KR100861426B1 - Dual heating pipe for low power consumption - Google Patents

Abstract

A dual heating pipe for low power consumption is provided to effectively obtain the heating efficiency by reducing excessive heat storage material filled in the pipe. A dual heating pipe(100) for low power consumption comprises a heating pipe(110), an electric wire(120) for supplying power to the heating pipe, a heating wire(130) disposed in the heating pipe, a coupling part(140) electrically connecting the electric wire to the heating wire, and a sealing part(150) disposed at one end of the heating pipe. The sealing part includes an electric wire hole, a first nut, a second nut, a sealing pipe, an outer cap and an inner cap. The outer cap is disposed between the first nut and the sealing pipe. The inner cap connects the second nut to the sealing pipe. The inner cap has a cylindrical body, a side wall part extending from an edge of the body lengthwise along the body and an electric wire induction part wrapping the wire, protruding from an upper part of the body toward the drawing direction of the electric wire.

Description

Low Power Double Heat Sink {DUAL HEATING PIPE FOR LOW POWER CONSUMPTION}

The present invention relates to a low power double heat dissipation tube. More specifically, the present invention relates to a low power double heat dissipation tube having an easy sealing structure.

In general, in a conventional boiler tube using a hot wire, a heat storage medium such as water is injected into the boiler tube, and a hot wire is inserted to generate heat using electrical energy in the hot wire. After heating the thermally conductive material, heat is transferred around the boiler tube.

In the existing boiler tube, the wire is connected from the outside to transfer electrical energy to the heating wire in the boiler tube. That is, since the heating wire is inserted from the outside of the boiler tube to the inside, the packing or the like for preventing the leakage of the heat storage medium in the boiler tube is easily deformed by the heating wire. Therefore, the sealed state of the boiler tube is easily damaged, and thus, the internal substance injected into the tube easily leaks, causing a failure.

In addition, since the seal is directly sealed at the end of the boiler tube, it is necessary to take out and maintain all the heat storage medium therein at the same time as this sealing, and after the maintenance, it is necessary to re-inject the heat storage medium into the boiler tube again. have

In addition, in a general boiler tube, a heat storage medium is inserted into the heat dissipation pipe and the whole heat storage medium is heated with a heating wire. Since it takes a very long time to reach a temperature that the heat storage medium can radiate heat, there is a disadvantage that the efficiency of energy is lowered.

Accordingly, the present invention has been made in view of such a problem, and provides a low-power double heat dissipation tube having a structure capable of preventing the leakage of the internal heat storage medium and easily controlling the internal heat storage medium.

The low-power dual heat dissipation tube according to an embodiment of the present invention is a heat dissipation tube that transfers heat to a periphery, an electric wire that supplies power to the heat dissipation tube from the outside, is located in the heat dissipation tube, and receives electric energy from the electric wire to generate heat. A heating wire to be generated, located in the heat dissipation tube, a fastening portion electrically connecting the electric wire and the heating wire, and a sealing portion positioned at an end of the heat dissipation tube and sealing the heat dissipation tube and the electric wire.

The sealing part may include a wire hole which is fastened to the end of the heat dissipation tube to seal the end of the heat dissipation tube, and the wire exits.

In addition, the sealing portion may include a first fastening nut; It may include a second fastening nut and a sealed tube.

The sealing part may include an outer stopper positioned between the first fastening nut and the sealing tube and an inner stopper coupling to the second fastening nut and the sealing tube.

The outer stopper may include a hook hole for preventing the wire from flowing out of the wire hole and the first fastening nut.

The inner stopper is cylindrical body portion; A side wall portion extending in the longitudinal direction of the body portion from an edge of the body portion; The wire may protrude in a direction in which the wire is drawn out from the upper portion of the cylindrical body may include a wire guide portion surrounding the wire.

The inner stopper may be formed of a stretchable material to accommodate the pressure by extending the sidewall part when a pressure to the outside is applied to the inner stopper.

The end of the side wall portion of the inner stopper may include a fastening jaw to prevent the second fastening nut from being pushed outward.

It may further include a packing located between the fastening jaw of the inner plug and the second fastening nut.

It may further include an inner tube formed inside the heat dissipation tube and sealed to fill the heat dissipation tube even though the amount of material inserted into the heat dissipation tube is reduced.

The inner tube may include a sealing member positioned at the end of the inner tube to seal the material in the heat dissipation tube from entering the inner tube.

The sealing member of the inner tube may be inserted into the inner tube at the end of the inner tube, it may be fixed to the end of the inner tube with a fastening pin.

The sealing member of the inner tube may include polyurethane.

According to such a low-power double heat pipe, it is possible to prevent the leakage of the internal material, to easily manage the internal material during repair, and to remove the heat storage medium inserted into the tube by the volume of the inner tube, thereby realizing The amount of heat storage medium is reduced. Therefore, the heat radiation effect can be efficiently generated.

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

1 is a perspective view of a low power double heat dissipation tube according to a first embodiment of the present invention.

Referring to FIG. 1, the low power dual heat dissipation tube 100 according to the first embodiment of the present invention includes a heat dissipation tube 110, an electric wire 120, a heating wire 130, a fastening unit 140, and a sealing unit 150. It includes. The heat dissipation tube 110 includes a heat storage material therein, and transmits heat to a peripheral portion of the heat dissipation tube 110.

The wire 120 supplies electrical energy from the outside. The wire 120 is led through the sealing part 150 and extends to an upper portion of the heat dissipation pipe 110. The wire 120 extending to the upper portion of the heat dissipation pipe 110 supplies electrical energy to the heating wire 130. The heating wire 130 receives electrical energy from the wire 120 and converts it into thermal energy.

The heating wire 130 generates heat and heats the heat storage material filled in the heat dissipation pipe 110. The heating wire 130 may extend to the whole of the heat dissipation tube 110. In addition, the heating wire 130 may extend to a part of the heat dissipation pipe 110 for efficient heating, and the heat storage material heated by the heating wire 130 may transfer heat through convection.

The fastening unit 140 electrically connects the wire 120 and the heating wire 130. The fastening part 140 is located inside the heat dissipation pipe 110. The fastening part 140 insulates the connection portion of the electric wire 120 and the heating wire 130 from the heat storage medium in the heat dissipation pipe 110. Accordingly, the fastening part 140 may include rubber, silicon, and various resins, and electrically insulates the heat storage medium, the connection portion of the wire 120 and the heating wire 130, and connects two or more of the connections. Isolate the parts electrically from each other. The interior of the fastening portion 140 has a structure that is sealed from the outside. Therefore, the heat storage medium penetrates into the fastening part 140, and is electrically connected between the wires 120 or the heating wires 130 to prevent electrical defects such as a short circuit.

Since the fastening part 140 is located inside the heat dissipation tube 110, the heating wire 130 is located only inside the heat dissipation tube 110. Therefore, since only the heat storage medium is in contact with the heating wire 130, the other components in the present embodiment are not deformed by the heat generated by the heating wire 130.

The sealing part 150 is located at the end of the heat dissipation pipe 110. The sealing part 150 seals the wire 120 introduced into the heat dissipation tube 110 and the heat dissipation tube 110 so that the heat storage material filled in the heat dissipation tube 110 does not leak to the outside. The sealing part 150 has a wire hole, through which the wire 120 is introduced.

FIG. 2 is a side view of the low power double heat sink of FIG. 1. FIG. Referring to FIG. 2, the sealing part 150 includes a first fastening nut 151, a second fastening nut 152, and a closed pipe body 155.

The first fastening nut 151 and the second fastening nut 152 are fastened to the end of the heat dissipation pipe 110 to fix the sealing part 150. The hermetic pipe 155 is connected to the first fastening nut 151 and the second fastening nut 152 and introduces the wire 120.

The closed tube 155 connects the first fastening nut 151 and the second fastening nut 152 to each other. The closed tube 155 may adjust the distance between the first fastening nut 151 and the second fastening nut 152. In addition, the closed tube body 155 facilitates the connection and separation of the first fastening nut 151 and the second fastening nut 152, it is possible to work more easily during repair and assembly.

3 is a cross-sectional view of the low power double heat dissipation tube of FIG. 1.

Referring to FIG. 3, an outer stopper 180 and an inner stopper 160 are positioned in the seal. The outer stopper 180 is positioned between the first fastening nut 151 and the sealing tube 155, and introduces the wire 120 from the outside while preventing the leakage of the heat storage medium to the outside.

In addition, the inner stopper 160 is located in the second fastening nut 152, and the inner stopper 160 is also inserted into the wire through the outer stopper 180 while preventing the outflow of the heat storage medium. Lead 120 into the inner tube.

Some space is secured between the outer stopper 180 and the inner stopper 160, and the inner stopper 160 may be formed of an elastic plastic resin. Therefore, when the heat storage medium of the inner tube is pressured to the outside due to heating or the like, the inner plug 160 has a margin that can be increased by the space between the inner plug 160 and the outer plug 180. It can be secured. Indeed, the inner stopper 160 extends by the space between the inner stopper 160 and the outer stopper 180 to buffer the pressure of the heat storage medium of the inner tube.

4 is a perspective view of a low power double heat dissipation tube according to a second embodiment of the present invention.

Referring to FIG. 4, the low power double heat dissipation tube 500 according to the second embodiment of the present invention includes a heat dissipation tube 510, a heating wire 530, and an inner tube 570. The heat dissipation tube 510 fills the heat storage medium therein, and the heating wire 530 is formed inside the heat dissipation tube 510.

The inner tube 570 may fill the heat dissipation tube 510 even though the amount of heat storage medium filled in the heat dissipation tube 510 is reduced. Thus, both ends of the inner tube 570 are sealed. The heat dissipation tube 510 fills the heat storage medium therein. When the heat dissipation tube 510 is filled with a predetermined space, and the remaining space is filled with the heat storage medium, Since the heat storage medium reaches the desired temperature without heating all the heat storage medium, it is possible to save considerable energy. In addition, the ratio of the cross-sectional area of the inner tube 570 to the heat radiating tube 510 is preferably about 30 to 50 percent.

The inner tube 570 includes a tube body 571 and a sealing member 573. The sealing member 573 is located at the end of the tubular body 571, and seals the heat storage medium so that the heat storage medium does not enter the inner tube 570. The sealing member 573 may be formed of a material that is easily bonded to the tube body 571 and easily sealed, and may include polyurethane.

5 is a cross-sectional view taken along the line II ′ of FIG. 4.

Referring to FIG. 5, an inner tube 570 including the tube body 571 and the sealing member 573 and the heating wire 530 are disposed in the heat radiating tube 510. The inner tube 570 is preferably located at the center of the heat dissipation tube 510. For this purpose, a separate support material (not shown) may be formed in the heat dissipation tube 510. In addition, in order to effectively heat the heating wire 530, the heating wire 530 may be spaced apart from each other by a predetermined distance along the outside of the inner tube 570. In addition, the heating wires 530 may be symmetrically positioned in the heat dissipation tube 510.

6A is a cross-sectional view of the inner plug. 6B is a cross-sectional view of the outer plug. 7A is a perspective view of the inner plug of FIG. 6A. FIG. 7B is a perspective view of the outer plug of FIG. 6B. FIG.

Referring to FIG. 6A, the inner plug 160 includes a cylindrical body portion 164, a side wall portion 162, and a wire guide portion 165. An introduction hole 163 is formed in the cylindrical body 164 to allow the wire to be introduced from the outside. The side wall portion 162 is formed to extend in the longitudinal direction of the body portion 164 at the edge of the body portion 164. An empty space is formed inside the side wall portion 162. The wire guide part 165 protrudes in the direction in which the wire is drawn out from the upper portion of the cylindrical body 164 to surround the wire. The wire guide part 165 is formed in an inner space surrounded by the side wall part 162.

The wire induction part 165 may be formed in a thin cylindrical shape, and may be formed in a pointed structure at the end of the wire induction part 165. This is because the pressure of the internal heat storage medium for entering the hole itself is dispersed by the hydraulic pressure in the hole through which the terminal wire of the wire guide part 165 exits.

In addition, the end of the side wall portion 162, as shown in Figure 6a, may include a locking step for preventing the escape from the first fastening nut.

The locking jaw prevents the internal stopper 160 from being pulled out by the pressure of the heat storage medium inside the first locking nut, and a separate ring is provided between the locking jaw and the first locking nut. It may further include.

Referring to FIG. 6B, the outer stopper 180 includes a wire entry hole 183 in the cylindrical body 182. The wire inlet hole 183 is formed on an extension line of the wire inlet hole of the inner plug, and leads the wire from the outside into the inside.

8 is an exploded perspective view of a sealing part of a low power double heat dissipation tube according to a first embodiment of the present invention.

Referring to FIG. 8, the sealing part includes a first fastening nut 151, an external stopper 180, a sealing tube 155, a packing 191, a second fastening nut 152, and an internal stopper 160. As mentioned above, the outer stopper 180 is located between the first fastening nut 151 and the sealing tube 155, and the inner stopper 160 is the sealing tube 155, the packing 191, the first 2 is located in the fastening nut 152 to prevent the internal heat storage medium from escaping to the outside.

Although the detailed description of the present invention has been described with reference to the preferred embodiments of the present invention, those skilled in the art or those skilled in the art will have the idea of the present invention described in the claims to be described below. It will be understood that various modifications and variations can be made in the present invention without departing from the scope of the present invention.

1 is a perspective view of a low power double heat dissipation tube according to a first embodiment of the present invention.

FIG. 2 is a side view of the low power double heat sink of FIG. 1. FIG.

3 is a cross-sectional view of the low power double heat dissipation tube of FIG. 1. 4 is a perspective view of a heat sink according to a second embodiment of the present invention.

5 is a cross-sectional view taken along the line II ′ of FIG. 4.

6A is a cross-sectional view of the inner plug.

6B is a cross-sectional view of the outer plug.

7A is a perspective view of the inner plug of FIG. 6A.

FIG. 7B is a perspective view of the outer plug of FIG. 6B. FIG.

8 is an exploded perspective view of a sealing part of a low power double heat dissipation tube according to a first embodiment of the present invention.

<Description of reference numerals for the main parts of the drawings>

100, 500: low power double heat sink

120, 520: wire 130, 530: heating wire

140: fastening part 150: sealing part

160: internal stopper 180: external stopper

570: inner tube 680: entrance hall

Claims (13)

A heat dissipation tube transferring heat to the periphery; An electric wire for supplying power to the heat dissipation tube from the outside; A heating wire positioned in the heat dissipation tube and generating heat by receiving electrical energy from the wire; A fastening part disposed in the heat dissipation pipe and electrically connecting the electric wire and the hot wire; And It is located at the distal end of the heat dissipation tube, a sealing unit for sealing the heat dissipation tube and the wire; includes; The sealing part is fastened to the end of the heat dissipation tube to seal the end of the heat dissipation tube, the wire hole through which the wire exits; First fastening nut; Second fastening nut; Airtight tube; The sealing portion is an outer stopper positioned between the first fastening nut and the sealing tube; And an inner stopper coupled to the second fastening nut and the sealed tube; The inner stopper is cylindrical body portion; A side wall portion extending in the longitudinal direction of the body portion from an edge of the body portion; Low-power double heat dissipation tube, characterized in that it comprises a wire induction portion protruding in the direction in which the wire is drawn out from the upper portion of the cylindrical body portion. delete delete delete The low power double heat dissipation tube according to claim 1, wherein the outer plug includes a catch hole for preventing the wire from flowing out of the wire hole and the first fastening nut. delete The low-power double heat dissipation tube according to claim 1, wherein the inner stopper is made of a stretchable material, and the sidewall portion is extended to receive the pressure when an outward pressure is applied to the inner stopper. The low-power double heat dissipation tube according to claim 1, wherein the end of the side wall portion of the inner stopper includes a fastening jaw for preventing the second fastening nut from being pushed outward. The low power double heat dissipation tube according to claim 8, further comprising a packing positioned between the fastening jaw of the inner plug and the second fastening nut. The low power double heat dissipation tube according to claim 1, further comprising an inner tube formed inside the heat dissipation tube and sealed to fill the heat dissipation tube even though the amount of material inserted into the heat dissipation tube is reduced. 11. The low power double heat dissipation tube of claim 10, wherein the inner tube includes a sealing member positioned at an end of the inner tube to seal a material in the heat dissipation tube from entering the inner tube. 12. The low power double heat dissipation tube according to claim 11, wherein the sealing member of the inner tube is inserted into the inner tube at the end of the inner tube and is fixed to the end of the inner tube with a fastening pin. The low power double heat dissipation tube according to claim 12, wherein the sealing member of the inner tube includes polyurethane.

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