KR102235820B1 - LED cooling unit by heat pipe with the condensated liquid absorbing wick and the liquid return wick of rod type - Google Patents

Abstract

The present invention relates to an LED cooling device using a heat pipe having a condensate suction wick and a rod-type condensate return wick, and more particularly, a heat pipe is coupled to one side of an LED that is driven to generate light irrespective of the direction of the LED light. , In the evaporation wick containing the working fluid in the heat pipe, the working fluid in the liquid state in the evaporation wick is evaporated by the heat generated by the LED, and the working fluid, which has become a gas, is cooled with a cooling fan attached to the condenser to cool the suction wick and return wick. It relates to an LED cooling device using a heat pipe having a condensate suction wick and a rod-type condensate return wick to allow continuous and rapid cooling of the LED by returning to the evaporation wick through the wick.

Description

LED cooling unit by heat pipe with the condensated liquid absorbing wick and the liquid return wick of rod type}

The present invention is a condensate suction wick that has an evaporation wick, a suction wick, and a return wick inside a heat pipe to cool the LED generated during operation by evaporation of the working fluid, and to condense the evaporated working fluid so that it can be used for cooling. And an LED cooling device using a heat pipe having a rod-type condensate return wick.

LED (Light Emitting Diode) is a kind of semiconductor that uses a phenomenon in which electric energy changes into light energy when voltage is applied to emit light.

Lighting equipment using such LEDs has the advantage of being able to implement various colors of light as well as low power consumption compared to incandescent lamps, which are currently mainly used as lighting equipment, but there is also a disadvantage of increasing heat generation.

However, there is a problem in that the large-capacity LED lighting fixtures currently used do not effectively cool the heat generated from the LED during operation when the light is directed upward.

Accordingly, development of a device capable of solving such a problem is on the rise.

Korean Registered Patent Publication No. 10-1035100 (registered on May 9, 2011)

The present invention was conceived to solve the above problems, and an object of the present invention is to enable a large-capacity LED that generates heat during use to be operated regardless of the direction of light and to be efficiently cooled during operation to be used, A heat pipe is installed at one end of the LED, and the evaporation wick, suction wick, and return wick are installed in the heat pipe. The condensate suction wick and the rod-type condensate return wick are structured to be cooled and returned to the evaporation wick by the capillary force of the return wick, and can be used for LED cooling even when directed upward, horizontally and downwardly, regardless of the direction of the LED light. It is to provide an LED cooling device using a heat pipe.

Other objects and advantages of the present invention will be described below, and will be understood by examples of the present invention. Further, the objects and advantages of the present invention can be realized by means and combinations shown in the claims.

The present invention is a means for solving the above problems,

A heat pipe 10 composed of a hollow evaporation unit 20 and a tube-shaped condensation unit 30 that is connected to the center of one surface of the evaporation unit 20 and extends in the longitudinal direction; An LED 40 installed on an outer surface of the evaporation unit 20 to emit light; It is formed on one side of the evaporation unit 20 and contains a working fluid (W) therein. When the LED 40 is driven, the working fluid (W) is evaporated by heat generation, and the working fluid vapor (W1) The evaporation wick 50 is generated; A suction wick 60 that is formed at one end of the condensing unit 30 and is condensed while moving to the end of the condensing unit 30 along the longitudinal direction of the working fluid vapor W1 and absorbed into the working fluid condensate W2. ); It is installed to connect the evaporation wick 50 and the suction wick 60 in the heat pipe 10, so that the working fluid condensate W2 in the suction wick 60 is sucked by the capillary force to the evaporation wick 50. A return wick 70 for cooling the LED 40 with a working fluid condensate (W2) to be returned; Including a large-capacity LED light source is characterized in that it is possible to cool in any direction.

As described above, in the present invention, the large-capacity LED light source being driven can be operated in any direction and can be easily and easily cooled, so that there is an effect that can be used for a long time and extended life.

In addition, the present invention cools the heat generated by the large-capacity LED light source in a short time by attaching a cooling fin to the surface of the condensing part to the working fluid evaporated by the heat generated by the LED, allowing the working fluid of the heat pipe to return to the evaporation wick to cool the LED By being used for, there is an effect of increasing the cooling efficiency.

In addition, the present invention has the effect of installing an evaporating wick, a suction wick, and a return wick in the heat pipe, so that the evaporation, movement, condensation, and return of the working fluid are made quickly, and it operates regardless of the direction of the light source to enable efficient cooling There is.

1 is a view showing a first embodiment of an LED cooling device using a heat pipe having a condensate suction wick and a rod-type condensate return wick according to the present invention.
2 is a view showing the second and third embodiments of the LED cooling device using a heat pipe having a condensate suction wick and a rod-type condensate return wick according to the present invention.
3 and 4 are views of an embodiment showing a cooling fin according to the present invention.
Figure 5 is a view of one embodiment showing a double tube type for the steam flow path according to the present invention.
Figure 6 is a view of an embodiment showing the form of a double tube of the condensing unit according to the present invention.

Before describing various embodiments of the present invention in detail, it will be appreciated that the application is not limited to the details of configurations and arrangements of elements described in the following detailed description or illustrated in the drawings. The present invention can be implemented and practiced in different embodiments, and can be carried out in various ways. Also, device or element orientation (eg "front", "back", "up", "down", "top", "bottom" The expressions and predicates used herein with respect to terms such as ", "left", "right", "lateral"), etc. are used only to simplify the description of the present invention, and related devices Or you will find that the element simply does not indicate or implies that it should have a particular orientation. Further, terms such as “first” and “second” are used in this application and the appended claims for purposes of explanation and are not intended to represent or imply any relative importance or spirit.

The present invention has the following features to achieve the above object.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. Prior to this, terms or words used in the specification and claims should not be construed as being limited to their usual or dictionary meanings, and the inventors appropriately explain the concept of terms in order to explain their own invention in the best way. Based on the principle that it can be defined, it should be interpreted as a meaning and concept consistent with the technical idea of the present invention.

Accordingly, the embodiments described in the present specification and the configurations shown in the drawings are only the most preferred embodiment of the present invention, and do not represent all the technical spirit of the present invention. It should be understood that there may be equivalents and variations.

Looking at an embodiment according to the present invention,
In the first embodiment, a heat pipe 10 consisting of a hollow evaporation unit 20 and a tubular condensation unit 30 that is connected to the center of one surface of the evaporation unit 20 and extends in the longitudinal direction; An LED 40 installed on an outer surface of the evaporation unit 20 to emit light; An evaporation wick 50 that is formed on one side of the evaporation unit 20 and contains a working fluid W therein, so that the working fluid W is evaporated by heat when the LED 40 is driven; A suction wick 60 that is formed at one end of the condensing unit 30 and is condensed while moving to the end of the condensing unit 30 along the longitudinal direction of the working fluid vapor W1 and absorbed into the working fluid condensate W2. ); It is installed to connect the evaporation wick 50 and the suction wick 60 in the heat pipe 10, so that the working fluid condensate W2 in the suction wick 60 is sucked by the capillary force to the evaporation wick 50. Including a return wick 70 for cooling the LED 40 with a working fluid condensate (W2) to be returned,
The evaporation wick 50 and the suction wick 60 are mutually horizontal, and each center of the evaporation wick 50 and the suction wick 60 is a return wick 70 in the condensing part 30 in a longitudinal direction. By connecting, the evaporation wick 50, the suction wick 60, and the return wick 70 are formed in a'├┤' shape, so that the evaporation wick 50 is evaporated and absorbed by the suction wick 60. The fluid condensate (W2) is characterized in that it is moved along the return wick (70) to return to the evaporation wick (50).
The second embodiment includes a heat pipe 10 comprising a hollow evaporation unit 20 and a tubular condensation unit 30 that is connected to the center of the bottom of the evaporation unit 20 and extends in the longitudinal direction; An LED 40 installed on the outer upper surface of the evaporation unit 20 to emit light upward; An evaporation wick 50 formed on an upper surface of the evaporation unit 20 and containing a working fluid W therein, so that the working fluid W is evaporated by heat when the LED 40 is driven; A suction wick 60 that is formed at the lowermost end of the condensing unit 30 and is condensed while moving downwardly to the lowermost end along the longitudinal direction of the condensing unit 30 and absorbed into the working fluid condensate W2. ); It is vertically installed to connect the evaporation wick 50 and the suction wick 60 in the heat pipe 10, so that the working fluid condensate W2 in the suction wick 60 is sucked by capillary force, and the evaporation wick ( 50) to return while moving upward, so that the LED 40 can be cooled with the working fluid condensate (W2);
The evaporation wick 50 and the suction wick 60 are mutually horizontal, and each center of the evaporation wick 50 and the suction wick 60 is a return wick 70 in the condensing part 30 in a longitudinal direction. By connecting the evaporation wick 50, the suction wick 60, and the return wick 70 to have an'I' shape, the working fluid evaporated from the evaporating wick 50 and absorbed by the suction wick 60 The condensate (W2) is characterized in that it is moved along the return wick (70) to return to the evaporation wick (50).
In a third embodiment, a heat pipe 10 composed of a hollow evaporation unit 20 and a tubular condensation unit 30 that is connected to the center of the upper surface of the evaporation unit 20 and extends in the longitudinal direction; An LED 40 installed on the outer bottom surface of the evaporation unit 20 to emit light downward; It is formed on the bottom surface of the evaporation unit 20, and the working fluid W is contained therein. When the LED 40 is driven, the working fluid W is evaporated by heat generation, so that the working fluid vapor W1 is An evaporation wick 50 that moves upward from the evaporation unit 20 in the longitudinal direction of the condensation unit 30, and the working fluid vapor W1 that has been moved upward falls while condensing to be reabsorbed; A suction wick that is formed at the uppermost end of the condensing unit 30 and is condensed while moving upwardly to the uppermost end along the longitudinal direction of the condensing unit 30 and partially absorbed into the working fluid condensate W2. 60); It is vertically installed to connect the evaporation wick 50 and the suction wick 60 in the heat pipe 10, so that the working fluid condensate (W2) sucked in the suction wick 60 is sucked by capillary force, and the evaporation A return wick 70 for cooling the LED 40 with a working fluid condensate (W2) by moving downwardly to the wick 50 and returning to it.
The evaporation wick 50 and the suction wick 60 are mutually horizontal, and each center of the evaporation wick 50 and the suction wick 60 is a return wick 70 in the condensing part 30 in a longitudinal direction. By connecting the evaporation wick 50, the suction wick 60, and the return wick 70 to have an'I' shape, the working fluid evaporated from the evaporating wick 50 and absorbed by the suction wick 60 The condensate (W2) is characterized in that it is moved along the return wick (70) to return to the evaporation wick (50).
In addition, a plurality of the heat pipes 10 are spaced apart and protrude in the longitudinal direction, and a cooling fin 80 for increasing the condensation efficiency of the working fluid vapor W1; is provided,
The shape and number of the cooling fins 80 can be changed according to the preset temperature range of the working fluid W in the heat pipe 10,
A central hole for fastening to the outer periphery of the heat pipe 10 is perforated, and cooling fins 80 in the form of a plurality of circular plates having the same diameter are spaced apart from each other in the longitudinal direction of the heat pipe 10. Form 1 (A), or
A central hole for fastening to the outer periphery of the heat pipe 10 is formed, and a plurality of circular plate-shaped cooling fins 80 are spaced apart from each other toward the length direction of the heat pipe 10, and the plurality of cooling fins (80) is a second form (B) in which a cooling fin 80 whose diameter gradually decreases toward the moving direction of the working fluid vapor (W1) is used, or
The third form (C) is formed protruding from the outer periphery of the heat pipe 10 in the longitudinal direction, and a plurality of peripherals are spaced apart from each other and installed around the outer periphery of the heat pipe 10, or
It is formed protruding from the outer periphery of the heat pipe 10 in the longitudinal direction, and a plurality of them are spaced apart from each other around the outer periphery of the heat pipe 10, and each cooling fin 80 is a working fluid vapor (W1). It is characterized in that it is any one of the fourth form (D) having a form in which the width gradually decreases toward the moving direction of.
In addition, the condensing unit 30 has a plurality of ring-shaped first guide grooves 91 spaced apart from each other in the longitudinal direction, so that the condensed working fluid condensed along the first guide groove 91 ( W2) is easily guided and moved toward the evaporation wick 50,
Each second guide groove 92 of a straight line toward the longitudinal direction is formed on the inner periphery of the condensation part 30, and the second guide groove 92 crosses a plurality of first guide grooves 91 In this way, the working fluid condensate (W2) condensed along the first guide groove (91) is collected in the second guide groove (92) so that it can be easily moved toward the evaporation wick (50).
In addition, the condensation unit 30 has a double tube structure consisting of an inner tube 31 in which the return wick 70 is installed, and an outer tube 32 installed outside the inner tube 31, A steam flow path 33 through which the working fluid vapor W1 and the working fluid condensate W2 are moved is formed between the inner tube 31 and the outer tube 32.

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Hereinafter, an LED cooling device using a heat pipe having a condensate suction wick and a rod-type condensate return wick according to a preferred embodiment of the present invention will be described in detail with reference to FIGS. 1 to 6.

The LED cooling device using a heat pipe having a condensate suction wick and a rod-type condensate return wick of the present invention includes a heat pipe 10, LED 40 (Light-Emitting Diode), evaporation wick 50, suction wick 60, It includes a return wick (70), cooling fins (80).

First, in the LED cooling device using a heat pipe having a condensate suction wick and a rod-type condensate return wick according to the present invention, a heat pipe 10 is installed on one side of the LED 40, but the light of the LED 40 is horizontal. In the first case of installing the device horizontally so as to face, the second case of installing the device vertically so that the light of the LED 40 faces upward and the LED 40 is located at the top of the device, the light of the LED 40 In the third case, in which the LED 40 is vertically installed so that the LED 40 is located at the bottom of the device (to be opposite to the second case), a total of three embodiments are presented.

Of course, the following configurations to be installed inside are all the same, and the installation form varies depending on where the light of the LED 40 is directed, but in the present invention, the evaporation wick 50, which will be described later, and the suction wick ( 60), by configuring the return wick 70, the LED 40, regardless of which direction (horizontal, upper, lower) to emit light, regardless of the installation type (horizontal, vertical), the inside of the evaporation wick 50 The working fluid (W) is evaporated by the heat of the LED (40), then cooled and moved to the original evaporation wick (50) so that it can be used for cooling. Thus, it is possible to continuously operate the LED (40).

First, for convenience of explanation, in the first case, that is, the case where the LED 40 is installed horizontally with the light facing the ground, and the entire device is installed horizontally with the ground, the configurations of the device will be described.

The heat pipe 10 is composed of a hollow evaporation unit 20 and a tubular condensation unit 30 that is connected to the center of one side of the evaporation unit 20 and extends in the longitudinal direction, and is horizontal with the ground. It is installed as.

In this case, the diameter of the evaporation unit 20 is such that the condensation unit 30 has a larger circular cross section than the evaporation unit 20, and the length of the condensation unit 30 is relatively longer than that of the evaporation unit 20. The part 20 is a disk, and the condensation part 30 is in the shape of a rod having a circular cross-section, so that it has a'T' shape.

In addition, a separate power supply device is connected to and fixedly installed on an outer surface of the evaporation unit 20 to emit or emit light (light).

Of course, the diameter of the evaporation unit 20 will be the same as the diameter of the LED 40, the cross-sectional shape of the heat pipe 10 is a shape corresponding to the shape of the LED 40, according to the user's embodiment, circular, It is natural that it can be changed in various ways, such as square and multiple angles.

In addition, the condensing unit 30 has a plurality of ring-shaped first guide grooves 91 spaced apart from each other in the longitudinal direction, so that the condensed working fluid condensed along the first guide groove 91 ( W2) can be easily guided and moved to the evaporation wick 50 side.

In addition, in addition to the first guide groove 91, each second guide groove 92 of a straight line toward the longitudinal direction is formed on the inner periphery of the condensing portion 30, the second guide groove 92 A plurality of first guide grooves 91 are intersected so that the working fluid condensate W2 condensed along the first guide groove 91 is collected in the second guide groove 92 and the suction wick 60 It can be easily moved to the side.

In addition, as another embodiment for the movement of the working fluid vapor (W1) and the working fluid condensate (W2), the condensing unit 30 includes an inner tube 31 in which a return wick 70 is installed, and the inner It has a double pipe structure consisting of an outer pipe 32 installed on the outside of the pipe 31, and between the inner pipe 31 and the outer pipe 32, the working fluid vapor W1 and the working fluid condensate ( It is also possible to form a vapor flow path 33 through which W2) is moved.

The evaporation wick 50 is formed on one side of the evaporation unit 20, has a shape corresponding to one side of the evaporation unit 20, and contains a working fluid (W) therein, and the LED 40 When driving to generate light, the working fluid (W) is evaporated by the driving heat of the LED (40), and the evaporated working fluid vapor (W1) is evaporated in the longitudinal direction of the condensing unit (30) in the evaporation unit (20). It is to move horizontally toward the direction.

That is, the evaporation wick 50 is located in the evaporation unit 20, but is installed on a surface corresponding to the LED 40 in the evaporation unit 20.

The suction wick 60 is formed at one end of the condensing unit 30 and has a shape corresponding to one surface of the condensing unit 30, and the working fluid vapor W1 evaporated from the above-described evaporation wick 50 A, when gradually condensing while moving horizontally to the end along the longitudinal direction of the condensing part 30, this is a part in which the working fluid condensate W2 is absorbed.

The return wick 70 has a rod shape, and is horizontally installed in the center of the heat pipe 10 in the heat pipe 10, one end is connected to the evaporation wick 50, and the other end, the suction wick 60 It is installed horizontally so as to connect with, so that the evaporation wick 50, the return wick 70, and the suction wick 60 have an'I'-shaped structure in which they are laid on each other.

This return wick 70 is such that the working fluid condensate W2, which is moved into the suction wick 60 and absorbed, is sucked by the capillary force of the return wick 70 and is returned to the evaporation wick 50 side. In 50), the LED 40 can be cooled with the working fluid condensate (W2).

The cooling fins 80 are formed protruding from the outer periphery of the heat pipe 10, spaced apart from each other in the longitudinal direction, to increase the condensation efficiency of the working fluid vapor W1, and the heat pipe 10 The shape and number can be changed according to the preset operating temperature range of the internal working fluid (W).

A total of four forms of the cooling fin 80 are presented in the present invention.

1. First Form (A): The heat pipe 10 has a shape of a circular plate in which a central hole for fastening to the outer periphery of the heat pipe 10 is perforated, and the cooling fins 80 of this circular plate are a plurality of the heat pipes having the same diameter. It is installed spaced apart toward the length direction of (10).

2. Second form (B): A central hole for fastening to the outer periphery of the heat pipe 10 has a circular plate shape in which a hole is formed, and a plurality of circular plate-shaped cooling fins toward the longitudinal direction of the heat pipe 10 (80) is installed spaced apart, the plurality of cooling fins (80) toward the moving direction of the working fluid vapor (W1), a form in which a cooling fin (80) whose diameter gradually decreases is used.

That is, the cooling fins 80 in the second form (B) all have different diameters, and these are gradually smaller toward the longitudinal direction of the heat pipe 10 (the moving direction of the working fluid vapor (W1)). The cooling fin 80 is to be fastened.

3. Third form (C): It is formed protruding from the outer periphery of the heat pipe 10 in the longitudinal direction, and a plurality of them are spaced apart from each other around the outer periphery of the heat pipe 10 and installed.

4. Fourth form (D): It is formed protruding from the outer periphery of the heat pipe 10 in the longitudinal direction, and a plurality of them are spaced apart from each other around the outer periphery of the heat pipe 10, and each cooling fin ( 80) is a form in which the width gradually decreases toward the moving direction of the working fluid vapor (W1).

The cooling fin 80 in the present invention is formed in one of the first, second, third, and fourth forms (A, B, C, D) described above.

In addition, in the present invention, as described above, the case with the return wing 70 has been described, but when the LED light is directed to the bottom, the return wing 70 may be implemented in an unused form.

That is, even if the earpiece wing 70 is installed as described in the present invention, the working fluid condensate (W2) automatically evaporates and moves automatically, so it can be configured in a form without the return wing 70 as follows. have.

That is, a heat pipe 10 composed of a hollow evaporation unit 20 and a tubular condensation unit 30 that is connected to the center of one surface of the evaporation unit 20 and extends in the longitudinal direction, and the evaporation unit It is installed on the outer side of (20), the LED 40 to emit light, is formed on one side of the evaporation unit 20, the working fluid (W) is contained therein, driving the LED (40) The working fluid vapor (W1) between the inner tube 31 and the outer tube 32 in the form of a double tube constituting the evaporation wick 50 and the condensing unit 30 by which the working fluid W is evaporated during heat generation. ) And the working fluid condensate (W2) is to be in a form in which the vapor flow path 33 is formed.

As a result, since the return of the working fluid condensate W2 is automatically moved to the evaporation wick 50 by gravity, a configuration in which the ear blade 70 can be omitted can be implemented.

As described above, although the present invention has been described by the limited embodiments and drawings, the present invention is not limited thereto, and the technical spirit of the present invention and the following by those of ordinary skill in the technical field to which the present invention pertains. It goes without saying that various modifications and changes are possible within the equivalent range of the claims to be described.

10: heat pipe 20: evaporation unit
30: condensation unit 31: inner tube
32: outer pipe 33: steam flow passage
40: LED 50: evaporation wick
60: suction wick 70: return wick
80: cooling fin 91: first guide groove
92: second guide groove
W: working fluid W1: working fluid vapor
W2: working fluid condensate

Claims (8)

A heat pipe 10 composed of a hollow evaporation unit 20 and a tube-shaped condensation unit 30 that is connected to the center of one surface of the evaporation unit 20 and extends in the longitudinal direction;
An LED 40 installed on an outer surface of the evaporation unit 20 to emit light;
An evaporation wick 50 that is formed on one side of the evaporation unit 20 and contains a working fluid W therein, so that the working fluid W is evaporated by heat when the LED 40 is driven;
A suction wick 60 that is formed at one end of the condensing unit 30 and is condensed while moving to the end of the condensing unit 30 along the longitudinal direction of the working fluid vapor W1 and absorbed into the working fluid condensate W2. );
It is installed to connect the evaporation wick 50 and the suction wick 60 in the heat pipe 10, so that the working fluid condensate W2 in the suction wick 60 is sucked by the capillary force to the evaporation wick 50. Including a return wick 70 for cooling the LED 40 with a working fluid condensate (W2) to be returned,
The evaporation wick 50 and the suction wick 60 are mutually horizontal, and each center of the evaporation wick 50 and the suction wick 60 is a return wick 70 in the condensing part 30 in a longitudinal direction. By connecting, the evaporation wick 50, the suction wick 60, and the return wick 70 are formed in a'├┤' shape,
Condensate suction, characterized in that the working fluid condensate (W2) evaporated from the evaporation wick 50 and absorbed by the suction wick 60 is moved along the return wick 70 and returned to the evaporation wick 50 LED cooling system using heat pipe with wick and ROD type condensate return wick.
A heat pipe 10 composed of a hollow evaporation unit 20 and a tubular condensation unit 30 communicating with the center of the bottom of the evaporation unit 20 and extending in the longitudinal direction;
An LED 40 installed on the outer upper surface of the evaporation unit 20 to emit light upward;
An evaporation wick 50 formed on an upper surface of the evaporation unit 20 and containing a working fluid W therein, so that the working fluid W is evaporated by heat when the LED 40 is driven;
A suction wick 60 that is formed at the lowermost end of the condensing unit 30 and is condensed while moving downwardly to the lowermost end along the longitudinal direction of the condensing unit 30 and absorbed into the working fluid condensate W2. );
It is vertically installed to connect the evaporation wick 50 and the suction wick 60 in the heat pipe 10, so that the working fluid condensate W2 in the suction wick 60 is sucked by capillary force, and the evaporation wick ( 50) to return while moving upward, so that the LED 40 can be cooled with the working fluid condensate (W2);
The evaporation wick 50 and the suction wick 60 are mutually horizontal, and each center of the evaporation wick 50 and the suction wick 60 is a return wick 70 in the condensing part 30 in a longitudinal direction. By connecting, the evaporation wick 50, the suction wick 60, and the return wick 70 are formed in an'I' shape,
Condensate suction, characterized in that the working fluid condensate (W2) evaporated from the evaporation wick 50 and absorbed by the suction wick 60 is moved along the return wick 70 and returned to the evaporation wick 50 LED cooling system using heat pipe with wick and ROD type condensate return wick.
A heat pipe 10 composed of a hollow evaporation unit 20 and a tubular condensation unit 30 that is connected to the center of the upper surface of the evaporation unit 20 and extends in the longitudinal direction;
An LED 40 installed on the outer bottom surface of the evaporation unit 20 to emit light downward;
It is formed on the bottom surface of the evaporation unit 20, and the working fluid W is contained therein. When the LED 40 is driven, the working fluid W is evaporated by heat generation, so that the working fluid vapor W1 is An evaporation wick 50 that moves upward from the evaporation unit 20 in the longitudinal direction of the condensation unit 30, and the working fluid vapor W1 that has been moved upward falls while condensing to be reabsorbed;
A suction wick that is formed at the uppermost end of the condensing unit 30 and is condensed while moving upwardly to the uppermost end along the longitudinal direction of the condensing unit 30 and partially absorbed into the working fluid condensate W2. 60);
It is vertically installed to connect the evaporation wick 50 and the suction wick 60 in the heat pipe 10, so that the working fluid condensate (W2) sucked in the suction wick 60 is sucked by capillary force, and the evaporation A return wick 70 for cooling the LED 40 with a working fluid condensate (W2) by moving downwardly to the wick 50 and returning to it.
The evaporation wick 50 and the suction wick 60 are mutually horizontal, and each center of the evaporation wick 50 and the suction wick 60 is a return wick 70 in the condensing part 30 in a longitudinal direction. By connecting, the evaporation wick 50, the suction wick 60, and the return wick 70 are formed in an'I' shape,
Condensate suction, characterized in that the working fluid condensate (W2) evaporated from the evaporation wick 50 and absorbed by the suction wick 60 is moved along the return wick 70 and returned to the evaporation wick 50 LED cooling system using heat pipe with wick and ROD type condensate return wick.
The method according to any one of claims 1 to 3,
The heat pipe 10 is
A plurality of cooling fins 80 are provided to increase the condensation efficiency of the working fluid vapor (W1) by being spaced apart and protruding in the longitudinal direction,
The cooling fin 80 is
The shape and number of the working fluid (W) in the heat pipe (10) can be changed according to the preset operating temperature range,
A central hole for fastening to the outer periphery of the heat pipe 10 is perforated, and cooling fins 80 in the form of a plurality of circular plates having the same diameter are spaced apart from each other in the longitudinal direction of the heat pipe 10. Form 1 (A), or
A central hole for fastening to the outer periphery of the heat pipe 10 is formed, and a plurality of circular plate-shaped cooling fins 80 are spaced apart from each other toward the length direction of the heat pipe 10, and the plurality of cooling fins (80) is a second form (B) in which a cooling fin 80 whose diameter gradually decreases toward the moving direction of the working fluid vapor (W1) is used, or
The third form (C) is formed protruding from the outer periphery of the heat pipe 10 in the longitudinal direction, and a plurality of peripherals are spaced apart from each other and installed around the outer periphery of the heat pipe 10, or
It is formed protruding from the outer periphery of the heat pipe 10 in the longitudinal direction, and a plurality of them are spaced apart from each other around the outer periphery of the heat pipe 10, and each cooling fin 80 is a working fluid vapor (W1). LED cooling device using a heat pipe having a condensate suction wick and a ROD-type condensate return wick, characterized in that in any one of the fourth form (D) having a form in which the width gradually decreases toward the direction of movement of.
The method of claim 1,
The condensing part 30 is
A plurality of ring-shaped first guide grooves 91 are spaced apart from each other in the longitudinal direction, so that the working fluid condensate (W2) condensed along the first guide groove 91 is directed toward the evaporation wick 50. LED cooling device using a heat pipe having a condensate suction wick and a ROD-type condensate return wick, characterized in that it can be easily guided and moved.
The method of claim 5,
The condensing part 30 is
Each second guide groove 92 of a straight line toward the longitudinal direction is formed on the inner periphery of the condensation part 30, and the second guide groove 92 crosses a plurality of first guide grooves 91 The condensate liquid, characterized in that the working fluid condensate (W2) condensed along the first guide groove (91) is collected in the second guide groove (92) and can be easily moved toward the evaporation wick (50). LED cooling system using heat pipe with suction wick and ROD type condensate return wick.
The method according to any one of claims 1 to 3,
The condensing part 30 is
By having a double tube structure consisting of an inner tube 31 in which the return wick 70 is installed and an outer tube 32 installed outside the inner tube 31,
A condensate suction wick and ROD, characterized in that a vapor flow path 33 through which the working fluid vapor W1 and the working fluid condensate W2 are moved is formed between the inner tube 31 and the outer tube 32 LED cooling device using heat pipe with type condensate return wick.
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