KR101004007B1 - Heating system using solar heat - Google Patents

Abstract

The present invention relates to a solar heating system, and more particularly, to a solar heating system having a solar heat absorbing plate capable of absorbing solar heat efficiently regardless of the season and the position of the sun, the solar heating system according to the present invention A solar heat absorber that absorbs solar heat; A heat storage unit for absorbing and storing heat; A refrigerant circulation unit configured to circulate a refrigerant to the solar heat absorbing unit and the heat storage unit to transfer heat absorbed by the solar heat absorbing unit to the heat storage unit; It includes; heating unit for heating the room by transferring the heat of the heat storage unit to the room.

Solar heat, heating, heat sink, heat storage

Description

Solar Heating System {HEATING SYSTEM USING SOLAR HEAT}

The present invention relates to a solar heating system, and more particularly, to a solar heating system having a solar heat absorbing plate capable of absorbing solar heat efficiently regardless of the season and the position of the sun.

In the case of oil, the amount of energy in a liter is about 10 kWh, but there is a loss when burning, so more oil needs to be burned to get the desired energy. In addition, carbon dioxide emitted when burning oil is a greenhouse gas, which is a major cause of global warming. About 183g of carbon dioxide is released to obtain 1kWh of energy.

The Global Warming Prevention Kyoto Conference, held in December 1997, regulated greenhouse gases by reducing 5% by 2012 on greenhouse gases (CO ₂ , NO ₄ , N ₂ O, etc.) in all developed countries. Day by day, the study on environmentally friendly energy sources that do not emit greenhouse gases, etc., is being actively conducted. Among these energy sources, the sun emits about the same amount of energy as the world's annual energy in 40 minutes, making it one of the more viable alternatives.

The technologies using solar energy include solar power generation using solar light, solar power generation using solar heat, and solar thermal devices used for heating and hot water.

The structure of the heat absorbing plate or the heat absorbing tube is important for effective utilization of solar heat, as shown in FIG. 1, the heat collecting device 30 is included, and the light is absorbed in the form of the transparent plate 10 through which the light is transmitted. When this comes in, a greenhouse effect occurs in it, producing hot heat. The lower part and the side part of the heat absorbing plate are surrounded by the heat insulator 20 to reduce the possible heat loss. When a heating medium such as water or air passes through a heating device in which the greenhouse effect occurs, solar energy is transferred to the heating medium and used for heating.

In Korea, hot water devices with integrated water tanks and heat sinks are often found on roofs, but solar heating devices are hard to find. This is because the winter is so cold that the heat of the heat absorbing plate goes out too much. Complementary to this is the vacuum tube type heat absorbing plate. Since heat conduction does not occur in the vacuum, the heat loss is small, but the vacuum tube type heat absorbing plate is expensive to manufacture and the solar energy absorbing plate is contained in one vacuum tube. There is a disadvantage that the area is significantly reduced compared to the flat heat collecting plate. In addition, since the energy of the sun is changed depending on the season, weather and time, when the solar heat is less, there is a problem that separate heating with oil or gas, or need to install a heat storage tank separately.

If a costly heat absorbing plate is required or the manufacturing cost of the solar heating device is increased due to the installation cost of the heat storage tank, the heating cost of the solar heating device is hardly reduced due to the expensive device cost. It is the hardest reason.

Therefore, there is an urgent need for the development of a solar heating system that can reduce the production price by having a heat absorbing plate having a simple structure with a heat absorbing structure having a small influence on the position of the sun and high energy exchange efficiency.

The technical problem to be solved by the present invention is to provide a solar heating system having a heat absorbing plate capable of absorbing solar heat efficiently regardless of the season and the position of the sun.

Solar heating system according to the present invention for achieving the above technical problem, the solar heat absorbing portion for absorbing the heat; A heat storage unit for absorbing and storing heat; A refrigerant circulation unit configured to circulate a refrigerant to the solar heat absorbing unit and the heat storage unit to transfer heat absorbed by the solar heat absorbing unit to the heat storage unit; It includes; heating unit for heating the room by transferring the heat of the heat storage unit to the room.

In the present invention, the solar heat absorbing portion, the housing having a structure in which one surface is open; A transparent plate covering one open surface of the housing; And a heat absorbing plate disposed inside the housing to absorb solar heat transmitted through the transparent plate.

Here, it is preferable that the heat absorbing plate is formed in a wavy shape having a valley and a floor repeatedly because it can effectively absorb solar heat. And the plurality of heat absorbing plates are arranged side by side, the valleys and the floor of the neighboring heat absorbing plate is arranged to be staggered with each other, the temperature riser and the heat absorbing plate is interlaced, it is preferable to efficiently raise the temperature of the refrigerant.

And it is preferable that the said heat absorbing plate is arc-shaped in cross section because it can absorb solar heat efficiently regardless of the position of the sun.

On the other hand, the refrigerant circulation unit, the temperature riser is installed in the housing to increase the temperature of the refrigerant by the heat absorbed by the heat absorbing plate; A heat dissipation unit installed in the heat storage unit and dissipating heat to lower the temperature of the refrigerant; It is preferable to include a; connecting portion connecting the temperature rise portion and the heat dissipation portion.

In the present invention, it is preferable that the temperature rise part is arranged in a structure intertwined with the heat absorbing plate because the heat absorbed by the heat absorbing plate can be effectively used to increase the temperature of the refrigerant.

At this time, it is preferable that the temperature rising part has a coil shape, so as to maximize the movement time and distance of the refrigerant in the heat absorbing part, thereby obtaining an effective temperature rising result of the refrigerant.

The solar heating system according to the present invention further includes a compression unit disposed between the connection unit and the heat dissipating unit and compressing the refrigerant to increase the temperature of the refrigerant, so that the temperature of the refrigerant can be raised to a desired temperature. Do.

On the other hand, the solar heating system according to the present invention, it is preferably disposed between the heat dissipating portion and the connecting portion, it is preferable to further include an expansion portion for expanding the refrigerant to lower the temperature of the refrigerant.

According to the present invention, there is an advantage of absorbing solar heat most efficiently by using a heat absorbing plate capable of absorbing solar heat most efficiently regardless of season or position of the sun.

In addition, according to the present invention there is an advantage that a heating effect can be obtained without the help of other heating system or environmental pollution.

Hereinafter, with reference to the accompanying drawings will be described in detail a specific embodiment of the present invention.

First, as shown in FIG. 2, the solar heating system 1 according to the present embodiment includes a solar heat absorbing part 100, a heat storage part 300, a refrigerant circulation part 200, and a heating part 400. It is composed.

The solar heat absorbing part 100 is a component that absorbs solar heat, and is a very essential component in the solar heating system 1 according to the present embodiment. In this embodiment, the solar heat absorbing part 100 includes a housing 110, a transparent plate 120, and a heat absorbing plate 130, as shown in FIGS. 2 and 3.

Here, the housing 110 is a component constituting the overall appearance of the solar heat absorbing unit 100, and provides a constant internal space so that the heat absorbing plate 130 and the like can be installed therein. The housing 110 is preferably made of a material having excellent heat insulating properties so that solar heat absorbed by the heat absorbing plate 130 is not discharged to the outside. And the housing 110 has a structure that is open on one surface, as shown in Figure 3 to receive sunlight.

The transparent plate 120 is coupled to one open surface of the housing 100. The transparent plate 120 is preferably made of a material having a very high transparency so that sunlight can pass through well. For example, glass or the like can be used. The transparent plate 120 is also preferably made of a material having excellent heat insulating performance so that solar heat inside the solar heat absorbing part 100 does not leak out.

The inner space of the housing is blocked from the outer space by the housing 110 and the transparent plate 120 to form a sealed space. The heat absorbing plate 130 is disposed in the sealed space. As shown in FIGS. 2 and 3, the heat absorbing plate 130 is disposed inside the housing 110 to absorb solar heat transmitted through the transparent plate 120.

Meanwhile, as shown in FIGS. 2 and 3, the heat absorbing plate 130 according to the present embodiment preferably has a wavy shape having a valley and a floor. By having a wavy shape as described above, the heat absorbing plate 130 according to the present embodiment has the largest area in the housing 110. As the area of the heat absorbing plate 130 increases, the amount of solar heat absorbed increases, so that solar heat can be absorbed more efficiently. In addition, by having a wavy shape, the heat absorbing plate 130 according to the present embodiment has a curved surface. This curved surface allows for the most efficient absorption of sunlight, regardless of the position of the sun during the day.

In addition, as shown in FIG. 3, the heat absorbing plate 130 according to the present embodiment is arranged in a plurality of housing 110 side by side. At this time, the shape of the neighboring heat absorbing plate 130, it is preferable that the valley and the floor are alternately arranged. The structure in which the neighboring heat absorbing plates 130 and the valleys and the floor are alternately arranged with each other forms a structure in which the temperature riser 210 and the heat absorbing plate 130, which will be described later, are intertwined with each other to effectively raise the temperature of the refrigerant. .

Meanwhile, although the cross-sectional shape of the heat absorbing plate 130 according to the present embodiment may be various, as shown in FIG. 4, it is preferable to form a curved shape, in particular, an arc shape. Thus, when the cross-sectional shape of the heat absorbing plate 130 is formed in an arc shape, it is possible to effectively absorb solar heat regardless of the altitude difference according to the season of the sun.

Next, the heat storage unit 300 is a component that stores heat absorbed by the solar heat absorbing unit 100. In this embodiment, as shown in FIG. 2, the heat storage unit 300 includes an enclosure 310, a heat storage tank 320, a heat insulating material 330, a heat storage medium, a water supply pipe 340, and a hot water supply pipe 350. It is configured to include. First, the enclosure 310 is a component forming the overall appearance of the heat storage unit 300 according to the present embodiment, and may be made of various materials. The enclosure 310 provides a space in which a predetermined space is formed so that various components constituting the heat storage unit 300 may be disposed.

Next, the heat storage tank 320 is a component in which the heat storage medium is filled, and the heat dissipation part 230 described later is wound on the outside thereof. The heat storage tank 320 may have various structures such as a cylindrical shape or a polygonal column shape, and preferably has a cylindrical shape. The heat insulating material 330 is exterior to the outer surface of the heat storage tank 320. The heat storage tank 320 has a structure for preventing heat from flowing out to the outside. Here, as the heat storage medium, various mediums capable of absorbing heat well may be used, for example, a liquid such as water may be used.

One side of the heat storage tank 320 may be further provided with a hot water supply pipe 350 and the water supply pipe 340. Thus, when the hot water supply pipe 350 and the water supply pipe 340 are provided, the heat storage medium is used as water.

In addition, an auxiliary heater 500 may be further provided at one side of the heat storage tank 320 so as to auxiliaryly heat the heat storage medium when solar heat is not available. The auxiliary heater 500 may have a variety of structures, for example, may be composed of an electric heater.

Next, the refrigerant circulation unit 200 circulates the refrigerant to the solar heat absorbing unit 100 and the heat storage unit 300 to transfer heat absorbed by the solar heat absorbing unit 100 to the heat storage unit 300. Element. As shown in FIG. 2, the refrigerant circulation part 200 according to the present exemplary embodiment includes a temperature rising part 210, a heat dissipation part 230, a connection part 220, and the like. Here, the temperature riser 210 is a component installed in the housing 110 to increase the temperature of the refrigerant by heat absorbed by the heat absorbing plate 130. That is, the temperature rise part 210 refers to a section disposed in the housing 110 as part of a path through which the refrigerant circulates. The refrigerant is warmed by solar heat absorbed by the heat absorbing plate 130 while passing through this section.

In this embodiment, in order to heat the refrigerant most effectively using solar heat absorbed by the heat absorbing plate 130, as shown in FIGS. 2 and 3, the heat absorbing plate 130 and the temperature riser 210 are mutually different. It is desirable to have a staggered structure. That is, the plurality of heat absorbing plates 130 have a structure in which the valleys and the floor are alternately disposed, and the temperature rise part 210 passes between them. Here, the temperature rising part 210 is preferably made of a transparent material because it does not interfere with the solar heat absorption of the heat absorbing plate 130 disposed on the rear surface of the temperature rising part 210.

In addition, in the present embodiment, the temperature riser 210 preferably has a coil shape, as shown in FIG. 3. The refrigerant stays in the solar heat absorbing part 100 for a long time, and passing a long section may absorb solar heat most effectively. Therefore, as described above, by manufacturing the temperature rise unit 210 in a coil shape, the movement distance is sufficiently secured in the solar heat absorbing unit 100 of the refrigerant.

Next, the heat dissipation unit 230 is a component installed in the heat storage unit 300 to radiate heat to lower the temperature of the refrigerant. That is, the heat dissipation unit 230 refers to a section wound around the outer periphery of the heat storage tank 320 among the circulation paths of the coolant, and the coolant whose temperature is increased in the temperature rising unit 210 passes through this section. Heat is transferred to the medium and its temperature drops.

In addition, the connection part 220 is a section connecting the temperature rising part 210 and the heat dissipation part 230. That is, the remaining portion excluding the portion passing through the solar heat absorbing portion 100 and the heat storage portion 300 of the circulation path of the refrigerant. The connection portion 220 is preferably the shortest distance to minimize the loss of heat, in particular, the heat insulation so that the heat loss does not occur in the section in which the refrigerant discharged from the solar absorber 100 is transferred to the heat dissipation unit 230 It is preferable to be made of a material having excellent performance.

The solar heating system 1 according to the present embodiment further includes a compression unit 240 disposed between the connection unit 220 and the heat dissipation unit 230 and compressing the refrigerant to increase the temperature of the refrigerant. It is preferable. The compression unit 240 compresses the refrigerant whose temperature is increased while passing through the solar heat absorbing unit 100 to further increase the temperature of the refrigerant. That is, the temperature of the refrigerant is much higher than the temperature raised by the solar heat absorber 100 by the compression unit 240. Of course, if the temperature raised by the solar absorber 100 is sufficient, this compression unit may not be further provided, but if the temperature rise by the solar absorber 100 is not sufficient or for a more efficient heating system, It is preferable that the portion 240 is further provided.

Meanwhile, when the compression unit 240 is provided, an expansion unit 250 is disposed between the heat dissipation unit 230 and the connection unit 220 and expands the refrigerant to lower the temperature of the refrigerant. It is preferable. The expansion unit 250 is disposed in a position corresponding to the compression unit 240 serves to expand the refrigerant compressed by the compression unit 240. Therefore, the expansion unit 250 does not need to be installed when the compression unit 240 is not installed.

Next, the heating unit 400 is a component for heating the room by transferring the heat of the heat storage unit 300 to the room. This heating unit 400 may be provided substantially similar to that of a general heating system. For example, the heating medium may include a heating medium circulation pipe 410 for circulating a heating medium used for heating, and a pump 420 for circulating the heating medium. A portion of the heating medium circulation pipe 410 is wound around the outer periphery of the heat storage tank 320 so that the heating medium is heated by the heat storage tank. Therefore, the heating medium rises in temperature through this section, moves to the room, and heats the room.

Of course, the heating medium may be filled in the heat storage tank 320 and the heating medium may be circulated to perform indoor heating.

Meanwhile, as illustrated in FIG. 5, the solar heating system 1 according to the present embodiment may further include a cooling system 600. The cooling system 600 is arranged side by side in the solar heating system 1, as shown in FIG. 5, and is configured to perform a cooling function on its own. In the present embodiment, the heat storage tank 620 is further provided in the heat dissipation portion of the path in which the refrigerant circulates in the cooling system 600, and the cooling medium heats the heat storage medium by dissipating the cooling medium in the heat storage tank 620. In this way, the heat storage medium whose temperature is raised is used for heating or hot water supply.

In addition, a connection pipe 680 connecting the heat storage tank 620 of the cooling system and the heat storage tank 320 of the heating system is further provided to allow both heat storage media to move. That is, in summer, the connection pipe 680 is blocked to use the heating-side heat storage tank 320 for hot water supply, and the cooling-side heat storage tank 620 is used as a heat dissipation tank for cooling. In winter, the connection pipe 680 is opened to connect the heating side heat storage tank 320 and the cooling side heat storage tank 620 to be used for heating.

BRIEF DESCRIPTION OF THE DRAWINGS It is a figure explaining the structure of the conventional solar heat absorption apparatus.

2 is a view showing the structure of a solar heating system according to an embodiment of the present invention.

3 is a perspective view illustrating a structure of a solar heat absorber according to an exemplary embodiment of the present invention.

4 is a cross-sectional view showing the structure of a heat absorbing plate according to an embodiment of the present invention.

5 is a view showing the structure of a solar heating system according to another embodiment of the present invention.

Claims (10)

The housing 110 having an open structure on one surface, the transparent plate 120 covering the open one surface of the housing, a plurality of arranged in parallel in a wave shape having a valley and a floor repeatedly inside the housing, The heat absorbing plate 100 has a heat absorbing plate 100 having a heat absorbing plate 130 arranged to alternate with each other and absorbing solar heat transmitted through the transparent plate; A heat storage unit 300 for absorbing and storing heat; A refrigerant circulation part 200 circulating a refrigerant to the solar heat absorbing part 100 and the heat storage part 300 to transfer heat absorbed by the solar heat absorbing part to the heat storage part; And a heating unit (400) for heating the room by transferring the heat of the heat storage unit (300) to the room. delete delete delete The method of claim 1, The heat absorbing plate 130, The cross-sectional shape is arc-shaped, The solar heating system characterized by the above-mentioned. The method of claim 1, The refrigerant circulation unit 200, A temperature riser 210 installed in the housing 110 to increase a temperature of the refrigerant by heat absorbed by the heat absorbing plate 130; A heat dissipation unit 230 installed in the heat storage unit 300 to dissipate heat to lower the temperature of the refrigerant; And a connecting portion (220) connecting the temperature rising portion (130) and the heat dissipation portion (230). The method of claim 6, The temperature rise unit 210, Solar heating system, characterized in that arranged in the structure that is woven on the heat absorbing plate (130). The method of claim 7, wherein The temperature rising unit 210 is a solar heating system characterized in that it has a coil shape. The method of claim 6, Is disposed between the connecting portion 220 and the heat dissipating portion 230, the solar heating system, characterized in that the compression unit 240 is further provided to increase the temperature of the refrigerant by compressing the refrigerant. 10. The method of claim 9, Is disposed between the heat dissipating portion 230 and the connecting portion 220, the solar heating system, characterized in that the expansion portion 250 is further provided to expand the refrigerant to lower the temperature of the refrigerant.

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