in the baseplate 5 of the base 2, as shown in FIG. A female connector 15 is provided at the side end of the control device 14. Further, the female connector 15 is provided with a pin hole 16 corresponding to the pin 10 of the male connector 9. Then, by inserting the pin 10 of the male connector 9 into the pin hole 16 of the female connector 15, the support 7 is fixed to the control device 14 so that the axis is substantially vertical.

(Cover 4)
As shown in FIG. 1, the cover 4 is formed in a dome shape, and is provided on the side wall 6 of the base 2 so as to cover the light emitting unit 3 from above. The cover 4 is made of a light-transmitting plastic colored in red. Further, fine irregularities are formed on the inner surface of the cover 4 so that the structure inside the cover 4 cannot be seen when attached to the base 2.
In this embodiment, the cover 4 is formed of a plastic colored in red. However, the cover 4 may be formed by attaching a red plastic film to a colorless plastic.

Further, in the present embodiment, fine irregularities are provided on the inner surface of the cover 4, but the present invention is not limited to this, and the cover 4 may be formed so as to be transparent but not transparent. That's fine. Specifically, for example, a plastic film on which fine irregularities are formed may be attached to the inner surface of the cover 4. Further, the cover 4 may be formed of a translucent plastic that transmits the light of the light emitter 11 but cannot visually recognize the internal structure.
(Flashing operation of pseudo rotating lamp 1)
The pseudo rotating lamp 1 according to the present embodiment has three types of blinking patterns, and is formed so that the blinking pattern can be selected as appropriate.

(First flashing pattern)
First, all the light emitters 11 of the first light emitting group 12a are turned on all at once.
Next, after a predetermined time has elapsed, all the light emitters 11 of the second light emitting group 12b are turned on all at once, and all the light emitters 11 of the first light emitting group 12a are turned off all at once.
Then, after a predetermined time has elapsed, all the light emitters 11 of the third light emitting group 12c are turned on all at once, and all the light emitters 11 of the second light emitting group 12b are turned off all at once.
In this manner, the light emitters 11 of the light emitting group 12 are sequentially blinked so as to flow from the first light emitting group 12a to the thirteenth light emitting group 12m.

In addition, when the lighting of the light emitting body 11 reaches the 13th light emitting group 12m, after a predetermined time has elapsed, all the light emitting bodies 11 of the first light emitting group 12a are turned on all at once, and all of the 13th light emitting group 12m are turned on. The light emitters 11 are turned off all at once. Then, the blinking as described above is continued.
(Second blinking pattern)
First, all the light emitters 11 of the first light emission group 12a and the seventh light emission group 12g are turned on simultaneously.
Next, after a predetermined time has elapsed, all the light emitters 11 of the second light emission group 12b and the eighth light emission group 12h are turned on simultaneously, and all the light emitters of the first light emission group 12a and the seventh light emission group 12g. Turn off the lights all at once.

After a predetermined time has elapsed, all the light emitters of the third light emitting group 12c and the ninth light emitting group 12i are turned on all at once, and all the light emitters 11 of the second light emitting group 12b and the eighth light emitting group 12h are turned on. Turn off all lights at once.
In this way, all the light emitters 11 of the two sets of light emitting groups 12 are simultaneously turned on and blinked so as to flow sequentially.
(3rd blink pattern)
First, all the light emitters 11 of the first light emitting group 12a and the second light emitting group 12b are turned on simultaneously.
Next, after a predetermined time has elapsed, all the light emitters 11 of the third light emitting group 12c are turned on all at once, and all the light emitters 11 of the first light emitting group 12a are turned off all at once.

Then, after a predetermined time has elapsed, all the light emitters 11 of the fourth light emitting group 12d are turned on all at once, and all the light emitters 11 of the second light emitting group 12b are turned off all at once.
In this way, all the light emitters 11 of the two adjacent sets of light emitting groups 12 are simultaneously turned on and blinked so as to flow sequentially.
Note that the blinking pattern of the present invention is not limited to the above-described one, and a reflection mirror such as a conventional rotating lamp reflects the light of the light emitter while rotating around the light emitter. It is only necessary to make an illusion.
In this embodiment, when the light emitters 11 are turned on for each light emitting group 12, all the light emitters 11 of each light emitting group 12 are turned on, but some of the light emitters 11 of each light emitting group 12 are turned on. You may let them. Specifically, for example, the light emitters 11 from the fourth light emitter 11d to the sixth light emitter 11f of each light emitting group 12 may be turned on.

Further, the pseudo revolving lamp 1 may be formed so as to have a single flashing pattern or may be formed so as to have a plurality of flashing patterns.
As described above, according to the first embodiment, the 13 pseudo-rotating lamps 1 are provided on the outer peripheral surface of the cylindrical support 7 along the circumference of the support 7 at approximately equal intervals. A group 12 is provided, and each light emitter 11 of the adjacent light emitting group 12 blinks sequentially. Thereby, the pseudo revolving light 1 can make the viewer have an illusion that the reflecting mirror reflects the light of the light emitter while rotating around the light emitter, like a conventional revolving light. Therefore, since the pseudo rotating lamp 1 does not require a motor for rotating the reflecting plate, it can be miniaturized and can reduce power consumption. Further, since the pseudo rotating lamp 1 does not have a motor or rotating part for rotating the reflecting plate, failure can be reduced even if it is used for a long time.

Further, the partition plate 13 of the pseudo rotating lamp 1 is not transparent, but transmits the light of the light emitter. This makes it possible to give the viewer an illusion as if the reflecting mirror is rotating around the light emitter and reflecting the light from the light emitter, as in the conventional rotating lamp, The pseudonym can be increased.
Further, the cover 4 transmits the light of the light emitter 11, but the structure of the support 7, the light emitting group 12, and the partition plate 13 inside the cover 4 cannot be visually recognized. This makes it possible to give the viewer an illusion as if the reflecting mirror is rotating around the light emitter and reflecting the light from the light emitter, as in the conventional rotating lamp, The pseudonym can be increased.

(Use of pseudo rotating lamp 1)
The pseudo rotating lamp 1 can be used as a means for producing a game in a gaming machine such as a slot machine or a pachinko machine. Hereinafter, an example of the use of the pseudo rotating lamp 1 will be described.
As shown in FIG. 6, the slot machine 20 includes a box-shaped housing having a front opening that opens to the front side, and a front door 21 that can close and open the front opening. Also, inside the housing, there are a payout device for paying out medals, a game machine control device for controlling the game and effects of the slot machine 20, a power supply device for supplying power, and a plurality of surroundings. A rotating reel 22 displaying the symbol is stored. In addition, the start switch 24 for starting the rotation of the rotary reel 22, the stop switch 25 for stopping the rotation of the rotary reel 22, and the number of credit medals are reduced at the center of the front side of the front door 21. A bet switch 26 for replacing medal insertion and a medal insertion port 27 for inserting medal are provided. The front door 21 is provided with a symbol display window 23 above the stop switch 25 so that the symbol of the rotary reel 22 can be seen from the front side. Further, the pseudo revolving light 1 according to the present invention is attached to the upper part of the rear side of the front door 21, and the pseudo revolving light 1 is viewed from the front side at a position corresponding to the pseudo revolving light 1 in the front door 21. A pseudo rotating lamp display window 28 is provided.

  Whether the slot machine 20 wins one of a plurality of roles when the start switch 24 is pressed on condition that a medal is inserted from the medal slot 27 or a credit medal is inserted by pressing the bet switch 26. Alternatively, a lottery (role lottery) is performed. In addition, rotation of all three rotary reels 22 is started almost simultaneously with the role lottery. Thereafter, when one of the three stop switches 25 is pressed, the rotation of the rotary reel 22 corresponding to the stop switch 25 is stopped. When all the three stop switches 25 have been pressed, the rotation of the three rotary reels 22 is stopped. At this time, when the symbols related to the winning combination are arranged on the effective winning line of the symbol display window 23, the winning combination corresponding to the symbol is won, and a predetermined number of medals are paid out from the payout device. In addition, instead of paying out medals or along with paying out medals, a predetermined profit may be given to the player.

In addition, for the winning, a small role winning in which a predetermined number of medals are paid out by winning a prize, a re-game winning in which a game is not paid out but a game can be played again without newly inserting a medal, a small role winning and There are special wins that give players even greater profits than replay wins.
When the player depresses the start switch 24 and wins the special winning as a result of the lottery, the game control device immediately controls the pseudo revolving light 1 to blink once in the first blinking pattern with a predetermined probability. Do. By blinking the pseudo revolving light 1 in this way, it is possible to notify the player that the player has won the special winning, so that the player's expectation can be enhanced.

In addition, as a result of the lottery, if the player wins the special winning but the pseudo-rotating light 1 is not blinked, the game control device will perform the pseudo-rotation when the player presses the stop button located on the left side. The control that the lamp 1 immediately blinks once in the third blinking pattern is performed with a predetermined probability. By flashing the pseudo revolving light 1 in this manner, it is possible to notify the player that the player has won the special winning, so that the game is not monotonous and the player's interest can be enhanced.
In addition, as a result of the lottery, when the special winning is won and the symbols related to the winning combination are all on the effective winning line of the symbol display window 23, the special game is started and the pseudo rotating lamp 1 Starts blinking the second blinking pattern. Then, until the special game ends, the gaming machine control device controls the pseudo revolving light so that the second blinking pattern continues to blink. By blinking the pseudo revolving light 1 in this way, the game can be excited and the player's interest can be enhanced.

(Second Embodiment)
(Explanation of drawings)
FIG. 7 is a partial rear view of the light emitting unit 3 according to the second embodiment.
(Feature point)
In the second embodiment, the number of light emitters 11 of each light emitting group 12 located on the back side of the support 7 is larger than the number of light emitters 11 of each light emitting group 12 located on the front side of the support 7. Although it is different from the first embodiment in that it is formed so as to be reduced, the other points are the same as in the first embodiment, so the difference will be described.

The plan view of the light emitting unit 3 according to the second embodiment is the same as the plan view of the light emitting unit 3 shown in FIG. The partial front view of the light emitting unit 3 according to the second embodiment is the same as the partial front view of the light emitting unit 3 shown in FIG.
(Luminescent group 12)
The light emitting group 12 according to the second embodiment will be described with reference to FIGS. 4, 5, and 7.
As in the first embodiment, the light emitting groups 12 from the first light emitting group 12a to the seventh light emitting group 12g located on the front side of the support 7 include the first light emitter 11a to the ninth light emitter 11i. 9 light emitters 11 are arranged at almost equal intervals (see FIGS. 4 and 5).

Further, as shown in FIG. 7, the light emitting groups 12 from the eighth light emitting group 12h to the thirteenth light emitting group 12m located on the back side of the support 7 include the first light emitter 11a to the fifth light emitter 11e. Five light emitters 11 are arranged at almost equal intervals.
As described above, according to the second embodiment, the pseudo rotary lamp 1 includes the number of the light emitters 11 located on the back side of the support 7 and the number of the light emitters 11 located on the front side of the support 7. It is less than the number. Thereby, since the number of the light emitters 11 provided on the back side of the support 7 can be reduced, the number of parts can be reduced and the power consumption can be further reduced. In addition, since the light emitting body 11 positioned on the back side of the support body 7 appears darker than when the light emitting body 11 positioned on the front side of the support body 7 is turned on, the conventional rotating lamp It is possible to make the viewer have an illusion as if the reflecting mirror is rotating around the light emitter and reflecting the light of the light emitter, and the pseudo-rotation lamp 1 can be enhanced .

(Third embodiment)
(Explanation of drawings)
FIG. 8 is a plan view of the light emitting unit 3 according to the third embodiment.
(Feature point)
Since the third embodiment is different from the first embodiment in the shape of the support 7, the number of light emitting groups 12 and the number of partition plates 13, the other is the same as the first embodiment. Differences will be described.
The partial front view of the light emitting unit 3 according to the third embodiment is the same as the partial front view of the light emitting unit 3 shown in FIG.

(Light-emitting unit 3)
A light emitting unit 3 according to a third embodiment will be described with reference to FIGS.
The light emitting unit 3 is provided with a support 7 formed in a semi-cylindrical shape with a substantially vertical axis, and a plurality of light emitting units 3 provided at predetermined intervals along the circumference of the support 7 on the convex surface of the support 7. A light emitting group 12 composed of a plurality of light emitters 11 arranged substantially parallel to the axis and a partition plate 13 provided between adjacent light emitting groups 12 on the convex surface of the support 7 are provided.
The support 7 is formed in a semi-cylindrical shape whose axis is substantially vertical. Then, the pseudo rotating lamp 1 is installed so that the convex surface of the support 7 faces the front side.

In addition, on the convex surface of the support 7, seven sets of light emitting groups 12 each including nine light emitters 11 arranged substantially parallel to the axis of the support 7 are provided. Specifically, seven sets of light emitting groups 12 from the first light emitting group 12 a to the final light emitting group 12 g are provided on the convex surface of the support 7 at substantially equal intervals along the circumference of the support 7. Further, the nine light emitters 11 of each light emitting group 12 are arranged at substantially equal intervals.
In addition, partition plates 13 are provided between the adjacent light emitting groups 12 on the convex surface of the support 7. Specifically, six partition plates 13 from the first partition plate 13a to the sixth partition plate 13f are provided on the convex surface of the support 7.
(Flashing operation of pseudo rotating lamp 1)
First, all the light emitters 11 of the first light emission group 12a are turned on simultaneously.

Next, after a predetermined time has elapsed, all the light emitters 11 of the second light emitting group 12b are turned on all at once, and all the light emitters 11 of the first light emitting group 12a are turned off all at once.
Then, after a predetermined time has elapsed, all the light emitters 11 of the third light emitting group 12c are turned on all at once, and all the light emitters 11 of the second light emitting group 12b are turned off all at once.
In this manner, the light emitters 11 of the light emitting group 12 are sequentially blinked so as to flow from the first light emitting group 12a to the seventh light emitting group 12f.
Further, when the lighting of the light emitting body 11 reaches the final light emitting group 12f and all the light emitting bodies 11 of the final light emitting group 12f are turned off simultaneously after a predetermined time has elapsed, all the light emitting bodies 11 of the first light emitting group 12a are turned on. All the light emitters 11 in the first light emission group 12a are turned on simultaneously after a time substantially equal to the time required to turn off all the light emitters 11 in the final light emission group 12f after turning on all at once. Then, the blinking as described above is continued.

  As described above, according to the third embodiment, the pseudo rotary lamp 1 is provided with seven sets of light emitting elements provided on the convex surface of the semi-cylindrical support body 7 at substantially equal intervals along the circumference of the support body 7. A group 12 is provided, and each light emitter 11 of the adjacent light emitting group 12 blinks sequentially from the first light emitting group 12a to the final light emitting group 12f. Thereby, the pseudo revolving light 1 can make the viewer have an illusion that the reflecting mirror reflects the light of the light emitter while rotating around the light emitter, like a conventional revolving light. Therefore, since the pseudo rotating lamp 1 does not require a motor for rotating the reflecting plate, it can be miniaturized and can reduce power consumption. Further, since the pseudo rotating lamp 1 does not have a motor or rotating part for rotating the reflecting plate, failure can be reduced even if it is used for a long time.

Further, a plurality of light emitters 11 are provided on the convex surface of the support 7 so that the convex surface of the support 7 faces the front side, and the light emitter 11 is provided on the back side of the support 7. Is not provided. Thereby, since it is not necessary to provide the light emitter 11 on the back side of the support 7, the number of parts can be reduced and the power consumption can be reduced.
Further, the pseudo revolving lamp 1 is provided with a predetermined time lag from when the respective light emitters 11 of the final light emission group 12f are turned off to when each light emitter 11 of the first light emission group 12a is turned on. This makes it possible to give the viewer an illusion as if the reflecting mirror is reflecting the light of the illuminator to the back side, as in the conventional rotating lamp, and can improve the pseudo-imitation of the pseudo rotating lamp 1. it can.

(Fourth embodiment)
(Feature point)
The fourth embodiment is that the brightness of the light emitters 11 arranged at the center of each light emitting group 12 is formed so as to be higher than the brightness of the light emitters 11 arranged at the ends. Although the second embodiment is different from the first embodiment, the other points are the same as those of the first embodiment, and differences will be described.
The plan view of the light emitting unit 3 according to the fourth embodiment is the same as the plan view of the light emitting unit 3 shown in FIG. The partial front view of the light emitting unit 3 according to the fourth embodiment is the same as the partial front view of the light emitting unit 3 shown in FIG.

(Luminescent group 12)
The light emitting group 12 according to the fourth embodiment will be described with reference to FIGS. 4 and 5.
The light emitters 11 from the fourth light emitter 11d to the sixth light emitter 11f arranged at the center of each light emitting group 12 are controlled by the control device 14 to emit light with substantially the same luminance. Further, the control device 14 controls the light emission so that the luminance of the second light emitter 11b and the third light emitter 11c disposed above the fourth light emitter 11d is lower than the luminance of the fourth light emitter 11d. Has been. In addition, the control device 14 controls the light emission so that the luminance of the seventh light emitter 11g and the eighth light emitter 11h disposed below the sixth light emitter 11f is smaller than the luminance of the sixth light emitter 11f. Has been.

Further, the controller 14 controls the light emission so that the luminance of the first light emitter 11a disposed above the second light emitter 11b is smaller than the luminance of the second light emitter 11b. Further, the controller 14 controls the light emission so that the luminance of the ninth light emitter 11i disposed below the eighth light emitter 11h is lower than the luminance of the eighth light emitter 11h.
In the present embodiment, the light emission of each light emitter 11 is adjusted by the control device 14 so that the luminance of the light emitters 11 is different. The body 11 uses a high-intensity light-emitting diode, and the second, third, seventh, and eighth light-emitting bodies of each light-emitting group 12 use medium-intensity light-emitting diodes. The ninth light emitter may be formed using a low-intensity light emitting diode so that the luminance of each light emitter 11 is different.

As described above, according to the fourth embodiment, the luminance of the light emitters 11 arranged at the center of each light emitting group 12 is increased, and the luminance of the light emitters 11 arranged at the ends is lowered. Thus, when the light emitter 11 of the pseudo-rotating lamp 1 is turned on, the central portion of the pseudo-rotating lamp 1 appears to be brightest. This makes it possible to create an illusion of the viewer as if the reflector is reflecting the light of the light emitter while rotating around a single light emitter, like a conventional rotating lamp, and a pseudo rotation. The imitation of the lamp 1 can be increased.
(Fifth embodiment)
(Explanation of drawings)
FIG. 9 is a partial front view of the light emitting unit 3 according to the fifth embodiment.

(Feature point)
The fifth embodiment is different from the first embodiment in the arrangement of the light emitters 11 in each light emitting group 12, but the other points are the same as in the first embodiment, and the differences will be described. .
The plan view of the light emitting unit 3 according to the fifth embodiment is the same as the plan view of the light emitting unit 3 shown in FIG.
(Luminescent group 12)
The light emitting group 12 according to the fifth embodiment will be described with reference to FIGS. 4 and 9.
In each light emitting group 12, the light emitters 11 from the first light emitter 11a to the ninth light emitter 11i are arranged. Moreover, it arrange | positions so that the distance of the adjacent light-emitting body 11 may become large as it goes upwards from the 5th light-emitting body 11e. Moreover, it arrange | positions so that the distance of the adjacent light-emitting body 11 may become large as it goes below from a 5th light-emitting body.

As described above, according to the fifth embodiment, the density of the light emitters 11 disposed at the center of each light emitting group 12 is increased, and the density of the light emitters 11 disposed at the ends is decreased. Thus, when the light emitter 11 of the pseudo-rotating lamp 1 is turned on, the central portion of the pseudo-rotating lamp 1 appears to be brightest. This makes it possible to create an illusion of the viewer as if the reflector is reflecting the light of the light emitter while rotating around a single light emitter, like a conventional rotating lamp, and a pseudo rotation. The imitation of the lamp 1 can be increased.
(Sixth embodiment)
(Feature point)
Although the structure of the partition plate 13 is different from that of the first embodiment in the sixth embodiment, the other points are the same as those of the first embodiment, and differences will be described.

The front perspective view of the pseudo rotating lamp 1 according to the sixth embodiment is the same as the front perspective view of the pseudo rotating lamp 1 shown in FIG.
(Partition plate 13)
A partition plate 13 according to a sixth embodiment will be described with reference to FIG.
Each partition plate 13 is formed in a plate shape extending substantially parallel to the axis of the support 7. Each partition plate 13 is formed by injection molding using a transparent plastic, and a translucent plastic film is attached to the surface. This semi-transparent plastic film is formed so that the central portion when it is attached to the partition plate 13 has the highest light transmittance, and the light transmittance gradually decreases toward the upper and lower ends.

  As described above, according to the sixth embodiment, the partition plate 13 has the highest light transmittance at the center. This makes it possible to create an illusion of the viewer as if the reflector is reflecting the light of the light emitter while rotating around a single light emitter, like a conventional rotating lamp, and a pseudo rotation. The imitation of the lamp 1 can be increased.

1 Pseudo rotating light 2 Base
3 Light emitting unit 4 Cover
5 Bottom plate 6 Side wall
7 Support body 8 Board body
9 Male connector 10 pin
11 Luminescent body 12 Luminescent group
13 Partition 14 Control device
15 Female connector 16 pin hole
20 Slot machine 21 Front door
22 Rotating reel 23 Symbol display window
24 Start switch 25 Stop switch
26 Bet switch 27 Medal slot
28 Pseudo rotating lamp display window

Claims (1)

A support body formed in a cylindrical or semi-cylindrical shape having a convex surface on the front side and a substantially vertical axis;
A plurality of light emitting groups provided on the convex surface of the support body at predetermined intervals along the circumference of the support body, and composed of a plurality of light emitters arranged substantially parallel to the axis of the support body;
A control device for controlling the lighting and extinction of each light emitter,
Each light emitting group is formed such that the luminance of the light emitter disposed at the center is larger than the luminance of the light emitter disposed at the end,
The control device is configured to perform control for turning on and off each light-emitting body for each light-emitting group in order for the adjacent light-emitting groups in order, and a pseudo rotating lamp.

Images