CN221004830U - Ultra-thin optical fiber starry sky top light source machine with scintillation turntable - Google Patents

Abstract

The utility model relates to the technical field of automobile decoration, in particular to an ultrathin optical fiber starry sky roof light source machine with a flicker turntable, which comprises a shell upper cover and a shell lower cover, wherein two ends of the shell upper cover and the shell lower cover are respectively and fixedly connected with a shell rear panel through a shell front panel, a control main board is fixedly arranged in the shell lower cover, the flicker turntable and a light source emission assembly are arranged on the control main board, the flicker turntable is rotationally connected with the control main board through a rotary driving assembly, the light source emission assembly is positioned below the inner side of the flicker turntable, and the light source emission assembly horizontally corresponds to through holes formed in the shell front panel and the shell rear panel; according to the utility model, under the rotation effect of the flash turntable, the light emitted by the light source emitting assembly is shielded by the rotating flash turntable with the light holes to form a suddenly-flickering effect, and one or more lamp beads can be arranged below the flash turntable, so that the overall machine body height can be effectively reduced during use, and the effect of light flickering is not influenced.

Description

Ultra-thin optical fiber starry sky top light source machine with scintillation turntable

Technical Field

The utility model relates to a starry sky top light source machine, in particular to an ultrathin optical fiber starry sky top light source machine with a flicker turntable, and belongs to the technical field of automobile decoration.

Background

The starry sky top light source machine is a device for decorating automobile light, and the existing automobile starry sky top light source machine with a flicker turntable is installed in a vertical direction and can only rotate in the vertical direction, but the turntable is required to have a certain size, so that the height of a shell of the whole machine cannot be made small (the height cannot be made smaller than 30 mm); therefore, the existing light source machine with the flashing turntable is large in height and can be placed in a trunk, so that the distance between the light source machine and the star roof is too long, the use amount of inner optical fibers is greatly increased, the cost is increased, the intensity of light is attenuated, and certain defects exist in the using process.

In view of this, the present utility model has been made.

Disclosure of utility model

The utility model aims to solve the problems and provide an ultrathin optical fiber starry sky top light source machine with a flicker turntable, which has the advantages of effectively reducing the whole machine body height and not influencing the effect of light flicker.

The utility model realizes the aim through the following technical scheme that the ultrathin optical fiber starry sky top light source machine with the flicker turntable comprises a shell upper cover and a shell lower cover, wherein two ends of the shell upper cover and the shell lower cover are respectively and fixedly connected through a shell front panel and a shell rear panel, a control main board is fixedly arranged in the shell lower cover, the flicker turntable and a light source emitting assembly are arranged on the control main board, the flicker turntable is rotationally connected with the control main board through a rotary driving assembly, the light source emitting assembly is positioned below the inner side of the flicker turntable, and the light source emitting assembly horizontally corresponds to through holes formed in the shell front panel and the shell rear panel.

Further, in order to open through the control step motor, can drive the drive shaft rotates, rotary drive subassembly includes step motor, step motor passes through the connecting plate is fixed again on the control mainboard, step motor's output fixedly connected with drive shaft.

Further, in order to enable the driving shaft to rotate, the scintillation turntable can be driven to rotate, and one end of the driving shaft is fixed on the inner wall of the top end of the scintillation turntable.

Further, in order to make the light source of lamp pearl body transmission, can follow offer one on the shell front panel in the through-hole send, the light source transmission subassembly includes the heat dissipation support, fixed mounting has lamp pearl PCB board on the heat dissipation support with lamp pearl body, lamp pearl body with lamp pearl PCB board electric connection, fixed mounting has the reflector cup on the lamp pearl PCB board, the reflector cup joints on the lamp pearl body, the lamp pearl body with one of seting up on the shell front panel the through-hole level corresponds.

Further, in order to make the light source of lamp pearl body transmission, can follow respectively the shell front panel with set up one on the shell rear panel in the through-hole send, the light source transmission subassembly includes the heat dissipation support, the heat dissipation support quantity is two, two equal fixed mounting has lamp pearl PCB board and lamp pearl body on the heat dissipation support, the lamp pearl body with lamp pearl PCB board electric connection, fixed mounting has the reflector cup on the lamp pearl PCB board, the reflector cup joints on the lamp pearl body, fix two lamp pearl body on the heat dissipation support respectively with shell front panel with one set up on the shell rear panel the through-hole level corresponds.

Further, in order to make the light source of lamp pearl body transmission, can follow set up two on the shell front panel in the through-hole send, the light source transmission subassembly includes the heat dissipation support, fixed mounting has lamp pearl PCB board and lamp pearl body on the heat dissipation support, the lamp pearl body with lamp pearl PCB board electric connection, fixed mounting has the reflector cup on the lamp pearl PCB board, the reflector cup joints on the lamp pearl body, lamp pearl body quantity is two, two the lamp pearl body respectively with two set up on the shell front panel the through-hole level corresponds.

Further, in order to make the light source of lamp pearl body transmission, can follow respectively the shell front panel with set up two in the through-hole on the shell rear panel, the light source transmission subassembly includes the heat dissipation support, heat dissipation support quantity is two, two equal fixed mounting has lamp pearl PCB board and lamp pearl body on the heat dissipation support, the lamp pearl body with lamp pearl PCB board electric connection, fixed mounting has the reflector cup on the lamp pearl PCB board, the reflector cup is cup jointed on the lamp pearl body, every lamp pearl body on the heat dissipation support is two, fixes two on the same the lamp pearl body respectively with two on the shell front panel with the shell rear panel set up the through-hole level corresponds.

Furthermore, in order to conveniently fix the optical fiber connector outside the fixed ring, light rays are injected into the optical fiber, the fixed ring is inserted in the through hole, and a screw for fixing the optical fiber connector outside the fixed ring is arranged on the fixed ring.

The utility model has the technical effects and advantages that: the rotary driving assembly drives the scintillation turntable to rotate, so that the light emitted by the light source emitting assembly can form a suddenly-flickering effect after being blocked by the rotary scintillation turntable with the light holes, one or more lamp beads can be installed below the scintillation turntable, the overall body height can be effectively reduced when the novel light source LED street lamp is used, the light flickering effect can not be influenced, and the practicability is stronger.

Drawings

FIG. 1 is a schematic diagram of the overall structure of the present utility model;

FIG. 2 is a schematic view of a mounting structure of a lamp body according to the present utility model;

FIG. 3 is a schematic view of the mounting structure of a front and rear lamp bead body according to the present utility model;

FIG. 4 is a schematic view of the mounting structure of two side-by-side lamp bead bodies according to the present utility model;

fig. 5 is a schematic diagram of the mounting structure of each of the front and rear lamp bead bodies according to the present utility model.

In the figure: 1. an upper cover of the housing; 2. a housing lower cover; 3. a housing front panel; 4. a housing rear panel; 5. a control main board; 6. a scintillation turntable; 7. a light source emitting assembly; 701. a heat dissipation bracket; 702. a lamp bead PCB board; 703. a lamp bead body; 704. a reflective cup; 8. a rotary drive assembly; 801. a stepping motor; 802. a connecting plate; 803. a drive shaft; 9. a fixing ring; 10. and (5) a screw.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Referring to fig. 1-5, an ultra-thin optical fiber starry sky top light source machine with a flash turntable comprises an upper shell cover 1 and a lower shell cover 2, wherein two ends of the upper shell cover 1 and the lower shell cover 2 are respectively and fixedly connected through a front shell panel 3 and a rear shell panel 4, a control main board 5 is fixedly arranged in the lower shell cover 2, the flash turntable 6 and a light source emitting component 7 are arranged on the control main board 5, the flash turntable 6 is rotationally connected with the control main board 5 through a rotary driving component 8, the light source emitting component 7 is positioned below the inner side of the flash turntable 6, the rotary driving component 8 is controlled to rotate the flash turntable 6 and control the light source emitting component 7 to emit light so as to form a sudden and suddenly dark effect after being shielded by the flash turntable 6 with a light hole, and the light source emitting component 7 horizontally corresponds to through holes formed in the front shell panel 3 and the rear shell panel 4 so as to enable sudden and suddenly dark light to be emitted from the through holes.

The rotary driving assembly 8 comprises a stepping motor 801, the stepping motor 801 is fixed on the control main board 5 through a connecting plate 802, the output end of the stepping motor 801 is fixedly connected with a driving shaft 803, one end of the driving shaft 803 is fixed on the inner wall of the top end of the scintillation turntable 6, the stepping motor 801 is controlled to be started, and the driving shaft 803 is used for driving the scintillation turntable 6 to rotate.

The light source emission component 7 comprises a heat dissipation bracket 701, wherein a lamp bead PCB 702 and a lamp bead body 703 are fixedly arranged on the heat dissipation bracket 701, the lamp bead body 703 is electrically connected with the lamp bead PCB 702, a light reflecting cup 704 is fixedly arranged on the lamp bead PCB 702, the light reflecting cup 704 is sleeved on the lamp bead body 703, and the lamp bead body 703 horizontally corresponds to a through hole formed in the front panel 3 of the shell so as to emit light from the through hole of the front panel 3 of the shell.

The light source emission component 7 comprises two heat dissipation brackets 701, wherein the number of the heat dissipation brackets 701 is two, a lamp bead PCB 702 and a lamp bead body 703 are fixedly arranged on the two heat dissipation brackets 701, the lamp bead body 703 is electrically connected with the lamp bead PCB 702, a light reflection cup 704 is fixedly arranged on the lamp bead PCB 702, the light reflection cup 704 is sleeved on the lamp bead body 703, and the lamp bead body 703 fixed on the two heat dissipation brackets 701 respectively corresponds to a through hole formed in the front shell panel 3 and the rear shell panel 4 in a horizontal manner so as to facilitate the emission of a light source from the through holes in the front shell panel 3 and the rear shell panel 4 respectively.

The light source emission component 7 comprises a heat dissipation bracket 701, wherein a lamp bead PCB 702 and a lamp bead body 703 are fixedly arranged on the heat dissipation bracket 701, the lamp bead body 703 is electrically connected with the lamp bead PCB 702, a light reflecting cup 704 is fixedly arranged on the lamp bead PCB 702, the light reflecting cup 704 is sleeved on the lamp bead body 703, the number of the lamp bead bodies 703 is two, and the two lamp bead bodies 703 respectively correspond to the two through holes formed in the front panel 3 of the shell horizontally, so that light rays can be emitted from the two through holes of the front panel 3 of the shell conveniently.

The light source emission component 7 comprises two heat dissipation brackets 701, wherein the number of the heat dissipation brackets 701 is two, a lamp bead PCB 702 and a lamp bead body 703 are fixedly arranged on the two heat dissipation brackets 701, the lamp bead body 703 is electrically connected with the lamp bead PCB 702, a light reflection cup 704 is fixedly arranged on the lamp bead PCB 702, the light reflection cup 704 is sleeved on the lamp bead body 703, the number of the lamp bead bodies 703 on each heat dissipation bracket 701 is two, and the two lamp bead bodies 703 fixed on the same heat dissipation bracket 701 respectively correspond to the two through holes formed in the front shell panel 3 and the rear shell panel 4 in a horizontal mode so as to enable light sources to be respectively emitted from the two through holes in the front shell panel 3 and the rear shell panel 4.

A fixing ring 9 is inserted in the through hole, and a locking screw 10 is arranged on the fixing ring 9 so as to fix the optical fiber connector.

When the LED lamp is used, in order to reduce the height of a body of a light source machine, the design designs the scintillation turntable 6 into a flat cylinder shape, the side wall of the cylindrical scintillation turntable 6 is provided with light holes with different sizes, a stepping motor 801 is arranged below the cylindrical scintillation turntable 6, a lamp bead body 703 fixed on a heat dissipation bracket 701 is arranged at the same time, a reflecting cup 704 is arranged on the lamp bead body 703, when the stepping motor 801 is started to drive the cylindrical scintillation turntable 6 to rotate, the light of the lamp bead body 703 is shielded by the rotating scintillation turntable 6 with the light holes to form a flickering effect, and one or more lamp beads are arranged below the cylindrical scintillation turntable 6, so that the height of the body can be reduced, and the flickering effect of the light can not be influenced.

It will be evident to those skilled in the art that the utility model is not limited to the details of the foregoing illustrative embodiments, and that the present utility model may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. The present embodiments are, therefore, to be considered in all respects as illustrative and not restrictive, the scope of the utility model being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Furthermore, it should be understood that although the present disclosure describes embodiments, not every embodiment is provided with a separate embodiment, and that this description is provided for clarity only, and that the disclosure is not limited to the embodiments described in detail below, and that the embodiments described in the examples may be combined as appropriate to form other embodiments that will be apparent to those skilled in the art.

Claims (8)

1. The utility model provides an ultra-thin optical fiber starry sky top light source machine with scintillation carousel, includes shell upper cover (1) and shell lower cover (2), shell upper cover (1) with shell lower cover (2) both ends are respectively through shell front panel (3) and shell rear panel (4) fixed connection, its characterized in that: the LED lamp is characterized in that a control main board (5) is fixedly installed in the shell lower cover (2), a flicker rotary table (6) and a light source emission component (7) are installed on the control main board (5), the flicker rotary table (6) is rotationally connected with the control main board (5) through a rotary driving component (8), the light source emission component (7) is located below the inner side of the flicker rotary table (6), and the light source emission component (7) corresponds to the through hole level formed in the shell front panel (3) and the shell rear panel (4).

2. The ultra-thin optical fiber starry sky top light source with scintillation turntable of claim 1, wherein: the rotary driving assembly (8) comprises a stepping motor (801), the stepping motor (801) is fixed on the control main board (5) through a connecting plate (802), and the output end of the stepping motor (801) is fixedly connected with a driving shaft (803).

3. The ultra-thin optical fiber starry sky top light source with scintillation turntable of claim 2, wherein: one end of the driving shaft (803) is fixed on the inner wall of the top end of the flicker turntable (6).

4. The ultra-thin optical fiber starry sky top light source with scintillation turntable of claim 1, wherein: the light source emission assembly (7) comprises a heat dissipation support (701), a lamp bead PCB (702) and a lamp bead body (703) are fixedly installed on the heat dissipation support (701), the lamp bead body (703) is electrically connected with the lamp bead PCB (702), a light reflection cup (704) is fixedly installed on the lamp bead PCB (702), the light reflection cup (704) is sleeved on the lamp bead body (703), and the lamp bead body (703) corresponds to one through hole level formed in the front panel (3) of the shell.

5. The ultra-thin optical fiber starry sky top light source with scintillation turntable of claim 1, wherein: the light source emission assembly (7) comprises two heat dissipation brackets (701), wherein the number of the heat dissipation brackets (701) is two, a lamp bead PCB (702) and a lamp bead body (703) are fixedly installed on the heat dissipation brackets (701), the lamp bead body (703) is electrically connected with the lamp bead PCB (702), a light reflection cup (704) is fixedly installed on the lamp bead PCB (702), the light reflection cup (704) is sleeved on the lamp bead body (703), and the lamp bead bodies (703) fixed on the two heat dissipation brackets (701) are respectively corresponding to one through hole formed in the front shell panel (3) and the rear shell panel (4).

6. The ultra-thin optical fiber starry sky top light source with scintillation turntable of claim 1, wherein: the light source emission assembly (7) comprises a heat dissipation support (701), a lamp bead PCB (702) and lamp bead bodies (703) are fixedly installed on the heat dissipation support (701), the lamp bead bodies (703) are electrically connected with the lamp bead PCB (702), a light reflection cup (704) is fixedly installed on the lamp bead PCB (702), the light reflection cup (704) is sleeved on the lamp bead bodies (703), the number of the lamp bead bodies (703) is two, and the two lamp bead bodies (703) respectively correspond to the two through holes formed in the front panel (3) of the shell.

7. The ultra-thin optical fiber starry sky top light source with scintillation turntable of claim 1, wherein: the light source emission component (7) comprises two heat dissipation brackets (701), wherein the number of the heat dissipation brackets (701) is two, a lamp bead PCB (702) and a lamp bead body (703) are fixedly installed on the heat dissipation brackets (701), the lamp bead body (703) is electrically connected with the lamp bead PCB (702), a light reflection cup (704) is fixedly installed on the lamp bead PCB (702), the light reflection cup (704) is sleeved on the lamp bead body (703), the number of the lamp bead bodies (703) on each heat dissipation bracket (701) is two, and the two lamp bead bodies (703) on the same heat dissipation bracket (701) are respectively corresponding to the two through holes formed in the front shell panel (3) and the rear shell panel (4).

8. The ultra-thin optical fiber starry sky top light source with scintillation turntable of claim 1, wherein: the fixing ring (9) is inserted into the through hole, and a screw (10) for fixing the optical fiber connector outside the fixing ring (9) is arranged on the fixing ring (9).