KR200271900Y1 - Heat pipe - Google Patents

Abstract

The present invention relates to a heat pipe for heat exchange,

In the present invention, a plurality of heat dissipation fins are integrally formed with the main body to have improved thermal conductivity, and an inner diameter is provided for a heat pipe for heat exchange in which a lattice groove is formed to increase a contact area.

Description

Heat pipe for heat exchange {HEAT PIPE}

The present invention relates to a heat pipe for heat exchange, and more particularly, to form a plurality of heat dissipation fins integrally with the main body to have an improved thermal conductivity, and to an internal diameter heat pipe for heat exchange in which a lattice groove is formed to increase the contact area. It is about.

Generally, a heat exchanger is a device for transferring heat from a high temperature or low temperature fluid to a low temperature or high temperature fluid through a heat transfer wall, and the heat exchanger is used in a heater, a cooler, an evaporator, a condenser, and the like.

In addition, it is common to use a gas or a liquid as the fluid used for the heat exchange, and the heat transfer wall of the heat exchanger is configured by using a metal tube.

Such heat exchangers can be used for various purposes such as waste heat recovery in industrial sites, engine overheating of automobiles and heavy equipment, air conditioners, heaters for refrigerators or heating, power generation, refrigeration, air purification, food manufacturing processes, chemical processes, oil refining and transportation. It is used.

1 is a block diagram of a conventional heat exchanger, and shows a heat exchanger 20 using air as a cooling fluid.

As shown, the inlet 23 is provided at the upper left of the heat exchanger 20, and the outlet 24 is provided at the lower right of the heat exchanger 20 so that the heat-exchanged fluid is discharged to the outlet 24 via the lower tank 25. do. The fluid to be cooled is introduced into the upper tank 22 through the inlet 23.

On the other hand, a plurality of heat transfer pipe 28 is coupled between the upper tank 22 and the lower tank 25, so as to act as a cooling movement path of the cooled fluid flowing from the inlet 23 and discharged to the outlet 24. On the side of the heat transfer pipe 28, an uneven fin 26 is installed to improve the cooling efficiency of the fluid to be cooled.

That is, the high-temperature cooled fluid flows into the upper tank 22 through the inlet 23, and the cooled fluid in the upper tank 22 passes through the plurality of heat transfer pipes 28, and the outer circumferential edge of the heat transfer pipe 28. The fins 26 are cooled by heat exchange with the atmosphere and then discharged through the lower tank 24 to the outlet 24 formed at one side of the lower tank 25.

As described above, the movement paths of the fluid to be cooled in the conventional heat exchanger 20 are in the order of the upper tank 22, the heat transfer pipe 28, and the lower tank 25, so that the plurality of heat transfer pipes 28 having a small area to be cooled can be cooled. Since the passage resistance is increased, there is a problem to lower the heat radiation efficiency of the heat exchanger (20).

In addition, since a plurality of heat transfer tubes 28 are welded between the upper tank 22 and the lower tank 25, there is a high possibility of leakage, leakage and leakage of the cooled fluid.

Therefore, in recent years, a heat pipe having a structure as shown in FIG. 2 is applied as a heat transfer medium to a heat exchanger, thereby improving the cooling or heating rate of a fluid and simplifying the heat exchanger structure to improve product productivity. Has been presented.

However, the heat pipe 100 of the structure shown in Figure 2 has a structure to be fixed by a separate fixing means in the state in which the heat dissipation fin 110 is inserted into the outer circumference of the body taking the rod-shaped body of the contact portion There is a risk of abrasion or breakage, thereby causing a problem in that the heat dissipation performance is lowered.

In addition, the conventional heat pipe absorbs the heat of the high-temperature cooled fluid to increase the thermal contact area between the volatile working fluid (water, alcohol, freon, heat medium, etc.) and the heat dissipation fin, which are vaporized and evaporated, and the working oil smoothly. In order to be able to return to the heat input part, the guide net is installed as the inner diameter of the heat pipe, and as the guide net is installed, the manufacturing has a difficult problem.

Thus, the present invention was devised to solve the general problems of the above-described conventional heat pipe,

The purpose of the present invention is to form a plurality of heat radiation fins integrally with the main body to have improved thermal conductivity, and to eliminate the network installation to increase the contact area and to form a grid groove by the inner diameter to form a heat exchange heat can be simplified In providing pipes.

As a specific means of the present invention for achieving the above object;

The main body taking the rod-shaped body is divided into a heat input part and a heat dissipation part. The outer circumference of the heat dissipation part includes a plurality of heat dissipation fins integrally formed, and the inner diameter of the main body in which the volatile working fluid is filled with a lattice groove at a predetermined interval. It is implemented by having a heat pipe for heat exchange, characterized in that formed.

1 is a block diagram of a conventional heat exchanger

2 is a block diagram of a heat exchanger to which a conventional heat pipe is applied.

3 is a perspective view of a heat pipe according to the present invention

4 is a cross-sectional view of the heat pipe according to the present invention

5 is a configuration diagram of a heater to which a heat pipe according to the present invention is applied;

6 is a state diagram of the heat pipe according to the present invention

<Explanation of symbols for major parts of drawing>

1 heat pipe body 2 heat input unit

3: heat dissipation part 4: heat exchanger

11: lattice groove 31: heat dissipation fin

32: fixture 41: heating source

42: to-be-cooled body 43: heating tank

44: blower fan

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

Figure 3 is a perspective view of a heat pipe according to the present invention, Figure 4 is a cross-sectional view of the heat pipe according to the present invention, Figure 5 is a block diagram of a heater applying the heat pipe according to the present invention, Figure 6 is according to the present invention This is a state diagram of the heat pipe.

As shown therein, the heat pipe body 1 according to the present invention is composed of a heat input part 2 and a heat dissipation part 3, and the heat dissipation fin 31 is integrally formed at the outer circumference of the heat dissipation part 3. As the inner diameter of the main body 1, the grating groove 11 is formed.

Here, in the heat pipe of the present invention, as shown in FIG. 3, the central one side of the main body 1 taking the rod-shaped body corresponds to the heat input part 2, and the other center of the heat pipe corresponds to the heat dissipating part 3. It is preferable to apply the metal (copper etc.) which is excellent in thermal conductivity as a structural material of (1).

At this time, the outer circumference of the heat dissipation unit 3 is formed with a heat dissipation fin 31, the heat dissipation fin 31 is a heat dissipation unit through the "pin" processing, which is a thread processing method of the turning process is typically made through the lathe Spirally projected to the outer periphery of (3), the top end of the heat dissipation portion (3) to exclude the configuration of the heat dissipation fin 31, it is applied to the fixture 32 when installing the heater to be described later (heat dissipation fin 31). It is desirable to consider its own strength to prevent bending of the pin when machining.)

On the other hand, as the inner diameter of the main body 1 is filled with a volatile working fluid as shown in Figure 4 the groove 11 is formed in a lattice form, which is formed in the form of a conventional knurling processing method.

Thus, the heat pipe according to the present invention having the configuration as described above is applied to a heat exchanger that is used in various industrial fields, the application example to the heat exchanger (4) of the heater as a representative example through FIG.

As shown in the drawing, the heat exchanger 4 to which the heat pipe of the present invention is applied has a heating source (electric heater rod 41) installed at the lower end of the main body 1, and a heating tank in which the cooled fluid 42 is filled. 43 is located,

At least one heat pipe is installed at an upper portion of the tank 43, and the heat input portion 2 of each heat pipe is inserted into the tank 43 to fix the heat radiation fin 31 of the heat dissipation portion 3 to the tank 43. ) To the top, and the heat dissipating part (3) end fixture 32 is fixed to the upper frame.

Accordingly, in the heat exchanger 4 to which the heat pipe of the present invention is applied as described above, the cooled fluid 42 heated by the heating source 41 contacts the heat input part 2 of the plurality of heat pipes to exchange heat. do.

Referring to such a conventional heat exchange process in detail, it is a volatile working fluid such as water filled in the heat pipe (4), alcohol, freon, heat medium, etc. as shown in FIG. The heat of 42) is rapidly vaporized and evaporated by the absorption of heat, and the evaporated working fluid is transferred to the heat dissipation unit 3 in the heat pipe by the density of itself.

At this time, the evaporated working fluid is rapidly condensed because the heat is lost by the plurality of heat dissipation fins 31 formed at the outer circumference of the heat dissipating part 3 while passing through the heat dissipating part 3, and the condensed working fluid is gravity again. By returning the heat pipe inner wall surface to the heat input part 2 by the physical force of the back, the circulation process as described in the former is repeated.

On the other hand, as shown in Figure 6 by placing the blower fan 44 to one side of the heat dissipation unit 3 it is possible to perform the indoor heating while discharging the heat radiated from the heat dissipation fin 31 to the outside.

In the heat pipe of the present invention, the grid groove 11 is formed in the inner diameter of the main body 1 corresponding to the flow path of the working fluid as described above, so that the working fluid is indirectly connected to the cooled fluid 44 or the heat dissipation fin 31. It is possible to improve the area to be contacted to increase the heat exchange efficiency, the heat radiation fin (31) formed by the heat dissipation portion (3) is to be improved as much as the heat dissipation efficiency is formed as a structure integrated in the outer circumference.

In addition, such heat pipes can be used for various industrial machines (except waste heat recovery at industrial sites, engine overheating of automobiles and heavy equipment, air conditioners, refrigerators, power generation, refrigeration, air purification, food manufacturing) in addition to the heaters described as applications. Industrial machinery applied to processes, chemical processes, oil refining and transportation.

As described above, the heat pipe for heat exchange according to the present invention can form a heat dissipation fin formed at the outer circumference of the heat dissipation unit integrally with the heat dissipation unit through "fin" processing, so that the manufacturing process of welding and the like can be excluded as before. Ease of use, as well as having an improved thermal conductivity is to improve the heat dissipation efficiency.

In addition, it is possible to simplify the structure by forming a grid groove for increasing the contact area by the inner diameter of the body to eliminate the existing network installation.

Claims (3)

The main body taking the rod-shaped body is divided into a heat input part and a heat dissipation part. The outer circumference of the heat dissipation part includes a plurality of heat dissipation fins integrally formed, and the inner diameter of the main body in which the volatile working fluid is filled with a lattice groove at a predetermined interval. Heat pipe for heat exchange, characterized in that formed. The heat pipe for heat exchange according to claim 1, wherein the plurality of heat dissipation fins integrally formed in the heat dissipation unit has a spiral shape. The heat pipe for heat exchange according to claim 1, wherein a fixing tool, which is a fixing means of the main body, is formed at the uppermost end of the heat dissipation unit.