KR100983083B1 - The method to convert solar energy to electric energy and thereof apparatus - Google Patents

Abstract

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

An object of the present invention is to increase the efficiency of a module consisting of a plurality of solar cells for converting sunlight into electrical energy.

 The present invention can be solved by installing a heat exchanger to maintain an optimum temperature in a solar cell module consisting of a cell that converts sunlight into electrical energy.

The present invention as described above is to maximize the efficiency of the solar cell using the solar light, the structure is simple and easy to manufacture, by installing a heat exchanger in the solar cell converting sunlight into electrical energy solar By maintaining the optimal temperature at which light can be converted to power, the power efficiency of the power is maximized.

Photovoltaic, solar cells. Electrical energy. Heat exchanger,

Description

Method of converting solar energy to electric energy and apparatus thereof

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.

Conventional solar cells may be classified into silicon solar cells and compound solar cells according to materials, and are divided into bulk and thin film types according to substrate types. Among them, bulk silicon solar cells may be polycrystalline and It is divided into single crystal silicon solar cell.

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.

In more detail, when light of a greater energy than the prohibition band is irradiated to a semiconductor junction region having a PN junction surface, electrons and holes are generated. As the electromotive force is generated by moving, the electrodes attached to the N-type semiconductor and the P-type semiconductor become negative electrodes and positive electrodes, and thus DC current can be taken.

In this way, solar cells are made of p-type and n-type semiconductors made of materials such as silicon, gallium arsenide, and cadmium sulfide.

At this time, since the electron moves to the n-type and the positive hole moves to the p-type part, current from the n-type to the p-type is generated through an external circuit.

On the other hand, the conventional solar cell is largely divided into two types, such as crystalline form and amorphous form.

Crystalline, which is made of high purity silicon single crystal, has been extended to 20 years with photoelectric conversion efficiency improved by 7-12% and lifespan increased by 50% over the past 10 years, but it is expensive because of high production cost.

On the other hand, amorphous silicon has only one tenth of the production cost than monocrystalline silicon, so it is inexpensive and has a disadvantage in that photoelectric conversion efficiency is much lower.

However, the outlook is very bright due to the active research and development to increase the photoelectron conversion rate of amorphous silicon.

As described above, the first generation crystalline solar cell uses silicon as the main raw material, and controls 90% or more of the photovoltaic power generation market, but the second generation generation is because the cost of power generation is 5-20 times higher than that of coal, oil, and gas. Technology is emerging as an alternative.

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

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.

The present invention is invented to solve the above problems, the object of the solar cell module consisting of a plurality of solar cells to convert the sunlight into electrical energy to produce the maximum power.

 An additional object of the present invention is to enable the solar cell to maintain a temperature at which power generation can be maximized.

Another additional object of the present invention is to further minimize the thickness of the solar cell module.

As a means for solving the above problems, the solar cell converting solar light into electrical energy can be solved by installing a heat exchanger to maintain the optimum temperature.

The heat exchanger described above can be configured to be water-cooled using liquid, so that the maximum heat can be exchanged so that the solar cell maintains the optimum temperature.

As a means for solving the above additional problem, the heat exchanger for cooling the solar cell and the solar cell may be integrated with the solar cell to minimize the thickness.

The present invention as described above is to maximize the efficiency of the solar cell using the solar light, the structure is simple and easy to manufacture, by installing a heat exchanger in the entire lower end of the solar cell is always optimal By maintaining the temperature it is possible to maintain the maximum efficiency that can be converted into sunlight power.

In addition, the present invention by installing a water-cooled heat exchanger in the entire lower end of the cell to remove the heat generated in the solar cell as soon as possible to maintain the cell at the optimum temperature state can maximize the power production efficiency of the cell It is.

In addition, the present invention enables the solar cell to maintain an optimal temperature in a short time by using a heat exchanger using a liquid, and the thickness of the module can be reduced by integrally forming a heat exchanger for cooling the cell into the module. Therefore, manufacturing cost can be reduced.

The temperature sensing step of sensing the temperature of the solar cell module for converting sunlight into electrical energy by the temperature sensor, and sending this temperature to the controller,

Control step of controlling the circulation rate of the liquid for heat exchange by controlling the on / off of the pump and the speed of the pump in response to the signal of the temperature sensor,

A heat exchange liquid circulation step of operating the pump by the controller to circulate the heat exchange liquid to the transfer pipe,

The heat exchange liquid supplied to the transfer pipe passes through the entire lower surface of the solar cell module, and each solar cell installed in the solar cell module maintains a temperature (25 ° C) that is most suitable for converting solar energy into electrical energy. Heat exchange step to exchange heat,

The heat exchange liquid exchanged by the solar cell is discharged, and the heat exchange liquid is discharged to the external storage tank, and is generated by heat generated by solar light into electrical energy or seasonal change. The temperature difference is exchanged with a heat exchanger to maintain the temperature at which the solar cell can obtain the maximum power output for converting solar energy into electrical energy.

In a first embodiment of the heat exchange method,

The bottom surface of the solar cell 22 may be waterproofed so that the solar cell 22 is exposed to the lower end of the PVF film 23 so that the solar cell 22 is directly in contact with the liquid for heat exchange which is moved from the heat exchanger 10.

In a second embodiment of the heat exchange method,

A PVF film 33 having a high thermal conductivity is installed on the bottom of the solar cell 32, and a heat exchanger 10 is installed at the lower end thereof so that the solar cell 32 is connected to a liquid for heat exchange of the heat exchanger 10. It is also possible to perform heat exchange by indirect contact.

Third embodiment

In the heat exchange step, the temperature of the liquid for heat exchange is discharged to 40-60 ° C. by storing the heat exchange liquid quickly or slowly by the controller and the pump. It is also preferable to add.

Fourth embodiment

One step may be added so that the heat exchange liquid collected in the storage tank of the third embodiment can be used for heating through a separate pipe line.

Looking at the configuration of the present invention.

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,

PVF film 5 to protect the solar cell 2 from various foreign matters such as moisture,

The glass 3, the EVA film 4, the plurality of solar cells 2, and the PVF film 5 are laminated to the solar cell module 1 having the edges sealed on the frame 6. In

At the lower end of the solar cell module 1, the heat generated by the conversion of solar light into electrical energy or the temperature difference generated by the change of seasons is exchanged with a heat exchange liquid, so that the solar cell converts the sunlight into electrical energy. The heat exchanger 10 is installed to maintain the optimum temperature (25 ° C) for conversion.

The heat exchange device 10 is formed on the bottom surface of the solar cell module (1) by forming a concave-convex portion 24 at regular intervals to reinforce the strength, to protect the solar cell (2) 5,

Fastener 21 for protecting and fixing the solar cell 2 to the lower end of the PVF film (5),

The uneven portion formed between the lower end portion of the uneven portion 24 formed in the PVF film 5 and the fastener 21 and the inside of the frame 6 by the filler 26 is formed to protrude on the bottom surface of the PVF film 5 ( The flow path 25 is formed between the lower end of the 24 and the fastener 21 so that the heat exchange liquid flows to perform heat exchange with the heated solar cell 2 and at the same time the solar cell module and the heat exchange device It is made to be thin by manufacturing integrally.

The heat exchanger 10 is installed on the solar cell module 1 to check the temperature change of the solar cell (2),

Controller 14 for controlling the on / off and the speed of the pump 13 in response to the signal of the temperature sensor 11,

The pump 13 installed on the conveying pipe 12 for circulating the heat exchange liquid in the storage tank 20 by turning on / off by the controller 14 to adjust the speed

The signal sensed by the temperature sensor 11 is driven by the pump 14 by the controller 14 to circulate the heat exchange liquid in the storage tank 20 so that the heat exchange liquid contacts the lower end of the solar cell. The heat exchanger is intended to maintain the temperature at which the maximum efficiency can be obtained.

The storage tank 20 in which the heat exchange liquid is stored is provided by a cooling device 42 for cooling the heat exchange liquid.

Fifth Embodiment

In an embodiment of the heat exchanger 10,

On one side of the solar cell module 1, a temperature sensor 11 and a pump 13 for supplying a liquid for heat exchange are provided, and a fixed plate is formed on the entire lower end of the solar cell 2 constituting the solar cell module 1. 15) is installed, but one side of the fixing plate (15) connects the supply part (16) to which the heat exchange liquid is supplied, and on the other side is provided a discharge part (17) through which the heat exchange liquid is discharged. A plurality of diaphragms 19 are provided between the supplied supply portion 16 and the discharge portion from which the heat exchange liquid is discharged, so that a plurality of flow passages 18 are formed so that the heat exchange liquid flows along the flow passage. Do.

Referring to the embodiment when the heat exchange liquid heated by heat exchange in the present invention for heating.

Storage tank 20 in which the heat exchange liquid is heated in contact with the cell and heat exchanged,

Pipe line 50 for supplying the heat exchange liquid heated in the storage tank 20 to the room,

It is also possible to provide a water supply unit 52 for supplying a new heat exchange liquid as much as the heat exchange liquid discharged through the pipe line.

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

Figure 1 is a schematic perspective view of the main portion cutting the conventional solar cell, Figure 2 is a block diagram showing a heat exchange process of the solar cell of the present invention, Figure 3 is a schematic block diagram showing a heat exchanger of the present invention, Figure 4 Figure 5 is a schematic block cross-sectional view showing the interior of the solar cell of the present invention, Figure 5 is an enlarged cross-sectional view of the main portion of the flow path of the present invention, Figure 6 is an enlarged cross-sectional view of the main portion showing the state of the solar cell coupled to the heat exchanger, Figure 7 8 is an enlarged cross-sectional view showing an embodiment of an embodiment of the present invention in which a solar cell is coupled to a heat exchanger. FIG. Fig. 10 is a schematic side sectional view showing a coupling state of the heat exchange liquid of FIG. 8, and FIG. 11 is a schematic block diagram showing a storage tank of the heat exchange liquid of the present invention. It will be shown.

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 reaches 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.

When the solar cell 2 deviates from the proper temperature as shown in FIG. 3, the heat sensor 11 installed on one side of the solar cell 6 detects this.

When the heat sensor 11 detects heat as described above, the signal is transmitted to the controller 14 and the controller 14 receives the signal from the heat sensor 11 to operate the pump 13.

When the pump 13 is operated as described above, the heat exchanger 10 installed at the lower end of the solar cell 6 operates to cool the entire solar cell.

That is, when the pump 13 is operated and the heat exchanger 10 is operated, the heat exchange liquid flows along the pipe by the pump 13, and the heat exchange liquid is heat exchanged at the lower end of the solar cell 2. It is supplied to the device 10 to cool the solar cell to lead to the optimum optimum temperature of high efficiency when converting sunlight into electrical energy.

On the other hand, the liquid for heat exchange used in the present invention can be variously used as a liquid such as water or brain.

As such, when the solar cell 2 constituting the solar cell module 1 is cooled by the heat exchanger 10 to maintain an appropriate temperature, the solar cell 2 converts solar energy into electrical energy at an optimum temperature. The efficiency can be further improved because it can be converted to.

Meanwhile, when the pump 13 is operated by the heat sensor 11, the liquid for heat exchange is transported through a pipe and supplied to the supply part 16 of the fixed plate 15, and the supplied heat exchange liquid is fixed to the fixed plate 15. The heat of the heated solar cell 2 is absorbed and cooled while moving along the flow path 18 formed in the).

At this time, since the plurality of diaphragms 19 are formed on the fixed plate 15 up and down to constitute the flow path 18, the heat exchange liquid evenly moves the entire surface of the solar cell module while the solar cell module uses the solar energy as electrical energy. It is possible to maintain the optimum temperature for conversion to.

Then, as shown in FIG. 7, the waterproofing is performed on the lower end of the solar cell 22 that converts solar energy into electrical energy, and then the solar cell 22 directly contacts the liquid for heat exchange of the heat exchanger 10. This is to allow heat exchange.

In other words, by converting solar energy into electrical energy, the solar cell 22 generating heat can be in direct contact with the heat exchange liquid flowing in the heat exchanger 10, thereby achieving the fastest heat exchange. If you get out of the can be returned to the proper temperature as soon as possible to maintain.

6 shows a solar cell by attaching a fast heat transfer PVF film 33 to a lower end of a solar cell 32 that converts solar energy into electrical energy and allowing a liquid for heat exchange of the heat exchanger 10 to flow through the lower end of the solar cell 32. The cell 32 can be indirectly contacted with the heat exchange liquid of the heat exchange device 10 to protect the solar cell 32 from foreign matter contained in the heat exchange liquid.

In addition, the above method has the advantage of easy operation because it can be used as it is without going through a separate process.

As shown in FIGS. 4 and 5, the uneven portion 24 is formed in the PVF film 5 provided on the upper side of the channel 25, and the channel 25 is formed at the lower end of the uneven portion 24. As the wall is formed, it is possible to strongly reinforce the strength of the flow path due to heat expansion and pressure.

On the other hand, the present invention by installing a cooling device 42 for cooling the heat exchange liquid in the storage tank 20 for storing the heat exchange liquid, the heat exchange liquid is cooled to a lower temperature than the solar cell and then circulated The battery will maintain the optimum temperature.

That is, in summer, the heat exchange liquid stored in the storage tank 20 is cooled below the optimum temperature, and then circulated through the heat exchanger, so that the heat exchange liquid passes through the flow path and heat generated in the solar cell and the heat around the summer season. By heat exchange and cooling, the solar cell can be induced at the optimal temperature for converting solar energy into electrical energy.

On the other hand, as shown in Figure 11 when the heat exchange liquid heated by the heat exchange in the present invention as water may be used for the hot water or heating by installing another piping line in the storage tank 20.

At this time, if you want to obtain hot water of a constant temperature, the temperature of the water can be adjusted to 40-60 ℃ by adjusting the speedometer of the controller to allow the circulation rate of the heat exchange liquid transferred from the pump to circulate quickly or slowly.

In this way, the heat exchange liquid heated by the heat exchanger and stored in the storage tank 20 may be used for heating through another pipe line 50 installed in the storage tank 20, and when the heat exchange liquid is transferred for heating. In the storage tank, new heat exchange liquid is supplied to the storage tank 20 by the heat exchange liquid supply device 52.

1 is a perspective view schematically showing the cutting part of a conventional solar cell

Figure 2 is a block diagram showing a heat exchange process of the solar cell of the present invention

Figure 3 is a schematic block diagram showing a heat exchanger of the present invention

Figure 4 is a schematic block cross-sectional view showing the interior of the solar cell of the present invention

5 is an enlarged cross-sectional view of the main portion of the present invention flow path.

6 is an enlarged cross-sectional view showing main parts of the present invention in which the solar cell is coupled to a heat exchanger;

7 is an enlarged cross-sectional view showing main parts of an embodiment of the present invention in which a solar cell is coupled to a heat exchanger;

Figure 8 is a block diagram showing a circulation system diagram of the heat exchange liquid of the heat exchanger of the present invention

Figure 9 is a schematic separation perspective view showing a flow path of the heat exchange liquid of the heat exchange device of the present invention

Figure 10 is a schematic side cross-sectional view showing a coupling state of the eighth invention of the present invention

Figure 11 is a schematic block diagram showing a storage tank of the heat exchange liquid of the present invention

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

1. Solar Cell Module 2. 22. 32. Cell

10. Heat exchanger

11. Temperature sensing sensor 12. Pipe

13. Pump 14. Controller

15. Retaining Plate 16. Supply Section

17.Emission 18.25.Euro

19. Plate 20. Storage tank

21. Fasteners 23. 33. PVF film

24. Uneven portion 26. Filler

42. Cooling System 50. Piping Line

52. Water Supply

Claims (10)

The temperature of the solar cell module that converts sunlight into electrical energy is detected by the temperature sensor, the temperature sensing step of sending this temperature to the controller, and the operation of the pump by receiving the temperature sensor signal A control step for controlling, and a heat transfer liquid transfer step for supplying the heat exchange liquid to the transfer pipe by operating the pump by the controller, and a heat exchange liquid supplied to the transfer pipe pass through the entire lower surface of the solar cell module. When the solar cells installed in the module for the solar cell exchanges heat to maintain the temperature when converting solar energy into electrical energy, and the heat exchange liquid exchanged by the solar cell is discharged to collect to the external storage tank In the method for converting solar energy into electrical energy consisting of a liquid discharge step for heat exchange, In the heat exchange step, the bottom surface of the solar cell is waterproofed so that the solar cell is exposed to the flow path of the heat exchanger so that the solar cell is in direct contact with the heat exchanger liquid flowing in the heat exchanger to perform heat exchange. It is characterized in that the solar cell maintains a predetermined temperature when converting the solar energy into electrical energy by heat exchange method based on the heat difference generated by the heat generated while being converted into the electrical energy or the change of season. How to convert solar energy into electrical energy. Sunlight passes through the glass 3 to protect the solar cell 2, the EVA film 4 to cover and protect the entire solar cell 2, and to pass through the glass 3 and the EVA film 4 A plurality of solar cells 2 converting sunlight into electric power, and a PVF film 5 for protecting the solar cells 2 from various foreign substances such as moisture, glass 3, EVA film 4, and many Photovoltaic cell (1) and PVF film (5) by stacking the edges of the frame (6) and the solar cell module (1) and the solar cell module (1) at the bottom of the solar cell module (1) The heat exchanger is configured to maintain the temperature at which the solar cell converts solar energy into electrical energy by exchanging heat generated during the conversion or the temperature difference of the solar cell generated by the seasonal change with a heat exchange liquid. In the device for converting solar energy consisting of) into electrical energy, The heat exchange device 10 is formed on the bottom surface of the solar cell module (1) by forming a concave-convex portion 24 at regular intervals to reinforce the strength, to protect the solar cell (2) 5, Fastener 21 for protecting and fixing the solar cell 2 to the lower end of the PVF film (5), The uneven portion formed between the lower end portion of the uneven portion 24 formed in the PVF film 5 and the fastener 21 and the inside of the frame 6 by the filler 26 is formed to protrude on the bottom surface of the PVF film 5 ( A flow path 25 in which heat exchange liquid flows between the lower end of the 24 and the fastener 21 and heat exchanges with the heated solar cell 2, A temperature sensor 11 installed on the solar cell module to check a temperature change of the solar cell 2, Controller 14 for controlling the circulation rate of the liquid for heat exchange by adjusting the on / off of the pump 13 and the speed of the pump in response to the signal of the temperature sensor 11, A pump 13 installed on the conveying pipe 12 for circulating the heat exchange liquid in the storage tank 20, on / off and controlled by the controller 14; The signal sensed by the temperature sensor 11 is driven by the pump 14 by the controller 14 to circulate the heat exchange liquid in the storage tank 20 so that the heat exchange liquid contacts the lower end of the solar cell. A device for converting solar energy into electrical energy characterized by maintaining heat at a temperature at which maximum efficiency can be obtained by heat exchange. delete 3. The method of claim 2, Device for converting solar energy into electrical energy, characterized in that to form a concave-convex portion (24) at regular intervals in the PVF film (5) protecting the solar cell (2) to reinforce the strength of the flow path (25). 3. The method of claim 2, On one side of the solar cell module 1, a temperature sensor 11 and a pump 13 for supplying a heat exchange liquid are provided, and a fixed plate is provided on the entire lower end of the solar cell 2 constituting the solar cell module 1. (15) is installed, but one side of the fixing plate (15) connects the supply part (16) to which the heat exchange liquid is supplied, and on the other side is provided a discharge part (17) to discharge the heat exchange liquid, The diaphragm 19 is provided between the supply part 16 to which the gas is supplied and the discharge part from which the heat exchange liquid is discharged, so that the flow path 18 is formed so that the heat exchange liquid flows along the flow path. A device that converts solar energy into electrical energy. delete In the heat exchange step of claim 1, The solar cell is characterized in that the solar cell is heat exchanged by indirect contact with the heat exchange liquid of the heat exchanger by installing a fast thermal conductivity PVF film on the bottom of the cell and a heat exchanger at the bottom thereof. How to convert energy into electrical energy. The method of claim 1, The heat exchange step is characterized in that by controlling the flow rate of the heat exchange liquid by the controller and the pump for the heat exchange liquid, the temperature of the discharged heat exchange liquid is discharged to 40-60 ℃ to be stored in the storage tank How to convert solar energy into electrical energy. 3. The method of claim 2, A storage tank 20 in which the heat-exchange liquid is heated in contact with the solar cell, Pipe line 50 for supplying the heat exchange liquid heated to the storage tank 20 for heating, Apparatus for converting solar energy into electrical energy, characterized in that by installing a water supply unit 52 for supplying a new heat exchange liquid as much as the heat exchange liquid discharged through the pipe line (50). 3. The method of claim 2, The concave-convex portion 24 formed between the concave-convex portion 24 and the fastener 21 formed in the PVF film 5 and the filler 26 is filled in the entire interior of the frame 6 to protrude on the bottom surface of the PVF film 5. A flow path 25 is formed between the lower end portion of the cuff and the fastener 21 to allow heat exchange with the heated solar cell 2 so that the solar cell module and the heat exchanger are integrally formed. Device for converting solar energy into electrical energy, characterized in that the thickness of the solar cell module is configured thin.

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