CN113063106B - Multipurpose anticollision lamp structure - Google Patents

Abstract

The invention discloses a multipurpose anti-collision lamp structure which has two modes of friendly and hidden, and mainly comprises a lamp shade body, a lamp shade top plate, a lamp holder body, a lamp holder bottom plate and the like. The lamp shade body is internally provided with a visible light source component, an infrared light source component, an upper reflecting seat, a lower reflecting seat and an infrared reflecting seat. The invention has the beneficial effects that: the overall dimension is reduced through optical design, heat dissipation design and seal design, guarantee with the normal position replacement of small-size xenon lamp anticollision lamp to reduce anticollision lamp's overall dimension and weight, satisfy airborne equipment miniaturization, lightweight requirement.

Description

Multipurpose anticollision lamp structure

Technical Field

The invention relates to a multipurpose anti-collision lamp structure.

Background

The anti-collision lamp is mainly used for providing position information for other machines for preventing collision at night and under the condition of poor visibility. The traditional anticollision lamp is single mode xenon lamp light source, needs control box control to realize the stroboscopic function of anticollision lamp. Because the plasticity of the xenon lamp light source is poor, the shape ruler is not easy to control, and the processing difficulty is high, however, the LED is used as a novel light source, and has the advantages of high efficiency, easy controllability, small size, long service life and the like, so that the LED light source is widely applied to the design of an anti-collision lamp.

The existing LED anti-collision lamp can realize single-mode and dual-mode designs, so that the heat radiation performance of an LED light source is guaranteed, the overall dimension of the anti-collision lamp is large, and the control circuit is realized by a control box, so that the in-situ replacement of the anti-collision lamp with a small-dimension xenon lamp cannot be realized. Therefore, the invention designs the multipurpose small-size LED anti-collision lamp, the stroboscopic control circuit is positioned inside the anti-collision lamp, the application of a control box is avoided, the weight of the anti-collision lamp system is reduced, the in-situ replacement of the anti-collision lamp with the small-size xenon lamp can be realized, the anti-collision lamp adopts a dual-mode design, and the requirements of different use environments can be met.

Disclosure of Invention

The invention aims to solve the problem that the LED anti-collision lamp in the prior art cannot meet the requirements of in-situ replacement of the anti-collision lamp of a xenon lamp and miniaturization and light weight of airborne equipment, and provides a novel multipurpose anti-collision lamp structure.

In order to achieve the purpose, the technical scheme of the invention is as follows: a multipurpose anti-collision lamp structure comprises,

The LED lamp comprises a lamp shade body, wherein the lamp shade body is provided with a lamp shade side wall, a lamp shade built-in space is defined in the lamp shade side wall, the lamp shade built-in space is vertically penetrated, a visible light source component, an infrared light source component, an upper reflection seat, a lower reflection seat and an infrared reflection seat are arranged in the lamp shade built-in space, the visible light source component is provided with a visible light source printed board, an upper visible light source LED arranged on the top surface of the visible light source printed board and a lower visible light source LED arranged on the bottom surface of the visible light source printed board, the light emitting direction of the upper visible light source LED is upward, the upper reflection seat is arranged on the top surface of the visible light source printed board and surrounds the inner side of the upper visible light source LED, a light beam generated by the upper visible light source LED passes through the upper reflection seat and then outwards emits through the lamp shade side wall, the light emitting direction of the lower visible light source LED is downward, the lower reflection seat is arranged on the bottom surface of the visible light source printed board and the lower reflection seat surrounds the inner side of the lower visible light source LED, the infrared light source LED is arranged on the bottom surface of the infrared light source printed board, the infrared light beam generated by the infrared light source LED is downwards, the infrared light beam generated by the infrared light seat surrounds the infrared light source LED and outwards, and the infrared light source LED is downwards emitted by the infrared light seat is downwards;

a lamp cover top plate covering an upper opening of the lamp cover built-in space;

The lamp holder body is provided with a lamp holder top wall, a lamp holder side wall and a lamp holder partition board, wherein a lamp holder built-in space is defined in the lamp holder side wall, the lamp holder partition board, a driving printed board component and a power supply processing printed board component are arranged in the lamp holder built-in space, partition board perforations are formed in the lamp holder partition board, connecting screws are arranged in the partition board perforations, and penetrate through the infrared reflection seat, the infrared light source printed board, the lower reflection seat, the visible light source printed board and the upper reflection seat in sequence upwards to reach the lamp cover top plate; and

And the lamp holder bottom plate is covered on the lower opening of the lamp holder body.

As a preferable scheme of the multipurpose anti-collision lamp structure, the upper reflection seat adopts a parabolic curved surface, the upper visible light source LED is positioned at the focal position of the upper reflection seat, or the lower reflection seat adopts a parabolic curved surface, and the lower visible light source LED is positioned at the focal position of the lower reflection seat.

As a preferable scheme of the multipurpose anti-collision lamp structure, the infrared light-emitting seat adopts a two-section broken line type curved surface, and the infrared light source LED is positioned at the intersection point of the broken lines of the infrared light-emitting seat.

As a preferable scheme of the multipurpose anti-collision lamp structure, a first positioning concave part is formed on the bottom surface of the upper reflecting seat, and a first positioning convex part extending to the first positioning concave part is formed on the top surface of the visible light source printed board; a second positioning concave part is formed on the top surface of the lower reflecting seat, and a second positioning convex part extending to the second positioning concave part is formed on the bottom surface of the visible light source printed board; the infrared light source printed board is characterized in that a connecting column is arranged on the top surface of the infrared light source printed board, the infrared light reflecting seat, the infrared light source printed board and the connecting column are fixed through screws, a third positioning concave part is formed on the top surface of the connecting column, and a third positioning convex part extending to the third positioning concave part is formed on the bottom surface of the lower light reflecting seat.

As a preferable scheme of the multipurpose anti-collision lamp structure, radiating fins are formed on the top surface of the lamp cover top plate, and sealing rings are arranged between the bottom surface of the lamp cover top plate and the top surface of the side wall of the lamp cover.

As a preferable scheme of the multipurpose anti-collision lamp structure, the lamp holder top wall extends outwards from the top edge of the lamp holder side wall, the lamp holder top wall and the lamp shade top plate clamp the lamp shade side wall together, and a sealing ring is arranged between the top surface of the lamp holder top wall and the bottom surface of the lamp shade side wall.

As a preferable scheme of the multipurpose anti-collision lamp structure, a sealing ring is arranged between the outer peripheral surface of the lamp holder bottom plate and the inner peripheral surface of the lamp holder side wall, and an outgoing cable of the power supply processing printed board part passes through the lamp holder bottom plate and penetrates out of the lamp holder built-in space.

Compared with the prior art, the invention has the beneficial effects that: the overall dimension is reduced through optical design, heat dissipation design and seal design, guarantee with the normal position replacement of small-size xenon lamp anticollision lamp to reduce anticollision lamp's overall dimension and weight, satisfy airborne equipment miniaturization, lightweight requirement.

Drawings

Fig. 1 is a schematic structural diagram of an embodiment of the present invention.

Detailed Description

The invention will be described in further detail below with reference to the accompanying drawings of specific embodiments. The description of these embodiments is provided to assist understanding of the present invention, but is not to be construed as limiting the present invention. In addition, the technical features of the embodiments of the present invention described below may be combined with each other as long as they do not collide with each other.

Referring to fig. 1, a small-sized multipurpose anti-collision light structure is shown, which has both friendly and concealed modes.

The anti-collision lamp structure mainly comprises a lamp shade body 1, a lamp shade top plate 2, a lamp holder body 3, a lamp holder bottom plate 4 and other parts.

The canopy body 1 has canopy side walls 10. The interior of the lamp housing sidewall 10 defines a lamp housing-built-in space 100. The space 100 inside the lampshade is vertically communicated. The visible light source component 11, the infrared light source component 12, the upper reflecting seat 13, the lower reflecting seat 14 and the infrared reflecting seat 15 are arranged in the lampshade built-in space 100.

The visible light source part 11 is used for friendly mode. The visible light source part 11 has a visible light source printed board 111, an upper visible light source LED112 disposed on the top surface of the visible light source printed board 111, and a lower visible light source LED113 disposed on the bottom surface of the visible light source printed board 111. The light emitting direction of the upper visible light source LED112 is upward. The upper reflection seat 13 is disposed on the top surface of the visible light source printed board 111, and the upper reflection seat 13 surrounds the inner side of the upper visible light source LED 112. The light beam generated by the upper visible light source LED112 passes through the upper reflective base 13, and then exits outwards through the side wall 10 of the lampshade. Preferably, the upper reflector seat 13 adopts a parabolic curved surface design. The upper visible light source LED112 is located at the focal position of the upper reflector base 13. The light emitting direction of the lower visible light source LED113 is downward. The lower reflection seat 14 is disposed on the bottom surface of the visible light source printed board 111 and the lower reflection seat 14 surrounds the inner side of the lower visible light source LED113. The light beam generated by the lower visible light source LED113 passes through the lower reflection seat 14, and then exits outwards through the side wall 10 of the lampshade. Preferably, the lower reflector 14 is designed with a parabolic curved surface. The lower visible light source LED113 is located at the focal position of the lower reflector base 14.

The infrared light source unit 12 is used in a hidden mode. The infrared light source 12 is disposed below the lower reflector base 14. The infrared light source part 12 has an infrared light source printed board 121 and an infrared light source LED122 arranged on the bottom surface of the infrared light source printed board 121. The light emitting direction of the infrared light source LED122 is downward. The infrared reflecting base 15 is disposed on the bottom surface of the infrared light source printed board 121, and the infrared reflecting base 15 surrounds the inner side of the infrared light source LED122. The light beam generated by the infrared light source LED122 passes through the infrared reflecting seat 15 and then exits outwards through the side wall 10 of the lampshade. Preferably, the infrared light emitting seat 15 adopts a two-section fold-line curved surface design. The infrared light source LED122 is located at the intersection point of the folding lines of the infrared light emitting base 15.

Preferably, a first positioning recess is formed on the bottom surface of the upper reflector base 13. A first positioning convex portion extending to the first positioning concave portion is formed on the top surface of the visible light source printed board 111.

Preferably, the top surface of the lower reflection seat 14 is formed with a second positioning recess. A second positioning convex portion extending to the second positioning concave portion is formed on the bottom surface of the visible light source printed board 111.

Preferably, the connection posts 16 are disposed on the top surface of the infrared light source printed board 121. The infrared reflecting seat 15, the infrared light source printed board 121 and the connecting post 16 are fixed by screws. A third positioning recess is formed on the top surface of the connection post 16. A third positioning protrusion extending to the third positioning recess is formed on the bottom surface of the lower reflection seat 14.

The cover top plate 2 covers an upper opening of the cover built-in space 100. A heat radiating fin 20 is formed on the top surface of the lamp housing top plate 2. The extending direction of the radiating fins 20 is consistent with the heading direction of the airplane. A sealing ring 6 is arranged between the bottom surface of the lamp cover top plate 2 and the top surface of the lamp cover side wall 10.

The socket body 3 has a socket top wall 31, socket side walls 32, and socket partition 33. The interior of the socket side wall 32 defines a socket built-in space 30. The socket-built-in space 30 accommodates the socket spacer 33, a driving printed board member 34 and a power supply processing printed board member 35 below the socket spacer 33. The lamp socket partition 33 is formed with partition perforations. The inside of the baffle perforation has a connecting screw 5. The connecting screw 5 passes through the infrared reflecting seat 15, the infrared light source printed board 121, the lower reflecting seat 14, the visible light source printed board 111 and the upper reflecting seat 13 in turn upwards to reach the lamp cover top plate 2, so that the lamp holder partition 33, the infrared reflecting seat 15, the infrared light source printed board 121, the lower reflecting seat 14, the visible light source printed board 111, the upper reflecting seat 13 and the lamp cover top plate 2 form a whole, and the lamp holder top wall 31 and the lamp cover top plate 2 jointly clamp the lamp cover side wall 10. The socket top wall 31 extends outwardly from a top edge of the socket side wall 32. A sealing ring 6 is provided between the top surface of the lamp base top wall 31 and the bottom surface of the lamp housing side wall 10.

The socket bottom plate 4 covers the lower opening of the socket body 3. A sealing collar 6 is arranged between the outer circumferential surface of the base plate 4 and the inner circumferential surface of the base side wall 32. The outgoing cable of the power supply processing printed board part 35 passes through the socket base plate 4 and out of the socket built-in space 30.

While only embodiments of the invention have been shown and described in detail, it is not intended that the scope of the invention be limited thereby. It should be noted that it will be apparent to those skilled in the art that several variations and modifications can be made without departing from the spirit of the invention, which are all within the scope of the invention. Accordingly, the scope of protection of the present invention is to be determined by the appended claims.

Claims (5)

1. A multipurpose anti-collision lamp structure is characterized in that the structure comprises,

The LED lamp comprises a lamp shade body, wherein the lamp shade body is provided with a lamp shade side wall, a lamp shade built-in space is defined in the lamp shade side wall, the lamp shade built-in space is vertically penetrated, a visible light source component, an infrared light source component, an upper reflection seat, a lower reflection seat and an infrared reflection seat are arranged in the lamp shade built-in space, the visible light source component is provided with a visible light source printed board, an upper visible light source LED arranged on the top surface of the visible light source printed board and a lower visible light source LED arranged on the bottom surface of the visible light source printed board, the light emitting direction of the upper visible light source LED is upward, the upper reflection seat is arranged on the top surface of the visible light source printed board and surrounds the inner side of the upper visible light source LED, a light beam generated by the upper visible light source LED passes through the upper reflection seat and then outwards emits through the lamp shade side wall, the light emitting direction of the lower visible light source LED is downward, the lower reflection seat is arranged on the bottom surface of the visible light source printed board and the lower reflection seat surrounds the inner side of the lower visible light source LED, the infrared light source LED is arranged on the bottom surface of the infrared light source printed board, the infrared light beam generated by the infrared light source LED is downwards, the infrared light beam generated by the infrared light seat surrounds the infrared light source LED and outwards, and the infrared light source LED is downwards emitted by the infrared light seat is downwards;

a lamp cover top plate covering an upper opening of the lamp cover built-in space;

The lamp holder body is provided with a lamp holder top wall, a lamp holder side wall and a lamp holder partition board, wherein a lamp holder built-in space is defined in the lamp holder side wall, the lamp holder partition board, a driving printed board component and a power supply processing printed board component are arranged in the lamp holder built-in space, partition board perforations are formed in the lamp holder partition board, connecting screws are arranged in the partition board perforations, and penetrate through the infrared reflection seat, the infrared light source printed board, the lower reflection seat, the visible light source printed board and the upper reflection seat in sequence upwards to reach the lamp cover top plate; and

A socket base plate covering a lower opening of the socket body;

The infrared light-emitting seat adopts a two-section broken-line curved surface, and the infrared light source LED is positioned at the intersection point of the broken lines of the infrared light-emitting seat;

A first positioning concave part is formed on the bottom surface of the upper reflecting seat, and a first positioning convex part extending to the first positioning concave part is formed on the top surface of the visible light source printed board; a second positioning concave part is formed on the top surface of the lower reflecting seat, and a second positioning convex part extending to the second positioning concave part is formed on the bottom surface of the visible light source printed board; the infrared light source printed board is characterized in that a connecting column is arranged on the top surface of the infrared light source printed board, the infrared light reflecting seat, the infrared light source printed board and the connecting column are fixed through screws, a third positioning concave part is formed on the top surface of the connecting column, and a third positioning convex part extending to the third positioning concave part is formed on the bottom surface of the lower light reflecting seat.

2. The multipurpose anti-collision light structure of claim 1, wherein the upper reflector base is a parabolic curved surface, the upper visible light source LED is located at a focal position of the upper reflector base, or the lower reflector base is a parabolic curved surface, and the lower visible light source LED is located at a focal position of the lower reflector base.

3. The multipurpose anti-collision light structure of claim 1, wherein the top surface of the lamp cover top plate is formed with heat dissipation fins, and a sealing ring is arranged between the bottom surface of the lamp cover top plate and the top surface of the lamp cover side wall.

4. The multipurpose anti-collision light structure of claim 1, in which the top wall of the lamp holder extends outwardly from the top edge of the side wall of the lamp holder, the top wall of the lamp holder and the top wall of the lamp housing cooperate to clamp the side wall of the lamp housing, and a sealing ring is provided between the top surface of the top wall of the lamp holder and the bottom surface of the side wall of the lamp housing.

5. The multipurpose anti-collision light structure of claim 1, in which a sealing ring is disposed between the outer peripheral surface of the base plate and the inner peripheral surface of the side wall of the lamp base, and the outgoing cable of the power supply processing printed board member passes through the base plate and out of the space inside the lamp base.