WO2013183002A4

WO2013183002A4 - System and method of cooling of photovoltaic panel and method of installation of system

Info

Publication number: WO2013183002A4
Application number: PCT/IB2013/054617
Authority: WO
Inventors: Michal Masaryk
Original assignee: Michal Masaryk
Priority date: 2012-06-05
Filing date: 2013-06-05
Publication date: 2014-05-30
Also published as: WO2013183002A2; WO2013183002A3

Abstract

A heat is taken from a photovoltaic panel (1) using air that flows through the photovoltaic panel (1) unit with an air cooler (2). The unit has an air intake opening (3) and an outtake vent (4) and the air flow is enforced by a natural draft of a chimney (5), to which the photovoltaic panel (1) unit is connected to. At least a part of the chimney (5) is exposed to solar radiation. Outtake vents (4) of several photovoltaic panel (1) units can lead to one chimney (5), preferably through thermal collectors (6) and piping. The air in the chimney is warmed up by solar radiation, the air ascends towards the chimney (5) mouth and the chimney (5) natural draft created in this way enforces air flow within the photovoltaic panel (1) unit. Even the air cooler (2) of the sucked air can form part of the system - preferably in the form of a ground-coupled heat exchanger (9). The chimney (5) can be equipped with heat-absorbing surface and it can also have a supporting wind device transforming wind energy into a natural draft within the chimney (5).

Claims

AMENDED CLAIMS received by the International Bureau on 23 March 2014

1. A photovoltaic panel (1) cooling system, in which a heat is taken away using air that flows next to a panel (1) and/or through a panel (1) and/or along a panel (1), the photovoltaic panel (1) has an air cooler (2) located within a closed unit that is adjusted for air flow; the unit has an air intake opening <3) and an air outtake vent (4) that i s characterized by the fact that the air outtake vent (4) is connected to a chimney (5) In order to create a natural draft, while at least a part of the chimney (5) is exposed to solar radiation that supports the chimney's (5) natural draft; and the chimney mouth (5) is above the level of the air outtake vent (4).

2. A photovoltaic panel (1) cooling system according to the claim 1 i s characterized by the fact that at least a part of the chimney (5) is equipped with a heat-absorbing surface.

3. A photovoltaic panel (1) cooling system according to the claims 1 or 2 Is characterized by the fact that on the side with tne solar exposure, at least a part of the chimney (5) coating is transparent and, preferably, the remaining part of the coating is equipped with a heat-absorbing surface on the inside.

4. A photovoltaic panel (1) cooling system according to any of the claims 1 to 3 i s characterized by the fact that at least on the side with the solar exposure, the chimney (5) has a double layer coating; the first, the outer layer, is transparent and the second one is equipped with a heat-absorbing surface.

5. A photovoltaic panel (1) cooling system according to any of the claims 1 to 4 is characterized by the fact that the chimney (5) is in the shape of a rotational hyperboloid.

6. A photovoltaic panel (1) cooling system according to any of the claims 1 to 5 i s characterized by the fact that the chimney (5) has at least one joint In its lower part; the joint is safeguarded by a safety catch and is oriented so that in case of a too strong a wing, the safety catch is activated and the chimney (5) falls down in a controlled manner outside a zone with photovoltaic panels (1).

7. A photovoltaic panel (1) cooling system according to any of the claims 1 to 6 is characterized by the fact that the chimney (5) has a frame made from rods and a coating made from a bendable layer, preferably a coating made from a canvas

1. A photovoltaic panel (1) cooling system, in which a heat is taken away using air that flows next to a panel (1) and/or through a panel (1) and/or along a panel (1), the photovoltaic panel (1) has an air cooler (2) located within a closed unit that is adjusted for air flow; the unit has an air intake opening (3) and an air outtake vent (4) that i s characterized by the fact that the air outtake vent (4) is connected to a chimney (5) in order to create a natural draft, while at least a part of the chimney (5) is exposed to solar radiation that supports the chimney's (5) natural draft; and the chimney mouth (5) is above the level of the air outtake vent (4).

3. A photovoltaic panel (1) cooling system according to the claims 1 or 2 Is characterized by the fact that on the side with tne solar exposure, at least a part of the chimney (5) coating is transparent and, preferably, the remaining part of the coating is equipped with a heat-aljtsorbing surface on the inside.

) 6. A photovoltaic panel (1) cooling system according to any of the claims 1 to 5 i s characterized by the fact t h a t the chimney (5) has at least one joint In its lower part; the joint is safeguarded by a safety catch and is oriented so that in case of a too strong a wing, the safety catch is activated and the chimney (5) falls down in a controlled manner outside a zone with photovoltaic panels (1).

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7. A photovoltaic panel (1) cooling system according to any of the claims 1 to 6 i s characterized by the fact that the chimney (5) has a frame made from rods and a coating made from a bendable layer, preferably a coating made from a canvas or an impregnated fabric, while the required shape of the chimney is defined by the frame made from rods,

8. A photovoltaic panel (1) cooling system according to any of the claims 1 to 7 i s characterized by the fact that air outtake vents (4) of several photovoltaic panel (1) units lead to one chimney (5), preferably through thermal collectors (6) and warm air piping (7), the pipework of which is gradiently descending and/or connected in an opposite configuration in order to reach identical air flow in photovoltaic panel (1) units.

9. A photovoltaic panel (1) cooling system according to any of the claims 1 to 8 i s characterized by the fact that it encompasses a supporting wind device that transforms wind energy into natural draft of a chimney (5); this device is preferably in the form of a wind turbine head at the chimney (5) mouth.

10. A photovoltaic panel (1) cooling system according to any of the claims 1 to 9 i s characterized by the fact that the unit has the same attachment elements at its rear side as the photovoltaic panel (1) to which the unit is attached itself.

11. A photovoltaic panel (1) cooling system according to any of the claims 1 to W is characterized by the f act that it encompasses an air cooler that is connected with the unit's air intake opening (3) into a branch.

12. A photovoltaic panel (1) cooling system according to the claim 11 is characterized by the fact that the unit^'s air intake opening (3) is connected to an air cooler using a cooling air piping (8) or a two-way valve or a by-pass that sucks the air from the pane! (1) surrounding environment.

13. A photovoltaic panel (1) cooling system according to the claims 11 or 12 is characterized by the fact that the air cooler is formed out of a ground- coupled heat exchanger (9) of the air - ground (10) type, in which the pipework of the ground-coupled heat exchanger (9) Is stored in the ground (10), preferably at least 1 m deep and most suitably at least 1 ,5 m deep,

14. A photovoltaic panel (1) cooling system according to the claim 13 is characterized by the fact that the pipework of the ground-coupled heat exchanger (9) is sinuously placed and/or it encompasses a cross-connected register and the ground-coupled heat exchanger (9) pipework is gradiently descending to the place a condensate drains, preferably to the place where the condensate drains into a dry well.

15. A photovoltaic panel (1) cooling system according to any of the claims 11 to 14 is characterized by the fact that the unit's air intake opening (3) and/or Intake opening of the ground-coupled heat exchanger (9) is equipped with a replaceable air filter,

16. A photovoltaic panel (1) cooling system according to any of the claims 13 to 15 is characterized by the fact that the ground-coupled heat exchanger (9) is equipped with a pressure valve for a disconnection of the ground-couple heat exchanger (9) in case of a low suction pressure.

17. A photovoltaic panel (1) cooling system according to any of the claims 13 to 16 i s characterized by the fact that the ground-coupled heat exchanger (9) pipework is laid in ground (10) in an alley between photovoltaic panel (1) rows.

18. A photovoltaic panel (1) cooling system according to any of the claims 13 to 16 is characterized by the fact that the ground-coupled heat exchanger (9) pipework is laid in ground (10) under photovoltaic panels (1).

19. A method of a system (1) installation according to any of the claims 13 to 17 is characterized by the fact that in case fields with photovoltaic panels (1) are already installed, a groove is dug up in the ground (10) in the alley between photovoltaic panel (1) rows and a pipe or several parallel pipes of the air cooling ground- coupled heat exchanger (9) are placed into this groove.

20. A method of a system (1) installation according to any of the claims 13 to 17 is characterized by the fact that in case fields with photovoltaic panels (1) are already installed, a drill well is dug up in the ground (10) in the atley between photovoltaic panel (1) rows and a pipe of the air cooling ground-coupled heat exchanger (9) is placed into this opening.

21. A method of a system (1) installation according to any of the claims 13 to 16 and 18 i s characterized by the fact that the pipes of the cooling air ground- coupled heat exchanger (9) are placed into the ground (10) before photovoltaic panels (1) are installed.

22. A method of a photovoltaic panel (1) cooling, during which a heat is taken away using air that flows next to a panel (1) and/or through a panel (1) and/or along a panel (1) i s characterized by the fact that solar radiation is used to warm up air In a chimney (5); the air ascends up towards the chimney (5) mouth and the chimney (5) natural draft created in this way enables air flow within a photovoltaic panel (1) unit.

23. A method of a photovoltaic panel (1) cooling according to the claim 22 is characterized by the fact that a cooling air sucked into the photovoltaic panel (1) unit is being cooled to a temperature that is lower than the surrounding environment temperature, preferably in such a way that we lead the air through a hydronic piping in a ground (10) or in a water source.

Statement under article 19(1)

In claim 1 we have moved the features concerning the air cooler itself in the body of the photovoltaic panel to the preamble. This move corresponds to earlier publication Dl.

Chimneys according to D2 and D3 are intended for creation 'of high airflow capable of spinning the electricity generators. These chimneys are not used for cooling. We can presuppose that the airflow in chimneys according to D2 and D3 must achieve speed in several m/s, usually at least 5 m/s. In our invention, however, the chimney works for different purpose. In order to support heat convention in back side of a photovoltaic panel any speed higher than 0 m/s suffices,

Cooling chimneys are also used for cooling, but these work on different principle; they use water that evaporates inside a chimney. If a person skilled in art wants to cool something, for example a photovoltaic panel, and something suggests him or her to use a chimney, he or she will naturally has at hand the solution with existing cooling chimneys working on existing principles. Such chimney does not have to be exposed to sunlight. Nothing suggests person skilled In art to use a chimney used for production of energy.

In the first claim the arrangement Is, besides the use of a chimney for the purposes of cooling, also explained, in that the chimney mouth is above the level of the air outtake vent. Such arrangement is not clarified in Dl or D2, because the point of entering of air is In these documents always the lowest point of a chimney.

Taking in account the abovementioned, we believe that the first claim and, subsequently, following claims as well do contain an inventive step.