KR200332080Y1 - The Heat Pipe with Heat Source - Google Patents

Abstract

The present invention relates to an integrated (panel type) heat pipe in which a heat source 2 is built in the heat pipe 1 and the heat pipe 1 and the heat source 2 are integrated into one. In the heating construction using heat pipes, a plurality of heat pipes are individually installed at predetermined intervals in the head (hot water pipe), and the underfloor heating construction works in the order of finishing with cement mortar, but the present invention integrates all these processes. As the panel-type heat pipe 1, that is, the panel itself has a heat pipe 1 structure in which the porous hook 4 and the working fluid 3 are embedded, there is no need for cement construction time as well as convenience of construction. (No need for finishing materials such as cement mortar) It is possible to immediately heat and move in construction, and it is possible to work on heating even in the cold winter season, and the panel type heat pipe (1) itself is a vacuum sealed container, which is ultra lightweight and reduces the cost of building In addition, it provides the effect of reducing the construction process, and the heating time is long due to the thermal insulation principle of the vacuum (see thermos and thermal insulation). Is reduced is reduced by heating the fuel (oil and gas) consumption is provided to enable any user to the economic benefit

Description

Integrated Heat Pipe with Heat Source {The Heat Pipe with Heat Source}

When heating work using a heat pipe, one end of the heat pipe (evaporator) is connected to a hot water pipe or electric heater, which is an external heat source, and the working fluid on the inside of the heat pipe heats up (evaporates) to radiate heat (condense). Get the effect. Because of this, when constructing heating work using heat pipes, many heat pipes should be joined to the hot water pipe (head) at regular intervals, and the process is difficult and technical problems such as welding stress, shrinkage, crack, and water leakage are caused in the coupling part. If there is a defect in the back, and not a Wick type heat pipe, but a thermo-syphon type heat pipe (most of heat pipes used for heating in Korea are thermo-cyphon type), the working fluid is radiated (condensed). In order to return to the endothermic part (evaporation part) and endotherm again, the condensation part must be installed with a slope higher than the evaporation part. Therefore, the cement mortar that finishes after heating the heat pipe also enters as much as the inclined volume. Of course, the construction load also becomes a problem, and the construction cost is too high. Compared to water pipe heating (Excel pipe, copper pipe, etc.), heating fuel (oil, gas) can be reduced by about 50%. In Korea, heating using heat pipe has been attempted for about 10 years, but supply is not activated. .

The present invention has been devised to solve and improve the above problems, and the present invention has a heat pipe (1) structure in which the porous panel (4) and the working fluid (3) are embedded in the temperature panel itself. The process of joining the head, attaching brackets, etc. are no longer necessary. Also, the problem of on-site construction, such as the disadvantage that a lot of cement mortar finish enters due to the inclined surface during the heating and heating construction using the thermo-syphon heat pipe, It was solved at one time. In addition, since the panel itself is a vacuum sealed container, it is very lightweight, reducing the construction load (no cement mortar finish required) and no need to cure cement mortar, thus enabling heating work in the cold winter season.

In addition, heat is applied to the entire surface of the bottom of the panel type heat pipe (1) by heat dissipation. Wherever the condensed working fluid (3) is located, the capillary phenomenon of the porous hook (4) returns to the heat source (2). The heat of (2) can be absorbed (evaporated) so that the inclined surface is not required unlike the thermo-syphon heat pipe. In addition, the working fluid 3 is always absorbed in the porous Wick 4 by the porous Wick 4 being wrapped in close contact with the entire outer surface of the heat source 2, and the absorbed working fluid 3 has a low density. It became possible to endotherm (evaporate) the heat of (2) more quickly, and the thermal efficiency became better.

1 is a perspective view of the present invention

2 is a plan cross-sectional view of the present invention

3 is a side cross-sectional view of the present invention, Figure 3a is a horizontal side cross-sectional view 3b is a longitudinal side cross-sectional view

4 is a cross-sectional view of the heat source of the present invention, Figure 4a is when the heat source is a FinTube type hot water pipe, Figure 4b is when the heat source is a corrugated pipe type hot water pipe, and Figure 4c is when the heat source is an electric heater rod

Figure 5 is a perspective view of the standing (heat radiator type) which is another example of the present invention

<Explanation of symbols for main parts of drawing>

Heat pipe body (sealed container) 2. Heat source (FinTube type and corrugated pipe type hot water pipe or electric heater rod)

3. Working Fluid 4. Porous Wick

5. Heat dissipation Fin 6. Heat pipe body top plate (metal plate)

7. Heat Pipe Body Bottom Plate (Metal Plate)

8. Work space (hot water pipe connection) 9. Corrugated groove

In order to achieve the above object, the construction and operation will be described with reference to the accompanying drawings (integrated panel) heat pipe 1 of the present invention.

1 is a perspective view of a panel-type heat pipe 1 of the present invention, which is formed in a metal plate 6 constituting the body top plate of the present invention to form a rumpled wrinkled groove 9, which is formed outside the Saemaul train, thereby increasing its strength. Porous Wick (4) applied to the entire inner surface of the bottom metal plate (7) provides a capillary tube for the heat dissipation and condensation of the working fluid (3) to the heat sink (2). Porous Wick (4) is also formed on the outer surface of the formed heat source (2), the return and evaporation of the working fluid (3) is made more smoothly and faster. In addition, the metal plate (7) constituting the bottom surface of the body, such as the body top plate (6) was formed in the same groove (9) as formed on the outside of the Saemaul train train (in contrast to the top plate) to increase the strength.

2 is a planar cross-sectional view of the present invention in which the heat source (2) longitudinally in the center of the body avoids the pleated fold groove (9) in the body upper plate metal plate 6, the concave fold groove, (9) opposite the bottom metal plate (7) It was formed in a curved shape, and the area of the heat source 2 was doubled.

3 is a side cross-sectional view of the present invention. FIG. 3A is a cross-sectional side view, and FIG. 3B is a longitudinal cross-section, wherein the porous hook 4 is applied to the entire inner surface of the bottom metal plate 7 of the panel-type heat pipe 1, and the body top metal plate 6 and the bottom metal plate ( 7) Corrugated grooves 9, which are formed outside the Saemaul train, are formed in the top plate and in the bottom plate, which are opposite to the bottom plate, so that the strength and load are enhanced. Improved thermal efficiency)

Figure 4 is a cross-sectional view of the heat source (2) of the present invention, Figure 4a is when the heat source (2) is a FinTube type hot water pipe, the heat radiation Fin (5) is attached to the heat source (2) to increase the heat radiation efficiency. When the heat source (2) is a corrugated pipe type hot water pipe, a longer length of hot water corrugated pipe can be inserted as shown in the figure to adjust the size of the heat dissipation area. FIG. 4C is when the heat source (2) is an electric heater rod.

5 is a perspective view of a heat sink (heat radiator) of another embodiment of the present invention, in which a heat source (when (2) FinTube type hot water pipe) and a heat pipe (1) are integrally formed, and heat radiating fin (5) is applied to the entire surface of the radiator. High heat dissipation efficiency

As described above, the present invention has been simplified by integrating all processes from production of heat pipes to on-site heating work. In addition, the present invention is a prefabricated panel type (1), heating work is possible even in the cold winter season, and because of the ultra-lightweight, the construction load is reduced, and also the panel-type heat pipe (1) itself is a vacuum sealed container, vacuum insulation principle (thermo bottle, If the heating time is shortened due to the long heat retention time, and the consumption of heating fuel (oil and gas) is saved, the consumption of heating fuel (oil and gas) is reduced. It will also contribute to the national economy, and will help to improve the environment by reducing the occurrence of more serious pollution.

Claims (3)

Porous Wick (4) is also formed in close contact with the outer surface of the heat source (2) formed in the panel type heat pipe (1), which is a vacuum sealed container, and the inner surface of the bottom metal plate (7). (1) The corrugated groove 9 for increasing the strength of the body bottom metal plate 7 and the upper metal plate 6 is formed in a top shape on the top metal plate 6 and in a bottom shape on the bottom metal plate 7. Integral (panel) heat pipe in which the heat source 2, the working fluid 3, and the porous wick 4 are all contained in the heat pipe 1 A porous Wick 4 is formed on the outer surface of the heat source 2 formed in the heat pipe 1, which is a vacuum sealed container, and the heat dissipation fin 5 is formed on the outer surface of the integrated heat pipe 1 (heat radiator). Type) Heat Pipe delete