KR100860238B1 - Heating pipe line provided with a heat pipe easy to horizontal circulation - Google Patents

Abstract

A heating pipeline having a heat pipe enabling easy horizontal circulation is provided to radiate heat at the central portion of a heat radiating part and allow condensed heat medium to rapidly move to a heating part by forming an inclined part on the bottom of the heat radiating part of the heat pipe, thus dramatically increasing heating efficiency. A heating pipeline having a heat pipe enabling easy horizontal circulation includes a heat source(3) to which energy required to radiate heat is supplied from the outside and the heat pipe(5) which transfers heat from the heat source to an object(20) to be heated and heats the object. The heat pipe includes a pair of heating parts(6), a plurality of heat radiating parts(7) and a heat medium(11). The heating parts extend long to be positioned in the heat source and are heated by the heat source. The heat radiating parts are arranged to be parallel to each other so that both ends of each heat radiating part are coupled to the heating parts, and heat supplied from the heat source is radiated from the central portion of each heat radiating part. The heat medium is accommodated in the heating parts and heat radiating parts, and is evaporated when the heat medium is heated by the heat source and is condensed when the heat radiating part radiates heat. Each heat radiating part has an inclined part(73) which extends obliquely from the center of the heat radiating part towards the heating parts.

Description

Heating pipe line provided with a heat pipe easy to horizontal circulation}

1 is a perspective view of a heating pipe having a conventional heat pipe.

FIG. 2 is a perspective view illustrating a use state in which a heating object such as a floor top plate is stacked on the heating pipe of FIG. 1.

3 is a cross-sectional view of FIG. 2.

4 is a perspective view of a heating pipe having a heat pipe according to the present invention;

5 is a perspective view illustrating a use state in which a heating object is placed on the heating pipe of FIG. 4.

FIG. 6 is a cross-sectional view of FIG. 5 illustrating an embodiment to which a thermosiphon type heat pipe is applied, and FIG. 6A illustrates a form in which an upper bottom is formed at the time of forming a heat pipe, and FIG. 6B illustrates a form in which an upper bottom is formed separately and attached. .

FIG. 7 is a cross-sectional view of FIG. 5 showing an embodiment to which a wick type heat pipe is applied.

FIG. 8 is a cross-sectional view of FIG. 5 showing yet another embodiment to which a thermosiphon type heat pipe is applied, in which a bottom surface is raised to a constant height to form an upper bottom portion.

9 is a longitudinal sectional view of a heat pipe to which a first connector of a T shape is applied;

10 is a longitudinal sectional view of a heat pipe to which a second connector of a + shape is applied;

<Description of the symbols for the main parts of the drawings>

1: heating piping 3: heat source

5 heat pipe 6 heating part

7,7-1, -2, -3: heat radiating portion 11: heat medium

13: Wick 20: Heating Object

31: first connector 33: second connector

73,73-1, -3: Upper base

The present invention relates to a heating pipe having a heat pipe that is easy to horizontally circulate, and more particularly, even when installed horizontally so that it can be used for floor heating of buildings, the heat transfer efficiency does not decrease, and at least one side of the floor top plate The present invention relates to a heating pipe having a heat pipe that is easy to horizontally circulate so as to be interviewed with a heating object so as to transfer heat generated therein to the heating object smoothly without disconnection.

In general, there are two methods of installing heating facilities on the floor of residential buildings such as houses or apartments, such as a wet method and a dry method. First, the wet method is the traditional method of placing concrete on the floor slab, curing it for a certain time, installing a heating pipe on it, applying concrete on it, and finally finishing with a top plate. On the other hand, the dry method is a new method of placing a preformed support frame on the floor slab, installing a heating pipe thereon, and then covering the finishing material such as a top plate on the support frame.

Among them, the heating piping by the dry method has a disadvantage of poor heating efficiency, such as the top plate, which is a heating object, is rapidly cooled when the heat source such as an electric heater is cut off. Construction methods that replace heat pipes, which are thermal conductors, have been proposed.

Heat pipes can be generally classified into thermophony type, vibrating tubular type, wick or mesh type, and the like, and an example of a dry heating pipe employing a wick type heat pipe will be described with reference to FIG. 1. do.

This heating pipe is composed of a heat source 103 and a heat pipe 105, as shown by the reference numeral 101 in Figs. 1 to 3, wherein the heat source 103 is a heat pipe 105 As a means for heating the heat medium 111 accommodated in the heating unit 106 of the heat exchanger, a heat exchanger that uses heat generated from an electric heater or another heat source outside to heat the heat medium 111 to directly generate heat to be applied to the heat medium 111. A device such as a tube is used and serves to supply heat to the heat pipe 105.

In addition, the heat pipe 105 is configured to quickly transfer heat generated from the heat source 103 to the heating object 120 such as the floor top plate shown in FIGS. 2 and 3. It consists of the heating part 106 of both ends, and the some heat dissipation part 107 arrange | positioned side by side between this heating part 106, The heating part 106 is comprised by the heat source 103 arrange | positioned coaxially. As shown in FIG. 3, the heat medium 111 accommodated therein is heated. The plurality of heat dissipating units 107 connected to form a single pipe by the heating units 106 at both ends ultimately emits the heat taken from the heat source 103 at both ends to heat the heating object 120. Floor heating is achieved in the support frame 110 of the dry floor heating equipment as shown in FIG.

However, the floor heating pipe 101 employing the conventional wick-type heat pipe is because of the horizontal characteristics of the floor top plate, that is, the heating object 120 of the building that the heat pipe 105 cannot protrude from a specific part. Since it can only be arranged horizontally, it cannot have a slope in the horizontal direction. Accordingly, the heat pipe 105 may be exposed to the capillary pressure of the wick 113 even if the heat medium 111 of the heating unit 106 is evaporated by the heat source 103 and then radiated and condensed at an intermediate point of the heat radiating unit 107. Since it depends solely on the heating unit 106, the movement is not performed smoothly, and thus active heat transfer cannot be achieved, and as a result, the heating object 120 cannot be heated quickly by the heat supplied from the heat source 103. There was a problem.

Furthermore, in the case of thermosiphon type heat pipes in which no wick is present and the condensed heat medium moves to the high temperature part by dropping depending entirely on gravity, the heat transfer performance is markedly degraded when used in horizontally installed floor heating piping. There was this.

In addition, as shown in FIG. 3, since the thickness of the heating unit 106 surrounding the heat source 103 is greater than the thickness of the heat dissipation unit 107, the heating object 120 such as a top plate on the heating pipe 101. The heating object 120 comes into contact only with the heating part 106 protruding upward from the heat dissipation part 107 when it is deposited. Therefore, a gap by a distance d is generated between the heat dissipation unit 107 and the heating object 120, so that the heat generated from the heat dissipation unit 107 is not directly conducted to the heating object 120. Since only the heat is transmitted to the heating object 120, the heat generated from the heating unit 106 may not be efficiently transferred to the heating object 120, and thus, the heating efficiency of the entire heating pipe 101 may be reduced.

The present invention has been proposed to solve the problems of the conventional heating pipe with a heat pipe as described above, by improving the internal structure of the heat pipe of the heating pipe installed on the building floor can not be locally inclined construction floor It is possible to improve heat transfer efficiency by heat pipe while constructing horizontally in accordance with the essential characteristics of the heat pipe, and change the cross-sectional shape of the heat pipe to have at least one flat surface, and at the same time, the flat surface is directly applied to a heating object such as a floor top plate. The purpose of the present invention is to allow heat generated in the heat pipe to be directly transmitted to the heating object to maximize heat transfer efficiency.

Therefore, the present invention, in order to achieve the above object, a heat source receiving energy required for heat generation from the outside; And a heat pipe configured to transfer the heat supplied from the heat source to the heating object to heat the heating object, wherein the heat pipe is extended to be long to arrange the heat source therein, by the heat source. A pair of heating parts to be heated; A plurality of heat dissipation parts arranged in parallel so as to be coupled to each other between the pair of heating parts, and configured to discharge heat supplied by the heat source from an intermediate portion; And a heat medium housed in an inner space of the heating unit and the heat dissipating unit and evaporated when heated by the heat source in the heating unit and condensed when dissipating in the heat dissipating unit. The heating pipe provided with the heat pipe which is easy to horizontal-circulate which formed the upper-bottom part which inclines toward the heating part of the both ends from this point is provided.

Hereinafter, a heating pipe having a heat pipe that is easy to horizontally circulate according to a preferred embodiment of the present invention will be described with reference to the accompanying drawings.

As shown in Figures 4 and 5, the heating pipe according to the present invention is largely composed of a heat source (3) and a heat pipe (5) like a general dry heating pipe widely used in building floor construction.

Here, the heat source 3 is a portion for heating the heating portion 6 of the heat pipe 5, which is relatively low temperature, as shown in Figs. 4 to 7, the heat dissipation portion of the heat pipe 5 (7) The heating medium 11 which is inserted into the heating part 6 connected to both ends and flows through the heating part 6 is heated. To this end, the heat source 3 is adapted to receive heat energy to be used for heating from the outside, and the heat source 3 is heated by an electric heater or another heat source externally operated by an external power source to generate heat. Heat exchange tubes or the like for generating heat may be used.

Thus, the heat pipe 5 in which the heat source 3 is disposed is composed of a heating part 6 made of a rod body, a heat dissipation part 7, and a heat medium 11 accommodated therein. Here, the pair of heating parts 6 into which the heat source 3 is first inserted and mounted is coupled to both ends of the plurality of heat radiating parts 7 arranged in parallel along the floor of the building, and thus the heat source 3 And also serves to connect the heat dissipation unit (7) thermally, as well as structurally. At this time, the heating part 6 has a ladder shape as a whole together with the heat dissipating part 7 so as to attach the heating object 20 such as a floor top plate to an upward facing surface as shown in FIG. 6A, B or 7. It is.

On the other hand, the plurality of heat dissipation units 7 coupled in parallel at regular intervals between the two heating units 6 at both ends is a portion that directly heats the heating object 20, and is connected to the heating units 6 at both ends. The heat medium 11 heated by the inserted heat source 3 is quickly moved to a relatively low temperature intermediate part to be transferred to the heating object 20.

At this time, each of the heat dissipating portion 7 may be applied to the thermosiphon type heat pipe shown in Figure 6a, this heat dissipating portion (7) is a heat medium 11 inside the rod forming the outer body like a typical thermosiphon type heat pipe ) Is accommodated, and in particular, the upper bottom portion 73 is convexly formed at the bottom of the inner circumferential surface. In addition, the heat dissipation portion 7 is made of a copper tube having excellent thermal conductivity, and is hollow to accommodate the heat medium 11, and the male fastening portion 79 protrudes from both ends of the outer circumferential surface, and the male fastening portion 79 is formed. Is connected to the heating part 6 by being joined to the female fastening part 59 of the coupling hole penetrated in the middle of the body of the heating part 6 by welding or the like.

As shown in FIG. 6A, the heating parts 6 and the heat dissipating parts 7 coupled to each other may have upper surfaces 67 and 77 in contact with the heating object 20 as flat surfaces, so as to be in close contact with the heating object 20 without a gap. To this end, it is preferably made of a square rod having a square cross-sectional shape as shown in Figures 4 to 7. However, of course, if the heating part 6 and the heat radiating part 7 have upper surfaces 67 and 77 which may be in close contact with the heating object 20, the cross-sectional shape may be deformed in any form.

On the other hand, the heat dissipating portion (7, 7-1), as shown in Figure 6a, b so that the bottom surface 75 in the form of venturi tube, the bottom of the inner circumferential surface is raised up from the center point, the heating portion 6 on both ends The upper bottom portion 73, 73-1 is inclined toward 6, wherein the upper bottom portion 73 may be integrally formed when forming the heat radiating portion 7 as shown in FIG. 6A. 6b may be separately manufactured, such as the upper bottom portion 73-1, and may be attached to the bottom of the inner circumferential surface of the heat radiating portion 7-1. Therefore, the upper bottoms 73 and 73-1 have gravity due to the difference in height of the bottom surface 75 of the liquid heat medium 11 condensed at a relatively low temperature by the bottom surface 75 inclined toward both ends. By the action of the potential energy is lost to move smoothly to the connecting pipes (3). Furthermore, the upper bottom portion 73-1 may be made of a heat insulating material, which may prevent the heat emitted from the heat radiating portion 7-1 from being lost downward.

In addition, the heating pipe 1 of the present invention is also applicable to the wick type heat pipe as shown in FIG. 7, wherein the wick type heat pipe used as the heat dissipation part 7-2 also has a wick 13 on its inner surface. Except for being attached, it has the same structure as the thermosiphon type heat dissipation parts 7 and 7-1 shown in Figs. 6A and 6B.

Therefore, the heat medium 11 is accommodated in the inside of the rod body which also constitutes an outer body, and the upper bottom part 73 is formed in the bottom of an inner peripheral surface. The wick 13 is attached to a predetermined thickness along the inner circumferential surface and the bottom surface 75 of the upper bottom portion 73. Here, the heat medium 11 and the upper bottom 73 are the same as those of the thermosiphon type heat dissipation part 7 shown in Fig. 6A, and thus detailed description thereof will be omitted. However, the wick 13 surrounding the inner circumferential surface of the heat dissipating portion 7-2 and the bottom surface 75 of the upper bottom portion 73 is condensed at the middle portion of the heat dissipating portion 7-2 similarly to the commonly used wick. The liquid heat medium 11 to be moved to both ends with the heating portion 6 through the capillary phenomenon appearing in the fine gap therein. At this time, a portion of the liquid heat medium 11 may move toward the heating part 6 by gravity along the wick 13 surface inclined in the same shape as the upper bottom 73 bottom surface 75, so that the movement is quick. Can be done.

Meanwhile, as another embodiment of the present invention, as shown in FIG. 8, an upper bottom portion 73-3 having a stepped shape may be formed on the inner circumferential surface of the thermosiphon type heat dissipating portion 7-3. 73-3) is formed by projecting at least a portion of the central portion higher than both ends connected to the heating parts 6 and 6 in terms of the total length of the inner circumferential surface of the heat dissipation part, and the bottom surface through which the heat medium 11 flows. Mobility of the liquid medium 11 condensed at the middle portion of the heat dissipating portion 7-3 to flow out to the heating portions 6 and 6 of both ends is inferior to the 75-3, but the left and right end faces are depressed. As shown in each of the left and right sides of 8, the heat sink 7-3 has a simple shape that is inclined at a right angle or at an angle with respect to the inner circumferential surface thereof. Have

In addition, the heating pipe 1 of the present invention is a heating portion (6 ', 6 ″) and the heating portion (6', 6 ″) in order to make the assembly of the heat radiating portion 7 more convenient to FIG. 9 and FIG. As shown in FIG. 10, it consists of the some 1st connection port 31 which has a T-shaped longitudinal cross-sectional shape, or the some 2nd connection port 33 which has a + cross-sectional shape. Here, the first connector 31 forming the heating part 6 ′ shown in FIG. 9 is first connected to the first portion 35 corresponding to the head of the T and the center of the first portion 35. It consists of a second portion 37 corresponding to the body portion, the first portion 35 is continuously extended in the longitudinal direction of the heat pipe 5 so that the heat source 3 can be disposed therein do. In addition, the second portion 37 extends at right angles from the middle portion of the first portion 35 to connect the heat dissipation portion 7 in the transverse direction, and thus is formed by the continuous first portions 35. The heating portion 6 ′ may be connected to the heat radiating portion 7 at a right angle. In this case, as shown in the lower part of FIG. 9, the distance between the heat dissipating parts 7 may be increased by interposing the connection pipe 8 between the first portions 35 of the first connector 31.

The coupling between the first connectors 31 or the coupling between the first connector 31 and the heat dissipation unit 7 or the connector 8 may be, for example, as shown in FIG. 9. It can be achieved by welding or the like. For this purpose, the first connector 31 has a female fastening portion 38 at one end of the first portion 35, a male fastening portion 39 at the other end, and a second portion 37. At the end of the female fastening portion 40 may be processed, respectively, so that the female fastening portion 42 at one end of the heating portion 6, the male fastening portion 43 at the other end may be processed to be coupled thereto, Male fastening portions 45 may be processed at both ends of the portion 7, respectively.

On the other hand, the second connector 33 constituting the heating portion 6 ″ shown in FIG. 9 is perpendicular to the middle of the first portion 46 and the first portion 46 in the longitudinal direction so as to have a + shape. The first portion 46 extends in the longitudinal direction of the heat pipe 5, similarly to the first portion 35 of the first connector 31. When overlapping, the heat source 3 can be fitted inside. In addition, the second portion 47 extends to intersect at right angles in the middle of the first portion 46 so as to be able to connect between the heat radiating portions 7 adjacent in the lateral direction, and thus the first portion 46 This allows the heating portions 6 ″ formed by being continuous to be connected at right angles between the radiating portions 7.

In this manner, the second connector 33 which simultaneously forms the heating part 6 '' and the heat dissipation part 7 in the longitudinal and horizontal directions is also coupled to the male and female coupling parts 42 and 43 of the heating part 6, respectively. The female fastening portion 48 may be processed at one end of the portion 46 and the male fastening portion 49 may be processed at the other end thereof, and the male fastening portions at both ends of the heat dissipating portion 7 may be formed at both ends of the second portion 47. Female fastening portion 50 to which 45 is coupled may be processed.

Now, the operation of the heating pipe having a heat pipe with easy horizontal circulation according to a preferred embodiment of the present invention configured as described above will be described.

The heating pipe 1 of the present invention is installed in the form of a support frame as in the prior art when constructed as a floor heating equipment of the building, as shown in Figure 5, a plurality of heat dissipating portion 7 in the center so as to form a ladder as a whole The heating parts 6 are arranged side by side at equal intervals and are coupled to both ends of each of the heat dissipation parts 7. And the heating object 20, such as the floor top plate is installed in close contact on the heating pipe 1 is coupled as shown in Figure 6a, b or 7.

Therefore, the heating pipe 1 of the present invention is to heat the floor of the building in the following order, first, the heat source (3) at both ends such as the electric heater or heat exchanger tube is operated to the inside of the heating section (6) Heat the heating medium. The heat medium 11 heated in the heating part 6 to be relatively high temperature evaporates immediately and moves to the middle part of the heat dissipation part 7, and cools in this relatively low temperature part and condenses into the liquid phase and heats out. Release. The heat emitted from the heat dissipation unit 7 is not shown, but is blocked by the heat insulating material of the support frame or the upper bottom portion 73-1 of the heat insulating material shown in FIG. 6B, and transferred to the heating object 20 at the upper portion. Since the part 7 is in close contact with the heating object 20 by the flat upper surface 77, the heat discharged from the heat radiating part 7 is transmitted to the heating object 20 without fail, thereby efficiently heating the floor.

After the heat dissipation, the heat medium 11 of the liquid condensation generated in the middle of the heat dissipation part 7 is the upper bottom portion 73 by gravity in the case of the thermosiphon type heat dissipation parts 7 and 7-1 shown in FIGS. 6A and 6B. It is easily moved to the heating parts 6 and 6 at both ends along the bottom surface 75 of 73-1). Therefore, despite being arranged horizontally, the heat pipe 5 can easily transfer the heat generated from the heat source 3 to the heating object 20. Similarly, in the wick-type heat dissipation unit 7-2 shown in FIG. 7, the wick 13, which surrounds the heat medium 11 in the heat dissipation unit 7-2, is inclined downward from the center point along the upper bottom 73 toward both ends. Since the liquid heat medium 11 condensed and produced moves not only by the capillary phenomenon which arises in the clearance gap of the wick 13 but also by gravity, it moves toward the heating part 6, and smooth heat transfer is achieved.

Similarly, the heat radiating portion 7-3 shown in FIG. 8 also has an upper bottom portion 73-3 extending from the right center of the inner circumferential surface to the left and right sides, and thus a liquid heat medium condensed from the middle portion of the heat radiating portion 7-3. Since 11 has the potential energy as high as the height of the upper bottom 73-3, it moves to the heating parts 6 on both the left and right ends faster than when the upper bottom 73-3 is absent.

As described above, according to the heating pipe having the heat pipe which is easy to horizontally circulate according to the present invention, the inner circumferential surface of the heat dissipating portion is formed at the center of the heat dissipating portion by forming an upper bottom portion on the bottom of the heat dissipating portion inner circumferential surface of the heat pipe used for the heating pipe of the building floor. Even if the heat pipe is installed horizontally along the top of the building floor, the heat pipe is radiated from the middle part of the heat dissipation unit and the condensed liquid heat medium is heated according to the inclination of the top or wick. Since it can be quickly moved to the negative, it is possible to significantly improve the heat transfer efficiency of the heating pipe using the heat pipe.

In addition, by making the bar of the heat pipe in the shape of a rectangle to be in close contact with the heating object in contact with the upper surface it is possible to transfer the heat generated from the radiator to the heating object without missing, it is possible to significantly improve the heating thermal efficiency.

Claims (7)

A heat source 3 receiving energy required for heat generation from the outside; And A heat pipe 5 for transferring the heat supplied from the heat source 3 to the heating object 20 to heat the heating object 20. The heat pipe 5, A pair of heating parts 6 extending long to arrange the heat source 3 therein and heated by the heat source 3; A plurality of heat dissipating parts (7) arranged in parallel so as to be coupled at both ends between the pair of heating parts (6), and dissipating heat supplied by the heat source (3) from an intermediate portion; And Condensed when accommodated in the inner space of the heating part 6 and the heat dissipation part 7 and evaporated when heated by the heat source 3 in the heating part 6 and radiated by the heat dissipation part 7. Consisting of a heating medium (11), The heat dissipating part 7 is formed at the bottom of the inner circumferential surface of the heat pipe with easy horizontal circulation, characterized in that the upper bottom portion 73 is inclined toward the heating parts 6 and 6 at both ends. Heating piping provided. According to claim 1, The heat radiating portion 7-1 has a horizontal circulation, characterized in that an upper bottom portion 73-1 is attached to the bottom of the inner circumferential surface of the heat radiating portion 7-1 inclined toward the heating portions 6 and 6 at both ends. Heating piping with easy heat pipes. According to claim 1, The heat dissipation unit 7-2 further includes a wick 13 attached to a predetermined thickness along an inner circumferential surface and a bottom surface 75 of the upper bottom portion 73. Heating piping equipped with. The method according to any one of claims 1 to 3, Each of the heating part 6 and the heat dissipation part 7 has a rectangular cross section, and the heating object 6 and the heat dissipation part 7 are heated by the heat dissipation part 7. A heating pipe having a heat pipe with easy horizontal circulation, characterized in that the upper surfaces (67, 77) in contact with (20) are flat surfaces of the same height, respectively. The method of claim 4, wherein The upper bottom portion 73-3 is formed by making the inner circumferential surface of at least a portion of its center higher than both ends thereof in terms of the entire length of the heat dissipating portion 7-3. Heating piping with pipes. The method of claim 4, wherein The heating part 6 ′ is composed of a plurality of first connection ports 31 continuously connected in the longitudinal direction, The first connector 31, A first portion 35 into which the heat source 3 can be inserted; and And a second portion (37) connected at right angles to the first portion (35) and connected to the heat dissipation portion (7). The method of claim 4, wherein The heating portion 6 '' is composed of a plurality of second connecting ports 33 connected in a longitudinal direction continuously, The second connector 33 is, A first portion 46 into which the heat source 3 can be inserted; and And a second portion (47) connected to the first portion (46) at right angles to cross the first portion (46) and connected to the heat radiating portion (7).

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