KR200297323Y1 - A heat pipe having an infrared lamp and heat exchanger using of it - Google Patents

Abstract

Disclosed is a heat dissipation pipe for reducing corrosion and environmental pollution of equipment and a heat exchanger employing the same. This is a hollow pipe 20 having an endothermic heat 21 formed on the outer circumferential surface, an infrared lamp 10 fixedly coupled to the hollow pipe 20, and an end cap 23 for closing both ends of the hollow pipe 20. 24 and a heat exchange tank 40 for accommodating at least one hollow pipe 20 for receiving the infrared lamp 10 and having a water supply line 41 and a drain line 42 connected thereto. The drain line 42 has a structure in which a storage tank 50 to which the service valve 51 is connected is connected, and a circulation pump 60 for circulating water from the storage tank 50 to the heat exchange tank 40 is connected. . Such a heat dissipation pipe and a heat exchanger using the heat dissipation pipe are heated by radiant heat by an infrared lamp, and heat exchange is performed from the water supply, thereby solving the problem of endothermic heat being corroded by a heat source such as gas. Heating by prevents environmental pollution and is harmless to human body.

Description

A heat pipe having an infrared lamp and heat exchanger using the same

The present invention relates to a heat dissipation pipe having an infrared lamp and a heat exchanger using the same, and more particularly, a heat dissipation pipe for increasing thermal efficiency by heating the heat dissipation pipe with infrared rays, preventing corrosion and reducing the emission of harmful gases, and It relates to a heat exchanger using the same.

Generally, a heat exchanger of a conventionally known gas boiler is provided with a burner having a plurality of groups in a casing, and a blower for supplying combustion air is installed at a bottom thereof, and an exhaust port for discharging exhaust gas is provided through the gas boiler's casing. Formed. In addition, a heating tube for use as heating water and hot water passes through the casing and is zigzagly piped to the upper portion of the burner, and a heat exchange action is performed in which the heating tube is heated by the combustion heat of the burner, and at this time, the endothermic area of the heating tube In order to increase the number, it is common to connect a plurality of plate-shaped endothermic pins perpendicular to the heating tube.

The heating tube and the heat absorbing fin of the heat exchanger configured as described above are mainly made of metal components such as iron, copper, aluminum, and stainless steel for thermal efficiency, and the heating tubes and components made of such materials are various corrosive substances contained in the heating source. Inevitably had the disadvantage of low temperature corrosion by gas and moisture.

In other words, the hardened corrosion layer is deposited on the surface of the heating tube or the heat absorbing fin, which lowers the thermal conductivity, which not only causes the thermal efficiency to be greatly reduced, but also the surface thereof is easily damaged, thereby reducing the life of the entire apparatus.

In addition, there was always a risk of explosion due to the use of gas.

The present invention to achieve the above object is to provide a heat dissipation pipe having an infrared lamp and its structure is improved so that the thermal efficiency is improved and the corrosion is greatly reduced to extend the life of the device and its heat exchanger using the same.

1 is an exploded perspective view showing a heat radiation pie of the present invention,

Figure 2 is a perspective view of the main portion coupling of Figure 1,

3 is a schematic cross-sectional view showing a heat exchanger using the heat dissipation pipe of FIG.

4 is a cross-sectional view showing another embodiment of a heat exchanger using the heat dissipation pipe of FIG. 1.

* Explanation of symbols for main parts of the drawings

10 Infrared lamp 11,12 Fixed frame

13, 14 ... clamp 20 ... hollow pipe

21, 22 Endothermic heat 30 Heat dissipation pipe

40 ... heat exchange tank 50 ... storage tank

The present invention heat dissipation pipe to achieve the above object is a hollow pipe with endothermic heat is formed on the outer peripheral surface;

It is characterized in that the infrared lamp is fixed to the inside of the hollow pipe.

The infrared lamp is located in the center of the inside of the pipe, one end is fixed to the inner circumferential surface of the pipe and the other end of the fixing frame to form a seating portion is seated on the other end, the seating portion of the fixing frame and the infrared lamp It has a structure with a clamp clamping the end.

On the other hand, the present invention heat exchanger to achieve the above object is a hollow pipe having an endothermic heat is formed on the outer circumferential surface, an infrared lamp fixedly coupled to the inside of the hollow pipe, and at least one hollow pipe for receiving the infrared lamp And it characterized in that the heat exchange tank is connected to the inlet line and the outlet line.

The heat exchange device is a water supply through the inlet line and drained through the outlet line, the storage tank is connected to the outlet line is connected, the circulation pump for circulating the water supply from the storage tank to the heat exchange tank Has a connected structure.

In addition, the heat exchange device may be of a structure that is supplied with the outside air by the suction fan through the inlet line, the hot air heat exchanged through the outlet line is discharged.

In addition, the infrared lamp emits a near infrared ray of 0.8㎛ 2㎛.

According to the features of the present invention, the heat radiation pipe and the heat exchanger using the present invention heat absorption pipe is radiated by the radiation heat by the infrared lamp and heat exchange of the water supply or outside air is made so that the endothermic heat by a heating source such as gas as in the prior art The problem of corrosion is solved, and it is harmless to human body and prevent environmental pollution by heating by near infrared rays.

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

1 and 2 showing a heat dissipation pipe according to the present invention, this is a hollow pipe 20 having an endothermic heat 21 formed on an outer circumferential surface thereof, and an infrared lamp fixedly coupled to the hollow pipe 20. 10) and end caps 23 and 24 for closing both ends of the hollow pipe 20.

The infrared lamp 10 is fixed to a central portion inside the pipe 20. Both ends of the infrared lamp 10 are fixed to the inner surface of the hollow pipe 20 by fixing frames 11 and 12 and clamps 13 and 14.

The fixing flames 11 and 12 form seating portions 11a and 12a, one end of which is fixed to the inner circumferential surface of the pipe 20 and the other end of which the end of the infrared lamp 10 is seated. 11) The mounting portions 11a and 12a of the 12 and the ends of the infrared lamp 10 are clamped by the clamps 13 and 14.

The heat dissipation pipe 30 absorbs heat by the near infrared rays of 0.8 μm to 2 μm emitted from the infrared lamp 10 to emit heat to exchange heat with the surrounding fluid.

The heat dissipation pipe 30 may be applied to an air conditioner such as indoor heating by employing a blower fan 70 as shown in FIG. 4, and also to supply heating water by heating water supply as shown in FIG. 3. It can also be applied to the device.

On the other hand, referring to Figure 3 showing an embodiment of a heat exchanger using the heat dissipation pipe 30, which is a hollow pipe 20, the endothermic heat 21 is formed on the outer peripheral surface, and the hollow pipe 20 inside At least one infrared lamp 10 fixedly coupled to the at least one end cap 23 and 24 for closing both ends of the hollow pipe 20, and a hollow pipe 20 accommodating the infrared lamp 10. It is provided with a heat exchange tank 40 to accommodate the above and the water supply line 41 and the drain line 42.

In addition, a storage tank 50 to which the service valve 51 is connected to the drain line 42 is connected, and a circulation pump 60 for circulating water from the storage tank 50 to the heat exchange tank 40 is provided. It has a connected structure.

In the heat exchanger having the above structure, the suction fan 21 is heated by near infrared rays of 0.8 μm to 2 μm emitted from the infrared lamp 10, and water is supplied from the heated pipe 20 through the water supply line 41. The circulating water is heated to supply heating water from the service valve 51 through the drain line 42.

In addition, when the use of the heating water is stopped through the service valve 51, the circulating water is circulated through the heat exchange tank 40 by driving the circulation pump 60 from the storage tank 50.

In the embodiment, when a plurality of heat dissipation pipes 30 are employed in the heat exchange tank 40, both ends thereof may be closed by a single closing plate (not shown), not by the end caps 23 and 24. have.

In addition, referring to Figure 4 showing another embodiment of the heat exchanger using the heat dissipation pipe, this is a hollow pipe 20, the endothermic heat 21 is formed on the outer circumferential surface, the fixed coupling inside the hollow pipe 20 Receiving at least one or more infrared lamps 10, end caps 23 and 24 for closing both ends of the hollow pipes 20, and hollow pipes 20 for receiving the infrared lamps 10. It is provided with a heat exchange tank 60 to which the inlet line 61 and the outlet line 62 are connected.

In addition, the inlet line 61 is provided with a blowing fan 70 for supplying outside air.

In the heat exchanger having the above structure, the suction fan 21 is heated by near infrared rays of 0.8 μm to 2 μm emitted from the infrared lamp 10, and is supplied through the inlet line 61 from the heated pipe 20. The outside air is heated so that the warm air is supplied to the room through the outlet line 62.

It is needless to say that the present invention as described above is not limited to the above embodiments and can be carried out with many modifications without departing from the spirit and scope of the present application.

The heat dissipation pipe of the present invention and the heat exchanger using the heat dissipation pipe are heated by radiant heat by an infrared lamp, and heat exchange of water supply or external air is performed therefrom. Thus, the problem of endothermic heat being corroded by a heating source such as gas is solved. It is also harmless to human body and prevent environmental pollution by heating by near infrared rays.

Claims (5)

Hollow pipes having endothermic heat on the outer circumferential surface; A heat radiation pipe, characterized in that provided with an infrared lamp fixedly coupled to the inside of the hollow pipe. The method of claim 1, wherein the infrared lamp is located in the center of the inside of the pipe, A fixing frame having one end fixed to an inner circumferential surface of the pipe and forming a seating portion at which the end of the infrared lamp is seated at the other end, and a clamp for clamping the seating portion of the fixing frame and an end portion of the infrared lamp. Heat dissipation pipe. Hollow pipes having endothermic heat on the outer circumferential surface; An infrared lamp fixedly coupled to the hollow pipe, And a heat exchange tank accommodating at least one hollow pipe accommodating the infrared lamp and having an inlet line and an outlet line connected thereto. According to claim 3, wherein the water is supplied through the inlet line and drained through the outlet line, A storage tank connected to the service valve is connected to the outlet line, characterized in that the circulation pump for circulating the water supply from the storage tank to the heat exchange tank is connected. The heat exchanger of claim 3, wherein the outside air is supplied by the suction fan through the inlet line, and the warm air heat exchanged through the outlet line is discharged.