KR20100121755A - Solar collecting apparatus - Google Patents

Abstract

PURPOSE: A solar collecting apparatus is provided to increase heat collection efficiency of solar energy, since heat collectors, installed on a sub heat collecting plate, are serially connected for the increment of heat-collecting capacity. CONSTITUTION: A solar collecting apparatus comprises heat collecting plates(100,100-1) and a heat collector(1200). The heat collecting plate is integrated with sub heat collecting plates(100a,100b) of a half circle form. The heat collecting plate is installed around a first rotary shaft(200) cross-coupled with a second rotary shaft(300). The heat collector is parallel along a rectangular opening. The opening is longitudinally formed on the sub heat collecting plate. A fluid inlet and a fluid outlet are formed in the heat collector.

Description

Solar heat collecting device {SOLAR COLLECTING APPARATUS}

The present invention is to collect the solar heat to the heat collecting plate, and more specifically provided with a pair of semi-circular auxiliary heat collecting plate having an opening for passing the wind in a pair on both sides around the first pivot, The present invention relates to a heat collecting device for collecting solar heat by connecting a collector installed in series.

Recently, the world has depended on only limited resources such as electricity, gas, and oil, and the shortage of petroleum energy is gradually realized, while the price of oil is continuously rising, and Due to the increase of greenhouse gases, the environmental pollution problem has been raised seriously, and efforts to reduce the emission of carbon dioxide (CO₂) as much as possible in order to prevent global warming are being accelerated by taxation.

Accordingly, interest in the development of alternative energy using nature such as solar power or solar heat, wind power and tidal power, which can be used indefinitely in an eco-friendly environment without generating environmental pollution, among them, especially The development of devices for producing heat sources for hot water and heating as well as the production of electric energy required for homes and industries using solar heat is actively progressing.

1 is a view showing a heat collecting device for collecting conventional solar heat.

Conventional solar collector 10 is provided with a body (12) mounted on the upper surface of the transparent glass 11 of the plate type (Type) for collecting the solar heat emitted from the sun (16). .

In addition, a semi-circular reflector 13 having a reflective surface 13-1 is provided inside the body 12, and a fluid 15 is filled and circulated inside the reflector 13. It is configured by installing a fluid pipe (Pipe) 14 having a constant diameter.

 In the collector 10, the direct sunlight emitted from the sun 16 is collected directly in the fluid pipe 14 through the glass 11, or indirectly the solar heat reflected through the reflective surface 13-1. It is delivered to the fluid pipe 14 and the collection is made.

Such a conventional collector 10 has a significant limitation in producing the temperature of the fluid 15 filled in the fluid pipe 14 to a temperature higher than a temperature suitable for hot water or heating (for example, 60 ° C. or higher) using solar heat. In this case, especially when the weather is cloudy, the heat collecting efficiency of the collector 10 is further reduced.

Therefore, in the conventional technology, since only the ordinary heating water can be used in households with low heat capacity, in terms of energy saving, the contribution is very low compared to the installation cost, and at the time of expanding application Is followed.

The present invention for solving the conventional problems as described above is provided with a pair of semi-circular sub-collecting plate having an opening for passing a strong upwind on both sides about the first rotational axis, matching each of the sub-collecting plate one by one (Matching) The purpose is to increase the heat collecting capacity of the solar heat emitted from the sun by increasing the heat collecting capacity by connecting the collector installed in series.

As a means for solving the problems of the present invention as described above, a pair of semi-circular shapes are provided in a frame on both sides around at least one or more first pivot shafts that are cross-coupled to a second pivot shaft. Characterized in that the heat collecting plate having an auxiliary heat collecting plate integrally configured.

In addition, the auxiliary heat collecting plate provided in the heat collecting plate is characterized in that the heat collectors are installed in parallel along each of the rectangular openings formed in the longitudinal direction.

In addition, the collector is provided with a fluid inlet and a fluid outlet, respectively, the fluid stored in the fluid storage tank (Tank) is introduced into the fluid pipe through the fluid pipe (Pipe) through the fluid inlet connected to the fluid transfer pipe (Pipe) Collected by a vacuum tube, the collected fluid is again passed through the fluid pipe (Pipe) through the fluid inlet of another collector connected in series through a fluid transfer pipe (Pipe) connected to the fluid outlet after the outflow. In addition to being flowed in and collected by the vacuum tube, and the fluid collected in the another collector connected in series through the fluid pipe (Pipe) again through the fluid pipe connected to the fluid outlet (pipe) includes a path toward the heat exchanger It is characterized by the configuration.

Hereinafter, the objects and solutions to the present invention will become more apparent from the detailed description of the various embodiments shown in the accompanying drawings.

As described above, the present invention provides an effect of further increasing the heat collecting efficiency of the solar cell by further increasing the heat collecting capacity by connecting the heat collectors installed in series with each other, respectively, installed in the auxiliary heat collecting plate provided with a pair of heat collecting plates in series.

Secondly, the present invention can prevent the heat collecting plate from being damaged from strong upwind, thereby providing another effect of more efficiently collecting solar heat even in a windy weather.

Third, the present invention provides another effect of collecting solar heat more efficiently because the heat collecting plate provided on the first rotating shaft provided in plurality can be integrally rotated toward the sun in the east-west and north-south directions.

Fourth, by combining the heat collecting plate of the present invention with a reflector or a solar cell, it can be used for heating and water supply using solar heat collection, and also provides another effect that can simultaneously produce power through solar light collection. give.

In describing a specific embodiment of the present invention, it is illustrated by the drawings of the present invention, the configuration and operation thereof will be described as at least one embodiment, whereby the technical spirit of the present invention and its core Configurations and operations should not be limited.

For reference, in designating reference numerals in the drawings to be described in the present invention, it should be noted that the same components are given the same reference numerals as much as possible, even if shown in different drawings.

Hereinafter, with reference to the accompanying drawings for the heat collecting apparatus using solar heat according to the present invention will be described in detail.

2 is a plan view schematically showing an overall configuration of a heat collecting device for collecting solar heat through a plurality of heat collecting plates according to the present invention.

In general, the method using solar heat is classified into three types according to the temperature range collected in the collector, low temperature use in the range of 50 to 100 ° C, medium temperature use in the range of 100 to 300 ° C, and high temperature use in the range of 300 ° C or more. .

In addition, a commonly used solar house is a kind of low-temperature use means that mainly uses the solar heat for heating and hot water of the house, and also according to the nature of the installed system, the Passive Solar System and the equipment type system It can be divided into (Active Solar System).

The natural system is a method of collecting and storing solar heat in a natural manner (for example, a structure using a building structure) without using a special operating mechanism, using heating and hot water, and the installation system uses a separate heat medium. After absorbing and distributing solar heat, heating and hot water are also used through facilities such as collectors, heat exchangers, fluid storage tanks, and control devices.

At least one first pivot 200 which is cross-coupled to the second pivot 300 to collect solar heat radiated from the sun 900 as a means for solving the problem of the present invention. The heat collecting plates 100 and 100-1 are integrally provided with semi-circular auxiliary heat collecting plates 100 a and 100 b provided in pairs in a frame 110 over both sides.

At this time, the second rotating shaft 300 is installed in the east-west direction as shown in the accompanying Figures 2 to 6 is rotated in the north-south direction, and also the cross (cross) coupled to the second rotating shaft (300) The first rotating shaft 200 is characterized in that rotated in the east-west direction.

In addition, the heat collecting plates 100 and 100-1 installed on the first pivot shaft 200 are symmetrically installed on both sides of the second pivot shaft 300, that is, in the north-south direction.

In addition, the sub-collecting plates 100a and 100b respectively provided in the heat collecting plates 100 and 100-1 have a photoelectric effect in which current is generated when the solar light is received to condense sunlight emitted from the sun 900. The solar cell 120 using the photoelectric characteristics is characterized in that it is configured in the frame (110).

In addition, the sub-collecting plates 100a and 100b respectively provided in the heat collecting plates 100 and 100-1 are reflectors 120a which are made of light reflection to collect the solar heat emitted from the sun 900 to the heat collecting unit 1200. ) Is configured in a frame (110).

In this case, it is preferable to use a material having a high reflectance on the surface of the reflector 120a in order to increase the reflection efficiency of the solar heat emitted from the sun 900, which is smoothly processed like a mirror, or The surface may be plated or the reflective film or silver foil, which is formed of a thin film on the surface, may be attached using a separate adhesive means.

Of course, the reflector 120a should not be harmful to the environment, and in particular, it would be desirable to have a material that does not generate rust.

In addition, a rectangular shape for passing strong upwind blown toward the auxiliary heat collecting plates 100a and 100b in a longitudinal direction on the center of the auxiliary heat collecting plates 100a and 100b provided in the heat collecting plates 100 and 100-1 ( An open portion 130 of a long shape is configured, and a collector 1200 that is installed in parallel along the open portion 130 is configured.

In this case, the collector 1200 is provided with a fluid inlet 1262 and a fluid outlet 1264, respectively, the fluid 1280 stored in a fluid storage tank (not shown) is a fluid transfer pipe (Pipe) ( It is introduced into the fluid pipe 1232 through the fluid pipe 1262 through the fluid inlet (1262) connected to 1282 is collected by the vacuum tube 1230, the collected fluid 1280 is again the fluid Fluid through a fluid inlet 1262 of another collector 1200 connected in series via a fluid transfer pipe 1242 connected to the fluid outlet 1264 following an outflow via a pipe 1272. In addition to being introduced into the tube 1232 and collected by the vacuum tube 1230, the fluid 1280 collected in the another collector 1200 connected in series is again passed through the fluid pipe 1272 and the fluid outlet ( Flows toward a heat exchanger (not shown) through a fluid transfer pipe 1282 connected to 1264. And that is configured, including as to the features.

In other words, as shown in FIG. 2, the collector 1200 and the other collector 1200 alternate between the fluid outlet 1264 and the fluid inlet 1262 by a fluid transfer pipe 1282. It is preferable to connect in series, which is characterized by the effect of increasing the overall heat collecting area of the collector (1200).

Next, a configuration of the vacuum tube 1320 provided in the collector 1200 according to the present invention will be described in detail with reference to FIGS. 7 and 8.

The material of the vacuum tube 1230 is a colored or black color or a darkened or near black color for efficient absorption of solar heat emitted from the sun 900, or provided with a coated glass or synthetic resin, In this case, it is preferable to use a reinforcing material so as not to be damaged by expansion, even at high temperatures due to the strong absorption of solar heat in the summer, and also not to be damaged by shrinkage, etc., even at low temperatures due to the cold in winter.

In addition, the outer side of the fluid tube 1232 is characterized by using a double vacuum tube 1230 having a space portion 1231a and having a double or more vacuum units 1231.

In other words, when the solar heat emitted from the sun 900 is collected on the surface of the vacuum tube 1230 through the heat collecting plate 100, 100-1, the fluid 1280 filled in the fluid tube 1232 with radiant heat accordingly. The temperature of) will be increased, and since the fluid 1280 is insulated from the outside air by the vacuum part 1231, it is more advantageous for keeping warm for a long time, so that a double vacuum tube 1230 is used. It would be more desirable to.

Here, the space portion 1231a is also treated with a vacuum to maintain the heat retention of the fluid 1280 as well as the solar heat collected on the surface of the vacuum tube 1230 to the fluid 280 filled in the fluid tube 1232. In the act of copying will be able to further increase the heat collection efficiency.

On the other hand, the fluid 1280 is characterized in that it is not filled in the space portion 1231a of the vacuum tube 1230, which means that the fluid 1280 in the space portion 1231a of the vacuum tube 1230 When filled, there is a risk that the vacuum tube 1230 may be damaged due to thermal expansion of the fluid 1280, thereby preventing a factor of shortening the life of the collector 1200.

In addition, the fluid pipes 1272 are inserted and installed one by one on the center of the fluid pipes 1232 filled with the fluid 1280, and the fluid pipes 1232 are spaced portions of the vacuum tube 1230. 1231a) It is characterized in that the insertion is installed on the center one by one (Matching).

Here, the end of the fluid tube 1232 is covered with a buffer cap (1234) of various materials such as sponge, rubber, urethane, etc. to protect the inner wall 1235 of the vacuum tube 1230, the vacuum tube It would be desirable to prevent 1230 from breaking from impact or the like.

At this time, the buffer cap (Cap) 1234, it is preferable to use a material that is not deteriorated by the chemical action of the fluid 1280 even if used for a long time.

In addition, the material of the fluid pipe 1272 may be a metal or a synthetic resin, but if possible, it is preferable to use a copper pipe having high thermal conductivity and hardly rusting.

For reference, in FIG. 5, reference numerals 1261, 1263, and 1265 denote fluid inlets 1262, fluid outlets 1264, and detection lines 1267 in caps 1250, respectively. It is a connecting member using a separate coupling (Coupling) for connecting and fixing.

In addition, the reference numeral 1213 fixes the cap 1250 and the body 1210 of the collector 1200 integrally with each other through a packing 1253 so that the fluid 1280 may be formed. To prevent leakage to the outside, separate fixing bolts and nuts Fixed member used.

In addition, the heat collecting plates 100 and 100-1 are joined by separate fixing means, welding, and the like through a shaft fixing part 310 for coupling the second pivotal shaft 300 installed in both east and west directions. It is configured to be firmly supported by the support portion 800 consisting of the support portion 810 and the second support portion 820.

At this time, the additional heat collecting plate (100, 100-1) is further extended through any one of the fixing portion 310 provided at both ends of the second pivot shaft 300, the heat collecting area of the solar heat Can be increased further.

In addition, the support part 800 uses a separate fixing member (not shown) such as an anchor bolt to the second support part 820, and a floor surface 850 such as a roof of a building or the ground. By fixing it firmly) is installed on the heat collecting plate 100, 100-1 of the present invention.

Here, the frame 110 and the auxiliary frame 111 (111a), the support portion 800, etc., which will be described later, are required to have sufficient strength so that the heat collecting plates 100 and 100-1 are not damaged by strong wind. It would be desirable to consist of a material or a material having a strength equal to or greater than that.

In addition, in order to rotate the heat collecting plate 100, 100-1 in the east-west direction as shown by the arrow in the drawing, a driving force is provided on the first pivot 200, including a separate power transmission member 210, 220. The first driving unit 400 for transmitting is configured.

In addition, in order to rotate the heat collecting plate (100) (100-1) in the north-south direction as shown by the arrow shown in the drawing also includes a separate power transmission member 320 to transmit the driving force to the second pivot 300 (300). Do you know that the second drive 500 is configured? .

As shown in FIGS. 2 to 4, the first driver 400 and the second driver 500 are formed of a linear actuator in which an electric motor (not shown) is incorporated. It features.

The electric motor provided in the first driver 400 and the second driver 500 is controlled by various driving voltages such as DC voltage 12 volts (V) and 24 volts (V) as well as a predetermined AC voltage. Will be done.

In addition, one of the heat collecting plates 100 and 100-1 is provided with an optical sensor unit 600 for detecting the position of the sun 900 in the east, west and north and south directions, and is detected by the optical sensor unit. The heat collecting plate 100, 100-1 is rotated by tracking the sun 900 in the east-west and north-south directions by a separate position tracking device 700 for tracking the position of sunlight.

Here, the above-mentioned light sensor unit and the position tracking device will be omitted for more detailed operation description in order to avoid confusion with the technical idea according to the present invention.

On the other hand, the collector 1200 installed in the auxiliary heat collecting plate (100a, 100b) is installed by matching the body (1210) having a fluid inlet (1262) and the fluid outlet (1264) in the north direction to install a vacuum tube 1230 By maintaining the position always higher than the tube end 1233 of the), the fluid 1280, such as antifreeze or insulating oil filled in a separate fluid tube 1232 provided inside the vacuum tube 1230 is the fluid storage tank (not shown) It will be desirable to facilitate the circulation operation flowing into the fluid inlet (1262) from the fluid outlet (1264) toward the heat exchanger (not shown).

Here, at least one of the collectors 1200 connected in series is provided with a temperature sensor 1266 for detecting the temperature of the fluid 1280 through the temperature sensing line 1267 (not shown). By sensing in the), the fluid 1280 is collected by the heat collector 1200, if it is heated to a certain temperature or more, such as 30 ℃, 50 ℃, 60 ℃ or more, and the circulation pump (not shown) By operating the circulating the fluid 1280.

Subsequently, the fluid 1280 stored in the fluid storage tank flows through the fluid inlet 1262 and is pushed into the fluid pipe 1232 through the fluid pipe 1272 and at the same time, it is hot inside the fluid pipe 1232. A circulating operation of the fluid 1280 is performed by pushing the fluid 1280 held in a warm state to the heat exchanger through the fluid outlet 1264 by pushing in the direction of arrow A as shown in FIG. You lose.

In addition, the collector 1200, as shown in Figure 5 attached to the portion of the body 1210 and the tube end 1233 of the vacuum tube 1230, the first fixture (1291) (1291a) and the second fixture (1292) ( It is characterized in that the fixed to each of the frame 110 through 1292a.

At this time, the first fixing sphere (1291) (1291a) and the second fixing sphere (1292) (1292a) it is desirable to be firmly installed in the frame 110 using a separate fixing member such as a band (Band). will be.

Here, when fixing the tube end 1233 of the vacuum tube 1230, the second fixing sphere (1292) (1292a) is fixed by using a buffer member 1293, such as rubber, sponge, urethane, etc. It would be desirable to prevent 1230 from being damaged from impact or the like.

In addition, the opening 130 is characterized in that formed between the collector 1200 and the auxiliary frame (111) (111a) installed in parallel in the longitudinal direction as shown in FIG.

At this time, the opening 130 may be installed at least one or more parallel to the auxiliary heat collecting plate (100a) (100b) in parallel with the heat collector 1200 in the longitudinal direction as mentioned above to correspond to the strong wind. will be.

The area of the opening 130 is appropriately formed according to the size of the auxiliary heat collecting plates 100a and 100b, preferably at least 5 to 30 based on the area of one of the auxiliary heat collecting plates 100a and 100b. Forming it in the% range would be advantageous for the counter-wind.

On the other hand, the opening 130 is also installed at least one or more parallel to the auxiliary heat collecting plate (100a) (100b) in the longitudinal direction with the collector 1200, the diameter (D1) of the opening 130 is By forming the diameter (D1 = D2) equal to the diameter (D2) of the vacuum tube 1230 provided in the collector 1200, it is characterized in that it is configured to be much more advantageous to the passage of upwind.

In other words, the portions of the sub-collecting plates 100a and 100b in which the openings 130 are formed are also portions in which the shadow of the sun 900 is partially generated by the vacuum tube 1230, and thus the openings ( If the area of 130 is made too small, the area of the auxiliary heat collecting plates 100a and 100b is relatively increased, which is advantageous for solar heat or solar heat collection, but is an adverse condition for strong upwind. If the area of 130 is made too large, the area of the auxiliary heat collecting plates 100a and 100b may be relatively reduced, which may be advantageous to cope with strong wind, but may be a very unfavorable condition for solar heat or solar heat collecting.

In addition, the heat collecting plates 100 and 100-1 installed on the first pivot shaft 200 are symmetrically installed on the basis of the second pivot shaft 300, and the aforementioned first driver 400 and By the second driving unit 500 to rotate at the same rotation angle toward the sun 900 in the east-west and north-south direction of the heat collecting plate 100, 100-1, thereby improving the heat collecting efficiency of solar heat or the light collecting efficiency of sunlight. The note will act.

Here, the first rotating shaft 200 is cross-coupled to each other through the shaft fixing portion 230 provided in the second rotating shaft 300 (cross) is characterized in that the rotating action in the east-west direction as mentioned above It is done.

The heat collecting plates 100 and 100-1 configured as described above reflect the solar heat emitted from the sun 900 and reflectors 120a of the auxiliary heat collecting plates 100a and 100b provided in the heat collecting plates 100 and 100-1. And then intensively reflects to focus on the surface of the vacuum tube 1230 of the collector 1200 which is installed longitudinally on the central portion of the auxiliary heat collecting plate 100a and 100b. The collection operation is to be made.

Similarly, the heat collecting plates 100 and 100-1 are solar cells of the auxiliary heat collecting plates 100a and 100b provided in the heat collecting plates 100 and 100-1 to emit sunlight emitted from the sun 900. By collecting through the surface of the 120, the condensing operation for the sunlight is made accordingly.

On the other hand, by using the bearings (230, 310) is built in the bearing (Bearing), the heat collecting plate 100, 100 coupled through the first rotating shaft 200 and the second rotating shaft (300) It would be desirable to allow -1) to facilitate the rotation in the east-west and north-south directions.

It will be apparent to those skilled in the art that various changes, modifications, and the like can be made without departing from the technical spirit of the present invention through the above description.

Therefore, the technical scope of the present invention should not be limited to the contents described in the embodiments as mentioned, but should be defined by the claims of the present invention.

1 is a view showing a heat collecting device for collecting conventional solar heat.

2 is a plan view schematically showing an overall configuration of a heat collecting device for collecting solar heat through a plurality of heat collecting plates according to the present invention.

Figure 3 is a side view showing an embodiment of a heat collecting device for collecting solar heat in Figure 1 according to the present invention.

4 is a front view of an embodiment showing a heat collecting device for collecting solar heat in FIG. 1 according to the present invention.

5 is (a) one embodiment showing a state in which the collector is installed on the heat collecting plate viewed from the body side, (b) is a state showing the state in which the collector is installed on the heat collecting plate viewed from the protective cap side Example embodiment drawing.

FIG. 6 is a plan view showing an example of a state of a heat collecting plate before the heat collector is installed in the heat collecting plate in detail.

Figure 7 is a front view showing an embodiment in detail showing the assembled state of the collector installed on the heat collecting plate according to the present invention.

8 is a side cross-sectional view showing an embodiment in more detail by partially cutting the configuration of the vacuum tube in Figure 7 according to the present invention.

Explanation of symbols on the main parts of the drawings

100, 100-1: heat collecting plate

100a, 100b: auxiliary heat collecting plate

110: Frame

111, 111a: auxiliary frame

120: solar cell

120a: reflector

130: opening

200: first coaxial

210, 220: power transmission member

230, 310: High School Government

300: second coaxial

310: high government

320: power transmission member

400: first driving body

500: second drive body

800 support part

810: first support

820: second support

850: floor surface

900: the sun

1200: collector

1210: Body

1213: fixing member

1230: vacuum tube

1231: vacuum

1231a: space part

1232: fluid tube

1233: Observer

1234: buffer cap

1235: inner wall

1250: Cap

1253: Packing

1261, 1263, 1265: connecting member

1262: fluid inlet

1264 fluid outlet

1266: temperature sensor

1267: detection line

1272: Pipe

1280 fluid

1282: Fluid Transfer Pipe

1291, 1291a: First Fixture

1292, 1292a: Second Fixture

1293: cushioning member

Claims (10)

Semi-circular auxiliary heat collecting plate 100a installed in a pair on a frame 110 across the center of at least one or more first pivot shafts 200 which are cross-coupled to the second pivot shafts 300 ( A heat collecting plate 100 (100-1) integrally provided with 100b); A collector 1200 installed in parallel along the opening 130 of the rectangular shape formed in the longitudinal direction on the auxiliary collector plates 100a and 100b provided in the collector plates 100 and 100-1; The collector 1200 is provided with a fluid inlet 1262 and a fluid outlet 1264, respectively; a) the fluid 1280 stored in the fluid storage tank (Tank) is connected to the fluid pipe (1232) through the fluid pipe (1272) through the fluid inlet (1262) connected to the fluid transfer pipe (1282) Flows in and is collected by a vacuum tube 1230, b) the collected fluid 1280 is again passed through the fluid pipe 1272 and further connected in series via a fluid transfer pipe 1282 connected to the fluid outlet 1264. While flowing into the fluid tube 1232 through the fluid inlet 1262 of the collector 1200 and collected by the vacuum tube 1230, c) The fluid 1280 collected in another collector 1200 connected in series is again connected to the fluid outlet 1264 via a fluid pipe 1242 through a fluid transfer pipe 1282. Consisting of a path outflow towards the heat exchanger; Solar heat collecting device characterized in that. According to claim 1, The second rotating shaft 300 is installed in the east-west direction is rotated in the north-south direction, the first rotating shaft (200) cross-coupled to the second rotating shaft 300 is east-west Rotated in directions; Solar heat collecting device characterized in that. According to claim 1, wherein the heat collecting plate (100, 100-1) installed on the first pivot shaft 200 is installed symmetrically to each other on both sides of the second pivot 300; Solar heat collecting device characterized in that. According to claim 1, wherein the auxiliary heat collecting plate (100a, 100b) is composed of a reflector (120a) for collecting the solar heat emitted from the sun 900 to the collector (1200); Solar heat collecting device characterized in that. According to claim 1, wherein the auxiliary heat collecting plate (100a) (100b) is composed of a solar cell (Solar Cell) (120) for condensing sunlight emitted from the sun 900; Solar heat collecting device characterized in that. According to claim 1, wherein the collector (1200) is a body (1212) having the fluid inlet (1262) and the fluid outlet (1264) is installed in the north direction; Solar heat collecting device characterized in that. According to claim 1, The fluid pipe (1272) is installed and inserted (Matching) one by one on the center of the fluid pipe (1232) filled with the fluid 1280, the fluid pipe (1232) is the vacuum tube 1230 Matching one by one installed on the center of the space portion (1231a) of the installed; Solar heat collecting device characterized in that. According to claim 1, The opening portion 130 is installed at least one or more parallel to the auxiliary heat collecting plate (100a) (100b) in the longitudinal direction with the heat collector (1200), the area of the opening 130 It is formed in a range of at least 5 to 30% based on the area of the auxiliary heat collecting plate (100a) (100b); Solar heat collecting device characterized in that. According to claim 1, The opening portion 130 is installed at least one parallel to the auxiliary heat collecting plate (100a, 100b) in the longitudinal direction with the heat collector (1200), the diameter of the opening (130) D1) is formed to the same diameter (D1 = D2) of the diameter (D2) of the vacuum tube (1230) provided in the collector (1200); Solar heat collecting device characterized in that. The method of claim 1, wherein the collector 1200 and another collector 1200 are connected to each other in series by alternating the fluid outlet 1264 and the fluid inlet 1262 by a fluid transfer pipe (1282). ; Solar heat collecting device characterized in that.

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