KR101345454B1 - A solar heat collecting apparatus - Google Patents

Abstract

The present invention relates to a solar heat collection apparatus of a vacuum heat collection tube type, which is capable of improving heat collection efficiency and facilitating maintenance and repair by directly transferring a heat source absorbed to heat pipes to a heat collection tank. That is, the present invention provides the solar heat collection apparatus of a vacuum heat collection tube type, wherein heating portions of heat pipes are configured to pass through heat pipe coupling holes, respectively, to be coupled to the heat medium of the heat collection tank so as to directly touch the heat medium, a heat pipe packing fixing structure for watertight coupling with the heat pipe coupling holes is provided below the heating portions of the heat pipes, and heat collection tube fixing packings are provided on the upper ends of vacuum heat collection tubes, respectively. Therefore, the heating portions of the heat pipes are configured to directly touch the heat medium of the heat collection tank, thereby efficiently transferring a heat source absorbed to the heat pipes and easily replacing a vacuum heat pipe upon breakage thereof.

Description

Vacuum heat collector type solar heat collector

The present invention relates to a vacuum collector tube solar collector, and more particularly, in the vacuum collector tube solar collector, the heat generating portion of the heat pipe is configured to be coupled through the heat pipe coupling hole in direct contact with the heat medium of the collector tank. And a heat pipe packing fixing structure for watertight coupling with the heat pipe coupling hole under the heat generating portion of the heat pipe, and having a heat collecting tube fixing packing at the upper end of the vacuum heat collecting tube, where the heat source absorbed by the heat pipe is collected. It is intended to be directly delivered to the tank to improve the heat collection efficiency and to facilitate maintenance.

In general, solar heat is defined as renewable energy along with solar, bio, wind, hydro, ocean, waste, geothermal, etc. under the provisions of Article 2 of the New Energy and Renewable Energy Promotion and Promotion Act of Korea. And heavy residue gasification, hydrogen energy and the like are defined as new energy.

Solar heat, defined as renewable energy, is used to absorb and radiate radiant rays from the sun and convert it into thermal energy (storage if necessary), which is utilized for cooling and heating and hot water supply of buildings, industrial process heat, and thermal power generation. In heat collection, heat storage, and system control, solar energy has low energy density and changes energy seasonally and hourly, and heat storage and heat storage are the most fundamental technologies.

The solar heat collecting device as described above has been developed and used as a flat plate-type solar collector having a flat plate collector and a vacuum collector tube-type solar collector having a vacuum collector tube.

In the double vacuum collector tube type solar collector, the vacuum is composed of a vacuum tube composed of a double tube. The vacuum collector tube has a vacuum space formed between the outer tube and the inner tube, and the heat medium of the collecting tank is circulated inside the inner tube, but the heat collecting efficiency is improved. In order to increase the heat pipe is configured and implemented.

On the other hand, the heat pipe is composed of a heat absorbing portion is coupled to the heat pipe receiving portion formed in the heat collecting portion and the heat collecting tank inside the vacuum heat collecting tube.

In the conventional vacuum heat collecting tube-type solar heat collecting device configured as described above, the heat source absorbed by the heat absorbing portion of the heat pipe generates heat generated in the heat generating portion of the heat pipe is indirectly transferred to the heat medium inside the heat collecting tank.

However, the conventional vacuum heat collecting tube type solar heat collecting device as described above has a problem in that the heat source of the heat pipe is configured to be indirectly transmitted without being directly transmitted to the heat medium of the heat collecting tank.

Accordingly, the present invention is to solve the problem that the vacuum heat collecting tube type solar heat collector to which the conventional heat pipe is applied is indirectly transmitted when the heat source of the heat pipe is transferred to the heat collecting tank, thereby reducing its efficiency.

That is, in the vacuum heat collecting tube type solar heat collecting device, the heat generating portion of the heat pipe is configured to be coupled through the heat pipe coupling hole to be in direct contact with the heat medium of the heat collecting tank, and the heat pipe below the heat generating portion of the heat pipe. The heat pipe packing fixing structure for watertight coupling with the coupling hole is provided, and the top of the vacuum collecting tube is provided with the collecting tube fixing packing.

Therefore, the present invention is configured so that the heat generating portion of the heat pipe is in direct contact with the heat medium of the heat collecting tank, so that the heat source absorbed in the heat pipe can be efficiently delivered, and it can be easily replaced when the vacuum display tube is broken.

1 is an exploded perspective view of the present invention.
2 is a detailed perspective view of the heat pipe pagging structure of the present invention.
Figure 3 is a cross-sectional view of the heat pipe coupling state in the practice of the present invention.
4 is a perspective view showing a coupled state in the practice of the present invention.
5 is a cross-sectional view showing a vacuum jabara measurement unit according to another embodiment of the present invention.

Hereinafter, described in detail by the accompanying drawings as follows.

The present invention is to facilitate the maintenance of the vacuum heat collecting tube in addition to the efficient heat transfer of the heat source of the heat pipe to the heat collecting tank in the vacuum heat collecting tube type solar heat collector to which the heat pipe is applied.

That is, according to the present invention, as shown in FIGS. 1 to 4, the heat collecting tank 10 in which solar heat accumulated heat medium is stored and the vacuum heat collecting tube 20 and the vacuum heat collecting tube 20 absorbing and storing solar heat in the heat collecting tank. In the vacuum heat collecting tube-type solar heat collecting device consisting of a heat pipe (30) for transferring the solar heat collected and collected to the heat medium of the heat collecting tank (10), the vacuum heat collecting tube (20) is fitted to the heat collecting tank (10) The heat collecting tube inserting portion 11 recessed inwardly and the heat pipe coupling hole 12 formed in the inner surface of the heat collecting tube inserting portion 11 are formed, and the heat generating portion 32 of the heat pipe 30 is formed. ) Is coupled to penetrate the heat pipe coupling hole 12 so as to be in direct contact with the heat medium of the heat collecting tank 10, and the heat pipe coupling hole 12 is disposed below the heat generating part 32 of the heat pipe 30. Heat pipe packing fixing structure for watertight coupling with Top of yeolgwan 20 is fixedly coupled to the heat pipe 30, and is configured by having a vacuum house yeolgwan 20 fixed home yeolgwan packing to cause the adhesive bond to the home yeolgwan insertion portion 11 (51).

Here, the heat pipe packing fixing structure is formed with a diameter larger than the heat generating portion 32 formed with a diameter of more than twice the diameter of the heat absorbing portion 31 of the heat pipe 30, as shown in Figs. The tank fixing portion 41 formed in a smaller diameter than the coupling hole 12 and the heat pipe packing 42 is coupled between the tank fixing portion 41 and the heat pipe coupling hole 12 to maintain the watertightness. .

The heat pipe packing 42 is formed on the outer surface of the coupling hole seating recess 42a into which the inner surface of the heat pipe coupling hole 12 is inserted and seated.

On the other hand, the heat pipe packing 42 is the upper flange portion formed by the coupling hole seating groove 42a is formed in the upper flange portion is smaller than the lower flange portion to facilitate the coupling of the heat pipe 30.

In addition, the heat collecting tube fixing packing 51 is made of synthetic resin having elasticity as shown in FIG. 3, and fitted to an upper end side of the opening of the vacuum collecting tube 20, and the heat absorbing portion 31 of the heat pipe 30 is inside. The inner wall of the heat collecting tube inserting portion 11 of the heat collecting tank 10 is formed in the heat collecting tank 10 to form a heat absorbing portion coupling hole 51a through which the heat absorbing portion 31 of the heat pipe 30 is hermetically coupled. The tank coupling flange 51b having a diameter larger than the outer diameter of the vacuum heat collecting tube 20 is formed to be in close contact with each other.

Meanwhile, in the practice of the present invention, as shown in FIG. 5, the heat pipe 30 loses the internal vacuum state due to breakage, and the heat pipe at the lower end of the heat absorbing portion of the heat pipe 30 can be confirmed from the outside. It can be carried out by forming a vacuum jabar measuring unit 60 elastically contracted by the internal vacuum.

The vacuum jabara measurement unit 60 is formed of a corrugated tube having elastic force and is contracted by the vacuum pressure of the heat pipe 30, and is expanded when the vacuum pressure of the heat pipe 30 is lost.

Hereinafter, the operation of the present invention will be described.

In the vacuum heat collecting tube type solar heat collecting device as described above, the heat collecting tube inserting portion 11 and the heat collecting tube inserting portion 11 which are recessed inwardly so that the vacuum collecting tube 20 is fitted into the heat collecting tank 10. A heat pipe coupling hole 12 formed through the inner surface of the heat pipe 30 is formed, and the heat generating portion 32 of the heat pipe 30 penetrates the heat pipe coupling hole 12 so as to be in direct contact with the heat medium of the heat collecting tank 10. The heat pipe packing fixing structure for watertight coupling with the heat pipe coupling hole 12 is provided below the heat generating portion 32 of the heat pipe 30, and the vacuum heat collecting tube 20 When the heat pipe 30 is coupled to and fixed to the heat collecting tube fixed packing 51 to allow the vacuum heat collecting tube 20 to be tightly coupled to the heat collecting tube inserting portion 11, the heat pipe ( The heat generating portion 32 of the 30 is immersed in the heat medium of the collecting tank 10 and directly contacted Heat absorbed by the heat absorbing portion 31 in the heat pipe 30 is transferred to the heat medium of the heat collecting tank 10 without loss.

In particular, the heat pipe 30 is composed of a heat pipe packing fixing structure consisting of the tank fixing portion 41 and the heat pipe packing 42 is made of a watertight coupling with the heat pipe coupling hole (12).

In addition, in the practice of the present invention, when the heat collecting pipe fixing packing 51 is configured by the heat absorbing portion coupling hole 51a and the tank coupling flange 51b, the heat collecting pipe fixing packing 51 is the heat pipe 30. ) Is coupled to the collection tank 10 with a fixed coupling.

When the vacuum heat collecting tube 20 is broken, the vacuum heat collecting tube 20 can be separated and replaced only by the vacuum heat collecting tube 20, so that the maintenance is easy.

On the other hand, in the practice of the present invention, if the vacuum Java measurer 60 is formed at the lower end of the heat absorbing portion 31 of the heat pipe 30, the vacuum Java measurer 60 in the process of using the solar heat collector. By confirming the presence or absence of elastic expansion of the heat leakage of the heat pipe 30 can be confirmed to facilitate, quick and clear maintenance of the heat pipe (30).

10: heat collecting tank
11: collecting pipe insertion part 12: heat pipe coupling hole
20: vacuum collector tube
30: Heat pipe
31: heat absorbing portion 32: heat generating portion
41: tank fixing
42: heat pipe packing 42a: coupling hole seating groove
51: collecting pipe fixing packing
51a: endothermic coupling hole 51b: tank coupling flange
60 vacuum vacuum measuring unit

Claims (3)

The heat collecting tank 10 in which the heat medium in which solar heat is stored is stored, and the vacuum heat collecting tube 20 for absorbing and storing solar heat in the heat collecting tank and the solar heat inserted into and collected in the vacuum heat collecting tube 20 of the heat collecting tank 10. In the vacuum heat collecting tube-type solar heat collecting device composed of a heat pipe (30) for transferring to the heat medium;
The heat pipe coupling hole 12 formed through the inner surface of the heat collecting tube inserting portion 11 and the heat collecting tube inserting portion 11 recessed inwardly so that the vacuum collecting tube 20 is fitted into the heat collecting tank 10. And a heat generating portion 32 of the heat pipe 30 is coupled to penetrate through the heat pipe coupling hole 12 to be in direct contact with the heat medium of the heat collecting tank 10. The heat pipe packing fixing structure for watertight coupling with the heat pipe coupling hole 12 is provided on the lower side of the heat generating unit 32, and the heat pipe 30 is fixed to the upper end of the vacuum heat collecting tube 20, The heat pipe 20 is provided with a heat collecting pipe fixing packing 51 to be tightly coupled to the heat collecting tube insert 11;

The heat pipe packing fixing structure is formed of a diameter larger than the heat generating portion 32 formed to have a diameter greater than or equal to twice the diameter of the heat absorbing portion 31 of the heat pipe 30 and formed of a diameter smaller than that of the heat pipe coupling hole 12. The heat pipe packing 42 is coupled between the government part 41 and the tank fixing part 41 and the heat pipe coupling hole 12 to maintain the watertightness, and the heat pipe packing 42 is heated on the outer surface. The inner surface of the pipe coupling hole 12 is formed to form a coupling hole seating recess 42a,
The heat collecting tube fixing packing 51 is formed of a synthetic resin having elasticity and is fitted into an upper end of the opening of the vacuum collecting tube 20, and is formed through a diameter smaller than that of the heat absorbing portion 31 of the heat pipe 30. A heat collecting part coupling hole 51a is formed to allow the heat absorbing part 31 of the pipe 30 to be hermetically coupled, and the vacuum heat collecting pipe is formed to be tightly coupled to the inner wall of the heat collecting pipe inserting part 11 of the heat collecting tank 10 at the upper end thereof. A vacuum heat collecting tube type solar heat collecting device, characterized in that a tank coupling flange (51b) having a diameter larger than the outer diameter of 20) is formed. The method of claim 1, further comprising:
The vacuum pipe measuring unit 60 is elastically shrunk by a vacuum inside the heat pipe at the bottom of the heat absorbing portion of the heat pipe 30 so that the heat pipe 30 loses the internal vacuum state due to breakage. Vacuum collector tube type solar collector, characterized in that.
3. The method of claim 2,
The vacuum jabara measurement unit 60 is a vacuum heat collecting tube-type solar heat collector, characterized in that formed in a corrugated pipe body.

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