KR102284056B1 - Heat absorbing and dissipating device with multi-pipe reversely transported temperature difference fluids - Google Patents

Abstract

The present invention transmits a fluid having a temperature difference from the same side of a first fluid pipe and a second fluid pipe arranged in parallel or close to parallel in the reverse direction to absorb heat or absorb heat from an object or space that is passively transferred or absorbed heat By creating a function of dissipation, the heat transfer fluid forms a relatively averaged temperature distribution state in the heat absorbing body or the heat sink 100 or the object or space 200 to which the emitted or absorbed heat is passively transferred. An endothermic and heat dissipation device that reversely transfers a fluid with a temperature difference.

Description

A heat absorption and heat dissipation device that reversely transfers a fluid with a temperature difference through multiple pipes

The present invention is a heat absorbing and dissipating device for reversely transferring a fluid having a temperature difference through multiple pipes, wherein a first fluid pipe having at least one flow path and a second fluid pipe having at least one flow path are parallel or close to parallel. is installed, and the first fluid pipe and the second fluid pipe are a gaseous fluid having a temperature difference in an object or space to which absorbed or emitted heat is passively transmitted, or a liquid fluid, or a fluid converted from a gaseous phase to a liquid phase , or heat dissipated or absorbed by transferring heat transfer fluids composed of fluids converted from liquid to gaseous in opposite directions to form a function of absorbing or discharging heat to an object or space to which the emitted or absorbed heat is passively transferred to form a relatively averaged temperature distribution state for an object or space that is passively transmitted.

As in a conventional engine coolant tank, heat is transferred by passing a heat transfer fluid consisting of a gaseous fluid of a heat sink or heat sink, or a liquid fluid, or a fluid converted from a gaseous to a liquid, or a fluid converted from a liquid to a gaseous phase. An application device that absorbs or releases heat, or a cooling energy exhaust device that absorbs heat into a heat transfer fluid, such as a heating appliance, or a thermal energy exhaust device that dissipates heat into a heat transfer fluid Therefore, the heat transfer fluid has a disadvantage in that it forms a relatively large temperature difference at each position of the heat sink or heat sink.

The present invention is a heat absorbing and dissipating device for reversely transmitting a fluid with a temperature difference by means of multiple pipes proposed to solve the problems as described above. An application for absorbing or dissipating heat is improved with first and second fluid tubing arranged in parallel or near-parallel, the first and second fluid tubing passively transferring the absorbed or dissipated heat The heat transfer fluid transferred by transferring the heat transfer fluid composed of a gaseous fluid having a temperature difference in a receiving object or space, or a liquid fluid, or a fluid converted from a gaseous to a liquid phase, or a fluid converted from a liquid to a gaseous phase, in opposite directions When it operates with a function of absorbing or dissipating heat, its purpose is to allow an object or space to passively receive the emitted or absorbed heat to form a relatively averaged temperature distribution state.

it is composed of a heat absorbing body or a heat dissipating body and a first fluid pipe and a second fluid pipe;

The function of absorbing or discharging heat to an object or space that is released or passively receives absorbed heat by transferring the fluid with a temperature difference in the reverse direction through multiple pipes and absorbing or discharging heat to the heat transfer fluid passed through In order to form a relatively averaged temperature distribution state for an object or space that is passively transferred to the emitted or absorbed heat by forming

- The heat absorbing body or heat sink is a structure that absorbs or releases heat composed of a solid, rubbery, liquid or gaseous thermally conductive material, and the first fluid pipe and the second fluid pipe are coupled thereto. A solid phase, a rubber phase, which receives the heat energy of the heat transfer fluid composed of a fluid, or a liquid fluid, or a fluid converted from a gaseous to a liquid phase, or a fluid converted from a liquid to a gaseous phase, and passively transferred the absorbed or released heat; It has a function of discharging cooling energy that absorbs heat to a liquid or gaseous object or space, or has a function of discharging heating energy that emits heat, and the heat absorbing body or heat sink is one or one may consist of the above;

- The first fluid pipe and the second fluid pipe are made of a material having excellent thermal conductivity and are composed of a gaseous fluid, or a liquid fluid, or a fluid converted from a gaseous to a liquid, or a fluid converted from a liquid to a gaseous phase. By transferring heat transfer fluids in opposite directions, heat energy is transferred to the heat absorber or heat sink made of a solid, rubbery, liquid or gaseous thermal conductive material, wherein the first fluid pipe and the second fluid pipe are each one or one In what may be composed of more than one flow path,

A first fluid inlet of the first fluid pipe is connected in parallel with a second fluid inlet of the second fluid pipe, and the heat transfer fluid flows therein, and the first fluid outlet of the first fluid pipe is connected to the second fluid pipe. 2 connected in parallel with a second fluid outlet of the fluid pipe, to which the heat transfer fluid flows;

The first fluid pipe and the second fluid pipe are installed in the heat absorbing body or the heat sink in a parallel or near-parallel planar shape or a three-dimensional shape, and the feature is that the first fluid inlet and the second fluid outlet are The first fluid outlet and the second fluid inlet are installed at different positions adjacent to the heat sink or heat sink, and the first installed in the heat sink or heat sink during operation. A solid phase that transmits the heat transfer fluid in opposite directions with respect to the fluid pipe and the second fluid pipe, and receives the absorbed or emitted heat passively by distributing the overall temperature difference between the heat absorbing body or the heat sink in a relatively average manner. , It provides a heat absorbing and dissipating device that reversely transfers a fluid with a temperature difference through multiple pipes, characterized in that it absorbs or emits heat to or from a rubbery, liquid, or gaseous object or space.

According to the present invention, an application device that absorbs or emits heat by passing a heat absorbing or dissipating body through an existing heat transfer fluid flowing in a constant direction is improved to a first fluid pipe and a second fluid pipe arranged in parallel or close to parallel, and , The first fluid pipe and the second fluid pipe are a gaseous fluid having a temperature difference in an object or space to which absorbed or emitted heat is passively transmitted, or a liquid fluid, or a fluid converted from a gaseous to a liquid, or a liquid When the transferred heat transfer fluid acts as a function of absorbing or dissipating heat by transferring the heat transfer fluid composed of the fluid converted from An averaged temperature distribution state can be formed.

1 is a heat transfer fluid composed of a gaseous fluid or liquid fluid that absorbs or releases heat, or a fluid converted from a gaseous to a liquid phase, or a fluid converted from a liquid to a gaseous fluid, which flows in a constant flow direction. A perspective view showing the main structure passing through the heat absorption and heat dissipation device,
2 is a temperature difference distribution diagram showing the temperature difference distribution in the function and operation of the cooling energy discharge device used for absorbing the heat shown in FIG. 1;
3 is a temperature difference distribution diagram showing the temperature difference distribution in the function and operation of the thermal energy discharge device for emitting the heat shown in FIG. 1;
4 is a perspective view showing the main structure of a heat absorbing and dissipating device for reversely transmitting a fluid having a temperature difference by means of multiple pipes according to the present invention;
5 is a temperature difference distribution diagram showing the temperature difference distribution in the function and operation of the cooling energy discharge device that absorbs heat in the structure shown in FIG. 4;
6 is a temperature difference distribution diagram showing the temperature difference distribution in the function and operation of the thermal energy discharging device for emitting heat in the structure shown in FIG. 4;
FIG. 7 is a structure shown in FIG. 4, directly constructing a cavity structure with a first fluid pipe and a second fluid pipe that directly reversely transmits a heat transfer fluid having a temperature difference to multiple pipes, and passively transfers absorbed or emitted heat A perspective view showing a main structure that directly transfers thermal energy to a receiving object or space;
8 is a temperature difference distribution diagram showing the temperature difference distribution in the function and operation of the cooling energy discharge device that absorbs heat in the structure shown in FIG. 7;
9 is a temperature difference distribution diagram showing the temperature difference distribution in the function and operation of the thermal energy discharging device for emitting heat in the structure shown in FIG. 7;
10 is a structure shown in FIG. 4, in which the fluid inlet and the fluid outlet of the first fluid pipe and the second fluid pipe of the heat absorbing and dissipating device for reversely transmitting a fluid with a temperature difference through multiple pipes are installed on both sides of the pipe. A perspective view showing an example,
FIG. 11 shows an embodiment in which a heat absorber or a heat sink 100 and a tubular structure 100 ′ through which a heat transfer fluid passively receives the emitted or absorbed heat passes through is combined in the embodiment shown in FIG. 4 . one perspective,
12 is an embodiment in which, in the embodiment shown in FIG. 4 , a heat absorber or a heat sink 100 and a tubular structure 100 ′ through which a heat transfer fluid passively receives several sets of emitted or absorbed heat passes through is combined. A perspective view showing an example,
13 shows an embodiment in which a heat absorbing body or a heat sink 100 and a tubular structure 100 ′ that passively receive emitted or absorbed heat and pass a heat transfer fluid are combined in the embodiment shown in FIG. 10 . one perspective,
14 is an embodiment in which, in the embodiment shown in FIG. 10 , a heat absorber or a heat sink 100 and a tubular structure 100 ′ through which a heat transfer fluid passively receives a plurality of sets of emitted or absorbed heat passes through is combined. A perspective view showing an example,
15 shows several sets of first fluid pipes 101 and second fluid pipes 102 flowing in opposite directions according to the present invention are cross-arranged in sequence, and are connected in parallel in the reverse direction to transfer the heat transfer fluid 110 A perspective view showing an embodiment structure to
16 is a perspective view showing an embodiment structure in which an independent heat conduction plate is additionally installed in a first fluid pipe and/or a second fluid pipe according to the present invention;
17 is an AA anatomical view of FIG. 16;
18 is a perspective view showing an embodiment structure in which a common heat conduction plate is additionally installed between adjacent fluid pipes of a first fluid pipe and/or a second fluid pipe according to the present invention;
19 is an anatomical view of the BB of FIG. 18;
20 is a perspective view showing the structure of an embodiment in which a heat conduction plate having a heat-blocking hole is additionally installed between adjacent fluid pipes of a first fluid pipe and/or a second fluid pipe according to the present invention;
21 is a CC anatomical view of FIG. 20;
22 is a perspective view showing the structure of an embodiment in which an independent heat conduction plate is additionally installed in the first fluid pipe and/or the second fluid pipe in the embodiment shown in FIG. 15;
23 is an AA anatomical view of FIG. 22;
24 is a perspective view showing an embodiment structure in which a common heat conduction plate is additionally installed between adjacent fluid pipes of a first fluid pipe and/or a second fluid pipe in the embodiment shown in FIG. 15;
25 is an anatomical view of the BB of FIG. 24;
26 is a perspective view showing the structure of an embodiment in which a heat conduction plate having a heat-blocking hole is additionally installed between adjacent fluid pipes of a first fluid pipe and/or a second fluid pipe in the embodiment shown in FIG. 15;
27 is a CC anatomy of FIG. 26 and
28 is a block diagram illustrating a system for pumping forward and reverse directions according to a cycle according to the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail based on the accompanying drawings.

1 is a gaseous fluid or a liquid fluid that absorbs or releases heat, or a heat transfer fluid consisting of a fluid converted from a gaseous to a liquid phase, or a fluid converted from a liquid to a gaseous phase, a heat transfer fluid flowing in a constant flow direction. and a perspective view showing a main structure passing through the heat dissipation device.

As shown in FIG. 1 , a first fluid pipe 101 by transferring the heat transfer fluid 110 converted from a gaseous fluid, a liquid fluid, or a gaseous phase to a liquid phase, or from a liquid phase to a gaseous phase, having a constant flow direction. ) as a heat absorbing device or heat dissipating device configured to be coupled with a heat absorbing body or a heat dissipating body 100 by passing it through, which is (1) the heat transfer fluid 110 passing through the first fluid pipe 101 is the heat absorbing body or heat dissipating device. Cooling or heating the solid, rubbery, liquid or gaseous object or space 200 passively receiving heat absorbed or released through the sieve 100, or (2) the first fluid pipe 101 ) through which the heat transfer fluid 110 receives cooling energy or heat energy transferred from around the heat absorbing body or heat sink 100 in the opposite direction to cool or heat it;

Paragraph (1) above refers to an engine coolant tank, or a heat energy discharging device or the heat transfer fluid ( 110) is often applied to a heat energy dissipating device that emits heat, and the above-mentioned (2) can be seen frequently applied to cooling energy or heat energy transmitting devices. When applied to the above (1), the heat transfer fluid Reference numeral 110 is input to the inlet of the first fluid pipe 101 on one side of the heat absorbing body or heat sink 100, and the heat transfer fluid 110 is again output from the other side to the heat absorbing body or heat sink. A relatively large temperature difference is formed between the heat transfer fluid 110 at the inlet of the first fluid pipe 101 of 100 and the heat transfer fluid 110 at the outlet of the first fluid pipe 101, and likewise, the When applied to (2), the disadvantage is that a relatively large temperature difference is formed between the inlet of the first fluid pipe 101 and the outlet of the first fluid pipe 101 .

FIG. 2 is a temperature difference distribution diagram showing the temperature difference distribution in the function and operation of the cooling energy discharge device used for absorbing the heat shown in FIG. 1 .

As shown in FIG. 2, in the process of using the heat transfer fluid 110 transferred in the conventional constant flow direction shown in FIG. 1 as a heat energy discharge device for emitting heat, it is When the heat transfer fluid 110 passes through the first fluid pipe 101, the inlet of the heat transfer fluid 110 of the heat absorber or the heat sink 100 and the heat transfer fluid 110 A distribution state with a relatively large temperature difference is formed between the outlets.

3 is a temperature difference distribution diagram showing the temperature difference distribution in the function and operation of the thermal energy discharging device for emitting heat shown in FIG. 1 .

As shown in FIG. 3, in the process of using the heat transfer fluid 110 transferred in the conventional single flow direction shown in FIG. 1 as a cooling energy discharge device for absorbing heat, this is a single flow direction When the heat transfer fluid 110 passes through the first fluid pipe 101, the inlet of the heat transfer fluid 110 of the heat absorber or the heat sink 100 and the heat transfer fluid 110 ), a distribution state with a relatively large temperature difference is formed between the outlets.

The present invention, which was invented to cope with the above phenomenon, is a heat absorption and heat dissipation device that reversely transmits a fluid with a temperature difference by using multiple pipes invented for the first time. By forming a function of absorbing or dissipating heat with respect to an object or space to which the heat is passively transferred, the object or space to which the emitted or absorbed heat is passively transferred forms a relatively averaged temperature distribution state.

4 is a perspective view showing the main structure of a heat absorbing and dissipating device for reversely transmitting a fluid having a temperature difference by means of multiple pipes according to the present invention.

As shown in Fig. 4, in the main structure of the heat absorbing and dissipating device for reversely transferring a fluid with a temperature difference by multiple pipes according to the present invention,

- The heat absorber or heat sink 100 is a structure for absorbing or discharging heat composed of a solid, rubbery, liquid or gaseous thermally conductive material, and the first fluid pipe 101 and the second fluid coupled thereto The heat energy of the heat transfer fluid 110 composed of a gaseous fluid flowing inside the pipe 102, a liquid fluid, or a fluid converted from a gaseous to a liquid, or a fluid converted from a liquid to a gaseous phase, is absorbed or released It has a function of discharging cooling energy that absorbs heat to a solid, rubbery, liquid or gaseous object or space 200 that is passively transmitted heat, or a function of discharging heating energy that emits heat. and, the heat absorbing body or heat dissipating body 100 may be composed of one or more than one;

- The first fluid pipe 101 and the second fluid pipe 102 are made of a material having excellent thermal conductivity and are gaseous fluid, or liquid fluid, or fluid converted from gaseous to liquid, or from liquid to gaseous. By transferring the heat transfer fluid 110 composed of a converted fluid in opposite directions to each other, heat energy is transferred to the heat absorbing body or heat sink 100 composed of a solid, rubbery, liquid or gaseous thermal conductive material, and the first fluid In which the pipe 101 and the second fluid pipe 102 may each be composed of one or more than one flow path,

The first fluid inlet 111 of the first fluid pipe 101 is connected in parallel with the second fluid inlet 121 of the second fluid pipe 102 , and the heat transfer fluid 110 flows therein. The first fluid outlet 112 of the first fluid pipe 101 is connected in parallel with the second fluid outlet 122 of the second fluid pipe 102, and the heat transfer fluid 110 is connected thereto. is leaked;

The first fluid pipe 101 and the second fluid pipe 102 are installed in the heat absorbing body or the heat dissipating body 100 in a planar shape or a three-dimensional shape close to parallel or parallel, and the feature is that the first fluid The inlet 111 and the second fluid outlet 122 are installed adjacent to the heat absorbing body or the heat sink 100 , and the first fluid outlet 112 and the second fluid inlet 121 are the heat absorbing elements. The heat transfer fluid ( 110) in opposite directions, and by distributing the overall temperature difference of the heat absorbing element or the heat sink 100 in a relatively average way, the absorbed or emitted heat is passively transferred to the solid, rubbery, liquid or gaseous phase. Absorbs or radiates heat to or from an object or space 200 .

The heat absorber or heat sink 100 and the first fluid pipe 101 and the second fluid pipe 102 shown in FIG. 4 may be configured in one or more structural relationships as follows. ,

(1) at least one of the heat absorber or heat sink 100 and the first fluid pipe 101 and the second fluid pipe 102 has a combined structure;

(2) at least one of the heat absorber or heat sink 100 and the first fluid pipe 101 and the second fluid pipe 102 is configured as an integral structure;

(3) at least one of the first fluid pipe 101 and the second fluid pipe 102 directly constitutes the function of the heat absorbing body or the heat dissipating body 100;

(4) additionally installing an independent heat conduction plate 300 not connected to a pipe adjacent to the first fluid pipe 101 and/or the second fluid pipe 102;

(5) the first fluid pipe 101 and/or the adjacent fluid pipe adjacent to the second fluid pipe 102 is connected by a common heat conduction plate 400;

(6) The first fluid pipe 101 and/or the adjacent fluid pipe adjacent to the second fluid pipe 102 is connected by a heat conduction plate 350 having a heat blocking hole.

FIG. 5 is a temperature difference distribution diagram showing the temperature difference distribution in the function and operation of the cooling energy discharging device that absorbs heat in the structure shown in FIG. 4 .

As shown in Figure 5, in the structure shown in Figure 4,

In the heat absorber or heat sink 100 made of a solid, rubbery, liquid or gaseous thermally conductive material, the first fluid inlet 111 of the first fluid pipe 101 and the second fluid pipe ( The second fluid outlet 122 of 102 is installed close, and the second fluid outlet 112 of the first fluid pipe 101 and the second fluid inlet of the second fluid pipe 102 ( 121) are installed close to each other at different locations to transfer the heat transfer fluid 110 in opposite directions, the input heat transfer fluid 110 is in a low temperature state with a relatively low temperature, and the output heat transfer fluid ( 100) has a relatively high temperature state, and in the heat absorber or heat sink 100, the heat absorbing body has an intermediate temperature between the input heat transfer fluid 110 and the output heat transfer fluid 100. Alternatively, by distributing in a relatively average manner in the radiator 100, the absorbed or emitted heat is partially absorbed by absorbing heat with respect to the solid, rubber, liquid, or gaseous object or space 200 to which the absorbed or emitted heat is passively transmitted, thereby discharging cooling energy. to prevent the temperature from being excessively lowered.

6 is a temperature difference distribution diagram showing the temperature difference distribution in the function and operation of the heating energy discharging device used for dissipating heat in the structure shown in FIG. 4 .

As shown in Figure 6, in the structure shown in Figure 4,

In the heat absorber or heat sink (100) made of a solid, rubbery, liquid or gaseous thermal conductive material, the first fluid inlet (111) of the first fluid pipe (101) and the second fluid pipe (102) ) of the second fluid outlet 122 are installed close to each other, and the second fluid outlet 112 of the first fluid pipe 101 and the second fluid inlet 121 of the second fluid pipe 102 are provided. ) is installed close at different locations to transfer the heat transfer fluid 110 in opposite directions, the input heat transfer fluid 110 has a relatively high temperature state, and the output heat transfer fluid 110 ) is in a low-temperature state having a relatively low temperature, and in the heat absorbing body or heat sink 100, the heat absorbing body or the heat absorbing body or By distributing in a relatively average way in the radiator 100, the absorbed or emitted heat is released to the solid, rubber, liquid, or gaseous object or space 200 to which the absorbed or emitted heat is passively transmitted, thereby discharging heat energy to some high temperature. This should be avoided to increase excessively.

The heat absorbing and dissipating device for reversely transferring a fluid having a temperature difference by means of multiple pipes according to the present invention can transmit heat energy through the heat absorbing or heat dissipating body 100, and in parallel or close to parallel planar shape or three-dimensional shape A structure can be directly configured with the first fluid pipe 101 and the second fluid pipe 102 installed as The first fluid pipe 101 and the first fluid pipe 101 and the heat transfer fluid 110 composed of a fluid converted from a gaseous phase to a liquid phase, or a fluid converted from a liquid phase to a gas phase, in the reverse direction The heat energy absorbed by the second fluid pipe 102 is discharged directly to an object or space to which the emitted heat is passively transferred, or the cooling energy is discharged by absorbing heat.

FIG. 7 is a structure shown in FIG. 4, directly constructing a cavity structure with a first fluid pipe and a second fluid pipe that directly reversely transmits a heat transfer fluid having a temperature difference to multiple pipes, and passively transfers absorbed or emitted heat It is a perspective view showing a main structure that directly transfers thermal energy to a receiving object or space.

7, in its additional configuration,

- The first fluid pipe 101 and the second fluid pipe 102 are made of a material having excellent thermal conductivity and are gaseous fluid, or liquid fluid, or fluid converted from gaseous to liquid, or from liquid to gaseous. By transferring the heat transfer fluid 110 composed of a converted fluid, heat energy is transferred to a solid, rubbery, liquid or gaseous object or space 200 to which the absorbed or released heat is passively transferred, and the first fluid The pipe 101 and the second fluid pipe 102 may each be composed of one or more than one flow path; The first fluid inlet 111 of the first fluid pipe 101 is connected in parallel with the second fluid inlet 121 of the second fluid pipe 102 , and the heat transfer fluid 110 flows therein. The first fluid outlet 112 of the first fluid pipe 101 is connected in parallel with the second fluid outlet 122 of the second fluid pipe 102, and the heat transfer fluid 110 is connected thereto. is outflowed, and the first fluid pipe 101 and the second fluid pipe 102 are installed in a flat or three-dimensional shape close to parallel or parallel to constitute a cavity structure, and the feature is that the first fluid pipe ( The first fluid inlet 111 of 101 and the second fluid outlet 122 of the second fluid pipe 102 are installed at a position close to the cavity structure, and the The first fluid outlet 112 and the second fluid inlet 121 of the second fluid pipe 102 are installed at different positions close to the cavity structure, so that the first fluid among multiple pipes installed in the cavity structure during operation The pipe 101 and the second fluid pipe 102 transfer the heat transfer fluid 110 in opposite directions to each other, and the overall temperature difference of the cavity structure is a solid phase, which passively receives the absorbed or emitted heat. By distributing the absorbed or emitted heat on a relatively average basis in the free, liquid, or gaseous object or space 200 , heat is absorbed or let it be released

In the heat absorbing and dissipating device in which a fluid having a temperature difference is reversely transmitted by a multi-pipe according to the present invention, a solid, rubbery, liquid or gaseous object or space 200 to which the absorbed or emitted heat is passively transferred; The structural relationship between the first fluid pipe 101 and the second fluid pipe 102 is that at least one of the first fluid pipe 101 and the second fluid pipe 102 is the heat absorber or the heat sink ( 100) directly composing the function of absorbing or discharging heat to a solid, rubbery, liquid or gaseous object or space 200 to which the absorbed or emitted heat is passively transmitted, or a fluid having a temperature difference in multiple pipes A solid, rubbery, liquid or gaseous object or space to which the absorbed or emitted heat is passively transferred to a cavity structure composed of the first fluid pipe 101 and the second fluid pipe 102 that transfer the With respect to (200), there is a direct transfer of thermal energy.

FIG. 8 is a temperature difference distribution diagram showing the temperature difference distribution in the function and operation of the cooling energy discharging device that absorbs heat in the structure shown in FIG. 7 .

As shown in FIG. 8, in the cavity structure shown in FIG. 7,

The first fluid inlet 111 of the first fluid pipe 101 and the second fluid outlet 122 of the second fluid pipe 102 are installed close to each other, and The second fluid outlet 112 and the second fluid inlet 121 of the second fluid pipe 102 are installed close at different positions to transfer the heat transfer fluid 110 in opposite directions, The heat transfer fluid 110 has a relatively low temperature state, the output heat transfer fluid 110 has a relatively high temperature state, and in the cavity structure, the input heat transfer fluid 110 and output The absorbed or released heat is absorbed or released by relatively average distribution in the solid, rubbery, liquid, or gaseous object or space 200 to which the absorbed or emitted heat is passively transferred while having an intermediate temperature between the heat transfer fluids 110 . By absorbing heat to a solid, rubbery, liquid or gaseous object or space 200 to which the received heat is passively transmitted, and discharging cooling energy, a portion of the low temperature is prevented from being excessively lowered.

9 is a temperature difference distribution diagram illustrating a temperature difference distribution in the function and operation of a thermal energy discharging device for emitting heat in the structure shown in FIG. 7 .

As shown in Fig. 9, in the cavity structure shown in Fig. 7,

The first fluid inlet 111 of the first fluid pipe 101 and the second fluid outlet 122 of the second fluid pipe 102 are installed close to each other, and The second fluid outlet 112 and the second fluid inlet 121 of the second fluid pipe 102 are installed close at different positions to transfer the heat transfer fluid 110 in opposite directions, The heat transfer fluid 110 has a relatively high temperature, and the output heat transfer fluid 110 has a low temperature state with a relatively low temperature, and in the cavity structure, the input heat transfer fluid 110 and output The absorbed or released heat is absorbed or released by relatively average distribution in the solid, rubbery, liquid, or gaseous object or space 200 to which the absorbed or emitted heat is passively transferred while having an intermediate temperature between the heat transfer fluids 110 . By discharging heat to the solid, rubber, liquid, or gaseous object or space 200 to which the heat is passively transferred, the heat energy is discharged to prevent a portion of the high temperature from becoming excessively high.

In the heat absorption and heat dissipation device for reversely transmitting a fluid having a temperature difference by means of multiple pipes according to the present invention, the first fluid pipe 101 and the second fluid pipe for transferring a heat transfer fluid having a temperature difference to the multiple pipes in the reverse direction The fluid inlet and fluid outlet of 102 may be respectively installed at the same height or different heights on both sides of the pipe.

10 is a structure shown in FIG. 4, in which the fluid inlet and the fluid outlet of the first fluid pipe and the second fluid pipe of the heat absorbing and dissipating device for reversely transmitting a fluid with a temperature difference through multiple pipes are installed on both sides of the pipe. It is a perspective view showing an example.

In the heat absorption and heat dissipation device for reversely transmitting a fluid having a temperature difference by means of multiple pipes according to the present invention, a solid, rubbery, liquid or gaseous object or space 200 to which the absorbed or emitted heat is passively transmitted is It can be constructed by replacing one or more fluid pipes or a tubular structure 100 ′ through which a heat transfer fluid passively transmitted passes the emitted or absorbed heat composed of a structure similar to the heat absorbing body or heat sink 100 . there is.

FIG. 11 shows an embodiment in which a heat absorber or a heat sink 100 and a tubular structure 100 ′ through which a heat transfer fluid passively receives the emitted or absorbed heat passes through is combined in the embodiment shown in FIG. 4 . It is a perspective view.

12 is an embodiment in which, in the embodiment shown in FIG. 4 , a heat absorber or a heat sink 100 and a tubular structure 100 ′ through which a heat transfer fluid passively receives several sets of emitted or absorbed heat passes through is combined. It is a perspective view showing an example.

13 shows an embodiment in which a heat absorbing body or a heat sink 100 and a tubular structure 100 ′ that passively receive emitted or absorbed heat and pass a heat transfer fluid are combined in the embodiment shown in FIG. 10 . It is a perspective view.

14 is an embodiment in which, in the embodiment shown in FIG. 10 , a heat absorber or a heat sink 100 and a tubular structure 100 ′ through which a heat transfer fluid passively receives a plurality of sets of emitted or absorbed heat passes through is combined. It is a perspective view showing an example.

In the heat absorption and heat dissipation device for reversely transmitting a fluid having a temperature difference by means of multiple pipes according to the present invention, several sets of the first fluid pipe 101 and the second fluid pipe 102 are cross-arranged in order, the reverse direction It may be configured in a structure that is connected in parallel to transfer the heat transfer fluid 110 .

15 shows several sets of first fluid pipes 101 and second fluid pipes 102 flowing in opposite directions according to the present invention are cross-arranged in order, and connected in parallel in the reverse direction to provide heat transfer fluid 110 It is a perspective view showing the structure of the embodiment to be delivered.

As shown in Fig. 15, the first fluid pipe 101 and the second fluid pipe 102 flowing in opposite directions in several sets are cross-arranged in order and the heat absorber or heat sink 100 is configured. is such that the heat transfer fluid 110 flows in a forward direction when passing through the first fluid pipe 101 that is cross-arranged in order, and flows in a reverse direction when passing through the second fluid pipe 102. It is possible to form a relatively averaged temperature distribution on both sides of the heat absorbing body or the heat sink 100, wherein the first fluid pipe 101 and/or the second fluid pipe 102 have a straight pipe on one side or at least one side. It may be a curved curved pipe, and each curved pipe of the first fluid pipe 101 and the second fluid pipe 102 is configured by being cross-arranged in the order of flowing in opposite directions.

In the heat absorption and heat dissipation device for reversely transmitting a fluid with a temperature difference by means of multiple pipes according to the present invention, the pipe has an independent heat conduction plate 300 and/or a common heat conduction plate 400 and or a heat conduction plate having a heat blocking hole ( 350) in which it is possible to enhance the effect of absorbing or emitting heat by additionally installing,

- In order to increase the effect of absorbing or releasing heat, the independent heat conduction plate 300 is additionally installed in the first fluid pipe 101 and/or the second fluid pipe 102 to reduce the area for absorbing or releasing heat. by increasing the effect of absorbing or releasing heat;

16 is a perspective view illustrating a structure in which an independent heat conduction plate is additionally installed in a first fluid pipe and/or a second fluid pipe according to the present invention.

17 is an A-A anatomical view of FIG. 16 .

- The cavity heat conduction plate 400 is additionally provided between adjacent fluid pipes of the first fluid pipe 101 and/or the second fluid pipe 102 in order to increase the stability of the area and structure for absorbing or releasing heat. By installing, the effect of absorbing or dissipating heat can be enhanced;

18 is a perspective view illustrating a structure in which a common heat conduction plate is additionally installed between adjacent fluid pipes of a first fluid pipe and/or a second fluid pipe according to the present invention.

19 is a B-B anatomical view of FIG. 18 .

- A heat conduction plate having the heat-blocking hole between adjacent fluid pipes of the first fluid pipe 101 and/or the second fluid pipe 102 in order to increase the safety of the area and structure for absorbing or releasing heat ( 350) can be additionally installed to enhance the effect of absorbing or dissipating heat;

20 is a perspective view illustrating the structure of an embodiment in which a heat conduction plate having a heat-blocking hole is additionally installed between adjacent fluid pipes of a first fluid pipe and/or a second fluid pipe according to the present invention.

21 is a C-C anatomical view of FIG. 20 .

In the heat absorption and heat dissipation device for reversely transmitting a fluid having a temperature difference by means of multiple pipes according to the present invention, the embodiment shown in FIG. 15 shows several sets of the first fluid pipe 101 and the second fluid pipe flowing in opposite directions. 2 The first fluid pipe 101 and the second fluid in which the heat transfer fluid 110 are cross-arranged in order as the heat absorbing body or heat sink 100 configured by intersecting the fluid pipes 102 in order When passing through the pipe 102, a relatively averaged temperature distribution can be formed on both sides of the heat absorbing body or the heat dissipating body 100, and in addition, in order to increase the effect of absorbing or dissipating heat, the first fluid pipe 101 ) and/or by additionally installing the independent heat conduction plate 300 in the second fluid pipe 102 to increase the area to absorb or release heat, thereby enhancing the effect of absorbing or emitting heat;

22 is a perspective view illustrating the structure of an embodiment in which an independent heat conduction plate is additionally installed in the first fluid pipe and/or the second fluid pipe in the embodiment shown in FIG. 15 .

23 is an A-A anatomical view of FIG. 22 .

In the embodiment shown in FIG. 15 of a heat absorbing and dissipating device for reversely transmitting a fluid having a temperature difference by means of multiple pipes according to the present invention, the first fluid pipe 101 and / or the cavity heat conduction plate 400 is additionally installed between adjacent fluid pipes of the second fluid pipe 102 to increase the area for absorbing or discharging heat and the stability of the structure;

FIG. 24 is a perspective view illustrating a structure in which a common heat conduction plate is additionally installed between adjacent fluid pipes of a first fluid pipe and/or a second fluid pipe in the embodiment shown in FIG. 15 .

FIG. 25 is a B-B anatomical view of FIG. 24 .

In the embodiment shown in FIG. 15 of a heat absorbing and dissipating device for reversely transmitting a fluid with a temperature difference by means of multiple pipes according to the present invention, in order to combine the stability of the structure and the process and the need for an independent temperature transfer function, the first By additionally installing a heat conduction plate 350 having a heat-blocking hole between the fluid pipe 101 and/or the adjacent fluid pipe of the second fluid pipe 102, the area for absorbing or releasing heat and the stability of the structure are increased. can do;

FIG. 26 is a perspective view illustrating the structure of an embodiment in which a heat conduction plate having a heat-blocking hole is additionally installed between adjacent fluid pipes of a first fluid pipe and/or a second fluid pipe in the embodiment shown in FIG. 15; .

FIG. 27 is a C-C anatomical view of FIG. 26 .

In the heat absorption and heat dissipation device for reversely transmitting a fluid having a temperature difference by means of multiple pipes according to the present invention, the first fluid pipe 101 and/or a heat transfer fluid to which the emitted or absorbed heat is passively transmitted passes through The fluid passing through the tubular structure 100 ′ drives the bidirectional fluid pumping device 600 to be pumped in forward and reverse directions according to the cycle under the control of the control device 500 to supply the heat transfer fluid 110 according to the cycle. Pumping in both directions can enhance the isothermal effect;

The bidirectional fluid pumping device 600 pumps bidirectionally according to a cycle under the control of an electromechanical device, an electronic device, or a control device composed of a microcomputer and related software;

28 is a block diagram illustrating a system for pumping forward and reverse directions according to a cycle according to the present invention.

In applying the heat absorbing and heat dissipating device that reversely transmits a fluid with a temperature difference by means of multiple pipes according to the present invention, one of the following based on the above-mentioned operating principle in consideration of application necessity, structural necessity and cost Or in one or more design methods that can be manufactured,

- In the heat absorbing and dissipating device for reversely transmitting a fluid having a temperature difference through multiple pipes according to the present invention, the first fluid pipe 101 and the second fluid pipe 102 are the heat absorbing body or the heat dissipating body 100 ) by the structure of the pipe may be manufactured and configured as an integral structure;

- In the heat absorbing and dissipating device for reversely transferring a fluid having a temperature difference through multiple pipes according to the present invention, the first fluid pipe 101 and the second fluid pipe 102 and the heat absorbing body or heat sink 100 ) may consist of structures bonded to each other;

- In the heat absorbing and dissipating device for reversely transmitting a fluid having a temperature difference by means of multiple pipes according to the present invention, the heat absorbing body or heat dissipating body coupled to the first fluid pipe 101 and the second fluid pipe 102 The reference numeral 100 may be configured as at least one structural unit among structural units having a plate shape, a block shape, or a multi-wing shape configured as a single structure, or a structural unit manufactured by combining wing wings, if necessary.

In the heat absorbing and dissipating device for reversely transmitting a fluid with a temperature difference by means of multiple pipes according to the present invention,

The heat absorber or heat sink 100 made of a solid, rubbery, liquid or gaseous thermally conductive material, and the first fluid pipe 101 and the second fluid pipe 102 are formed of various geometric shapes under the premise that the principle does not change. shape can be produced.

In the heat absorption and heat dissipation device for reversely transmitting a fluid having a temperature difference by means of multiple pipes according to the present invention, the heat transfer fluid 110 passing through the first fluid pipe 101 and the second fluid pipe 102 is Pumping, evaporating or cooling transfers the heat transfer fluid 110 in a naturally convective manner.

In the heat absorption and heat dissipation device for reversely transmitting a fluid having a temperature difference by means of multiple pipes according to the present invention, the heat transfer function of convection, radiation or conduction by natural convection or forcibly pumping the fluid by the cooling/heating temperature difference of the fluid Heat energy or cooling energy is released to an object or space 200 that is passively transferred to the absorbed or emitted heat in a fluid state through formation, or the absorbed or emitted heat is passively transferred through a conduction method. Thermal energy or cooling energy may be emitted to the received solid, rubber, liquid, or gaseous object or space 200 .

In the heat absorption and heat dissipation device for reversely transmitting a fluid having a temperature difference by means of multiple pipes according to the present invention, the heat transfer fluid 110 passing through the first fluid pipe 101 and the second fluid pipe 102 is conducting a closed flow circulation or an open flow discharge;

- In the heat absorption and heat dissipation device for reversely transmitting a fluid with a temperature difference by means of multiple pipes according to the present invention, the fluid inlet and the fluid outlet of each fluid pipe are located in the same direction or different directions pointing to the middle in the three-dimensional space installed;

- In the heat absorption and heat dissipation device for reversely transmitting a fluid having a temperature difference by means of multiple pipes according to the present invention, the fluid pipe has a tubular structure and/or a plate-like structure having a fluid pipe through which a fluid can flow and/or a fluid can flow It consists of a block-shaped structure of fluid piping with holes in it.

The heat absorbing and dissipating device for reversely transferring a fluid having a temperature difference through multiple pipes according to the present invention is a heat conduction application device that absorbs, dissipates, or cools heat such as a cooling radiator of an engine, or heat by a heat transfer fluid such as a cooling device A cooling energy discharge device that absorbs heat energy, or a heat energy discharge device that releases heat by means of a heat transfer fluid, or a heat energy transfer, or heating device, or heat energy transmission device, or heating or cooling of the ceiling, wall, or floor of a building, solar power generation Cooling of a photovoltaic panel, heating or cooling of electric or power machinery, heat absorption or heat dissipation of various machine cases, heat absorption or heat dissipation of machine cells with heat pipe structure, heat absorption or heat dissipation of various structural cases, Heat absorption or heat dissipation of various chips or semiconductor components, heat absorption or heat dissipation or heat energy transfer of various ventilation devices or information devices or sound or imaging devices, heat absorption or heat dissipation of various lighting devices or light emitting diodes (LEDs), or heat energy transfer, heat absorption in evaporators of air conditioners or heat dissipation or heat energy transfer in coolers, or heat energy transfer in mechanical devices, or heat dissipation of heat loss due to friction, or electrical heating devices or other electric heating appliances or Heat dissipation or heat energy transfer in electrothermal kitchen appliances, or heat absorption or heat energy transfer in ovens or kitchen appliances in flame heating, or heat absorption or heat dissipation or heat energy transfer in geological or underwater thermal energy, factory building or house building or construction It can be applied to heat absorption or heat dissipation or heat energy transfer in a material or building space, heat absorption or heat dissipation in a water tank, heat absorption or heat dissipation or heat energy transfer in a battery or fuel cell.

In addition, the present invention can be applied to the transfer of thermal energy in home appliances, industrial products, electronic products, electric or mechanical devices, power generation facilities, buildings, air conditioners, production facilities or industrial processes.

100: heat sink or heat sink
100': a tubular structure through which a heat transfer fluid that passively receives emitted or absorbed heat passes through
101: first fluid piping
102: second fluid piping
110: heat transfer fluid
111: first fluid inlet
112: first fluid outlet
121: second fluid inlet
122: second fluid outlet
200: A solid, rubbery, liquid or gaseous object or space that passively receives absorbed or emitted heat.
300: Independent heat conduction plate
350: heat conduction plate with heat blocking hole
400: Joint heat conduction plate
500: control device
600: Bidirectional fluid pumping device

Claims (19)

A device for absorbing and dissipating heat by passing a heat transfer fluid, the device comprising:
By a fluid method in which multiple pipes flow a heat transfer fluid having a temperature difference in opposite directions, the heat transfer fluid forms an overall uniform temperature distribution with respect to the heat absorbing body or the heat sink,
The heat absorbing or heat dissipating body 100 is a heat absorbing or dissipating structure composed of a solid or rubbery or liquid or gaseous thermal conductive material, and flows in the first fluid pipe 101 and the second fluid pipe 102 . A solid or rubbery or liquid or gaseous phase that receives heat energy of the heat transfer fluid 110 composed of a gaseous fluid or liquid fluid, Activates the cooling and heat energy dissipation function with respect to the object or space 200, or operates the warm and heat energy dissipation function, and the heat absorbing body or the heat dissipating body 100 can be configured by one or more,
The first fluid pipe 101 and the second fluid pipe 102 are made of a material with excellent thermal conductivity, and by flowing the heat transfer fluid 110 in opposite directions to each other, heat energy is transferred to the heat absorbing body or the heat sink 100 . and the first fluid pipe 101 and the second fluid pipe 102 are separately configured by a one-way,
Both the inlet 111 of the first fluid pipe 101 and the inlet 121 of the second fluid pipe 102 are installed so that the heat transfer fluid 110 flows in, and the outlet 112 of the first fluid pipe 101 is provided. and the outlet 122 of the second fluid pipe 102 are installed so that the heat transfer fluid 110 flows out,
The first fluid pipe 101 and the second fluid pipe 102 have a flat or three-dimensional shape that is parallel or close to parallel, and are installed on the heat absorbing body or the heat dissipating body 100, and the feature is the first fluid pipe 101 The inlet 111 of the inlet 111 and the inlet 121 of the second fluid pipe 102 are installed at a predetermined position near the heat absorbing body or the heat sink 100, and the outlet 112 of the first fluid pipe 101 and the second 2 The outlet 122 of the fluid pipe 102 is installed at a separate predetermined position of the heat sink or heat sink 100,
The first fluid pipe 101 extends from the predetermined position where the inlet 111 is installed to the separate predetermined position where the outlet 112 is installed, and the second fluid pipe 102 has the inlet 121 installed. After extending from the predetermined position to the outlet 112 side of the first fluid pipe 101 through a path separate from the first fluid pipe 101, from the outlet 112 side of the first fluid pipe 101, the inlet ( 111) side by extending parallel to the first fluid pipe 101, and then extending to the outlet 122 provided at the other predetermined position in a different path from the first fluid pipe 101, so that the first fluid pipe (101) and the second fluid pipe (102) to flow the heat transfer fluid 110 in opposite directions, uniformly distribute the temperature difference of the entire heat absorbing body or the heat dissipating body 100 as a whole, passively receiving heat dissipation or heat absorption A heat absorbing and dissipating device that absorbs or radiates heat from a solid or rubbery or liquid or gaseous object or space 200 . The method of claim 1,
The heat absorbing body or heat dissipating body 100, the first fluid pipe 101, and the second fluid pipe 102 are heat absorbing and dissipating devices, which can be configured by one or more of the following structures:
(1) the heat absorbing body or the heat dissipating body 100 has a structure in which at least one of two types of pipes, a first fluid pipe 101 and a second fluid pipe 102, is assembled;
(2) the heat absorbing body or the heat dissipating body 100 has a structure in which at least one of the two types of the first fluid pipe 101 and the second fluid pipe 102 is integrated;
(3) a structure in which at least one of the two types of the first fluid pipe 101 and the second fluid pipe 102 directly functions as a heat absorbing body or a heat dissipating body 100;
(4) a structure in which an independent heat conduction plate 300 is installed in at least one of the first fluid pipe 101 and the second fluid pipe 102 and the pipes do not communicate;
(5) a structure in which the fluid pipe in the vicinity of at least one of the first fluid pipe 101 and the second fluid pipe 102 communicates with the common heat conduction plate 400 ;
(6) a structure for communicating with a heat conduction plate 350 having a heat-blocking hole between a fluid pipe in the vicinity of at least one of the first fluid pipe 101 and the second fluid pipe 102; Heat absorption and heat dissipation device comprising
The method of claim 1,
The first fluid pipe 101 and the second fluid pipe 102 have a heat absorbing or heat dissipating structure made of a material having excellent thermal conductivity, and by allowing the heat transfer fluid 110 to flow, thermal energy is passively radiated or absorbed in a solid phase or It is transmitted to a rubbery or liquid or gaseous object or space 200, and the first fluid pipe 101 and the second fluid pipe 102 are separately configured as a one-way, and the inlet of the first fluid pipe 101 ( 111 ) and the inlet 121 of the second fluid pipe 102 are both installed so that the heat transfer fluid 110 is introduced, and the outlet 112 of the first fluid pipe 101 and the outlet of the second fluid pipe 102 . All 122 are installed so that the heat transfer fluid 110 flows out, and the first fluid pipe 101 and the second fluid pipe 102 are parallel or close to parallel planar shape or three-dimensional shape to form a cavity structure. The inlet 111 of the first fluid pipe 101 and the inlet 121 of the second fluid pipe 102 are installed at a predetermined position near the cavity structure, and the outlet of the first fluid pipe 101 The outlet 122 of the 112 and the second fluid pipe 102 is provided at a separate predetermined position of the cavity structure, and the first fluid pipe 101 and the second fluid in the multiple pipes installed in the cavity structure. The heat transfer fluid 110 flows in the pipe 102 in opposite directions, and the temperature difference of the cavity structure is passively radiated or absorbed into a solid or rubbery or liquid or gaseous object or space 200 uniformly as a whole. A heat absorbing and dissipating device for distributing and absorbing or dissipating heat with respect to a solid or rubbery or liquid or gaseous object or space 200 that is passively dissipated or absorbed. 4. The method of claim 3,
The structural relationship between the solid or rubbery or liquid or gaseous object or space 200 and the first fluid pipe 101 and the second fluid pipe 102 passively radiating or absorbing heat is the first fluid pipe 101, At least one of the two types of pipes of the second fluid pipe 102 directly constitutes the function of the heat absorbing body or the heat dissipating body 100, and a solid or rubbery or liquid or gaseous object or space passively radiating or absorbing heat. A heat absorbing and dissipating device that absorbs or radiates heat with respect to (200). 4. The method of claim 3,
The multi-pipe transports a heat transfer fluid having a temperature difference in opposite directions to the cavity structure directly constituted by a first fluid pipe and a second fluid pipe, and an object or space 200 that passively receives heat dissipation or absorption ), an endothermic and heat dissipating device that transfers thermal energy to. The method of claim 1,
The multiple pipes are respectively installed at the same altitude or different heights on both sides of the pipe at the fluid inlet and the fluid outlet of the first fluid pipe and the second fluid pipe of the heat transfer fluid having a temperature difference in opposite directions, respectively, absorbing heat and dissipating heat Device. The method of claim 1,
The solid, rubbery, liquid or gaseous object or space 200 passively radiating or absorbing heat is passively radiated or absorbed heat by one or more fluid pipes or a structure similar to the heat absorbing or heat dissipating body 100 . A heat absorbing and dissipating device capable of replacing the configuration of the receiving solid or rubbery or liquid or gaseous object or space 200 with the configuration of the tubular structure 100 ′ passing through the passively dissipating or absorbing heat transfer fluid. The method of claim 1,
A heat absorbing body or a heat dissipating body 100 is constructed by arranging a plurality of sets of first fluid pipes 101 and second fluid pipes 102 in turn indicating opposite flow directions, and the heat transfer fluid 110 intersects in turn. Passes through the arranged first fluid pipe 101 in a sequential flow direction, passes through the second fluid pipe 102 in the opposite flow direction, and uniformly distributes the temperature of both sides of the heat absorber or heat sink 100 as a whole. distributed, and at least one of the first fluid pipe 101 and the second fluid pipe 102 can be configured as a single straight pipe or at least one curved pipe, and also the first fluid pipe 101 and the second fluid pipe A heat absorbing and dissipating device, configured by a cross arrangement in the order of flow directions opposite to each other between each curved pipe of (102). The method of claim 1,
A heat absorbing and dissipating device that increases heat absorption or heat dissipation effect by attaching a heat conduction plate 350 having at least one of an independent heat conduction plate 300, a common heat conduction plate 400, and a heat blocking hole. 9. The method of claim 8,
An independent heat conduction plate ( 300), to increase the heat absorbing or dissipating area, and to increase the heat dissipation or heat absorbing effect, a heat absorbing and dissipating device. The method of claim 1,
The first fluid pipe 101 and the second fluid pipe 102 are heat absorbing and dissipating devices that can be configured as an integral structure, directly manufacturing the pipe by the structure of the heat absorbing body or the heat dissipating body 100 . The method of claim 1,
Three of the first fluid pipe 101 and the second fluid pipe 102 and the heat absorbing body or the heat dissipating body 100 are configurable in a prefabricated structure, a heat absorbing and dissipating device. The method of claim 1,
The coupling of the first fluid pipe 101 and the second fluid pipe 102 in the heat absorbing body or the heat dissipating body 100 is composed of a single structure as necessary, and also
A heat absorbing and dissipating device that can be configured by any one or more of a structural unit composed of a plate shape, a block shape, or a multi-wing shape, and a structural unit completed by assembling a wing piece. The method of claim 1,
The heat transfer fluid 110 passing through the first fluid pipe 101 and the second fluid pipe 102 transports the heat transfer fluid 110 in a natural convection manner of pumping or evaporation or cooling, heat absorption and heat dissipation device. The method of claim 1,
Natural convection generated by the temperature difference between the cold and heat of the heat transfer fluid, or the heat transfer function of convection or radiation or conduction generated by forcibly pumping the heat transfer fluid. A heat absorption and heat dissipation device that emits energy or cool heat energy, or releases warm heat energy or cold heat energy to an object or space 200 that is passively radiated or absorbed heat in a solid or rubbery state or liquid or gaseous phase through a conduction method . The method of claim 1,
The heat transfer fluid (110) passing in the first fluid pipe (101) and the second fluid pipe (102) includes a closed circulation type or an open type discharge. The method of claim 1,
A heat absorbing and dissipating device in which the inlet of the heat transfer fluid and the outlet of the heat transfer fluid of each fluid pipe are installed in the same direction or different directions pointing to the middle in the three-dimensional space. The method of claim 1,
Each fluid pipe is constituted by a tubular structure or a plate-like structure of a fluid pipe through which a heat transfer fluid flows, a heat absorbing and dissipating device. 4. The method according to claim 2 or 3,
Various heat-absorbing or heat-dissipating or cooling heat transfer applications, cooling radiators of engines or cooling-heat energy-dissipating devices that absorb heat through heat-transfer fluids or warm-heat energy-dissipating devices that radiate heat through heat transfer fluids, heat energy transfer or heating devices or thermal energy of heating appliances Heating or cooling of the ceiling, wall, or floor of a transmission device or building, cooling of a photovoltaic panel, heating or cooling of an electric or power machine, absorbing or dissipating heat from a machine shell of a heat pipe structure, absorbing or dissipating heat from various chips or semiconductor components or Heat dissipation, heat absorption or heat dissipation or transfer of heat energy of various ventilation devices or information devices or stereo or AV devices, heat absorption or radiation of various lighting devices or light emitting diodes or transfer of heat energy, absorbing heat of an evaporator of an air conditioner or heat dissipation or heat energy of a cooler Transmission or transmission of heat energy of mechanical devices or dissipation of heat loss by friction, or heat dissipation or transmission of heat energy of electric heating devices or electric heating appliances or electric heating cooking devices, or endothermic or thermal energy of stove tools or cooking devices of flame heating In the transfer of heat energy in strata or water, or the endothermic or heat dissipation or transfer of heat energy, the endothermic or heat dissipation or transfer of heat energy in a factory building or house building or building material or building space, or the endothermic or heat dissipation or transfer of heat energy in a battery or fuel cell can be applied,
Heat absorbing and dissipating device, applicable to the transfer of heat energy in household appliances, industrial goods, electronic goods, electrical or mechanical equipment, power generation equipment, buildings, air conditioning equipment, production equipment or industrial manufacturing processes.

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