KR100950898B1 - Transformational protection appliance of a solar cell to be inslalled a heat transfer device - Google Patents

Abstract

PURPOSE: A device for preventing transformation of a solar battery in which a heat exchanger is provided to prevent the deformation of a module by a thermal conduction difference. CONSTITUTION: A device for preventing transformation of a solar battery comprises a heat exchanger(10). An inlet port and outlet port are installed in the top and bottom of a metal plate(11) of the heat exchanger. The liquid for the heat exchange flows in through the inlet port and outlet port. A cap opens and closes the inlet port and outlet port. A fixture, in which a friction damper is formed in the inner side, is inserted into inlet port and outlet port.

Description

Transformational protection Appliance of a solar cell to be inslalled a heat transfer device}

The present invention relates to a solar cell used by converting sunlight into electricity.

In general, a solar cell or photovoltaic cell refers to a device capable of converting solar energy into electrical energy.

In the conventional solar cell principle, when sunlight is absorbed, electrons and holes are generated inside the cell, and when the electrons and the electrons move freely and enter the electric field generated by PN junction, the electrons and the electrons are respectively N-type and It moves to a P-type semiconductor, where internal electrons flow into an external circuit through an electrode, and a current is generated.

On the other hand, the key factor to determine the performance of the solar cell is the conversion efficiency using the durability and semiconductor characteristics, that is how much can convert the solar energy entered into the solar energy into electrical energy is the key.

In the conventional solar cell, heat is emitted as light introduced from the sun is converted into electricity by a solar cell, and this heat inhibits the efficiency and the amount of power generation of the solar cell.

In other words, a solar cell that converts sunlight into electrical energy can obtain the maximum amount of electricity produced at an appropriate temperature range (25 ° C).

However, in the conventional solar cell, heat is generated as the light from the sun is converted into electricity by the solar cell, and this heat affects the solar cell, thereby causing the solar cell to deviate from the optimum temperature for converting the electricity of the solar cell. As a result, it has become a big factor in reducing the amount of electricity generated by the solar cell.

As described above, the conventional solar cell did not maintain the proper temperature due to the solar cell converting solar energy into electrical energy due to the effects of seasonal changes and ambient weather and the heat generated by converting solar light into electrical energy. Due to this, there is a problem that the power production efficiency of the solar cell is significantly lower than the installation price.

In order to solve the above problems, the present applicant has applied for a temperature maintaining method and apparatus (2009 Patent Application No. 10429) for obtaining the maximum efficiency of a solar cell converting solar energy into electrical energy.

In the above invention, the solar cell maintains the optimal temperature so that the solar cell can convert the solar energy into the electric energy as much as possible in the optimal state at the bottom of the solar cell. It relates to a method and a device installed.

That is, in the above invention, by installing a heat exchanger at the lower end of the solar cell installed in the solar cell, it was possible to maximize the efficiency of converting solar energy into electrical energy by maintaining the performance of the solar cell in an optimal state.

However, the present invention has a disadvantage that the manufacturing cost is difficult because it is difficult and difficult to make the flow path through which the heat exchange liquid flows.

In addition, the above invention has a problem that the deformation caused by the difference in the thermal conductivity of the solar cell and the heat exchanger.

That is, in the above invention, the solar cell is heated while heat is generated while the solar cell is operating, and at the same time, the module itself is deteriorated by the difference in the thermal conductivity of the solar cell and the heat exchanger to be cooled while absorbing the heated heat of the solar cell. There is a disadvantage that deformation such as bending occurs.

The present invention has been invented to solve the above problems, the purpose is to install a heat exchange device in the module consisting of a plurality of solar cells to convert the sunlight into electrical energy to prevent deformation due to heat have.

Another additional object of the present invention is to facilitate the spread of the heat exchange liquid throughout the module.

As a means to solve the above problems, a high thermal conductivity material is installed on the bottom of a solar cell in which a plurality of solar cells are installed, and a metal heat exchanger is installed at the bottom thereof to prevent deformation by heat. There is a number.

As a method for solving the additional means of the present invention, the module can be eliminated by providing a sheet with high thermal conductivity between the heat exchangers.

The present invention as described above is to maximize the efficiency of solar cells using solar light, the structure is simple and easy to manufacture, heat conduction by installing a plate heat exchanger made of metal on the bottom of the module Modification of the module due to the difference can be prevented.

In addition, the present invention is a useful invention that can be bonded between the module and the heat exchanger by using polyurethane, but the heat exchange is easy and the thickness of the module can be made to a minimum thickness by installing a fast thermal conductivity between the module and the heat exchanger.

In the temperature maintenance device for obtaining the maximum efficiency of the solar cell converting solar energy into electrical energy,

Glass (3) through which sunlight passes and protects the solar cell (2),

EVA film (4) to wrap and protect the entire solar cell (2)

A plurality of solar cells 2 for converting sunlight passing through the glass 3 and the EVA film 4 into electric power,

In the module (1) to which the PVF sheet (5) is attached to protect the solar cell (2) from various foreign substances such as moisture,

It is composed of a metal plate 11 at the lower end of the module 1, the bent portion 12 is formed at a predetermined interval therein to form a plurality of flow paths 13, the thermal conductivity on the upper side of the metal plate 11 Heat exchanger 10 having a high PVF sheet 14 so as to absorb high heat shrinkage and expansion,

The heat exchanger 10 is formed on the lower end of the module 1 to form a polyurethane 30 so as to be wrapped around the side part, and the polyurethane 30 is introduced between the module 1 and the heat exchanger 10 so that the module ( 1) and the heat exchanger 10 is attached to a thin thickness to be integrated.

The heat exchanger 10 is installed on the upper and lower sides of the metal plate 11, the inlet 15 and the outlet 16 through which the liquid for heat exchange is introduced or discharged to be fastened tightly by the cap 17, each inlet 15 and the outlet 16 is inserted into the fixture 19 is formed with a friction projection 18 on the inside and then fixed to be sealed by polyurethane, each of the fixture 19 is connected to a metal hose or pipe It is made by fastening the connector 20.

The heat exchanger 10 forms a flow path 32 by punching the inner side of the metal plate 11 to form the groove portion 31, but each flow path 32 has a high inlet side and a lower corresponding side to lower the locking step. (33) is formed so that the heat exchange liquid introduced at a constant pressure is caught by the catching jaw (33) and flows uniformly to each of the flow paths (32) to uniformly heat exchange the entire area of the module (1). It was made possible.

When described in detail by the accompanying drawings of the present invention as described above are as follows.

1 is a perspective view showing the overall schematic view showing the back of the module of the present invention, Figure 2 is a block diagram showing a state before attaching the heat exchanger to the module of the present invention, Figure 3 is a thermal bridge attached to the module of the present invention Figure 4 is a schematic block diagram showing the state, Figure 4 is an enlarged cross-sectional view of the main portion of the inlet for the inflow of the heat exchange liquid of the present invention, Figure 5a shows another embodiment of the flow path of the heat exchanger flows through the heat exchange liquid of the present invention 5B is a schematic side cross-sectional block diagram of FIG. 5 of the present invention, and FIG. 6 is a block diagram showing a conventional solar cell.

The present invention focuses on the invention of the method for maintaining the temperature and the apparatus (2009 Patent Application No. 10429) for obtaining the maximum efficiency of the solar cell converting the solar energy to the applicant's application to electrical energy.

When sunlight shines on the solar cell, the solar energy reaches the solar cell 2 through the glass 3 and the EVA film 4 installed on the upper side of the solar cell 6, and the solar energy is transmitted to the solar cell 2. Is converted into electrical energy.

As described above, in the process of converting solar energy into electrical energy by the solar cell 2, heat is essentially generated in the solar cell 2, and as the heat is generated in the solar cell 2, the solar cell is optimal. Since the temperature is out of the proper temperature (25 ℃) of the efficiency is reduced.

As described above, when the solar cell 2 installed in the solar cell module 101 is out of the selected proper temperature, the thermal sensor 102 installed on one side of the solar cell detects this.

When the heat sensor 102 detects heat as described above, the signal is transmitted to the controller 104 and the controller 104 receives the signal of the heat sensor () to operate the pump 103.

When the pump 103 is operated as described above, the heat exchanger 10 installed at the lower end of the solar cell operates to cool the entire solar cell.

That is, when the pump 103 is operated to operate the heat exchanger, the liquid for heat exchange flows along the pipe by the pump (), and the heat exchanger liquid is supplied to the heat exchanger installed at the lower end of the solar cell 2. Cooling the solar cell leads to optimal temperature with high efficiency when converting sunlight into electrical energy.

When the pump operates by receiving a signal from the sensor as described above, the heat exchange liquid flows into the inlet 15 of the metal plate 11 constituting the heat exchanger 10, and the heat exchange liquid flows into each flow path ( 13) to flow down.

In this way, the liquid for heat exchange flows into the flow path and comes into contact with the heated solar cell 2 to lower the temperature of the solar cell.

At this time, when expansion and contraction due to the temperature difference occurs between the module 1 heated by the solar cell 2 and the heat exchanger 10 cooled by the heat exchange liquid, the lower end of the solar cell and the heat exchanger 10 PVF sheets (5) 14 attached to the upper end of the absorbed by it will be able to prevent deformation such as the module 1 bent.

In the present invention, by using a metal plate in the heat exchanger, the flow path is formed by a simple punching operation on the metal plate, so that the production is simple and the working time can be shortened.

Meanwhile, as another embodiment of the present invention, as shown in FIGS. 5A and 5B, each of the flow paths 32 of the heat exchanger 10 has a high inlet side through which the heat exchange liquid flows and a lower side corresponding to the other side. 33) is formed, even though the liquid for heat exchange flows into the abnormal pressure by the pump, it hits the catching jaw 33 and flows to each of the flow paths 32 formed by the recess 31 so that it is uniform throughout the module. Heat exchange is possible.

1 is an overall schematic perspective view showing the back of the module of the present invention;

Figure 2 is a block diagram showing a state before attaching the heat exchanger to the module of the present invention

Figure 3 is a schematic block diagram showing a state in which the thermal bridge is attached to the module of the present invention

Figure 4 is an enlarged cross-sectional view of the main portion of the inlet in which the liquid for heat exchange of the present invention is introduced

Figure 5a is a block diagram showing another embodiment of the flow path of the heat exchanger in which the heat exchange liquid for the present invention flows

Figure 5b is a schematic side cross-sectional block diagram of the present invention Figure 5

6 is a block diagram showing a heat exchanger of a conventional solar cell

              ** Description of symbols for the main parts of the drawing **

1. Module 2. Cell

3. Glass 4. EVA Film

5. 14. PVF Sheet

10. Heat exchanger

11. Metal Plate 12. Bends

13.32.Euro 15.Inlet

16.Outlet 17.Cap

18. Friction projections 19. Fixtures 20. End connections

       31. Groove 33. Hanging jaw

Claims (3)

Glass (3) through which sunlight passes and protects the solar cell (2), EVA film (4) to wrap and protect the entire solar cell (2) A plurality of solar cells 2 for converting sunlight passing through the glass 3 and the EVA film 4 into electric power, A module (1) having a PVF sheet (5) attached to protect the solar cell (2) from various foreign matters such as moisture, It is composed of a metal plate 11 at the lower end of the module 1, the bent portion 12 is formed at a predetermined interval therein to form a plurality of flow paths 13, the thermal conductivity on the upper side of the metal plate 11 In the heat exchanger 10 in which the PVF sheet 14 is installed so as to absorb the high heat shrinkage and expansion, The heat exchanger 10 is installed on the upper and lower sides of the metal plate 11, the inlet 15 and the outlet 16 through which the liquid for heat exchange is introduced or discharged to be fastened tightly by the cap 17, each inlet 15 and the outlet 16 is inserted into the fixture 19 is formed with a friction projection 18 on the inside and then fixed to be sealed by polyurethane, each of the fixture 19 is connected to a metal hose or pipe By fastening the connector 20, The heat exchanger 10 is formed on the lower end of the module 1 to form a polyurethane 30 so as to be wrapped around the side part, and the polyurethane 30 is introduced between the module 1 and the heat exchanger 10 so that the module ( 1) and the heat exchanger 10 is a strain preventing device of a solar cell is installed, characterized in that the heat exchanger is characterized in that the unit is attached to a thin thickness. delete The method of claim 1, The heat exchanger 10 forms a flow path 32 by punching the inner side of the metal plate 11 to form the groove portion 31, but each flow path 32 has a high inlet side and a lower corresponding side to lower the locking step. (33) is formed so that the heat exchange liquid flowing into the high pressure is caught by the catching jaw 33 and flows uniformly to each flow path 32 to uniformly heat exchange the entire area of the module (1). The strain preventing device of the solar cell is installed, characterized in that the heat exchanger.

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