JP6851432B2 - Cooling system for PV system - Google Patents

Description

The present invention relates to a cooling system for cooling a power generation element of a photovoltaic power generation system.

In recent years, efforts to tackle environmental problems have been actively carried out, and the utilization of natural energy is drawing attention. In a photovoltaic power generation system, which is a power generation system that converts sunlight, which is natural energy, into electric power, in order to increase power generation efficiency, a lens, a mirror, or the like is used to increase the light collection magnification.

Cost savings can be achieved by increasing the light collection magnification while maintaining the size of the power generation element, but there is a concern that the temperature of the power generation element will rise and problems such as burning will occur.

Therefore, it is necessary to cool the power generation element, especially in the condensing type photovoltaic power generation system. At that time, since the cooling efficiency of the power generation element affects the power generation efficiency of the photovoltaic power generation system, an efficient cooling system is required.

Conventionally, as a cooling system for power generation elements, air cooling or water cooling has been proposed. However, it is difficult to reuse the recovered heat in the air-cooled cooling system.

A water-cooled cooling system requires a large amount of water as a refrigerant and a large heat exchanger to cool it in order to improve the cooling performance. Therefore, there is a problem that the cooling system itself has a large and complicated structure, which leads to an increase in cost.

Since no suitable prior art document could be found for the above-mentioned cooling system which is the prior art of the present invention, the prior art document such as the patent document is not shown.

The present invention has been made in view of the above circumstances, and enables efficient cooling of the power generation element of the photovoltaic power generation system and efficient reuse of heat recovered from the power generation element by cooling. It is intended to provide a cooling system that can be made possible.

The characteristic configuration of the cooling system according to the present invention for achieving the above object is a cooling system for cooling the power generation element of the solar power generation system, which is a circulation path in which the cooling refrigerant circulates and the cooling refrigerant. A refrigerant pump that circulates in the circulation path, a flow control valve provided on the downstream side of the refrigerant pump and on the upstream side of the power generation element that functions as an evaporator in the circulation path, and the power generation element. have a, a heat exchanger for recovering heat from the cooling refrigerant heat exchange between the cooling refrigerant, the power generating element, the heat exchanger, the refrigerant pump, said flow control valve, The power generation element, the heat exchanger, the refrigerant pump, and the flow rate control valve are arranged in this order in the circulation path so as to circulate with and reach the power generation element again .

According to the above configuration, heat generated in the power generation element when power is generated from solar power is exchanged with a cooling refrigerant and recovered by a heat exchanger, so that not only power generation by solar power but also heat can be obtained. The overall energy conversion rate can be improved.

By the way, the lower the temperature of the power generation element, the higher the power generation efficiency. However, from the viewpoint of recovering the heat contained in the cooling refrigerant after cooling the power generation element, it is preferable that the temperature of the cooling refrigerant after cooling the power generation element is high. Therefore, it is important to maximize the amount of power generation and the amount of heat recovery.

In a conventional water-cooled cooling system, the boiling point of water is 100 ° C. under atmospheric pressure, so that the water as a cooling refrigerant must be 100 ° C. or lower, and therefore after cooling the power generation element. Even so, the temperature of water needs to be 100 ° C. or lower.

In the cooling system according to the present invention, a direct expansion type is adopted, and since cooling can be performed by latent heat of evaporation, cooling efficiency is higher than that of a conventional system that cools by sensible heat such as air cooling or water cooling. It is excellent and therefore the amount of cooling refrigerant required can be reduced.

Further, in the direct expansion type, the temperature of the cooling refrigerant can be set to 100 ° C. or higher by selecting an appropriate cooling refrigerant, and the amount of heat recovery can be increased, so that the heat exchange efficiency is high. The heat exchanger can be miniaturized. Therefore, a cooling system using a cooling refrigerant made of fluorocarbons can save space as compared with a cooling system in which the cooling refrigerant is air or water.

As a cooling system, a configuration is also conceivable in which the cooling refrigerant circulates with a power generation element that functions as an evaporator, a compressor, a condenser that functions as a heat exchanger, and an expansion valve, and reaches the power generation element again. However, in the cooling system according to the present invention, the cooling refrigerant circulates with the power generation element functioning as an evaporator, the condenser functioning as a heat exchanger, the refrigerant pump, and the flow control valve, and reaches the power generation element again. Since the configuration can be adopted, the evaporation temperature can be raised as compared with the configuration having a compressor in the circulation path even if the condensation temperature is the same.

That is, by adjusting the condensation temperature, it is possible to achieve a cooling temperature (evaporation temperature) at which the power generation efficiency of the photovoltaic power generation system is good.

Since the evaporation temperature can be adjusted, when considering the use of the exhaust heat recovered from the power generation element, the control range of the exhaust heat temperature should be wider than when the cooling refrigerant is air or water. Can be done. Therefore, the recovered waste heat can be widely used.

In addition, since the control range of the exhaust heat temperature is wide, the cooling system prioritizes the efficiency of power generation, the efficiency of heat recovery, the maximization of the amount of power generation and the amount of heat recovery, and so on. In addition, it is possible to freely control how the energy obtained from sunlight is used.

In the present invention, it is preferable that the heat exchanger is configured so that heat can be exchanged between the cooling refrigerant and water, air, or a refrigerant in a system outside the cooling system.

According to the above configuration, by exchanging heat between the cooling refrigerant passing through the condenser and water, air or refrigerant in the system outside the cooling system, water, air or water in the system outside the cooling system or The refrigerant can be heated and used.

In the present invention, it is preferable that the heat exchanger is a condenser.

According to the above configuration, the cooling system can be a cooling system in which the cooling refrigerant circulates with the power generation element, the condenser, the refrigerant pump, and the flow rate control valve whose circulation path functions as an evaporator, and reaches the power generation element again.

The characteristic configuration of the cooling system according to the present invention for achieving the above object is a cooling system for cooling the power generation element of the solar power generation system, which is a circulation path in which the cooling refrigerant circulates and the cooling refrigerant. A refrigerant pump that circulates in the circulation path, a flow control valve provided on the downstream side of the refrigerant pump and on the upstream side of the power generation element that functions as an evaporator in the circulation path, and the power generation element. It has a heat exchanger that recovers heat from the cooling refrigerant that has exchanged heat with and from the cooling refrigerant, and the heat exchanger has the cooling refrigerant and water, air, or refrigerant in a system outside the cooling system. The system outside the cooling system is configured so that heat can be exchanged between the two, the exhaust system that discharges the air sucked from the air conditioning space to the outside, and the supply that dehumidifies the air sucked from the outside and supplies it to the air conditioning space. The air system, the exhaust system, and a dehumidifying rotor arranged across the air supply system are provided, and the dehumidifying rotor absorbs moisture from the air to be dehumidified in the air supply system, and the exhaust system absorbs moisture from the air to be dehumidified. A desiccant air conditioning system configured to supply dehumidified air to the air conditioning space by repeating discharging, the exhaust system has a first preheater and a first preheater on the upstream side of the dehumidifying rotor. Two preheaters are provided, and the air supply system is provided with a precooler on the upstream side of the dehumidifying rotor and at least a first aftercooler on the downstream side of the dehumidifying rotor for an air conditioning system in which an air conditioning refrigerant as the refrigerant circulates. The air conditioning refrigerant by exchanging heat between the circulation path, the compressor that compresses the air conditioning refrigerant that circulates in the air conditioning system circulation path, and the heat of the air conditioning refrigerant and the heat of the cooling refrigerant. An air conditioner having a condenser and an expansion valve provided on the downstream side of the condenser, and at least one of the precooler or the first aftercooler is provided on the downstream side of the expansion valve. The cooling refrigerant is composed of a desiccant air conditioning system configured to function as a system evaporator, the second preheater functions as the heat exchanger, and heat is exchanged with the power generating element. The cooling refrigerant, which is configured to be heat exchangeable with the air passing through the second preheater and has completed heat exchange with the second preheater, reaches from the air conditioning system evaporator to the compressor. The cooling refrigerant, which is configured to be heat exchangeable with the air conditioning refrigerant and has completed heat exchange with the air conditioning refrigerant, is with the condenser. The point is that it is configured so that heat can be exchanged between them.

According to the above configuration, the air passing through the second preheater can be heated by the exhaust heat recovered by cooling the power generation element. Therefore, the energy required for drying the dehumidifying rotor of the desiccant air conditioning system can be supplemented.

Heat exchange between the cooling refrigerant after heating the air passing through the second preheater and the air conditioning refrigerant of the desiccant air conditioning system from at least one of the precooler or the first aftercooler to the compressor. Therefore, the temperature of the cooling refrigerant for cooling the air-conditioning refrigerant passing through the condenser can be lowered.

In the present invention, the desiccant air conditioning system includes a second aftercooler between the dehumidifying rotor and the first aftercooler, and the air passing through the second aftercooler reaches from the flow control valve to the power generation element. It is preferable that the system is configured so that heat can be exchanged with the cooling refrigerant.

According to the above configuration, the heat of the cooling refrigerant passing through the flow control valve can cool the air passing through the second aftercooler, thus heating the cooling refrigerant from the condenser to the power generation element. be able to. The evaporation temperature in the power generation element can be controlled by performing the heat exchange as necessary and controlling the temperature of the cooling refrigerant reaching the power generation element.

In the present invention, it is preferable that the air-conditioning refrigerant from the compressor to the condenser is configured to be heat exchangeable with the air passing through the first preheater.

According to the above configuration, the air passing through the first preheater can be heated by the heat of the air-conditioning refrigerant compressed by the compressor and reaching the condenser. Therefore, the energy required for heating the dehumidifying rotor of the desiccant air conditioning system can be supplemented.

Explanatory drawing of cooling system which concerns on this invention Moriel diagram of the cooling system of FIG. Explanatory drawing of cooling system which concerns on another embodiment Explanatory drawing of cooling system which concerns on another embodiment Explanatory drawing of cooling system which concerns on another embodiment

Hereinafter, embodiments of the cooling system according to the present invention will be described with reference to the drawings.

FIG. 1 shows the cooling system 10. The cooling system 10 is for cooling the power generation element 11 of the solar power generation system, and for example, a circulation path 12 in which a cooling refrigerant made of flones circulates and a cooling refrigerant circulates in the circulation path 12. Heat is recovered from the cooling refrigerant that has been heat-exchanged between the refrigerant pump 13 to be operated, the flow control valve 14 on the downstream side of the refrigerant pump 13 and provided on the upstream side of the power generation element 11, and the power generation element 11. It has a heat exchanger 15 and a heat exchanger 15. In this system, the power generation element 11 functions as an evaporator. The cooling refrigerant is not limited to fluorocarbons, and may be a natural refrigerant such as water or ammonia.

FIG. 2 shows a Moriel diagram of the cooling system 10 shown in FIG. In the heat exchanger 15, the cooling refrigerant is liquefied (a → b), and at that time, heat is released to the outside. After that, the cooling refrigerant is boosted by the refrigerant pump 13 (b → c). After that, the cooling refrigerant is stepped down in the flow rate control valve 14 as a liquid (c → d). After that, the cooling refrigerant absorbs the heat from the power generation element 11 in the power generation element 11, evaporates and vaporizes (d → a), and returns to the heat exchanger 15. The cooling refrigerant circulates in the circulation path 12 in this way.

In the present embodiment, the heat exchanger 15 is composed of a condenser, and is configured so that heat can be exchanged between the cooling refrigerant circulating in the circulation path 12 and water, air, or the refrigerant in the system outside the cooling system 10. ing.

For example, as shown in FIG. 3, the heat exchanger 15 can exchange heat between the cooling refrigerant and the hot water in the hot water storage tank 20. The water in the hot water storage tank 20 can be heated by the heat recovered from the power generation element 11 in the daytime, and can be used for heating or hot water supply at night, for example. Therefore, it is possible to reduce the energy cost of heating and hot water supply.

Further, as shown in FIG. 4, the heat exchanger 15 can exchange heat between the cooling refrigerant and the outside air. The air is heated by the heat recovered from the power generation element 11, and can be used, for example, in a heating or drying process. It is possible to reduce the energy cost of the heating and drying processes that were performed using electric heaters.

Further, as shown in FIG. 5, the heat exchanger 15 can exchange heat between the cooling refrigerant and the desiccant air conditioning system 100.

In explaining the heat exchange between the cooling system 10 and the desiccant air conditioning system 100, first, the desiccant air conditioning system 100 will be described.

The desiccant air conditioning system 100 includes a desiccant air conditioner 102 that exhausts air in the air conditioning space 101, dehumidifies and cools the outside air, and supplies the air to the air conditioning space 101, and a drive system 103 that drives the desiccant air conditioner 102.

The housing 104 of the desiccant air conditioner 102 includes an exhaust system 105 that discharges the air sucked from the air conditioning space 101 to the outside, an air supply system 106 that dehumidifies the air sucked from the outside and supplies the air to the air conditioning space 101, and an exhaust system. A dehumidifying rotor 107 arranged across the 105 and the air supply system 106 is provided.

The exhaust system 105 includes an exhaust fan 108 on the downstream side of the dehumidifying rotor 107, and a first preheater 109, a second preheater 110, and a heater 111 on the upstream side of the dehumidifying rotor 107. The air supply system 106 is provided with a precooler 112 on the upstream side of the dehumidifying rotor 107, a first aftercooler 113 and a second aftercooler 114 on the downstream side of the dehumidifying rotor 107, and is further supplied between the precooler 112 and the dehumidifying rotor 107. It is equipped with a ki fan 115.

The dehumidifying rotor 107 is configured to dehumidify the air supplied to the air conditioning space 101 by repeatedly releasing the moisture absorbed from the air to be dehumidified in the air supply system 106 in the exhaust system 105. ..

The drive system 103 for driving the desiccant air conditioner 102 includes an air conditioner system circulation path 116 in which an air conditioner refrigerant as a refrigerant in a system outside the cooling system 10 circulates, and an air conditioner refrigerant circulated in the air conditioner system circulation path 116. The compressor 117 for compressing the air conditioner, the condenser 118 for condensing the air conditioner refrigerant by exchanging heat between the heat of the air conditioner refrigerant and the heat of the cooling refrigerant of the cooling system 10, and the condenser 118 provided on the downstream side of the condenser 118. It also has an expansion valve 119. The condenser 118 also functions as an evaporator in the cooling system 10.

Depending on the balance between the amount of heat absorbed by the power generation element 11 from sunlight and the dehumidifying load of the air conditioning space 101, the air conditioning refrigerant may not be completely condensed by the condenser 118. For such a case, an auxiliary condenser may be provided between the condenser 118 and the expansion valve 119, and the heat of the air conditioning refrigerant may be dissipated to the outside of the system by this auxiliary condenser. It is possible.

The precooler 112 and the first aftercooler 113 function as an evaporator for an air conditioning system provided on the downstream side of the expansion valve 119.

The heat exchange between the cooling system 10 and the desiccant air conditioning system 100 configured as described above will be described.

The cooling refrigerant that has been heat-exchanged with the power generation element 11 of the cooling system 10 is configured to be heat-exchangeable with the air that passes through the second preheater 110. Therefore, the second preheater 110 functions as the heat exchanger 15 in the cooling system 10.

The cooling refrigerant that has completed heat exchange with the second preheater 110 is air-conditioned from the precooler 112 and the first aftercooler 113 to the compressor 117 in the heat exchanger 120 provided in the circulation path 116 for the air conditioning system. It is configured so that heat can be exchanged with the refrigerant for use.

In the cooling system 10, the cooling refrigerant that has completed heat exchange with the air-conditioning refrigerant by the heat exchanger 120 is supplied to the condenser 118 by the refrigerant pump 13 via the flow control valve 14. The cooling refrigerant that has completed heat exchange with the air conditioning refrigerant in the condenser 118 is then supplied to the power generation element 11 and exchanges heat with the power generation element 11 of the cooling system 10.

The circulation path 12 has a branch path 16 in the middle of the path from the flow rate control valve 14 to the power generation element 11 via the condenser 118, and passes through the cooling refrigerant flowing through the branch path 16 and the second aftercooler 114. It is configured so that heat can be exchanged with the air. The branch path 16 is provided with a flow rate control valve.

The air-conditioning refrigerant from the compressor 117 to the condenser 118 is configured to be heat exchangeable with the air passing through the first preheater 109.

Although not shown, the desiccant air conditioning system 100 can appropriately have a heat exchanger (not shown) other than the above configuration, depending on the amount of heat radiated from the cooling system 10.

As described above, it is possible to efficiently cool the power generation element 11 of the photovoltaic power generation system and to efficiently reuse the heat recovered from the power generation element 11 by cooling. became.

The above-described embodiments are all examples of the present invention, and the description does not limit the present invention, and the specific configuration of each part can be appropriately modified and designed within the range in which the effects of the present invention are exhibited. is there.

10: Cooling system 11: Power generation element 12: Circulation path 13: Refrigerant pump 14: Flow control valve 15: Heat exchanger 100: Desiccant air conditioning system 101: Air conditioning space 105: Exhaust system 106: Air supply system 107: Dehumidifying rotor 109: First preheater 110: Second preheater 112: Precooler 113: First aftercooler 114: Second aftercooler 116: Circulation path for air conditioning system 117: Compressor 118: Condenser 119: Expansion valve 120: Heat exchanger

Claims (6)

A cooling system that cools the power generation elements of a photovoltaic power generation system.
The circulation path through which the cooling refrigerant circulates,
A refrigerant pump that circulates the cooling refrigerant in the circulation path, and
A flow rate control valve provided on the downstream side of the refrigerant pump and on the upstream side of the power generation element that functions as an evaporator in the circulation path.
Have a, a heat exchanger for recovering heat from the cooling refrigerant heat exchange between the power generating element,
The power generation element and the heat exchanger in the circulation path so that the cooling refrigerant circulates with the power generation element, the heat exchanger, the refrigerant pump, and the flow rate control valve and reaches the power generation element again. , The cooling system , wherein the refrigerant pump and the flow control valve are arranged in this order. The cooling system according to claim 1, wherein the heat exchanger is configured so that heat exchange is possible between the cooling refrigerant and water, air, or a refrigerant in a system outside the cooling system. The cooling system according to claim 1 or 2, wherein the heat exchanger is a condenser. A cooling system that cools the power generation elements of a photovoltaic power generation system.
The circulation path through which the cooling refrigerant circulates,
A refrigerant pump that circulates the cooling refrigerant in the circulation path, and
A flow rate control valve provided on the downstream side of the refrigerant pump and on the upstream side of the power generation element that functions as an evaporator in the circulation path.
It has a heat exchanger that recovers heat from the cooling refrigerant that has exchanged heat with the power generation element.
The heat exchanger is configured so that heat can be exchanged between the cooling refrigerant and water, air, or a refrigerant in a system outside the cooling system.
The system outside the cooling system
An exhaust system that discharges the air sucked from the air conditioning space to the outside, an air supply system that dehumidifies the air sucked from the outside and supplies it to the air conditioning space, and the exhaust system and the air supply system are arranged across the air supply system. A dehumidifying rotor is provided, and the dehumidifying rotor supplies dehumidified air to the air-conditioned space by repeatedly absorbing moisture from the air to be dehumidified in the air supply system and discharging it in the exhaust system. A desiccant air conditioning system configured to be
The exhaust system includes a first preheater and a second preheater on the upstream side of the dehumidifying rotor.
The air supply system includes a precooler on the upstream side of the dehumidifying rotor and at least a first aftercooler on the downstream side of the dehumidifying rotor.
The circulation path for the air conditioning system in which the air conditioning refrigerant as the refrigerant circulates,
A compressor that compresses the air-conditioning refrigerant that circulates in the air-conditioning system circulation path.
A condenser that condenses the air-conditioning refrigerant by exchanging heat between the heat of the air-conditioning refrigerant and the heat of the cooling refrigerant.
It has an expansion valve provided on the downstream side of the condenser.
At least one of the precooler and the first aftercooler is composed of a desiccant air conditioning system provided on the downstream side of the expansion valve and configured to function as an evaporator for an air conditioning system.
The second preheater functions as the heat exchanger, and is configured to be heat exchangeable between the cooling refrigerant that has been heat exchanged with the power generation element and the air that passes through the second preheater.
The cooling refrigerant that has completed heat exchange with the second preheater is configured to be heat exchangeable with the air conditioning refrigerant extending from the evaporator for the air conditioning system to the compressor.
The cooling refrigerant cooling system that is characterized in that it is heat-exchangeably configuration between said condenser finishing heat exchange between the air conditioning refrigerant. The desiccant air conditioning system includes a second aftercooler between the dehumidifying rotor and the first aftercooler.
The cooling system according to claim 4, wherein the air passing through the second aftercooler is configured to be heat exchangeable with the cooling refrigerant from the flow rate control valve to the power generation element. The cooling according to claim 4 or 5, wherein the air-conditioning refrigerant from the compressor to the condenser is configured to be heat exchangeable with air passing through the first preheater. system.

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