KR200170637Y1 - Apparatus for collecting heat from sun - Google Patents

Abstract

The present invention relates to a solar heat collecting device, the support plate 23; First passages 29, 29 ′, 29 ′, 29 ″, and inner wall surfaces and first passages 29, 29 ′, 29 ′, 29 ′ which are installed on the support plate and have a cylindrical shape. A plurality of heat collecting members 25, 25 ', 25', 25 ", which consist of second flow paths 28, 28 ', 28', 28 " The first flow paths 29, 29 ', 29', 29 '' receive the first working fluid, and the second flow paths 28, 28 ', 28', 28 '' absorb the solar heat and By accommodating the second working fluid 39 conducting to the working fluid, the heat collecting performance is excellent and the structure of the heat collecting device is simply improved, thereby improving the assembly workability.

Description

Solar heat collector {apparatus for collecting heat from sun}

The present invention relates to a solar heat collecting device, and more particularly, to a solar heat collecting device having excellent heat collecting performance and simple structure of the heat collecting device, thereby improving assembly workability.

In general, the hot water supply device is to supply hot water to the house or building using solar and heaters.

The hot water supply apparatus using the heater is capable of supplying hot water generated by heating the heater with electricity. Hot water supply apparatus using a heater is a method of heating the heater directly with electricity has a drawback of high power consumption.

Thus, recently, a solar hot water heater that generates hot water using solar heat has been widely developed. The hot water supply device using solar heat is used to generate hot water using sensible heat that collects solar heat during the day, and to generate hot water by using heat storage accumulated during the day.

1 is a state diagram showing a conventional solar water heater, Figure 2 is a side cross-sectional view of Figure 1, Figure 3 is a front sectional view of FIG. As shown in this figure, a conventional solar water heater includes a plurality of support plates 2, a heat collecting plate 4 installed on the support plate 2, a glass plate 3 and a heat collecting tube 4 ′ installed on the heat collecting plate 4. It consists of the heat medium tank 9 etc. which store the heat medium liquid which flows inside.

In the heat collecting plate 4, the heat insulating plate 6, the heat insulating plate 5, and the plurality of heat collecting tubes 4 ′ are sequentially placed and embedded. The upper and lower ends of each of the heat collecting tubes 4 'are alternately connected to each other so that the heat collecting tubes 4' are continuously connected. One end and the other end of the heat collecting pipe 4 'continuously connected to each other are connected to the heat medium tank 9, so that the heat medium liquid 7 in the heat medium tank 9 flows through the inside of the heat collecting pipe 4' to circulate. It is supposed to be. In addition, the heat collecting plate 4 has a conventional selective coating having an optical principle of absorbing but not emitting light, and the heat collected from the heat collecting plate 4 flows through the inside of the heat collecting tube 4 'made of copper tubes. The body fluid 7 can be heated.

On the left and right sides of the heat medium tank 9, expansion fluid buffer chambers 10 'are formed, respectively, and a stainless heat insulating plate on which the heat insulating material is mixed is attached to the inner wall surface of the tank 9. Further, inside the heat medium tank 9, a multi-coiled tube heat exchanger 11 made of stainless steel is provided. Insulation material made of urethane foam is loaded on the inner circumferential surface of the heat medium tank 9 to increase the heat insulating efficiency of the heat medium liquid 7, and the heat exchanger 11 is subdivided like capillaries, so heat absorption is quick and sensitive. It is possible to play the role of instant hot water heater.

By this configuration, the heat medium liquid 7 in the heat medium tank 9 flows and circulates through the heat collecting pipe 4 ', and in this process, the heat medium liquid 7 is heated by heat-exchanging with the heat collecting pipe 4'. Heat storage at high temperatures.

However, since the solar water heater having the above-described configuration has a relatively complicated structure, the assembly workability is low, and since the collecting tube is a simple copper tube, there is a problem in that the collecting performance is not good.

Accordingly, an object of the present invention is to provide a solar heat collecting device that is devised to solve the above problems, and has excellent heat collecting performance and simple structure of the heat collecting device, thereby improving assembly workability.

1-a state diagram showing a conventional solar water heater.

2-side cross-sectional view of FIG.

3-forward cross-sectional view of FIG.

4-a perspective view of a solar heat collector according to the present invention.

5 to 4 are enlarged perspective views of a first embodiment of a heat collecting member constituting the heat collecting device of FIG.

6 to 4 are perspective views of a heat collecting device in which the heat collecting members of FIG. 4 are mounted in different directions.

7 to 4 are perspective views of a second embodiment of a heat collecting member constituting the heat collecting device of Figs.

8-4 is a perspective view of a third embodiment of a heat collecting member constituting the heat collecting device of FIG.

9 to 4 are perspective views of a fourth embodiment of a heat collecting member constituting the heat collecting device of Figs.

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

20: inlet pipe 21: support

22: discharge pipe 23: support plate

25, 25 ', 25' ', 25' '': heat collecting member

27: glass plate

28, 28 ', 28' ', 28' '': second euro

29, 29 ', 29' ', 29' '': Euro 1

31, 31 ', 31' ': projecting joint 33, 33', 33 '': recessed joint

35, 35 ', 35' ': heat collecting plate 39: second working fluid

Solar heat collecting apparatus according to the present invention for achieving the above object, a support plate; A plurality of heat collecting members configured to be provided on the support plate and having a cylindrical shape and formed of a first flow path formed in an inner hollow portion and a second flow path formed by an inner wall surface and an outer wall of the first flow path to absorb solar heat; The first flow passage accommodates the first working fluid, and the second flow passage contains a second working fluid that absorbs solar heat and conducts it to the first working fluid.

Here, each of the first flow passages are in communication with each other, and each of the second flow passages is sealed at both ends, so that the latent heat of the second working fluid evaporated by solar heat absorbed by the first working fluid flowing in the first flow passage. It is desirable to allow heating. More preferably, one side of each heat collecting member protrudes to form a protruding coupling portion, and the other side of the depressing coupling portion to form a recess so that each of the coupling portions are mutually uneven meshing, and each of the heat collecting members are mutually coupled and the outside of each heat collecting member The surface may be formed to form a heat collecting plate. In addition, the heat collecting member may be formed in a semi-cylindrical column or a square pillar shape.

Therefore, the heat collection performance is excellent and the assembly workability is improved.

Hereinafter, the present invention will be described in more detail with reference to the accompanying drawings. The same parts as in the conventional solar water heater will be described using the same reference numerals.

4 is a perspective view of a solar heat collector according to the present invention. As shown in this figure, the solar heat collecting apparatus has a support 21 having a table shape, a support plate 23 installed on the support 21, and a tubular shape installed on the support plate 23 to absorb solar heat. It consists of the glass plate 27 which covers the heat collecting member 25 provided in the many heat collecting member 25 and the support plate 23.

As illustrated in FIG. 5, the heat collecting member 25 is formed in a semi-cylindrical shape having a gentle curved surface. The heat collecting member 25 is composed of a first flow path 29 formed in the hollow portion inside and a second flow path 28 formed by an inner wall surface and an outer wall of the first flow path 29. The first flow path 29 accommodates the first working fluid, the second flow path 28 accommodates the second working fluid, respectively, and the second working fluid absorbs solar heat to conduct the first working fluid. have.

Inflow pipes 20 and discharge pipes 22 are provided in both end regions of the first flow path 29 in the lengthwise direction of the flow path, and the first flow path 29 passes through these pipes 20 and 22. It is intended to communicate with each other. The second flow passage 28 is sealed at both ends and the inside thereof is sealed in a vacuum state in which a predetermined amount of the second working fluid is received, so that the second working fluid evaporates above a predetermined temperature so that the second flow path ( 28) The inside is filled with hot gas. The first working fluid flowing inside the first flow path 29 is converted to a high temperature liquid state by being heated by conducting latent heat of the second working fluid evaporated by absorbed solar heat.

The first working fluid and the second working fluid are each made of a material having a different boiling point. For example, the first working fluid employs water having a relatively low boiling point, and the second working fluid employs Freon gas (model name R113) having a boiling point much higher than that of water.

Thus, since the second working fluid has a high latent heat during evaporation, it is possible to transfer a lot of heat to the first working fluid.

In addition, the protruding coupling portion 31 is protruded on one side of each of the heat collecting members 25, and the recessed coupling portion 33 is recessed on the other side thereof. ) Can be assembled together. In addition, the flat surfaces of the upper parts of the heat collecting members 25 coupled to each other form a heat collecting plate 35 so as to primarily collect heat from the sun. The flat surface serving as the heat collecting plate 35 is plated with black chromium (black Cr) having excellent thermal conductivity, so that heat can be absorbed more effectively from the sun.

Hereinafter will be described the operation and effect of the solar heat collector according to the present invention.

When the heat collecting device having the above structure operates, the solar heat is primarily collected by the heat collecting plate 35 of the heat collecting member 25, and the second working fluid in the second flow path 28 is collected by the heat collected. The evaporation causes the interior of the second flow path 28 to become a hot gas. At this time, the first working fluid introduced through the inlet pipe 20, that is, water flows through the first flow path 29, absorbs the latent heat of the second working fluid and is heated to a high temperature. The heated water is discharged to the outside of the heat collecting device through the discharge pipe 22 and used as hot water.

Since the first working fluid heated by the heat collecting device is considerably higher in thermal efficiency than in the related art, it may be used not only as hot water but also as heating water for indoor heating.

In addition, when fabricating and assembling the solar heat collecting device, a plurality of heat collecting members 25 are coupled to each other by uneven engagement of the protrusion coupling portions 31 in the recessed coupling portions 33 of the respective heat collecting members 25. In a state in which a plurality of collecting members 25 are assembled with each other, the respective coupling portions 31 and 33 are welded in the longitudinal direction of the collecting members 25, whereby each of the collecting members 25 is simply assembled. At this time, the operation of charging the second working fluid into the second passage 28 and making the interior into a vacuum is also performed at the same time. Then, by connecting both ends of the first passage 29 with the inflow pipe 20 and the discharge pipe 22, the first passage 29, the inflow pipe 20 and the discharge pipe 22 are assembled so as to communicate with each other. do. The assembled heat collecting member 25 is mounted on the support plate 23 and the glass plate 27 covers the upper portion thereof, so that the production of the heat collecting device is simply completed.

Therefore, the heat collecting performance of the solar heat collector having the simply improved structure is excellent and the assembly workability is improved.

In the above-described and illustrated examples, the heat collecting member constituting the solar heat collecting apparatus has been described as being formed in a semi-cylindrical shape, but the heat collecting member of the solar heat collecting apparatus according to the present invention is not limited thereto and variously improved for assemblability and heat conductivity. Of course, it can be manufactured in a shape.

6 is a perspective view of a heat collecting device in which the heat collecting member of FIG. 4 is mounted in different directions. The heat collecting member 25 is formed in the shape of a semi-cylindrical with a smooth curved surface similar to the heat collecting member 25 described above. However, the heat collecting member 25 is mounted on the support plate so that the portion forming the heat collecting plate 35 'is a curved surface rather than a flat surface.

7 is a perspective view of a second embodiment of a heat collecting member constituting the heat collecting device of FIG. The heat collecting member 25 'of the present embodiment is formed in a cylindrical shape. The first passage 29 'is formed in a pipe shape and is mounted on the central shaft portion of the heat collecting member 25' and extends in both directions. The second flow path 28 'is formed by the inner wall surface of the heat collecting member 25' surrounding the first flow path 29 'and the outer wall of the first flow path 29'. The second working fluid 39 is accommodated in the second flow passage 28 'on one side of the heat collecting member 25'.

8 is a perspective view of a third embodiment of a heat collecting member constituting the heat collecting device of FIG. 4. The heat collecting member 25 ″ employed in the present embodiment is formed in a square pillar shape, and similarly to the heat collecting member 25 of the first embodiment, protrusion coupling parts 31 ′ and recessed coupling parts 33 ′ are formed on both sides. Each is formed. A plurality of, for example, four first flow passages 29 ″ are mounted in the heat collecting member 25 ″ so that the first working fluid flows and circulates inside the first flow passage 29 ″. have. The space between the first flow paths 29 ″ forms a second flow path 28 ″.

Since the heat collecting member 25 '' in the present embodiment is equipped with a plurality of first flow paths 29 '', as compared with the above-described embodiment, the total number of the heat collecting members 25 '' is reduced and assembled. The advantage is that the work can be performed more simply. The heat collecting members 25 '' are welded in the longitudinal direction of the heat collecting members 25 '' by joining portions 31 'and 33' in a state where the heat collecting members 25 '' are also engaged with each other. It is simply assembled and the upper surface of the heat collecting member 25 '' forms the heat collecting plate 35 ''. Therefore, the assembly workability is significantly improved as compared with the related art, and the heat collecting performance is further improved.

9 is a perspective view of a fourth embodiment of a heat collecting member constituting the heat collecting device of FIG. 4. The heat collecting member 25 '' 'in this embodiment is formed in the shape of a square column, and one side, for example, the lower side, of the heat collecting member 25' '' is recessed, whereby the first flow path 29 '' is provided. The flow path groove portion constituting '' is integrally formed with the heat collecting member 25 '' ', and the second flow path 28' '' is formed between the side wall of the flow path groove portion and the side wall of the heat collecting member 25 '' '. . In addition, protruding coupling portions 31 &quot; and recessed coupling portions 33 &quot; are formed on both sides of each of the heat collecting members 25 '&quot;, so that these heat collecting members 25' &quot; It can be assembled.

In the present embodiment, unlike in the above-described embodiment, the flow path of the working fluid is integrally formed in the heat collecting member 25 '' 'without separately mounting the first flow path serving as the flow path of the first working fluid. As a result, the assembly workability is further improved. The assembling work is completed by simply coupling the plurality of heat collecting members having the flow path to each other.

The heat collecting members in the above embodiments can be manufactured by extrusion molding using a mold.

As described above, according to the solar heat collecting apparatus according to the present invention, the heat collecting performance is excellent and the structure is simply improved, thereby improving the assembly workability.

Claims (4)

Support plate; A plurality of heat collecting members having a tubular shape and having a first flow path formed on an inner hollow portion and a second flow path formed by an inner wall surface and an outer wall of the first flow path and absorbing solar heat; and, And said first flow passage contains a first working fluid, and said second flow path contains a second working fluid that absorbs solar heat and conducts it to said first working fluid. The method of claim 1, wherein each of the first flow passages is in communication with each other, and each of the second flow passages is sealed at both ends thereof, so that the first working fluid flowing inside the first flow passage is evaporated by absorbed solar heat. Solar heat collecting apparatus, characterized in that the heating by the latent heat of the second working fluid. The method of claim 1, wherein the one side of each of the heat collecting members protruding coupling portion is formed protruding, the other side of the depressed coupling portion is formed recessed each of these coupling members are combined with each other by each of the heat collecting member and each of the heat collecting member A solar heat collecting device, wherein an outer surface forms a heat collecting plate. The solar heat collecting apparatus of claim 2 or 3, wherein the heat collecting member is formed in a semi-cylindrical shape or a quadrangular shape.