KR102055002B1 - Solar absorption panel - Google Patents

Abstract

Transparent glass plate to maximize heat exchange efficiency by absorbing solar heat as much as possible with low manufacturing cost and simple structure; A heat collecting space formed by a gap holding portion provided on the bottom surface of the glass plate toward the edge; A heat transfer plate made of a metal material having a circulation path formed under the heat collecting space; A closing plate fixed to a surface on which a circulation path of the heat transfer plate is formed; It provides a solar heat absorbing panel comprising a; and a frame frame is finished on the edge of the glass plate, the heat transfer plate and the closing plate.
Accordingly, not only can the installation cost be reduced as much as possible, but the installation is also convenient and has the effect of smoothly receiving hot water or heating at a minimum cost.

Description

Solar absorption panel

The present invention relates to a solar heat absorbing panel, and more particularly, to a solar heat absorbing panel capable of maximizing heat exchange efficiency by absorbing solar heat as much as possible while having a low cost and simple structure.

In general, fossil energy generated by burning fossil fuels has a serious problem of causing environmental problems, and nuclear energy has a problem of causing radioactive pollution.

In addition, although wind energy is spotlighted as a natural environmentally friendly energy, this is also limited by the geographical conditions in which the wind power generator is installed.

On the other hand, solar energy is clean and almost indefinitely used compared to the fossil energy or nuclear energy described above, and is one of energy that is not significantly affected by geographical conditions for producing wind energy.

A typical example of solar energy is solar cells, but it is economically expensive and has many complex conditions for building facilities.

In view of the various problems as described above, a technique for exchanging heat by using solar heat has been proposed in the related art, which is published in Korean Patent Publication No. 10-1981-0001856 (hereinafter referred to as 'prior art document 1'). As described above, a technique has been proposed such as a solar heat absorbing panel that can obtain a high efficiency of the conversion energy circulation by arranging the inner tubular passage between the empty spaces between the two metal plates.

In addition, as disclosed in the Republic of Korea Patent Publication No. 10-2013-0060813 (hereinafter referred to as 'prior art document 2'), the solar heat including the body case, heat-radiating plate, induction member so that the structure is simple and low installation cost There has also been proposed a technology such as a solar heating apparatus having a heat supply panel and an assembly thereof and a heat supply panel assembly using the same.

In addition, as disclosed in the Republic of Korea Patent Publication No. 10-1605594 (hereinafter referred to as 'prior art document 3') using solar energy collectors that are directly heated by sunlight, in order to extract the thermal energy from the device Rather than the photovoltaic properties of heating fluids used for the purpose, techniques such as solar energy absorber devices of thermal properties have been proposed.

Republic of Korea Patent Publication No. 10-1981-0001856 Republic of Korea Patent Publication No. 10-2013-0060813 Republic of Korea Patent Publication No. 10-1605594

However, the prior art document 1 has a simple structure, but has a disadvantage of not very high efficiency.

Prior art document 2 has been able to smoothly supply the warm air using solar heat, but has a disadvantage that is not suitable for supplying hot water.

Prior art document 3 has a disadvantage that the manufacturing cost is excessively of course complicated structure.

The specific problem of the present invention for solving the conventional problems as described above is to provide a solar absorbing panel to maximize the heat exchange efficiency by absorbing the solar heat as possible while having a low cost and simple structure as possible. .

Another specific problem of the present invention is to maximize the heat collection efficiency of the solar.

Another specific problem of the present invention is to maintain high heat exchange efficiency even when solar heat is weak.

Specific solution means of the present invention for solving the above technical problem is a transparent glass plate which is absorbed by the solar heat; A heat collecting space formed by a gap holding portion provided on the bottom surface of the glass plate toward the edge; A circulation path through which heat-exchanged water circulates while the heat absorbed and collected in the glass plate and the collecting space is collected at a lower portion of the collecting space, and the collected heat is conducted to the opposite surface contacting the collecting space; A heat transfer plate formed of a metal material having a plurality of first divided passages formed between the first expansion passages and the first expansion passages formed at the inlet and outlet sides; A closing plate fixed to a surface on which a circulation path of the heat transfer plate is formed; It includes; and the frame frame is finished on the edge of the glass plate, the heat transfer plate and the closing plate.

The heat transfer plate is either copper or aluminum.

The expansion passage formed on the inlet side is divided into a number corresponding to the plurality of divided passages, and the expansion passage formed on the outlet side is divided into a number corresponding to the divided passage or a larger number.

The surface contacting the heat collecting space of the heat transfer plate further includes a heat collecting portion formed in an intaglio or embossed shape to have a large surface area.

The surface in contact with the heat collecting space of the heat transfer plate further includes a heat absorber is coated.

The heat exchanger plate further includes an opposite surface of the heat transfer plate coupled to a heat medium circulation plate having a heat medium circulation path formed on a surface thereof in contact with the finish plate.

The heat medium circulation path is composed of a plurality of second divided flow paths formed between the respective second expansion flow paths and the second expansion flow paths provided at the heat medium inlet and the heat medium outlet sides of the heat medium circulation plate.

The present invention is to reduce the installation cost as much as possible to minimize the cost of installation by maximizing the heat exchange efficiency by absorbing the solar heat while having a low cost and simple structure as possible, the installation is also made of hot water or at a minimum cost It has the effect of being able to receive the heating smoothly.

In addition, by maximizing the heat collection efficiency of solar heat, it also has the effect of further increasing the heat exchange efficiency.

In addition, it is possible to maintain a high heat exchange efficiency even when solar heat is weak, it has a high efficiency that can be used in all weather.

1 is an exploded perspective view for explaining the present invention,
Figure 2 is a bottom view for explaining the structure of the circulation path formed on the heat transfer plate according to Figure 1,
3 is a cross-sectional view of the combined state according to FIG.
4 is a partially exploded perspective view for explaining another embodiment of the present invention;
5 is a cross-sectional view of the coupled state according to FIG.

Hereinafter, preferred embodiments of the present invention will be described in more detail with reference to the accompanying drawings. The present invention is not limited or limited by the embodiments.

1 is an exploded perspective view for explaining the present invention, Figure 2 is a bottom view for explaining the structure of the circulation path formed on the heat transfer plate according to Figure 1, Figure 3 is a cross-sectional view of the combined state according to FIG.

As shown, the solar heat absorbing panel 1 is installed on a roof or a wall of a structure, or is installed at a predetermined height by a frame or the like from the ground to absorb solar heat, and then heat exchanges the water by the absorbed heat to hot water or heating water. Has a technical configuration that can provide.

The present invention is intended to maximize the heat exchange efficiency by absorbing the maximum solar heat while having a low cost and simple structure as possible.

The solar heat absorption panel 1 according to the present invention includes a transparent glass plate 10 in the form of a conventional plate in which solar heat is absorbed; The bottom surface of the glass plate 10 includes a heat collecting space 20 formed by the gap retaining region 12 provided to the edge side. The spacer 12 may be formed not only in the form of a frame corresponding to the glass plate 10 but also in plural numbers having a predetermined height.

The heat collecting space 20 serves to collect heat absorbed through the glass plate between heat transfer plates to be described later, and at the same time, raise the atmosphere temperature due to the heat collected.

In addition, heat absorbed and collected in the glass plate 10 and the collecting space 20 is collected at a lower portion of the collecting space 20, and is collected at an opposite surface contacting the collecting space 20. A circulation path 32 is formed in which heat exchange water that is heat-exchanged while conducting heat is circulated, and each circulation path 32 is formed at each of the inlet 32A and the outlet 32B. A heat transfer plate 30 made of a metal material having a plurality of first split flow paths 32-2 formed therebetween) and the first expansion flow path 32-1; A closing plate 40 fixed to a surface on which the circulation path 32 of the heat transfer plate 30 is formed; It includes; and the frame 50 is finished on the edge of the glass plate 10, the heat transfer plate 30 and the closing plate 40.

The closing plate 40 is provided with a packing on the heat transfer plate side in a conventional manner so as not to leak the heat exchanger circulated in the circulation path on the heat transfer plate 30 and the edge side can be coupled by bolting or the like, as well as brazing welding the edge side The fixing can be performed by, for example.

Frame 50 is also provided with a conventional hermetic method is provided so that the heat collected in the heat transfer space is not leaked to the outside and at the same time has a technical configuration to form a glass plate, the heat transfer plate and the finishing plate in one set.

In addition, the heat transfer plate 30 is preferably any one of copper or aluminum, which has excellent conductivity, relatively low cost, and excellent workability and convenient handling.

As described above, solar heat, which is solar energy having a high temperature, is absorbed and absorbed at the same time through the glass plate, and the heat to be absorbed and absorbed is collected in the heat collecting space provided between the glass plate and the heat transfer plate. That is, the heat collecting space serves to raise and absorb the heat absorbed and absorbed through the glass plate due to the continuous heat collection of solar heat between the heat transfer plates.

As a result, the collected temperature has a higher condition than the heat absorbed through the glass plate due to the increase in the ambient temperature in the collecting space.

The heat collected in this way is conducted to the heat transfer plate made of a material having excellent thermal conductivity, and the heat exchange water circulated in the circulation path formed on the heat transfer plate by the conducted heat may be heat exchanged at a high temperature.

In other words, the circulation passage flows through a plurality of first divided passages corresponding to the diverged passages at the same time as the circulation passages flow in the first expansion passage and then diverge in the first expansion passage, thereby further increasing heat exchange efficiency. Has a condition.

That is, as the heat is expanded in the first expansion passage divided into several branches at one inlet and then circulated through the plurality of first division passages, the conducted heat has a condition that heat exchange can be rapidly performed by a larger area.

In addition, the first expansion flow path provided on the outlet side also serves to be gathered to one outlet side via a plurality of first split flow paths, so that the heat exchanged heat exchanged water can be smoothly discharged through one outlet.

Here, the first expansion passage (32-1) formed on the inlet 32A side is divided into a number corresponding to the plurality of first divided passage (32-2), formed on the outlet 32B side The first expansion passage 32-1 may be divided into a number corresponding to the first division passage 32-1 or formed in a larger number.

Accordingly, the heat exchange water introduced into one inlet is divided into several branches in the first expansion passage and then circulated through the plurality of first division passages, thereby having a condition capable of maximizing heat exchange efficiency.

In addition, the heat exchange water circulated through the plurality of first divided flow passages is discharged in a state in which the heat exchange water is collected in one discharge port in the first expansion passage again, so that the heat exchanged heat exchange water may be smoothly discharged.

Thus, the present invention does not have a complicated technical configuration, but by allowing a simple technical configuration to absorb and collect the heat of the solar heat, there is an advantage that can maximize the heat exchange efficiency.

In addition, the manufacturing cost due to the simple structure also has the advantage that it can take a minimum.

On the other hand, the surface in contact with the heat collecting space 20 of the heat transfer plate 30 further includes a heat collecting portion 30A formed in an intaglio or embossed form to have a large surface area.

That is, since the heat collecting portion is formed in an intaglio or embossed shape compared to the same area, the surface area is widened, so that the heat collected in the heat collecting space can be conducted to a larger area, thereby further increasing heat exchange efficiency. .

In addition, the surface in contact with the heat collecting space 20 of the heat transfer plate 30 further includes a conventional heat absorber 34 is coated. The heat absorber may be coated by a known method in which any one of conventional powdered carbon powder or solution form lithium bromide, lithium chloride and ammonia is included in the adhesive component.

In addition, the heat absorbing agent is known PVD can be coated on the surface of the heat transfer plate by physical vapor deposition (Physical Vapor Deposition), wherein the excellent thermal conductivity and cost-effective micro unit aluminum powder or copper powder, etc. May be deposited. In addition, the micro powder of aluminum powder, copper powder and the like can be mixed with an adhesive and coated. In addition, the above-mentioned micro unit aluminum powder, copper powder, or the like may be produced and attached in a thin plate form by a known method.

In addition, the heat absorber may be coated with a conventional black paint, and may be applied to any material having a high heat absorption rate.

As a result, the heat absorber coated on the heat transfer plate has a condition in which heat transferred from the heat transfer space can be transferred more heat than the heat transfer plate itself, which increases heat conduction efficiency as it increases conduction efficiency. will be.

4 is a partially exploded perspective view for explaining another embodiment of the present invention, Figure 5 is a cross-sectional view of the combined state according to FIG.

As shown in the above configuration, there is also provided a technical configuration that can have a continuous heat exchange efficiency even in winter or at night when the amount of sunshine falls.

On the opposite side of the finishing plate 40 to which the heat transfer plate 30 is coupled, the heating medium circulation plate is formed in which the heating medium circulation path 62, through which the heating medium heated by a conventional boiler or the like, is circulated when the surface of the finishing plate 40 is in contact with the finishing plate ( 60) is further included. The heat medium circulation plate is provided with a packing on the heat medium circulation plate side, which is a common method, so that the heat medium circulated in the heat medium circulation path on the finishing plate and the edge side can be coupled by bolting, etc. Can be fixed by coupling. In addition, the heat medium circulation plate is also coupled in the frame. The heat medium mild plate is also made of copper or aluminum with excellent thermal conductivity.

The heat medium circulation path 62 has the same technical configuration as the above-described circulation path through which the heat exchange water is circulated, and each of the second expansion flow paths provided at the heat medium inlet port 62A and the heat medium outlet port 62B of the heat medium circulation plate 60 is formed. 62-1) and a plurality of second divided flow passages 62-2 formed between the second expansion flow passage 62-1. The refrigerant circulation path has the same function as the above-mentioned circulation path, and detailed description thereof will be omitted.

Accordingly, the present invention not only does not exchange heat even during winter or at night when the amount of sunshine falls, but also has a condition for continuously exchanging heat exchange water with high efficiency by the heat medium circulated through the heat medium circulation path.

Here, the heat medium circulation plate is preliminary, and is temporarily used in winter, at night, etc., which is weak in solar heat, and supplies hot water and heating water directly from the boiler due to its high heat exchange efficiency as compared to supplying hot water and heating water directly by the boiler. Compared to having the advantage of supplying hot water and heating water with a small amount of heat.

On the other hand, although the solar heat absorbing panel of the present invention is not shown, by providing a plurality of hot water according to the amount of hot water or heating applications required by connecting the heat transfer plate and the heat medium circulation plate in a conventional manner, it is also possible to maximize the amount of hot water and heating efficiency May have conditions.

1: solar heat absorber panel
10 glass plate 12 gap retaining zone
20: heat collecting space 30: heat transfer plate
30A: heat collecting section 32: circulation passage
32-1: 1st expansion flow path 32-2: 1st division flow path
32A: Inlet 32B: Outlet
34: heat absorber 40: finish plate
50: frame 60: heat medium circulation plate
62: heat medium circulation path 62-1: second expansion flow path
62-2: 2nd division flow path 62A: Heat medium inflow port
62B: Heat medium outlet

Claims (7)

Transparent glass plate which solar heat is absorbed;
A heat collecting space formed by a gap holding portion provided on the bottom surface of the glass plate toward the edge;
A circulation path through which heat-exchanged water circulates while the heat absorbed and collected in the glass plate and the collecting space is collected at the lower portion of the collecting space, and the heat collected at the opposite surface contacting the collecting space is conducted. A heat transfer plate formed of a metal material having a plurality of first divided passages formed between the first expansion passages and the first expansion passages formed at the inlet and outlet sides;
Closing plate is fixed to the surface formed with a circulation path of the heat transfer plate including a packing so that the heat exchange water is not leaked to the edge side; And
Including; frame frame is finished on the edge of the glass plate, the heat transfer plate and the closing plate;
The first expansion passage formed on the inlet side is divided into a number corresponding to the plurality of first divided passages, and the first expansion passage formed on the outlet side is divided into a number corresponding to the first divided passage. Formed by more numbers,
The surface in contact with the heat collecting space of the heat transfer plate further includes a heat collecting portion formed in an intaglio or embossed shape to have a large surface area,
And a heat absorber is coated on a surface of the heat collecting plate in contact with the heat collecting space such that a heat absorbing agent is coated so as to generate more heat than the heat transfer plate itself. The method of claim 1,
The heat transfer plate is a solar heat absorbing panel of any one of copper or aluminum. delete delete delete The method of claim 1,
And a heat medium circulation plate having a heat medium circulation path formed on a side thereof in contact with the finish plate on an opposite side of the finish plate to which the heat transfer plate is coupled. The method of claim 6,
And the heat medium circulation path comprises a plurality of second dividing flow paths formed between respective second expansion flow paths and the second expansion flow paths provided at the heat medium inlet and the heat medium discharge side of the heat medium circulation plate.

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