KR100993809B1 - Solar collector module and system - Google Patents

Abstract

PURPOSE: A solar power collector which prevents overheating using a first protective member, and solar power collecting system using the same are provided to protect the solar power collector from the external component including sand, wind and rail using first and second protective members. CONSTITUTION: A solar power collector comprises a first protection member(300) blocking the front side of the solar power collector. The first protection member comprises a shield(310) and a guide part(340). The shield fixing part(320), installed in order to fix the shield, comprises a first main body, a first rotation center axis(322) and a controlling part. The first main body is located in a longitudinal direction of a solar power collecting part. The shield is rolled in the outer circumference while the first rotation center axis located inside a first main body.

Description

SOLAR COLLECTOR MODULE AND SYSTEM

The present invention relates to a solar heat collector and a solar heat collecting system using the same, and more particularly, a protection means, a heat exchanger, and a blower are provided to block the heat of the sun or to cool the working fluid when the heat is not required without hindering the heat collection. The present invention relates to a solar collector which can prevent overheating, protects its internal composition from sand, and can be used in an extreme environment, and has a high durability.

Solar energy is an unlimited energy source, and it can be said that the collector which collects this energy as the energy which is easy to use is a basic structure for using the solar energy efficiently.

Collectors have been proposed in various forms such as flat plate type, single tube type and double tube type.

As a method for increasing the efficiency of the collector, an apparatus using a vacuum technology is used to prevent the incident energy from being discharged to the outside, and a heat pipe, which is a high efficiency heating element, is proposed to facilitate the transfer. .

The device as described above is called a vacuum tube solar collector.

Figure 1 shows the vacuum tube solar collector.

The vacuum tube-type solar collector shown in FIG. 1 is a glass tube 4 maintained in a vacuum state, a heat absorbing plate 3 for collecting solar heat provided in the glass tube 4, and heat from the absorbing plate 3. Vacuum tube-shaped heat collecting part 5 including a heat pipe 2, which is a high efficiency heat transfer element for receiving heat and transferring heat, and a manifold 1 through which a heat medium in which heat exchange is performed with the condensation part of the heat pipe 2 flows. (Manifold) is formed.

On the other hand, the heat pipe is also referred to as a heat pipe, the working fluid is sealed in the space, when the heat pipe is heated, the working fluid inside the evaporation is moved to the side (upper side) where the manifold is located, the heat exchange, After the heat dissipation process in the region, the working fluid is moved back to its original position (lower side).

However, the solar collector may be installed in various regions, and may be overheated more than necessary in a region where solar heat is very strong, and in order to prevent this, a heat exchange means in which a heat exchange medium, such as water, flows under the solar collector is more preferable. A method of formation has been proposed.

That is, the heat exchange means prevents overheating by circulating a heat exchange medium therein to exchange heat with the vacuum solar collector.

However, in order to drive the heat exchange means, a separate electric power is required for driving the heat exchange medium and controlling the temperature, and the heat exchange medium for preventing overheating is discharged as waste heat, which wastes energy.

On the other hand, when a sand storm is formed in an area such as a desert, the heat collecting part may be damaged by the sand and the like, and a method for protecting the sand is required.

In addition, when the sand is attached to the surface of the vacuum tube for a long time, the sand is solidified and is not easy to remove, there is a need to wash the surface to remove the attached sand.

The present invention has been made to solve the problems described above, the object of the present invention is provided with a first protection means that can block the solar heat manually or automatically by the user's operation can prevent overheating by solar heat And a second protection means for blocking the rear surface to protect the solar collector from external elements such as sand, wind, etc. together with the first protection means, and to improve the durability of the solar collector and the solar collector system using the same. To provide.

In addition, an object of the present invention is a simple structure for forming a bypass line including a heat exchanger and a blower in the connection line, solar heat that can prevent the problem due to overheating by cooling the working fluid by heat exchange with air It is to provide a collector and a solar heat collection system using the same.

In addition, the object of the present invention is that the configuration of the first protective means (control the degree of blocking) and the blower that is operated to prevent overheating is driven by the solar cell is not wasted electricity, and can stably collect solar energy It is to provide a solar collector and a solar collector system using the same.

The solar collector 1000 of the present invention includes a solar collector 1000 including a collector 100 for collecting solar heat, wherein the solar collector 1000 is capable of blocking a front surface of the solar collector of which solar heat is collected. It characterized in that the first protection means 300 is further provided.

At this time, the solar collector 1000 is characterized in that the length of the first protective means 300 in the longitudinal direction of the heat collecting portion 100.

In addition, the first protective means 300 is formed by including a blocking film 310, a blocking film fixing part 320 is formed with an adjusting part 330 to fix the blocking film 310 and to adjust the degree of blocking. The blocking film 310 is characterized in that formed of a material capable of blocking the sun's heat.

In addition, the first protective means 300 is further provided with a guide portion 340 for guiding the movement of the blocking film 310 on both sides of the blocking film 310, and fixing the blocking film 310. do.

In addition, the blocking film fixing part 320 is characterized in that the solar cell collector 1000 is blocked from the lower side of the heat collecting part 100.

In addition, the guide part 340 is spaced a predetermined distance in the longitudinal direction is formed a plurality of fixing holes 341, the blocking film fixing part 320 is provided on the lower side of the first body 321, the first body It is characterized in that it comprises a first rotary center shaft 322 is provided inside the 321, the blocking film 310 is wound on the outer peripheral surface, and the control unit 330 connected to one side of the blocking film (310).

In addition, the adjusting part 330 is provided on one side of the blocking film 310, and is connected to the rotary knob 326, and the handle 326 therein and is extended to both sides by the rotation of the handle 326. Link 327 is provided, the end of the link 327 by the operation of the handle 326 is inserted into the fixing hole 341, characterized in that for adjusting the fixing position of the blocking film 310 do.

In addition, the fixing hole 341 is formed so that one side is open, the control unit 330 is protruded in both directions of the blocking film 310 on one side of the blocking film 310, the fixing hole 341 It is characterized in that the locking portion 328 to be locked is formed.

In addition, the solar collector 1000 is formed such that the blocking film 310 has a predetermined height and is rotated about the lower side of the heat collecting part 100 to block a predetermined lower area of the heat collecting part 100. It is characterized by.

In addition, the solar collector 1000 is characterized in that the plate-shaped second protection means 400 for shielding the rear surface of the solar collector is formed, the second protection means 400 is formed of an aluminum alloy The second protective means 400 is characterized in that the coating layer is further formed so that the solar heat is reflected on the side where the heat collecting portion 100 is formed.

In addition, the guide portion 340 is characterized in that formed integrally with the second protective means (400).

On the other hand, the solar heat collecting system 10000 of the present invention includes a solar heat collector 1000 as described above; A storage unit 2000 in which working fluid is stored; And a connection line 3000 that connects the storage unit 2000 and the manifold 200 to collect individual rows of the heat collecting unit 100 in a module unit. Characterized in that it comprises a.

In addition, the solar heat collecting system 10000 includes a bypass line 3100 connected to the connection line 3000 for transferring the working fluid from the manifold 200 to the storage unit 2000; A control valve 3101 for controlling the transfer of the working fluid to the bypass line 3100; A heat exchanger 3110 provided in the bypass line 3100 and cooling the internal working fluid by external air; A blower 3120 for blowing air to the heat exchanger 3110; And a controller 5000; It characterized in that it further comprises.

At this time, the control unit 5000 is characterized in that for controlling the control valve 3101 to open and close the bypass line 3100 selectively in accordance with the temperature of the working fluid in the manifold 200.

In addition, the solar heat collecting system 10000 is characterized by being provided with a photovoltaic cell for power generation (4000) adjacent to the solar heat collector (1000).

In addition, the blower 3120 is driven by the photovoltaic cell 4000, and the driving means 350 of the first protection means 300 is driven by the photovoltaic cell 4000. It is done.

Accordingly, the solar collector of the present invention and the solar collector system using the same are provided with first protection means that can block solar heat manually or automatically by a user's operation to prevent overheating by solar heat, and to block the rear surface. A second protective means is provided to protect the solar collector from external elements such as sand, wind, etc. together with the first protective means, and has an advantage of increasing durability.

In addition, the solar collector of the present invention and the solar collector system using the same have a simple structure in which a bypass line including a heat exchanger and a blower is formed in the connection line. There is an advantage that can be reliably prevented.

In addition, the solar heat collector of the present invention and the solar heat collecting system using the same do not waste electricity by stably controlling the blocking degree of the first protection means and allowing the operation of the blower to be driven by the solar cell, which can stably collect solar energy. There is an advantage.

Hereinafter, the solar collector 1000 having the characteristics as described above will be described in detail with reference to the accompanying drawings.

2 and 3 are perspective views showing a solar collector 1000 according to the present invention, respectively, FIGS. 4 and 5 are exploded perspective views and a front view of the solar collector 1000 according to the present invention. FIGS. 6 and 7 Is a perspective view and an exploded cross-sectional view showing a solar collector 1000 according to the present invention, Figures 8 and 9 is another perspective view showing another solar collector according to the present invention, respectively.

The solar collector 1000 of the present invention is a means including a collector 100 for collecting solar heat.

In the drawing, the heat collecting part 100 shows the heat collecting plate 120 and the heat pipe 130 having a vacuum tube type heat collecting part 100 provided inside the vacuum glass tube 110, but the solar heat collector 1000 according to the present invention. The present invention is not limited thereto, and may be applicable to the shape of the heat collecting part 100 in various forms such as a flat plate type and a double vacuum tube type.

Hereinafter, the vacuum and string solar collector 1000 illustrated in the drawings will be described.

The solar collector 1000 has a heat collecting part 100 and a manifold 200 in which heat is exchanged with heat collected from the heat collecting part 100 and first protection means 300 for blocking a front surface of the heat collecting part 100. It includes.

The heat collecting part 100 is formed including a heat collecting plate 120 for collecting solar heat, and a pipe collecting heat of the heat collecting plate 120.

The vacuum glass tube 110 is a basic body constituting the heat collecting part 100, and the heat collecting plate 120 and the heat pipe 130 are provided therein, and the inside of the vacuum glass tube 110 is maintained in a vacuum to the inside of the vacuum glass tube 110. The collected heat is prevented from being discharged to the outside and protects the internal heat collecting plate 120 and the heat pipe 130.

The heat collecting plate 120 is configured to collect solar heat by being provided in a plate shape inside the vacuum glass tube 110, and the heat pipe 130 is formed long in the vacuum glass tube 110 in the longitudinal direction to be disposed therein. As a working fluid is encapsulated, heat collected through the heat collecting plate 120 is transferred to the manifold 200.

In the drawing, the heat collecting part 100 has an example in which the heat pipe 130 is formed long in the center in the longitudinal direction, and the heat collecting plate 120 is formed in a wing shape on both sides of the heat pipe 130. The present invention is not limited thereto, and the heat collecting plate 120 and the heat pipe 130 may be separately manufactured and formed adjacent to each other if the heat pipe 130 is capable of receiving heat from the heat collecting plate 120 effectively. Do.

That is, the heat collecting plate 120 of the heat collecting unit 100 is positioned so that solar light is incident, and the heat collected through the heat collecting plate 120 is transferred to the upper manifold through a working fluid inside the heat pipe 130. 200, the working fluid is heat-exchanged with the heat medium inside the manifold 200.

However, the heat collecting part 100 may generate overheating in an environment in which solar heat is strongly radiated, and a separate heat exchanger is required to prevent the overheating.

Solar collector 1000 of the present invention is provided with a first protection means 300 does not require a separate heat exchanger as described above, there is no heat to be heat exchanged can be significantly reduced energy wasted.

In more detail, the first protective means 300 is a means capable of blocking the front surface of the solar heat collector is collected to block the solar heat, the length may be adjusted.

The first protective means 300 is a blocking film fixing part 320 is formed with an adjusting part 330 for fixing the blocking film 310, the blocking film 310 and adjusting the blocking degree of the heat collecting part 100. It is formed to include.

The first protective means 300 is fixed to have the same height in the width direction of the entire heat collector 1000 by moving the blocking film 310 in the vertical direction of the heat collecting part 100 in the longitudinal direction.

When the first protective means 300 is moved in the horizontal direction and only a part of the vacuum glass tube 110 forming the heat collecting part 100 is blocked, the vacuum glass tube is not blocked by the first protective means 300. Since the problem due to the conventional overheating 110 may continue to occur, the solar collector 1000 of the present invention may have the first protective means 300 extending in the longitudinal direction of the vacuum glass tube 110 (in the drawing. Downward direction) is formed to adjust the length.

At this time, the blocking film 310 should be made of a material capable of blocking the sun heat to effectively prevent problems caused by overheating, for example, 100% acrylic yarn fabric, nylon (nylon), polyester (polyester) and fibish (PVC) ) Composites, and the like.

In addition, by adjusting the material of the blocking film 310 according to the environment in which the solar collector 1000 of the present invention is located, the degree of light blocking of the blocking film 310 may be adjusted.

In the solar collector 1000 of the present invention, the first protective means 300 may be formed in various forms, and specific examples will be described with reference to the drawings, and the present invention is not limited thereto.

First, in the solar collector 1000 of the present invention illustrated in FIG. 2, the barrier layer fixing part 320 is formed on the manifold 200, so that the barrier layer 310 is unfolded to lower the collector portion 100. An example formed to block is shown.

2 illustrates a first rotation center shaft 322 formed on the outer circumferential surface of the blocking membrane fixing part 320, and the first rotation center shaft 322 and the blocking film 310. The first body 321 included in the included is formed, the control unit 330 for adjusting the degree of blocking is connected to the first rotation center axis 322 is shown an example to be arbitrarily manually adjusted by the user. .

3 is further provided with a guide part 340 for guiding the movement of the blocking film 310 on both sides of the blocking film 310, and fixing the blocking film 310, and forming the blocking film fixing part 320. An example in which the driving unit 350 is connected to the first rotation center shaft 322 and can be automatically operated is illustrated.

Even in the form shown in FIG. 3, the user may manually operate the knob by rotating the handle instead of the driving means 350.

When the driving means 350 is formed, the degree of blocking of the blocking film 310 may be automatically controlled. The blocking film 310 may be controlled using the intensity of sunlight or the heat medium temperature of the manifold 200. The heat collecting unit 100 may be blocked or opened, and the degree of blocking may be adjusted.

In more detail, when the measured intensity of sunlight is above a certain value, when the temperature of the heat medium is above a certain value, or when it is determined that it is overheated by comparing the measured intensity of sunlight with the temperature value of the heat medium, the blocking film 310 is automatically ) To block the heat collecting part 100, and the degree of blocking is adjusted according to a specific value.

In this case, the intensity of the sunlight may be a sensor for measuring the amount of solar incident, the temperature of the heat medium may be a sensor for measuring the temperature inside the tank (not shown) in which the manifold 200 or the heat medium is stored. In the case of the automatic control, the sensor and the like may be provided, and the barrier layer 310 may be operated through an appropriate algorithm using the values measured by the respective sensors.

The guide part 340 guides the movement of the blocking film 310 at both sides of the blocking film 310, and prevents the blocking film 310 from being moved by wind or the like by fixing the blocking film 310, and the day after tomorrow. It protects the heat collecting portion 100 more securely from foreign substances such as.

In the form shown in FIG. 3, the adjuster 330 is not directly shown in the drawing, but is a means for electrically controlling the operation of the driving means 350.

In the solar collector 1000 of the present invention illustrated in FIGS. 4 to 7, the first protection means 300 is the lower side of the solar collector 1000 (the side where the manifold 200 is not formed), and the collector 100 is ) Is connected to the configuration for fixing the) is shown an example in which the blocking film 310 is moved upward and blocked.

When the blocking film fixing part 320 is formed at the lower side of the solar heat collector 1000 and is blocked from the lower side of the heat collecting part 100, even when only a certain area is blocked, the inside of the heat pipe 130 is operated. The fluid can be shut off.

In general, the working fluid inside the heat pipe 130 is positioned below by gravity, and when vaporized by the heat collection, the working fluid moves to the upper manifold 200 to be heat-exchanged, so that the solar collector 1000 of the present invention The blocking film 310 can prevent the overheating more effectively by intensively blocking the portion where the working fluid is located below.

The solar collector 1000 of the present invention may further include a second protective means 400 for blocking the rear surface of the heat collecting part 100 together with the first protective means 300.

The second protective means 400 is a configuration for protecting the internal configuration from sand storms and the like by shielding the rear surface of the heat collecting portion 100, it is preferably formed of a durable metal, in particular, aluminum alloy.

In the case of the solar collector 1000 that requires the reflector, the second protective means 400 may be formed by coating a side of an aluminum alloy forming the second protective means 400 to form a coating layer. ) Can also be used for the purpose of the reflector.

In addition, the second protection means 400 may be formed integrally with the guide portion 340, may be formed by bending the plate-shaped member forming the second protection means (400).

In the solar collector 1000 of the present invention, a rear surface of the solar collector 1000 is blocked by the second protection means 400, a side surface of the solar collector 1000 by a guide part 340, and a front surface of the solar collector 1000. The protection means 300 is formed to be able to open and close to control the degree of blocking, and can effectively collect solar heat irrespective of the external environment, while also increasing durability.

4 and 5 have a plurality of fixing holes 341 formed at a predetermined distance from the guide part 340 in the longitudinal direction, and the blocking film fixing part 320 is provided at a lower side thereof. The main body 321, the first rotation center axis 322 provided inside the first body 321 and wound around the outer circumferential surface, and an adjusting unit 330 connected to one side of the blocking film 310. It is configured to include.

At this time, the control unit 330 is provided on one side of the blocking film 310, and is connected to the rotary handle 326, and the handle 326 therein and extends to both sides by the rotation of the handle 326. A link 327 that is movable is provided, and an end of the link 327 is inserted into the fixing hole 341 by the manipulation of the handle 326 so that the blocking film 310 may adjust the fixing position.

4 and 5 illustrate that the link 327 is inserted inward by rotating the handle 326 when the blocking layer 310 moves up and down, and rotates the handle 326 at a position to be fixed. Thus, when the link 327 protrudes to both sides, an example in which the end of the link 327 is inserted into the fixing hole 341 is illustrated to be fixed.

In this case, the handle 326 is preferably fixed to the blocking film 310 by rotating when a force of a predetermined force or more is applied to increase the fixing force.

The blocking film fixing part 320 and the adjusting part 330 may be implemented in various ways as long as the blocking film 310 can be fixed by moving the blocking film 310 from the lower side even in the exception using the handle 326 and the link 327. .

6 and 7, the first main body 321 having the first rotational center shaft 322 is not formed with the manifold 200 as shown in FIGS. 4 and 5. Is formed on the lower side, the second rotation center shaft 324 is connected to the connecting means 325 also on the upper side, and the second body 323 is connected to the driving means 350 is shown as an example, the guide portion The blocking film 310 is connected to the second rotation center shaft 324 by the connecting means 325 and rotated by the driving means 350 connected to the second rotation center shaft 324. The degree of blocking of the blocking film 310 is adjusted.

In FIG. 6, only the first protection means 300 of the solar collector 1000 of the present invention is illustrated, and FIG. 7 illustrates a lower side surface thereof, and the blocking layer 310 is a central axis of rotation of the first body 321 ( 322, it may be moved upward or downward by rotation of the upper second rotational center shaft 324 although not shown.

At this time, the adjusting unit 330 is a means for electrically controlling the operation of the driving means 350.

8 and 9 are another perspective view showing a solar collector 1000 according to the present invention, respectively, in the form shown in FIG. 8 in which a predetermined upper region of the fixing hole 341 formed in the guide part 340 is opened. The first body 321 is formed so that the first rotation center axis 322 is formed is formed on the lower side of the manifold 200 is not formed as shown in Figures 4 and 5, the adjustment The part 330 shows an example in which a locking part 328 protruding in both directions of the blocking film 310 is formed at one side of the blocking film 310, and is fixed to the fixing hole 341.

That is, the user is wound around the locking portion 328 and the first rotational center shaft 322 as needed to pull the blocking film 310 located inside the first body to the upper side, and then the locking portion 328 By fixing to the fixing hole 341, the first protection means 300 blocks a predetermined region of the heat collecting part 100.

8 illustrates an example in which the fixing hole 341 is formed to protrude toward one side of the guide part 340, but the fixing hole 341 may be formed inside a predetermined area of the guide part 340. It's okay.

In the solar collector 1000 of the present invention illustrated in FIG. 9, the blocking film 310 is formed to have a predetermined height, and is rotated about the lower side of the collector 100 to be fixed at a lower side of the collector 100. An example is shown to block the area.

The height of the blocking film 310 shown in FIG. 9 may be variously formed according to the working fluid enclosed in the heat pipe 130. The shape shown in FIG. 9 has a fixed height of the blocking film 310. Therefore, the heat collecting unit 100 may not be blocked or may be blocked only by the height at which the blocking film 310 is formed.

In the drawing, when the blocking film 310 does not block the heat collecting part 100, the blocking film 310 is fixed at a position rotated by 180 ° in a counterclockwise direction based on the position of blocking the heat collecting part 100. Although one example is illustrated, the blocking layer 310 may be moved and fixed to a position rotated 270 ° counterclockwise from the reference position so as to contact the bottom surface of the collector 1000.

As shown in FIG. 9, the height of the blocking layer 310 may block only a predetermined region of the height of the heat collecting part 100, and may block the whole.

FIG. 9 illustrates an example in which the fixing hole 341 is formed to be open at a predetermined area to the front side.

On the other hand, according to the solar heat collecting system 10000 of the present invention, the first protective means 300 and the second protective means 400 are formed by using the solar heat collector 1000 as described above, and thus, the solar heat collecting system 10000 may be overheated with a low energy. There is an advantage to increase the durability by preventing and protecting the internal configuration from sand storms.

The solar heat collecting system 1000 is a storage unit 2000; And a connection line 3000; It is formed to include.

The storage unit 2000 is a space in which the working fluid is stored, and the working fluid is supplied into the manifold 200 by the connection line 3000, and heat exchanged with the heat medium, and then again the connection line 3000. Is moved to the storage unit 20000.

The working fluid may be used for heating and hot water, and a separate circulation line 3200 for heating may be formed in the storage part 2000 to be heated by a high temperature working fluid.

In addition, the storage unit 2000 may be formed with a hot water supply line 3300 for supplying hot water to supply hot water.

At this time, the circulation line 3200 and the hot water supply line 3300 may be added with a heating means for auxiliary heating of the working fluid.

In the solar heat collecting system 10000 of the present invention, the circulation line 3200 and the hot water supply line 3300 may be formed in various ways.

Meanwhile, the solar heat collecting system 10000 of the present invention has a bypass line connected to the connection line 3000 which transfers the working fluid from the manifold 200 to the storage unit 2000 in order to reliably prevent overheating. 3100); A control valve 3101 for controlling the transfer of the working fluid to the bypass line 3100; A heat exchanger 3110 provided in the bypass line 3100 and cooling the internal working fluid by external air; A blower 3120 for blowing air to the heat exchanger 3110; And a controller 5000; It may further include.

The bypass line 3100 is formed in the connection line 3000 that transfers the working fluid from the manifold 200 to the storage unit 2000 to form a separate flow line.

The control valve 3101 is formed between the bypass line 3100 in the connection line 3000 so that the working fluid is moved as it is along the connection line 3000 (see FIG. 11A). ) Is a means for determining whether to move along the bypass line 3100 and flow into the connection line 3000 (see flow in FIG. 11 (b)).

At this time, the bypass line 3100 is provided with a heat exchanger 3110 and a blower 3120 for cooling the working fluid.

The heat exchanger 3110 may use various structures in which a working fluid flows therein and heat exchange with external air may be performed.

For example, a plurality of tubes may be formed to form a flow path through which the working fluid may flow, and fins may be interposed between the tubes to increase contact area with air to improve heat exchange performance.

The blower 3200 is a means for cooling the working fluid more quickly and efficiently by blowing air to the heat exchanger 3110 side.

The control unit 5000 is a means for controlling the operation of the control valve 3101 and the blower 3200, and FIG. 10 shows that the control unit 5000 controls the operation of the control valve 3101 and the blower 3200. Rather, the example is formed to control the operation of the driving means 350 of the first protection means 300 to control the degree of blocking of the first protection means 300.

The control unit 5000 controls the control valve 3101 to allow the heat exchanger 3110 and the blower 3120 to cool by grasping the degree of overheating, and at this time, the inside of the manifold 200 The bypass line 3100 may be selectively opened and closed by controlling the control valve 3101 according to the temperature of the working fluid.

At this time, the control unit 5000 may control the overall configuration of the solar heat collecting system 10000 of the present invention.

In addition, the solar heat collecting system 10000 of the present invention, as shown in Figure 12, the connection line 3000 and the heated working fluid for heating the working fluid is circulated with the heat medium of the solar collector 1000, the heating fluid Since the working fluid must be circulated in each of the circulation lines 3200 used, the first circulation pump 3010 and the second circulation pump 3210 are added to the circulation line 3200.

In the solar heat collecting system 1000 of the present invention, the first circulation pump 3010 and the second circulation pump 3210 are provided in the connection line 3000 and the circulation line 3200, respectively. As an example, it may be manufactured integrally with another valve configuration, and an example of each one formed in FIG. 12 is illustrated.

At this time, the solar heat collecting system 10000 of the present invention may be provided with a photovoltaic cell 4000 for power generation adjacent to the solar heat collector 1000.

In the solar heat collecting system 10000 of the present invention, the first protection means 300 may be manually operated, but a means requiring power may be used, and the blower 312 may also require power to be driven. .

The photovoltaic cell 4000 is a means for supplying the power necessary for this, and generates power adjacent to the solar collector 1000.

In addition, the photovoltaic cell 4000 may be used as a driving power source of the first circulation pump 3010 and the second circulation pump 3210 circulating a working fluid to maintain the solar heat collecting system 10000.

The solar heat collecting system 10000 of the present invention may be used as a power source of other components required for driving the system, in addition to the above-described configuration of the solar cell 4000.

That is, the solar heat collecting system 10000 of the present invention uses only minimal energy for cooling, and this energy can also be produced by itself using the photovoltaic cell 4000 so that electricity is not wasted and stable solar energy is collected. There is an advantage to this.

The present invention is not limited to the above-described embodiments, and the scope of application is not limited, and various modifications can be made without departing from the gist of the present invention as claimed in the claims.

1 is a view showing a conventional vacuum tube solar collector module.

2 and 3 are a perspective view showing a solar collector according to the present invention, respectively.

4 and 5 are an exploded perspective view, and a front view showing a solar collector according to the present invention.

6 and 7 are a perspective view, and an exploded cross-sectional view showing a solar collector according to the present invention.

8 and 9 are each another perspective view showing a solar collector according to the present invention.

10 is a schematic view showing a solar heat collecting system according to the present invention.

11 is a view showing the working fluid flow of the solar heat collecting system according to the present invention.

12 is another schematic view showing a solar heat collecting system according to the present invention.

DESCRIPTION OF REFERENCE NUMERALS

10000: Solar Collecting System

1000: solar collector

100: heat collecting part

110: vacuum glass tube 120: heat collecting plate

130: heat pipe

200: manifold

300: first protective means 310: blocking film

320: blocking film fixing portion 321: the first body

322: first axis of rotation 323: second body

324: second rotation center axis 325: connection means

326: handle 327: link

328: catching part

330: control unit

340: guide portion 341: fixing hole

350: driving means

400: second protective means

2000: storage

3000: connection line 3010: first circulation pump

3100: bypass line 3101: control valve

3110: heat exchanger 3120: blower

3200: circulation line 3210: second circulation pump

3300: hot water supply line

4000: solar cell

5000: control unit

Claims (22)

In the solar collector 1000 including a collector 100 for collecting solar heat, The solar collector 1000 is Further provided with a first protective means 300 that can block the front surface of the solar heat collector is collected heat, The first protective means 300 guides and fixes the movement of the barrier layer 310 and the barrier layer 310 at both sides of the barrier layer 310 and is spaced a predetermined distance in the longitudinal direction to form a plurality of fixing holes 341. Is provided with a guide portion 340, the blocking film fixing part 320 is installed to fix the blocking film 310 is the first body 321 provided on one side in the longitudinal direction of the heat collecting part 100, the first 1 is provided inside the main body 321 and the first rotation center axis 322 is wound around the outer peripheral surface 322, and the other side in the longitudinal direction of the heat collecting part 100 is blocked degree of the blocking film 310 Solar collector, characterized in that formed by including a control unit for adjusting the 330. delete delete delete delete The method of claim 1, The shielding membrane fixing part 320 is a solar collector, characterized in that to be blocked from the lower side of the collector 100 of the solar collector (1000). delete The method of claim 1, The control unit 330 is provided on one side of the blocking film 310, and is connected to the rotary knob 326, and the handle 326 therein can be extended to both sides by the rotation of the handle 326. Link 327 is provided, the end of the link 327 by the operation of the handle 326 is inserted into the fixing hole 341, the solar heat, characterized in that for adjusting the fixing position of the blocking film 310 Collector. The method of claim 1, The fixing hole 341 is formed so that one side is opened, The control unit 330 is protruding in both directions of the blocking film 310 on one side of the blocking film 310, the solar heat, characterized in that the locking portion 328 is fixed to the fixing hole 341 is formed Collector. delete The method of claim 1, The solar collector 1000 is Solar collector, characterized in that the plate-shaped second protection means for shielding the back of the solar collector (400) is formed. The method of claim 11, The second protective means 400 is a solar collector, characterized in that formed of aluminum alloy. The method of claim 12, The second protective means 400 is a solar collector, characterized in that the coating layer is further formed to reflect the solar heat on the side where the heat collecting portion (100) is formed. The method of claim 11, The guide unit 340 is a solar collector, characterized in that formed integrally with the second protective means (400). A solar collector (1000) according to any one of claims 1, 6, 8, 9, and 11 to 14 ; A storage unit 2000 in which working fluid is stored; A connection line 3000 connecting the manifold 200 to collect individual rows of the storage unit 2000 and the heat collecting unit 100 in a module unit; And And a first circulation pump (3010) provided in the connection line (3000) to circulate the working fluid. The method of claim 15, The solar heat collecting system 10000 A bypass line 3100 connected to the connection line 3000 for transferring the working fluid from the manifold 200 to the storage 2000; A control valve 3101 for controlling the transfer of the working fluid to the bypass line 3100; A heat exchanger 3110 provided in the bypass line 3100 and cooling the internal working fluid by external air; A blower 3120 for blowing air to the heat exchanger 3110; And a controller 5000; Solar heat collection system, characterized in that it further comprises. The method of claim 16, The control unit 5000 controls the control valve (3101) to open and close the bypass line (3100) selectively in accordance with the temperature of the working fluid in the manifold (200). The method of claim 17, The solar heat collecting system 10000 includes a second circulation pump 3210 which circulates the heated working fluid in the storage unit 2000 and is provided in the circulation line 3200 and the circulation line 3200 to circulate the working fluid. Solar heat collection system, characterized in that is further provided. The method of claim 18, The solar heat collecting system (10000) is a solar heat collecting system, characterized in that is provided with a photovoltaic (4000) for power generation adjacent to the solar collector (1000). The method of claim 19, The blower (3120) is a solar heat collection system, characterized in that driven by the solar cell (4000). The method of claim 19, The driving means 350 of the first protection means 300 is driven by the photovoltaic cell (4000). The method of claim 19, The first circulation pump (3010) and the second circulation pump (3210) is a solar heat collection system, characterized in that driven by the solar cell (4000).

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