KR200199265Y1 - Heatpipe combustion exhaust waste heat recovery heat exchanger - Google Patents

Abstract

The present invention relates to a heat exchanger for recovering the waste heat of the combustion exhaust heat exchanged with the outside air for the waste heat of the exhaust combustion air generated during the combustion of the boiler through the integral heat pipe having a spiral corrugated structure.

Generally, for convenience of life, heating is artificially generated in a living space by using a boiler or a combustion heating device according to conditions, and the boiler or the combustion heating device uses the energy through the combustion heat of the used fuel. In this process, combustion air and gas are discharged to the outside through the flue. The thermal energy remaining in the gas and air discharged after the combustion is discharged to the outside through the combustion exhaust waste heat recovery heat exchanger, and the thermal energy is released to the outside. It recovers bay and transfers heat energy to the air of daily space and reuses it in the composition of space heating.

According to the present invention, the rapid heat transfer of the heat pipe quickly recovers the combustion heat energy remaining in the gas and air that is discharged, and allows the air of the daily space to pass through a separate inflow passage for efficient heat exchange. A spiral heat pipe heat dissipation tube (condensation tube) is placed in the inflow passage, and the exhaust waste heat transferred through the heat pipe is installed in a spiral heat pipe with a metal mesh or metal thread having excellent heat conduction around the heat dissipation tube. It is absorbed by the heat dissipation pipe and surrounding metal yarns so that the heat exchange with the inlet air is performed efficiently.

Description

Heatpipe combustion exhaust waste heat recovery heat exchanger. {.}

The present invention relates to a heat exchanger for recovering the waste heat of combustion exhaust gas for exchanging waste heat of exhaust combustion air (gas) generated by combustion of a boiler with indoor and outdoor air through an integral heat pipe having a spiral corrugated structure.

For convenience in daily life, heating is artificially created by using a boiler or other combustion heating device. In this process, the boiler or combustion heating device burns used fuel and uses heat energy through the combustion heat. Done. At this time, the heat energy generated must be efficiently recovered and diverted, but there have been various difficulties. In the boiler or combustion heating device, the combustion heat energy is diverted through a certain process through the combustion process, and the combustion air and gas are discharged to the outside through the flue. It is discarded. The exhaust gas and air that are discarded with this thermal energy are recovered through the heat pipe exhaust waste heat recovery heat exchanger to transfer thermal energy only to the air in the daily space, and the gas and air are discarded to the outside. Is to use energy to create space heating.

In general, the communication installed in the existing boiler or other combustion heating device has a double structure, and constitutes a separate pipe in the exterior of the communication to introduce outdoor air, thereby exchanging the heat of the waste gas generated in the communication to exchange the temperature of the inlet air. Is used as combustion air in boilers or other combustion heating devices. This approach has been limited in the recovery of thermal energy due to the area of thermal contact through the surface area of the communication.

Heat pipe is a hollow body and a thermally conductive sealed metal container is inserted with a suitable amount of a working material that causes a phase change depending on heating conditions such as water, alcohol, acetone, freon, etc. It is composed of (vacuum) and welded and sealed.The operating principle is that when heat is applied from the heat source to the evaporation section, the working material in the heat pipe evaporation section boils at a relatively low heat and condensates in a vessel with low pressure due to its relatively low temperature. Heat is transferred to the condensate, which is cooled to a lower temperature, and condensed on the inner wall of the vessel. The pressure difference and the influence of the gravitational field in the vessel allow the vessel to return to the evaporation section. This process is repeated in a vacuum condition and heat transfer is rapid.

The present invention recovers the combustion heat energy remaining in the gas and air that is discharged by using the fast heat transfer of the heat pipe, and is for efficient heat exchange with the inlet air. Spiral heat pipe heat dissipation tube (condensation tube) is located in the air inlet passage. Exhaust waste delivered to spiral heat pipe heat dissipation tube is equipped with a metal mesh or metal thread with excellent heat conduction around the heat dissipation tube. The heat energy is absorbed by the surrounding metal yarns so that the heat exchange with the inlet air is efficiently performed.

The present invention relates to an exhaust combustion air waste heat recovery heat exchanger that heat exchanges waste heat contained in exhaust gas (combustion air) generated during combustion of a boiler with indoor and outdoor air through an integrated heat pipe having a spiral corrugated structure. Specifically, the spirally corrugated tube is a gas (combustion air) discharge tube and a condensation part of the heat pipe, and a metal net or metal having excellent heat conduction around the spiral heat pipe heat dissipation tube (condensation tube). The exhaust gas (combustion air) waste heat delivered through the heat pipe is absorbed by the spiral heat pipe heat pipe and the surrounding metal sand to efficiently exchange heat with the inlet air. This is because a boiler or combustion heating device burns used fuel and uses thermal energy through the heat of combustion to recover the thermal energy remaining in the gas and combustion air discharged to the outside through the flue to warm indoor and outdoor air. It is to.

The heat pipe type heat exchanger and waste heat recoverer, which are generally used, are formed in such a structure that the heat contact surface corresponding to the heating and heat dissipation of the heat pipe is a tube having no bend, so that the heat exchange area is increased. It has been used by mounting a heat radiation fan.

The heat pipe exhaust waste heat recovery heat exchanger of the present invention consists of a spiral corrugated tube of heat and heat contact where heat is directly exchanged in a heat pipe heat exchanger. It is a device that efficiently recovers waste heat energy contained in exhaust combustion air and transfers it to indoor and outdoor inflow air for heat exchange.It has excellent heat conduction around heat pipe heat pipes to further increase the efficiency of heat exchange. Exhaust waste heat transferred through the heat pipe is installed on the spiral heat pipe heat dissipation pipe and surrounding metal yarn by mounting a metal or wire (scrap) of metal (zinc, aluminum, copper, etc.) and arranged to resist the flow of inlet air. Absorption allows efficient heat exchange with inlet air.

Figure 1 is a cross-sectional view schematically showing the configuration of the heat-prilled heat pipe to the heating portion by using the pipe portion of the flue molded in the present invention.

2 is a cross-sectional view schematically showing the longitudinal section of FIG.

Figure 3 is an exemplary view showing an example of assembling a plurality of heat pipes through the clip in accordance with the capacity of the heat exchange in the present invention.

Figure 4 is a longitudinal sectional view showing the structure of the present invention.

5 is a plan view showing a structure of the present invention.

<Description of the code | symbol about the principal part of drawing>

1, heat pipe evaporator tube. 2, heat pipe condensation unit pipe. 3, year (heating tube). 5, heat transfer metal yarn. 6, heat pipe connecting clip. 7, exhaust combustion air inlet year. 8, exhaust combustion air outlet part year. 9, year connection clip. 10, insulation panels. 11, suction air blowing fan. 12, inlet air conditioning passage panel. 13, inlet air passage, 14, ventilation fan connection. 15, intake air outlet. 16, intake air inlet. 17, evaporator insulation. 18, heat exchanger body. 19, incoming combustion air (gas). 20, exhaust combustion air (gas). 25, working material.

The present invention extends the thermal contact area with the combustion air discharged after combustion by making the discharge passage (communication) of the combustion air into a spirally pleated tube to form the heating part of the heat pipe heat exchanger so that the communication itself is heat pipe heat. An exhaust combustion air waste heat recovery heat exchanger that is configured in the form of an exchanger. Hereinafter, a preferred embodiment of the present invention will be described with reference to the accompanying drawings.

1, 2, 3, 4, and 5 are partially corrugated with a metal (copper, stainless, iron, etc.) having excellent heat conduction in the constitution of the present invention, and thus the exhaust passage of the combustion gas 20 (the flue) ) Pipes (1) are larger in diameter and shorter in length than the other flue pipes that are not corrugated on the outside of the flue (3) pipes. Sealed welding by forming a hole in a portion of the tube (1) by inserting a partially corrugated heat dissipation tube (2) and the internal space of the tube (1) and the tube (2) becomes a space Welded to be sealed to the outside, the inside is made in a constant vacuum state, an appropriate amount of working material 25 is introduced, and then the end portion 3-1 of the flue pipe is heat-exchanged with a heat pipe heat exchanger that seals the container. Folded to the C clip-shaped band (6) according to the heat exchange capacity The tube 2 of the heat dissipation portion condensed by the working material is formed by bending to increase the contact area with the inlet air, and FIG. 3 shows a number of C clip bands (6) according to the heat exchange capacity of the heat pipe heat exchanger. ) Shows an example of assembly configuration.

4 and 5 are components of the respective parts of the heat pipe combustion exhaust waste heat recovery heat exchanger 18 of the present invention, and the space is provided at the top of the panel 10 so that the mutual heat influence between the evaporator and the condenser is not affected. It is divided into a lower part and constitutes a shut-off 10. The heat pipe combustion exhaust waste heat recovery heat exchanger 18 has a heat insulating material (asbestos) at the bottom of the evaporator area (1) (3) 25 and the evaporator part of the heat pipe heat exchanger. (7) connecting pipes (8) of heat-insulated exhaust heat recovery heat exchanger with flue (8) mounted on boilers, etc. It is configured to be connected to the communication (8) of the exhaust gas (19) 20 of the combustion heating device such as a boiler (9) and the heat radiating tube (2) of the condensation part of the heat pipe heat exchanger Mesh of metal (iron, copper, aluminum, zinc, etc.) with heat conduction around the heat pipe The thread-shaped scraps 5 are arranged to resist the flow of the inlet air 19 so as to be in close contact with the heat dissipation pipe 2, and an air blower for forcing air into the air inlet 15 11) and control panels 12 and passages 13, 14 and 16 which control the direction and flow of air between the heat pipes of the condensation section in the combination of a plurality of heat pipe heat exchangers. Present what you have created.

In general, for convenience in daily life, heating is artificially generated in a living space by using a boiler or other combustion heating device. In this process, the boiler or combustion heating device burns used fuel and heat energy through the combustion heat. Will be used.

The effect obtained by the present invention is to exhaust the combustion air and gas to the outside through the flue after exhausting the combustion heat energy through a certain process through the combustion process of the fuel used in the boiler or the combustion heating device. It is thrown away with heat energy in the air. It is a device that transfers the heat energy to the air of daily space by recovering only the heat energy through the heat pipe combustion exhaust waste heat recovery heat exchanger, and the exhaust gas and air that is discarded with this heat energy are discharged to the outside of the space. The waste energy is used to create space heating.

In heat pipe heat exchanger, heat exchange is performed by smoothly circulating the flow of working materials and forming pipes with deep grooves in the shape of grooves in the form of grooves in the condensation and evaporation of working materials. Increased heat exchange capacity of the heat pipe heat exchanger by increasing the area, so that the exchange area of the commonly used heat pipe heat exchanger is small, which saves manpower, cost and resources due to the trouble of using a separate heat exchange aid. It is possible to save waste, and by insulating the outer surface of the evaporation part with a heat insulating material to block the heat effect on the evaporation part from the outside to remove condensation that inhibits the boiling of the working material inside the evaporation part. By improving the boiling of the working materials, the heat exchange efficiency of the heat pipe is maximized.

Claims (2)

Spiral corrugated metal (copper, stainless steel, iron, etc.) with excellent heat conduction is formed as a discharge passage (combustion) pipe of combustion gas, and is larger in diameter than a separate flue tube without corrugation outside the flue pipe. Form a short tube, roll it on both ends and seal it with the flue tube, insert a corrugated heat-resistant tube with a hole in a certain part of the container, and weld the inner space to be one space and sealed to the outside. In the heat pipe heat exchanger sealed by putting a proper amount of working material after forming a certain vacuum state, the ends of the flue pipe are folded outward so that they can be connected to each other by a C-clip-shaped band according to the heat exchange capacity. The corrugated pipe of the heat dissipation part where the working material condenses is formed by bending to increase the contact area with the inlet air. The panel divides the space into upper and lower sections to prevent mutual heat influence between the condenser and the condenser, and is insulated through heat-insulating material (asbestos, glass fiber, gypsum, etc.) outside the evaporation area of the heat pipe heat exchanger. And the pipe connecting the flue pipe of the heat pipe combustion exhaust waste heat recovery heat exchanger and the communication pipe installed in the boiler, etc., and to be connected to the communication of the exhaust gas of the combustion heating device such as the boiler, the top of the heat pipe heat exchanger The heat dissipation tube is placed around the heat dissipation tube and the heat dissipation tube in the condensation part to dispose scraps in the form of a mesh or thread of metal (iron, copper, aluminum, zinc, etc.) having heat conduction resistance to the inflow of air The air inlet is equipped with an air filter and a forced air inlet fan, and the combination of multiple heat pipe heat exchangers A heat pipe combustion exhaust waste heat recovery heat exchanger comprising a control panel and a passage for controlling the direction and flow of air between the heat dissipation tubes of each condensation part. The heat pipe combustion exhaust waste heat according to claim 1, wherein the heat dissipation portion forming the condensation of the working material in the heat pipe is a tube without spiral corrugation, and a heat dissipation fan is attached to a heat dissipation pipe to perform heat exchange. Recovery heat exchanger.