KR20140103665A - Heat sink - Google Patents

Abstract

The present invention relates to a heat sink for an LED lighting lamp which is configured to form a plurality of heat radiating fins on the periphery surface of a heat radiating portion, to form a pipe insertion portion therein, tightly connecting a fastening portion formed with a pipe receptacle portion perpendicular to the pipe insertion portion at one end to the heat radiating portion, to insert and connect one end of a heat pipe to the pipe insertion unit, to reduce the thermal resistance by forcibly fixing the other end to the pipe receptacle portion, transferring the heat of components emitting high heat quickly through the heat pipe to the heat radiating portion, and to radiate the heat from the cooled heat radiating portion by external air circulation. According to the present invention, the heat sink can prevent damage to components due to the high heat by rapidly releasing the heat generated from the component via the heat pipe, release the heat around the components to the outside through the heat radiating portion and increase the cooling efficiency of the components by the heat dissipation, and rapidly radiate the heat of the heat pipe and the heat inside the device by maintaining the heat radiating portion to be cooled by the outside air which is circulated externally.

Description

Heat sink for LED lighting fixture {Heat sink}

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a heat sink, and more particularly, to a heat sink for an LED lighting fixture having a heat radiating effect by a plurality of heat pipes.

Generally, a heat sink is a device that attaches to a component generating high heat and spontaneously discharges the heat to the outside.

Particularly, the heat sink is mainly attached to a microcomputer or a transistor used in an electronic product and an LED lamp that emits light, so that the performance of the device is deteriorated due to a high temperature generated in the device, prevent.

FIG. 1 is a view showing a conventional heat sink. The heat sink 20 has a hollow heat sink 20, a heat storage unit 40 filled in the heat sink 20, And a heat generating element 10 formed on the bottom surface of the heat sink 20 to receive heat.

Here, the heat generating element 10 receives heat and transfers heat to the heat dissipating plate 30 in a state where the heat generating element 10 is attached to a high heat generating component.

The heat transferred to the heat sink 20 is transferred to the heat storage unit 40, and heat is accumulated in the heat storage unit 40.

At this time, the heat accumulated in the heat storage unit 40 is transferred to the heat radiating fin 30 which is kept cooled by the outside air, and is cooled and discharged to the surrounding air.

However, in the related art as described above, the heat radiating plate 20 is maintained in a high-temperature state by the heat accumulated in the heat storage unit 40, and the heat radiating force of the heat generating element is lowered because the heat sink 20 is not cooled The amount of heat accumulated in the heat accumulating portion 40 is relatively large compared to the amount of heat radiated through the radiating fins 30 so that the heat is not properly discharged and the heat stays on the heat generating element 10 and the high- , Which causes high temperature parts to be damaged due to high temperatures.

In addition, the volume of the heat sink 20 and the heat dissipation fin 30 is increased according to the amount of heat dissipation of the component, so that the load is increased, which makes the installation work difficult and requires a separate fixing device for supporting the load.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and it is an object of the present invention to provide a heat exchanger having a plurality of radiating fins formed on an outer surface of a heat dissipating unit, a pipe inserting unit formed on an inner surface thereof, And the one end of the heat pipe is securely fitted to the pipe support portion by inserting the other end into the pipe support portion so that the heat resistance is lowered and the heat of the high temperature component is quickly transmitted through the heat pipe And to dissipate the heat in the heat dissipation unit cooled by the external air circulation.

According to an aspect of the present invention, there is provided a heat sink for an LED lighting fixture, comprising: a hollow bar-shaped heat sink having a plurality of radiating fins formed on an outer surface thereof, A heat dissipation unit formed; A fastening part tightly coupled to one end of the heat dissipating part and having a pipe receiving part formed on one surface thereof and perpendicular to the pipe inserting hole; And a heat pipe in which one end is inserted into the pipe inserting portion of the heat dissipating portion and the other end is forcedly fitted and fixed to the pipe receiving portion of the fastening portion.

In the heat sink for an LED lighting fixture according to the present invention, the fastening portion is formed with a through hole for passing air supplied through the heat dissipating portion to a central portion thereof.

In the heat sink for a LED lighting fixture according to the present invention, a plurality of discharge holes for discharging the air supplied through the heat dissipation part to the outside are formed on the outer surface of the fastening part at a predetermined interval.

In the heat sink for an LED lighting fixture according to the present invention, the pipe receiving portion is formed in an arch shape so as to surround the heat pipe.

The heat sink for an LED lighting fixture according to the present invention may further include an LED lamp coupled to one surface of the coupling portion and irradiating light to the outside.

In the heat sink for an LED lighting fixture according to the present invention, the LED lamp has an annular shape with an air passage hole formed at a central portion thereof, and a plurality of heat dissipation fins are formed spaced apart from each other along a rim of the air passage hole, A plurality of LED elements are provided so as to be spaced apart from each other along the edge of the through hole and a globe covering the LED element is coupled to the lower end thereof.

The heat sink for LED lighting fixture according to the present invention quickly dissipates heat generated from the component through the heat pipe to prevent damage to the component due to the high temperature and dissipates heat to the outside through the heat dissipation unit, And the heat radiation part is maintained in a cooled state by the outdoor air circulated inside and outside so that the heat of the heat pipe and the heat in the device can be dissipated quickly and can be easily fixed to the heat generating part of the flat plate structure, The luminaire can be lightened.

Further, since the heat radiating portion is formed in a hollow shape, the heat radiating area is increased, the weight load is reduced, and the heat radiating effect can be increased by adjusting the length of the heat radiating portion.

1 is a view showing a conventional heat sink;
2 is a perspective view illustrating a heat sink for an LED lighting fixture according to the present invention;
3 is an exploded perspective view of a heat sink for an LED lighting fixture according to the present invention;
FIG. 4 is a side cross-sectional view showing a state in which heat is transmitted through a heat sink for an LED lighting fixture according to the present invention; FIG.
5 is a perspective view illustrating a state in which a heat sink for an LED lighting fixture according to the present invention is installed in an LED lamp.
6 is an exploded perspective view of an LED lamp provided with a heat sink for an LED lighting fixture according to the present invention;

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

2 to 3, the heat dissipating unit 100 has a hollow bar shape and a plurality of heat dissipating fins 101 are formed on the outer surface thereof. The pipe inserting unit 102 is formed with annular spacing along the inner surface thereof .

The heat dissipation fin 101 may be formed in a plate shape and protrude along the longitudinal direction of the heat dissipation unit 100.

The heat radiating part 100 is opened upside and downside, and is self-cooled by outdoor air circulated through the upper and lower parts.

The heat dissipation unit 100 receives heat in a state of being cooled by outdoor air, and performs a heat dissipation function of cooling the heat or discharging the heat into the air.

The heat radiating part 100 forms an arcuate groove along the inner circumferential surface so that the thickness between the inner and outer surfaces becomes thin, so that the heat of the inner surface is quickly transmitted to the outer surface.

The length of the heat dissipation unit 100 is freely adjusted according to the user's intention, and the heat dissipation effect varies depending on the length.

The heat dissipation unit 100 is easily fixed to the heat dissipation unit of the LED lamp having a flat plate structure by the coupling unit 200.

The fastening part 200 is tightly coupled to one end of the heat dissipating part 100 and a pipe receiving part 201 is formed on one surface of the fastening part 200 so as to be orthogonal to the pipe inserting port 102.

The coupling part 200 connects and fixes the heat radiating part 100 with the heat generating device.

The pipe receiving portion 201 is formed in an arch shape to enclose the heat pipe 300.

The fastening part 200 has a through hole 202 through which the air supplied through the heat dissipating part 100 passes.

The diameter of the through hole 202 is preferably larger than the inner diameter of the heat dissipation unit 100.

A plurality of discharge holes 203 for discharging the air supplied through the heat dissipating unit 100 to the outside are formed on the outer surface of the coupling unit 200 at predetermined intervals.

The discharge hole 203 is preferably formed on the pipe receiving part 201.

An LED lamp 400 for emitting light is provided on one side of the fastening part 200.

Preferably, the LED lamp 400 is fastened to the coupling part 200 with screws.

The LED lamp 400 includes an air passage hole 401 at a central portion thereof and a plurality of radiating fins 402 spaced apart from each other along a top surface of the air passage hole 401, A plurality of LED elements 403 are provided at predetermined intervals along the rim 401 and a globe 404 covering the LED elements 403 is coupled to a lower end thereof.

The LED lamp 400 circulates outdoor air through the air passage hole 401 to allow air to pass through the coupling section 200 and the heat dissipation section 100.

In the LED lamp 400, the heat generated by the LED element 403 is dissipated by the heat pipe 300 and the heat dissipation unit 100.

The LED lamp 400 may be made of glass or synthetic resin, which is transparent or translucent.

One end of the heat pipe 300 is inserted into the pipe inserting portion 102 of the heat dissipating unit 100 and the other end of the heat pipe 300 is securely inserted into the pipe receiving portion 201 of the fastening unit 200.

One end of the heat pipe 300 is changed by the user, and the changed portion is rotated and inserted into the pipe inserting portion 102 in this state, and the deformed portion is pressed on the inner wall surface of the pipe inserting portion 102, And is tightly fixed to the inner wall surface of the pipe insertion portion 102.

It is preferable that the other end of the heat pipe 300, which is forcibly fitted in the pipe receiving portion 201, is in a horizontal state with one surface of the coupling portion 200.

The heat pipe 300 receives heat in a state of being closely attached to a heat-generating component, and transfers the heat to the heat-dissipating unit 100.

The heat pipe 300 is preferably formed to have one end bent.

At least four heat pipes 300 may be installed to transfer heat to the heat dissipation unit 100.

The heat sink for LED lighting fixture according to the present invention configured as described above is used as follows.

A heat sink for an LED lighting fixture according to the present invention is installed selectively in various LED lighting fixtures for generating heat and functions as a heat dissipation device. In the present invention, a heat sink for an LED lighting fixture is installed in the LED lamp 400 shown in FIG. And the heat generated in the LED lamp 400 is dissipated.

4 to 6, when power is applied to the LED lamp 400 to emit light to the LED element 403, light emitted from the LED element 403 is transmitted to the globe 404, As shown in FIG.

At this time, the LED element 403 emits light while emitting heat, and generates heat in the LED lamp 400, and the high heat is generated through the through hole 202 of the coupling part 200, The LED lamp 400 is circulated to the inner and outer surfaces of the LED lamp 400 to dissipate heat.

The heat of the LED lamp 400 heated by the heat emitted from the LED device 403 is transmitted to the heat pipe 300 and the heat is transmitted to the heat pipe 300 by the heat pipe 300, And the LED lamp 400 is cooled.

Particularly, the LED lamp 400 circulates outdoor air to the air passage hole 401 and discharges the heat emitted from the LED device 403 through the heat dissipation fin 101 to the air, .

Meanwhile, the heat dissipation unit 100 continuously circulates outdoor air to the inner and outer circumferential surfaces to maintain the cooling state. In this state, the heat received from the LED lamp 400 and the heat received from the heat pipe 300 Heat is radiated through the radiating fins (101) into the air to radiate heat.

The coupling part 200 guides the heat in the LED lamp 400 to the heat dissipation part 100 through the through hole 202 so that a part of the heat in the LED lamp 400 is discharged through the discharge hole 203 So that the heat inside the LED lamp 400 is quickly dissipated.

It is preferable that the heat that has passed through the through hole 202 and the discharge hole 203 of the coupling part 200 is simultaneously discharged to the inner and outer circumferential surfaces of the heat dissipation part 400.

As described above, the heat sink for the LED lighting fixture that dissipates heat to the heat pipe 300 and the heat dissipating unit 100 is a heat sink that rapidly dissipates heat generated from the component through the heat pipe 300, The heat of the surrounding parts is radiated to the outside through the heat dissipating unit 100 to radiate heat to increase the cooling efficiency of the components and the heat dissipating unit 100 is maintained in a cooled state by the outdoor air circulated inside and outside The heat of the heat pipe 300 and the heat in the apparatus can be rapidly dissipated.

As described above, the present invention is only one embodiment for implementing a heat sink for an LED lighting fixture according to the present invention, and the present invention is not limited to the above-described embodiments, It will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention.

100: heat dissipating unit 101:
102: pipe inserting part 200: fastening part
201: pipe receiving portion 202: through hole
203: discharge hole 300: heat pipe
400: LED lamp 401: air passage ball
402: heat dissipating fin 403: LED element
404: Globe

Claims (6)

A heat dissipation unit 100 having a plurality of radiating fins 101 formed on an outer surface thereof in a hollow bar shape and having a pipe insertion portion 102 formed at an annular spacing along an inner surface thereof;
A coupling part 200 tightly coupled to one end of the heat dissipating part 100 and having a pipe receiving part 201 formed on one surface thereof and perpendicular to the pipe inserting hole 102;
A heat pipe 300 one end of which is inserted into the pipe inserting portion 102 of the heat dissipating unit 100 and the other end of which is securely fitted to the pipe receiving portion 201 of the connecting unit 200;
And a heat sink for LED lighting fixture. The method according to claim 1,
Wherein the fastening part (200) is formed with a through hole (202) through which air supplied through the heat dissipating part (100) is passed, at a central part thereof. 3. The method according to claim 1 or 2,
Wherein a plurality of discharge holes (203) for discharging the air supplied through the heat dissipating unit (100) to the outside are formed on the outer surface of the fastening unit (200) so as to be spaced apart from each other at a predetermined interval. The method according to claim 1,
Wherein the pipe support part (201) is formed in an arch shape so as to surround the heat pipe (300). The method according to claim 1,
And an LED lamp (400) for emitting light is installed on one side of the coupling part (200). 6. The method of claim 5,
The LED lamp 400 includes an air passage hole 401 at a central portion thereof and a plurality of radiating fins 402 spaced apart from each other along a top surface of the air passage hole 401, Wherein a plurality of LED elements 403 are provided at predetermined intervals along a rim of the LED 401 and a globe 404 covering the LED element 403 is coupled to a lower end thereof. Heatsink.

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