KR200390206Y1 - Light module - Google Patents

Abstract

The light module includes a lighting unit, a heat sink and an insulating plate. The lighting unit has a tip contact. The heat sink is in intimate contact with the lighting unit and has a channel corresponding to the tip contact. The insulating plate is disposed under the heat sink and has a through hole corresponding to a predetermined conductive pattern and channel arranged thereon. The tip contact of the lighting unit is electrically connected to a predetermined conductive pattern of the insulating plate through the channel of the heat sink and the through hole of the insulating plate.

Description

LIGHT MODULE {LIGHT MODULE}

The present invention relates to a light module, and more particularly to a light module having a heat dissipation structure that is easy to assemble.

Electronics are becoming smaller and lighter. 1 illustrates a fixing structure designed for a conventional flashlight that radiates heat. The flashlight 1a has a cavity 11a formed therein for accommodating the battery device 12a. The flashlight 1a includes conducting structures 13a and 14a which are arranged in front and rear of the battery device 12a to insert and electrically connect the battery device 12a. The lighting unit 15a of the flashlight 1a is connected to the conductive structure 13a and irradiated. The heat generated by the irradiation of the lighting unit 15a adversely affects the service life of the product, which may damage the device. The aluminum sleeve 2a is arranged to hold against the conducting structure 13a for transferring heat. In addition, the lighting unit 15a is fixed to the flashlight 1a, and an aluminum ring 21a having an outer thread fixes the conductive structure 13a inside the flashlight 1a adjacent to the conductive structure 13a. . The conventional fixing structure described above is complicated in the assembly process step of the flashlight (1a). The aluminum ring 21a must first be arranged inside the flashlight 1a so as to face the conductive structure 13a, and after inserting the heat dissipating aluminum sleeve 2a, the other parts of the flashlight 1a are sequentially assembled. do. In addition, a conductive structure 13a made of a polypropylene plate (so-called PP plate) 132a is sandwiched between two metallic plates 131a and 133a. The lighting unit 15a is in direct contact with the metallic plate 133a. The metallic plate 133a has a circumferential portion that is bent downward to cover and contact the opposite metallic plate 131a to radiate heat to the outside. The contact between the two metallic plates 131a and 133a is constrained by the circumferential portion and the screw 134a penetrating. After the aluminum ring 21a is placed in contact with the metallic plate 133a, another contact area is formed in the aluminum sleeve 2a in a ring shape. The heat dissipation efficiency is constrained by the contact between the two metallic plates 131a and 133a and the contact area between the aluminum ring 21a and the metallic plate 133a. It is difficult to improve due to the design characteristics. Also, a structure formed by the metallic plate 133a and the aluminum ring 21a, and the aluminum ring 21a and the aluminum sleeve 2a should be considered. Clearly, this structure has at least two heat chokes. It occurs first between the two metallic plates 131a and 133a, and occurs between the aluminum ring 21a and the metallic plate 133a.

It provides a design of a light module that can be assembled quickly and simply, has a large heat dissipation area, and has better heat dissipation efficiency than the prior art. In addition, the number of parts is smaller than in the prior art, and manufacturing cost can be reduced.

The light module includes a lighting unit, a heat sink, and an insulating plate. The lighting unit has a tip contact. The heat sink is in intimate contact with the light module and has a channel corresponding to the tip contact. The insulating plate is disposed under the heat sink and has a through hole corresponding to a predetermined conductive pattern and channel arranged thereon. The tip contact of the lighting unit is electrically connected to a predetermined conductive pattern of the insulating plate through the channel of the heat sink and the through hole of the insulating plate.

To provide an easy understanding of the subject innovation, the following detailed description shows embodiments and examples of the subject innovation. Embodiments of more important features of the present invention are summarized in the following detailed description, which can be easily understood, and the contributions in the art. Accordingly, the present invention should fall within the scope of the present invention as defined in the appended claims.

2 to 4, the light module according to the present invention includes a lighting unit 10 having a front end contact 12, a heat sink 20 firmly contacting the lighting unit 10, and a heat sink 20. It includes an insulating plate 30 disposed below. The heat sink 20 has a channel 22 corresponding to the tip contact 12. The insulating plate 30 has a predetermined conductive pattern 32 arranged thereon and a through hole 34 corresponding to the channel 22. The tip contact 12 of the lighting unit 10 penetrates through the channel 22 of the heat sink 20 and the through hole 34 of the insulation plate 30 to electrically connect with the predetermined conductive pattern 32 of the insulation plate 30. Connected. Thus, in order to avoid the conventional fixed structure, which is complicated and difficult to assemble, the light module can be treated as a single modular device with improved efficiency, and can be used as a flashlight or other device.

In addition, the heat sink 20 firmly contacts the lighting unit 10, and the contact area formed between them is determined by the size. This contact area is different from the contact between the aluminum ring 21a and the metallic plate 133a because it transfers heat and is more efficient.

In addition, a single module to increase heat dissipation efficiency without other components, such as conventional lighting unit 15a, polypropylene plate 132a, metallic plate 133a, aluminum ring 21a and aluminum sleeve 2a, etc. The manufacturing unit can be reduced by using the lighting unit 10, the heat sink 20 and the insulating plate 30 is assembled to.

The tip contact 12 of the lighting unit 10 may be bent to conduct heat from a predetermined conductive pattern 32 of the insulating plate 30. As such, the conventionally installed polypropylene plate 132a and the metallic plate 133a are expensive and excessively large.

The lighting unit 10 may comprise an LED or bulb bulb. The lighting unit 10 may be clamped, attached or screwed to the heat sink 20.

The heat sink 20 is a metallic plate made of copper or aluminum or a partial alloy of copper or aluminum. In FIG. 3, a predetermined distance h is provided between the channel 22 of the heat sink 20 and the lighting unit 10, and the tip contact 12 extends outwardly along the predetermined distance and penetrates the channel 22. It is bent downward to make. Referring to FIG. 3A, the heat sink 20 is adjacent to the lighting unit 10, and the tip contact 12 extends downward through the channel 22.

The heat sink 20 also includes an outer thread to allow the heat sink 20 to be firmly attached to the flashlight or other lighting device.

The insulating plate 30 is made of polypropylene material.

According to the present invention, the advantages of the light module are as follows.

1. The light module can be assembled easily and quickly.

2. The light module has a large heat dissipation area and improves heat dissipation efficiency.

3. The light module is low in number of parts and inexpensive.

It is apparent to those skilled in the art that the foregoing detailed description is exemplary of specific embodiments and examples of the present invention. Therefore, the present invention includes various changes and modifications to the disclosed structure and operation of the present invention if it falls within the scope of the present invention as defined in the appended claims.

1 is an exploded view of a fixing structure suitable for a conventional heat radiation flashlight.

2 is a side view of the light module according to the present invention.

3 is a front view of the light module according to the present invention.

3A is another front view of the light module according to the present invention.

4 is a perspective view of a light module according to the present invention.

<Explanation of symbols for the main parts of the drawings>

10: lighting unit 12: tip contact

20: heat sink 30: insulation plate

22: channel 34: through hole

32: predetermined conduction pattern

Claims (7)

A lighting unit having a tip contact, A heat sink in close contact with the lighting unit and having a channel corresponding to the tip contact; An insulating plate disposed under the heat sink and having a predetermined conductive pattern arranged thereon and a through hole corresponding to the channel; And a front end contact point of the lighting unit is electrically connected to a predetermined conductive pattern of the insulating plate through the channel of the heat sink and the through hole of the insulating plate. The light module of claim 1, wherein the lighting unit comprises an LED. The light module of claim 1, wherein the lighting unit is connected to the heat sink by a screw. The light module of claim 1, wherein a channel of the heat sink is adjacent to the lighting unit, and the tip contact extends downward through the channel. The light module of claim 1, wherein the channel is spaced apart from the light module by a predetermined distance, and the tip contact portion extends outwardly along a predetermined distance and is bent downward through the channel. The light module of claim 1, wherein the heat sink has an outer thread. The light module of claim 1, wherein the insulation plate is made of polypropylene material.