KR200464282Y1 - Heating pipe having radial drainage structure - Google Patents

Abstract

The present invention relates to a heat pipe having a radial drainage structure, the heat pipe having a radial drainage structure comprising: a hollow main body; A first capillary structure installed on the inner wall surface of the main body; A trench disposed adjacent to the first capillary structure; An evaporation section and a condensation section respectively installed on both sides of the main body, wherein the main body is filled with a working fluid and circulated, and the first capillary structure penetrates the plurality of evaporation sections in the axial direction on the surface of the main body. It is made of a protruding part installed to extend to the condensation section, a guide groove installed in the form of a screw in the evaporation section, the trench is installed between the protruding parts, the guide groove is cut in the radial shape of the protruding part surface is evaporated Two adjacent trenches of the section portion are connected to each other through the guide groove. According to this, by introducing the working fluid flowing into the evaporation section to a position close to the heating element, it is possible to obtain the effect of increasing the evaporation speed of the working fluid and increasing the storage volume of the working fluid further, so that the local storage capacity of the working fluid is increased. Can be increased.

Description

Heat pipe with radial drainage structure {HEATING PIPE HAVING RADIAL DRAINAGE STRUCTURE}

The present invention relates to a heat pipe having a radial drainage structure, and more particularly to a heat pipe having a composite capillary structure of the radial drainage structure.

Conventional heat pipes have many advantages such as small heat pipe volume, light weight, long life, high thermal conductivity, high thermal conductivity, and can be used without additional external devices. It is very widely used.

Its main content is to conduct long-range, high-efficiency heat conduction using the principle of sealing the working fluid inside and absorbing and dissipating heat in response to weather changes.

When the outside of the heat pipe is in contact with the heat source, the working fluid inside the heat pipe becomes saturated and evaporates to take heat, and then, due to the gas pressure difference, the heat is rapidly moved to the condensation zone. In the above, the fluid dissipates heat, and the capillary structure provided in the tube moves the working fluid to the heat source part due to the difference in the fluid pressure, so that a high-efficiency heat conduction circulation operation is performed from the evaporation section to the condensation section.

Various complex capillaries are currently available on the market, and these various structures are intended to compensate for the shortcomings of a single capillary structure. However, most of them use a method of simply designing a plurality of heat sources and sending them to the same evaporation section, or by dividing the steps in the axial direction so that the capillary structure corresponds to the plurality of heat sources described above.

The trench-type capillary structure used in this type of heat pipe is designed axially, so that the diameters of the holes match so that the flow of fluid is controlled axially. As a result, the fluid in the opposite side and side trenches of the heat source cannot be returned directly to the evaporation zone, thereby affecting the maximum thermal conductivity. In addition to the capillary structure frequently used among other capillary structures, there is a method of reinforcing the capillary structure by using a rod-shaped net fiber method and a sintered powder, but such a structure also has a disadvantage in that the fluid flow is resisted in each direction. .

Therefore, the problem to be solved by the present invention is to form a first capillary structure in the evaporation section of the main body to trench each other and to return the working fluid flowing back to the evaporation section directly to a position close to the heating element, the heat source is emitted from the heating element for work By heating the fluid directly, it speeds up the evaporation rate of the working fluid, and increases the storage volume of the working fluid to increase the storage volume of the local working fluid, thereby preventing the fluid from drying out and burning. It is to provide a heat pipe with a radial drainage structure for improvement.

Heat pipe having a radial drainage structure according to an embodiment of the present invention for solving the above problems relates to a heat pipe having a radial drainage structure, the hollow body; A first capillary structure installed on the inner wall surface of the main body; A trench disposed adjacent to the first capillary structure; An evaporation section and a condensation section respectively installed on both sides of the main body, wherein the main body is filled with a working fluid and circulated, and the first capillary structure penetrates the plurality of evaporation sections in the axial direction on the surface of the main body. The protrusion is installed to extend to the condensation section, the guide groove is provided in the form of a screw in the evaporation section, the trench is installed between the protrusion, the guide groove is cut radially on the surface of the protruding parts Two adjacent trenches of the evaporation section are connected to each other through the guide grooves.

The guide groove may be configured in the form of a continuous screw, the trench and the guide groove may be formed in a net shape to cross each other.

A second capillary structure may be formed in the localized portion of the first capillary surface of the evaporation section in a sintered manner, and the second capillary structure may be filled with the trench and the guide groove and cover the protruding part surface.

The present invention can achieve the following effects by complementing and solving the disadvantages of the conventional structure.

(1) The first capillary structure 2 of the present invention uses a guide groove 22 in the form of a radial screw to connect a work fluid flowing into an evaporation section by connecting the trench 21 and the trench 21 with each other. By directly heating to the near position of the heat generating element 4 to heat the working fluid using a heat source emanating from the heat generating element 4 element to vaporize the working fluid at high speed without passing the heat transfer of the main body 1 In addition, the cross section between the trench 21 and the guide groove 22 of the first capillary structure 2 in a shape corresponding to each other to increase the storage volume of the working fluid to increase the local storage of the working fluid to increase the fluid The evaporation effect can be improved by preventing drying in the heating process.

(2) The flow resistance of the first capillary structure 2 is relatively small and the flow rate is the fastest, but is limited by the total flow cross-sectional area, and thus is influenced by the overall flow amount, whereas the total flow of the second capillary structure 3 is Although the cutting area is relatively large and the fluid flows in all directions, it is less affected by gravity, but has a disadvantage in that the capillary force is excessively strong and the flow resistance is large and the flow rate is slow. Therefore, the present invention combines the advantages of the first capillary structure 2 and the second capillary structure 3 described above, and eliminates the disadvantages of the first capillary structure 2 and the second capillary structure 3, and thus the evaporation section 11. The first capillary structure 2 on) is connected to each other through the trench 21 and the trench 21 using a continuous threaded guide groove 22, and the second capillary structure 3 is further added thereto. By increasing the evaporation area, the flow rate of the fluid is controlled in each section, and the difference between the first capillary structure 2 and the second capillary structure 3 and the flow characteristics are properly combined with each other, so that different working fluid flows and different heat sources The functions are harmoniously utilized.

1 is a side anatomy of the present invention.
Figure 2 is a front anatomy of the present invention.
Figure 3 is a local anatomy of the present invention.
Figure 4 is a side anatomy when using the present invention.
5 is a side view of another comparatively good embodiment of the present invention.
6 is a front anatomical view of yet another comparatively good embodiment of the present invention.

In order to explain the present invention more clearly, the present invention will be described with reference to the accompanying drawings.

1 and 2, the present invention includes a hollow body 1, a first capillary structure 2 is installed on the inner wall surface of the body 1, the first capillary structure ( 2) A second capillary structure 3 is sintered to the localized portion of the surface. Evaporation section 11 and the condensation section 12 are respectively installed on both side surfaces of the main body 1 and the working fluid is filled in the main body 1.

      In the axial direction of the first capillary structure 2, a protruding part 23 extending through the plurality of evaporation sections 11 and connected to the condensing section 12 is installed, and between two adjacent protruding parts 23. The trench 21 is formed in this.

In addition, the first capillary structure (2) is provided with a guide screw 22 in the form of a continuous screw in the evaporation section (11), the guide groove 22 is formed in the radial shape cut from the surface of the protruding part (23).

Two adjacent trenches 21 in the evaporation section 11 are connected to each other through the guide grooves 22, and the trenches 21 and the guide grooves 22 cross each other to form a net shape.

The guide groove 22 may be formed by cutting, pressing, forging, or the like, and the diameter of the capillary hole of the guide groove 22 may be larger or smaller than that of the trench 21.

     The second capillary structure 3 is formed on the surface of the evaporation section 11 of the first capillary structure 2 in a sintered manner, is filled between the trench 21 and the guide groove 22, and the protruding part 23. Covering the surface.

In addition, the second capillary structure (3) is provided with a plurality of axial intervals, the second capillary structure (3) is formed by one of a fiber net method, a powder sintering method, a polymer material or any composite method rich in water content. Can be.

       Looking at the example of using the present invention while simultaneously referring to the contents of Figures 1 to 4, first, the heating element 4 is in contact with the lower end of the evaporation section 11 of the main body 1, the second capillary structure (3) ), The heat generating element 4 is absorbed by the evaporation section 11 of the main body 1 when starting the operation, the first capillary structure ( Up to 2) and the second capillary structure (3).

At this time, after the first capillary structure 2 and the second capillary structure 3 absorb the heat source of the heating element 4, the working fluid is in the first capillary structure 2 and the second capillary structure 3. Boiling occurs and when the working fluid boils at a constant temperature and becomes saturated, the evaporation section 11 directly absorbs the heat source emitted from the heat generating element 4 so that the first capillary structure 2 and the second capillary structure are absorbed. Because of the transfer to (3), the temperature of the condensation section 12 is lower than the evaporation section 11 so that a difference in temperature occurs.

As a result, the vaporized working fluid flows into the condensation section 12, and in this process, it takes together the heat energy generated from the heat source, and when the steam arrives at the condensing section 12, the condensation is again condensed into the working fluid.

And the capillary force generated through the first capillary structure (2) sends the working fluid after condensation back to the evaporation section (11), through this process continues without adding a separate power in the whole process You can proceed with the rotation.

In addition, since the trenches 21 of the first capillary structure 2 are horizontally spaced apart from each other, the working fluid does not flow between the trenches 21 and the trenches 21, so that the work fluid is adjacent to the heat generating element 4. Only the trench 21 in the place directly absorbs the heat source of the heat generating element 4 to perform the heating and circulation work for the working fluid, and the trench 21 installed at a part far from the other heat generating element 4 has a main body. Since the heat conduction work can be performed only through (1), the heating work is indirectly performed on the working fluid in the trench 21, so that the heat source emitted from the heating element 4 can be conducted through one more step. Will be.

Therefore, the guide groove 22 in the form of a radial screw draws the working fluid returned to the evaporation section 11 to a position adjacent to the heat generating element 4, and in this process, the first capillary is not required without the heat conduction of the main body 1. The trench 21 and the guide groove 22 of the structure 2 can be used completely.

In addition, since the total cutting area of the fluid passage of the second capillary structure 3 is relatively large, it is very easy to evaporate because the working fluid flow is circulated at high speed without any resistance in all directions.

5 and 6, since the second capillary structure 3 is installed on the surface of the evaporation section 11 in a sintered manner, this also has the effect of accelerating the evaporation of the working fluid. You can get it.

The above description has been given by way of example only comparatively excellent embodiments to explain in detail the features and advantages of the present invention as the scope of the utility model registration claim is not limited to this within the spirit and scope of the utility model registration application In the case of changes and other modifications in the process also included in the utility model registration claims.

1: main body 11: evaporation section
12: condensation section 2: first capillary structure
21: trench 22: guide groove
23: protrusion part 3: second capillary structure
4: heating element

Claims (3)

As about heat pipe with radial drainage structure,
A hollow body 1;
A first capillary structure (2) installed on an inner wall surface of the main body;
A trench 21 adjacent to the first capillary structure 2;
Evaporation section 11 and the condensation section 12 which are respectively installed on both sides of the main body 1; including,
Inside the main body 1 is filled with a working fluid is circulated,
The first capillary structure 2 is
Protruding part 23 is installed to extend to the condensation section 12 through the plurality of evaporation section 11 in the axial direction on the surface of the main body 1,
Consists of a guide groove 22 installed in the evaporation section 11 in the form of a screw,
The trench 21 is installed between the protruding parts 23,
The guide groove 22 is cut radially from the surface of the protruding part 23 so that the two adjacent trenches 21 of the evaporation section 11 are connected to each other through the guide groove 22. Become,
The guide groove 22 is composed of a continuous screw form,
The trench 21 and the guide groove 22 are formed in a net shape to cross each other, and
A second capillary structure 3 is formed in the localized portion of the surface of the first capillary structure 2 in the evaporation section 11 by a sintering method, and the second capillary structure 3 is formed in the trench 21 and the A heat pipe having a radial drainage structure, characterized in that it is filled with a guide groove (22) and covers the surface of the protruding part (23). delete delete

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