JP5633498B2 - Solar power panels - Google Patents

Description

  The present invention relates to a photovoltaic power generation panel.

  2. Description of the Related Art Conventionally, in a photovoltaic power generation panel provided on a roof, a pedestal or the like of a house, dirt, bird droppings and chemical substances (dust) adhere to the panel surface. Since these deposits do not fall due to rain alone, cleaning and maintenance are required, but the work is difficult. In order to cope with this, for example, Patent Document 1 proposes cleaning the panel surface using a cleaning device capable of working at high places.

  Furthermore, since the power generation capacity decreases when the photovoltaic power generation panel becomes high temperature, cooling is performed by flowing cold water over the panel surface. For example, Patent Document 2 discloses a watering facility that prevents a temperature increase associated with photovoltaic power generation by watering the panel surface.

JP 2011-40592 A JP 2010-129677 A

However, the conventional photovoltaic power generation panel has the following problems.
That is, in a photovoltaic power generation panel supported by a conventional gantry, as shown in FIG. 14, for example, when wind E blows from the back of the panel 100 (right side in FIG. 14), a wake vortex U is generated on the leeward side. As a result, a negative pressure is generated in the upper part of the panel, and there is a problem that the lifting force P acts on the panel 100 and the panel 100 itself or the frame 101 is lifted.
Moreover, when cleaning the panel surface using the cleaning apparatus of patent document 1, it is necessary to use a special cleaning apparatus, and there existed room for improvement in that point.
Furthermore, in Patent Document 2, a special cooling device is required, and it is difficult to secure water supplied to the cooling device, and power for operating the device is required. In addition, in this case, there is a problem that the power generation efficiency is lowered due to the formation of a water film on the panel surface.

The present invention has been made in view of the above-described problems, and prevents the wake-side wake vortex from being generated and prevents the negative pressure from being generated at the top of the panel, thereby preventing the photovoltaic power generation panel from being lifted. It aims at providing the rectification stand for photovoltaic power generation panels which can do.
Another object of the present invention is to reduce the trouble of cleaning the panel surface and to cool the panel surface with a simple configuration and prevent a decrease in power generation efficiency without providing a special cooling facility. It is to provide a rectification stand for a photovoltaic power generation panel.

In order to achieve the above object, in the photovoltaic power generation panel according to the present invention, a plurality of louver-like panel bodies arranged adjacent to each other in a vertical direction with a gap between each other, and a panel body positioned at the top The panel body includes a current plate provided on the upper side of the panel, and a blowout port that discharges air from the rear of the panel so as to circulate along the panel surface of the panel body located on the uppermost part. The space on the front side of the panel and the space on the back side of the panel communicate with each other through a gap between them, and the windshield plate extending from the upper part of the panel toward the lower rear side of the panel is provided on the panel body provided at the uppermost part. The rectifying plate is characterized in that it is arranged at an interval with respect to the wind shielding surface of the wind shielding plate .

In the present invention, when wind blows from behind the photovoltaic power generation panel, air flows into the lower surface side of the rectifying plate provided on the upper side of the panel, which is the windward side, and the air is provided at the uppermost part from the outlet. It is blown out as a forced wind toward the panel surface of the main body. In addition, in the panel body excluding the uppermost part, the wind blown from the rear of the panel passes through the gap between the panel bodies positioned above and below, and the passing wind also circulates along the panel surface. It becomes a forced wind.
In addition, when wind blows from the front of the photovoltaic power generation panel, the air passes through the panel surface of each panel body, flows into the gap between the panel bodies (the outlet on the top panel body), and behind the panel Will be released. That is, by providing the gap and the outlet, air easily flows along each panel surface, and the passing air becomes a forced air.

Thus, by forcibly sending air from the leeward side to the leeward side on the panel surface, wake vortices are less likely to occur on the leeward side, and vortices are less likely to adhere to the panel surface. Therefore, the negative pressure at the upper part of the panel is reduced, and lifting due to the negative pressure of the panel main body or the gantry supporting the panel main body can be suppressed.
Furthermore, by providing the rectifying plate, a downward force (down force) is generated in the rectifying plate itself due to the pressure difference of the air passing through the upper and lower surfaces of the rectifying plate. Accordingly, since the photovoltaic power generation panel is pressed downward by the rectifying plate via the gantry, the panel itself or the cradle can be more reliably suppressed from being lifted.

In addition, by blowing forced air on the panel surface, it is possible to blow off dirt such as dirt and dust on the surface, and it is possible to prevent air from stagnating on the panel surface, so that dirt is removed. There is an advantage that it is difficult to adhere.
Furthermore, by blowing forced air on the panel surface, it is possible to suppress a temperature rise during power generation of the photovoltaic power generation panel, and to improve power generation efficiency.

Further, when wind is received from behind the photovoltaic power generation panel, air flows between a windshield plate provided on the windward side and a rectifying plate, and flows toward the outlet side along the windshield plate. That is, wind from the rear can be collected by the wind shielding plate and the rectifying plate, and the air can be blown out as forced air toward the panel surface provided at the uppermost portion from the blowout opening. In other words, since it is possible to collect more wind by the wind shield, the amount of forced wind (wind speed) can be increased, and the effect of the panel surface cleaning action and temperature rise restraining action can be enhanced. it can.

Moreover, in the photovoltaic power generation panel according to the present invention, it is preferable that a lower wind shielding plate extending downward from a lower portion of the panel is provided on the panel body positioned at the lowest level.
In the present invention, when wind blows from the front of the photovoltaic power generation panel, the air collected by the lower wind shielding plate is blown out as forced wind toward the panel surface of the panel body provided at the lowermost part, so that the panel surface The forced wind that circulates along can be more reliably formed.
Furthermore, by providing the rectifying plate, a downward force (down force) is generated in the rectifying plate itself due to the pressure difference of the air passing through the upper and lower surfaces of the rectifying plate. Accordingly, since the photovoltaic power generation panel is pressed downward by the rectifying plate via the gantry, the panel itself or the cradle can be more reliably suppressed from being lifted.

In the photovoltaic power generation panel according to the present invention, adjacent ones are provided on the upper side of the panel of the plurality of louver-like panel bodies arranged in the vertical direction with a gap therebetween and the panel body located at the top. A rectifying plate; and a blowout port that is provided on the rectifying plate and discharges air from behind the panel so as to circulate along the panel surface of the panel main body located at the uppermost portion, and between the panel main bodies. The space on the front side of the panel and the space on the back side of the panel communicate with each other through the gap, and the panel body located on the upper side of the panel bodies adjacent to each other in the vertical direction is located closer to the panel rear side than the panel body located on the lower side. The lower end of the panel body located on the rear side of the panel is opened above the upper end of the panel body adjacent to the front side of the panel in a direction perpendicular to the panel surface direction. It is characterized in that are superimposed.

According to the photovoltaic power generation panel of the present invention, the wind is actively distributed to the panel surfaces of all the panel bodies, thereby preventing the generation of wake vortices on the leeward side of the panel and the generation of negative pressure at the upper part of the panel. Can be suppressed, and the floating of each panel body can be prevented.
Also, at least when wind is blowing, air can flow constantly on the panel surface to prevent stagnation of the air, so that adhesion of dirt, dust, etc. can be reduced, and the panel surface needs to be cleaned. Time and effort can be reduced.
In addition, according to the photovoltaic power generation panel of the present invention, no special cooling facility is required, and the panel surface can be cooled with a simple configuration to prevent a decrease in power generation efficiency.

It is the perspective view which looked at the photovoltaic power generation panel by the 1st Embodiment of this invention from the front. It is the perspective view which looked at the photovoltaic power generation panel shown in FIG. 1 from the rear side. It is a side view of a photovoltaic power generation panel. It is a side view which shows the flow of the air of a photovoltaic power generation panel, Comprising: (a) is a figure which shows the flow of the wind from back, (b) is a figure which shows the flow of the wind from the front. It is the perspective view which looked at the photovoltaic power generation panel by a 2nd embodiment from the front. It is the perspective view which looked at the photovoltaic power generation panel shown in FIG. 5 from the rear side. It is a side view of the photovoltaic power generation panel shown in FIG. It is a side view which shows the flow of the air of the photovoltaic power generation panel of FIG. 5, Comprising: (a) is a figure which shows the flow of the wind from back, (b) is a figure which shows the flow of the wind from the front. It is the perspective view which looked at the photovoltaic power generation panel by a 3rd embodiment from the front. It is the perspective view which looked at the photovoltaic power generation panel shown in FIG. 9 from the rear side. FIG. 10 is a side view of the photovoltaic power generation panel shown in FIG. 9. It is a side view which shows the flow of the air of the photovoltaic power generation panel of FIG. 9, (a) is a figure which shows the flow of the wind from back, (b) is a figure which shows the flow of the wind from the front. It is a side view which shows the structure of the photovoltaic power generation panel by the modification of this Embodiment. It is a side view which shows the flow of the air with respect to the conventional photovoltaic power generation panel.

  Hereinafter, the photovoltaic power generation panel by embodiment of this invention is demonstrated based on drawing.

(First embodiment)
As shown in FIG. 1, the photovoltaic power generation panel 1 according to the present embodiment is installed on, for example, a roof or a roof of a building and supported from below by a gantry body 5.
As shown in FIGS. 1 to 3, the photovoltaic power generation panel 1 has a solar cell module on the panel surface 2 a and a plurality of adjacent ones arranged vertically with a gap (flow path S) therebetween. (In this case, three) louver-like panel main body 2 (2A, 2B, 2C), a rectifying plate 3 provided on the upper side of the panel main body 2 positioned at the top, and a rear panel provided on the rectifying plate 3 And a blow-out port 4 through which the air E is discharged so as to circulate along the panel surface 2a of the panel main body 2A located at the uppermost part. And the panel surface 2a side and the panel back surface 2b side (back side space R) are connecting via the flow path S between the panel main bodies 2. FIG.
In addition, the panel body 2C located at the lower part of the panel is spaced apart from the lower wind shielding plate 7 extending toward the lower side of the panel and the wind shielding surface 7a on the front side of the lower wind shielding plate 7, A lower rectifying plate 8 disposed so as to open downward with respect to the wind shielding surface 7a of the wind shielding plate 7 is provided.

  In addition, the solar power generation panel 1 is arrange | positioned diagonally toward the south in the panel surface 2a which makes a light-receiving surface. Here, in the installation state in FIG. 1, the panel back surface 2b side is referred to as “rear side” and “rear side”, and the panel surface 2a side is referred to as “front side” and “front side”.

  The gantry body 5 has a configuration in which H-shaped steel material, channel steel material (channel steel material), and the like are combined, and a base 51 fixed to the installation surface, and a panel body 2 that is erected on the base 51 with a predetermined inclination angle. The support column 52 is supported by And the panel main body 2 is each supported by the support | pillar 52, and is in the state which has the back side space R mentioned above in the panel back surface 2b side.

  The panel main bodies 2A, 2B, and 2C have a flat plate shape and are arranged in one direction (diagonally downward) in a louver shape, and each has a gap (flow current) at an inclination angle toward a predetermined direction (southward). The road S) is opened and arranged in parallel. That is, the flow path is such that the lower end of the panel main body 2 located on the upper side and the upper end of the panel main body 2 located on the lower side of the panel main bodies 2 adjacent to each other in the vertical direction are orthogonal to the respective panel surface directions. It is in a state of being overlapped with S. The overlap length in the panel surface direction can be arbitrarily set.

  The rectifying plate 3 extends in the width direction X of the panel body 2 and has a blade shape whose bottom surface is streamlined. The rectifying plate 3 is positioned immediately above the upper end 2c of the panel body 2A provided at the uppermost portion, and its upper end. 2c is arranged at intervals.

The outlet 4 is a plate-like member that is disposed substantially parallel to the panel surface 2a at the same inclination angle as the panel main body 2A provided at the uppermost portion, and is directed forward from the current plate 3. It is provided integrally so as to protrude. That is, the outlet 4 is configured to forcibly blow out the air E flowing in from the rear of the panel toward the panel surface 2a of the uppermost panel body 2A.
In addition, members, such as a steel plate, a plastics, a synthetic resin, can be employ | adopted for the baffle plate 3 and the blower outlet 4, for example.

Next, the effect | action of the photovoltaic power generation panel 1 mentioned above is demonstrated in detail based on drawing.
As shown in FIG. 4A, when wind blows from behind the photovoltaic power generation panel 1, air E flows into the lower surface side of the rectifying plate 3 provided on the upper side of the panel, which is the windward side. Is blown out as forced air directed from the outlet 4 toward the panel surface 2a of the panel body 2A provided at the top. Further, in the panel bodies 2B and 2C excluding the uppermost panel body 2A, the wind blown from the rear of the panel through the flow path S between the panel bodies 2 and 2 positioned above and below is directed toward the panel surface 2a. Passing through, this passing air also becomes a forced air flowing along the panel surface 2a.

  Moreover, as shown in FIG.4 (b), when a wind blows from the front of the photovoltaic power generation panel 1, the air E passes the panel surface 2a of each panel main body 2, and between panel main bodies 2 and 2 mutually. The flow path S (the blowout port 4 in the uppermost panel body 2A) is discharged to the rear side of the panel body 2. That is, by providing the flow path S and the outlet 4, the air E easily flows along each panel surface 2 a, and this passing air becomes a forced air.

  Thus, by forcibly sending air from the leeward side to the leeward side on the panel surface 2a, wake vortices on the leeward side are less likely to occur, and vortices are less likely to adhere to the panel surface 2a. Therefore, the negative pressure at the upper part of the panel is reduced, and the lifting due to the negative pressure of the panel main body 2 or the gantry main body 5 supporting the panel main body 2 can be suppressed.

Further, by blowing forced air on the panel surface 2a, it is possible to blow off dirt such as dirt and dust attached to the surface 2a, and it is possible to prevent the air E from stagnating on the panel surface portion. There is an advantage that dirt is difficult to adhere.
Furthermore, by blowing forced air on the panel surface 2a, it is possible to suppress a temperature rise during power generation of the photovoltaic power generation panel 1, and to improve power generation efficiency.

In the photovoltaic power generation panel according to the present embodiment described above, a flow path S is provided between a plurality of arranged panel bodies 2 and 2, and a rectifying plate 3 is provided on the uppermost panel body 2A. By positively circulating the wind over the panel surface 2a of all panel bodies 2, it is possible to prevent the generation of wake vortices on the leeward side of the panel and suppress the generation of negative pressure at the top of the panel. It is possible to prevent the main body 2 from being lifted.
Further, since the air E always flows on the panel surface 2a of each panel body 2 and the stagnation of the air E can be prevented, adhesion of dust, dust, etc. can be reduced, and the panel surface 2a can be cleaned. Such labor can be reduced.
In addition, no special cooling facility is required, and the panel surface 2a can be cooled with a simple configuration to prevent a decrease in power generation efficiency.

  Next, another embodiment of the photovoltaic power generation panel of the present invention will be described with reference to the accompanying drawings. The same reference numerals are used for members and parts that are the same as or similar to those of the first embodiment described above. Description is omitted, and a configuration different from the first embodiment will be described.

(Second Embodiment)
A photovoltaic power generation panel 1A according to the second embodiment shown in FIGS. 5 to 7 has a configuration in which the shape of the panel body 2 is not a flat plate, but the same shape as that of the rectifying plate 3.
The panel body 2 (2A to 2G) has a long and narrow wing plate shape in which the lower surface side is streamlined, and a plurality (seven here) are arranged in one direction (diagonally downward) in a louver shape. They are arranged parallel to each other with a gap (flow path S) at an inclination angle in a predetermined direction (southward). That is, the lower end part of the panel body 2 located on the upper side and the upper end part of the panel body 2 located on the lower side among the panel bodies 2 adjacent to each other in the vertical direction flow in directions orthogonal to the respective panel surface directions. It arrange | positions in the state which opened the path S and overlapped. The overlap length in the panel surface direction can be arbitrarily set.

  The gantry main body 5A according to the present embodiment includes a base 51 provided on the installation surface, and a panel receiving diagonal member 50 arranged obliquely rearward substantially parallel to the installation angle at which the plurality of panel main bodies 2A to 2G are arranged. The support diagonal member 54 is disposed obliquely forward and has an upper end joined to the upper part of the panel support diagonal member 50 and the intermediate portion in the longitudinal direction. The panel support diagonal member 50 and the support diagonal member 54 are disposed on the base 51. It has a fixed frame structure. Here, the joint between the upper portion of the panel receiving diagonal member 50 and the supporting diagonal member 54 is referred to as an upper corner portion 5a (FIGS. 6 and 7).

  A rectifying plate 3A (3) is disposed at the top of the panel body 2A provided at the top. As shown in FIG. 8A, the rectifying plate 3A is arranged so as to allow the wind (air E) blown from the rear to pass to the lower surface side and move toward the panel surface 2a of the panel body 2A. As shown in (b), it is arranged so that the wind (air E) blowing from the front passes to the lower surface side and flows toward the rear side.

The rectifying plate 3A located at the uppermost portion is integrally provided with a blowout port 4 as in the first embodiment, and blown from the blowout port 4 toward the panel surface 2a of the panel body 2A provided at the uppermost portion. It is designed to be hung.
In addition, the panel main body 2G provided at the lowermost portion is provided with a lower wind shielding plate 7 extending downward from the lower portion of the panel. The lower end portion of the lower wind shielding plate 7 is curved so as to follow the upper surface of the base 51 from the panel main body 2G. The panel main body 2G arranged at the lowermost part is arranged at an angle that opens downward with respect to the wind shielding surface 7a of the lower wind shielding plate 7, and the panel main body 2G and the wind shielding surface 7a have a predetermined interval. It is arranged with a gap.
Further, the panel main body 2 (2A to 2G) has an elongated wing plate shape whose lower surface side is formed in a streamlined manner, so that a downward force (on the panel itself due to a pressure difference of air passing through the upper and lower surfaces of the panel ( Downforce) will occur. Therefore, since the photovoltaic power generation panel 1A is pressed downward by the panel via the gantry body 5A, it is possible to more reliably suppress the panel itself or the cradle from being lifted.

(Third embodiment)
The solar power generation panel 1B according to the third embodiment shown in FIGS. 9 to 11 has a configuration in which the shape of the panel body 2 is the same as that of the rectifying plate 3 as in the second embodiment. It is. Since the panel body 2 (2A to 2G) has the same configuration as that of the second embodiment, detailed description thereof is omitted here.

  The gantry body 5B according to the present embodiment is provided with a base 51 on the installation surface, a support plate 53 arranged substantially parallel to the installation angle at which the plurality of panel bodies 2A to 2G are arranged and obliquely rearward, and this support. A support diagonal 54 arranged obliquely forward that supports the upper portion of the plate 53 forms a frame structure fixed on the base 51 in a state where the upper ends thereof are joined to each other. Here, the joint between the support plate 53 and the support diagonal 54 is referred to as an upper corner 5a (FIG. 11).

The panel main body 2A provided at the uppermost portion is provided with an upper wind shielding plate 6 extending from the upper portion of the panel toward the lower rear side of the panel. The upper wind shielding plate 6 has an upper end 6b fixed to the upper corner portion 5a of the gantry body 5, extends downward along the support diagonal 54, and has a lower end 6c curved rearward.
In the upper wind shielding plate 6, a plurality (four) of the rectifying plates 3 (3 </ b> A to 3 </ b> D) are arranged with an interval from the wind shielding surface 6 a facing rearward. These rectifying plates 3 </ b> A to 3 </ b> D are arranged so that the air E passing between the upper wind shielding plate 6 moves upward along the upper wind shielding plate 6.

As with the first embodiment, the rectifying plate 3A located at the uppermost portion is integrally provided with the outlet 4 and the wind collected by the upper wind shield 6 and the rectifying plates 3A to 3D is blown out. To the panel surface 2a of the panel body 2A provided at the top.
In addition, the panel main body 2G provided at the lowermost portion is provided with a lower wind shielding plate 7 extending downward from the lower portion of the panel. The lower end portion of the lower wind shielding plate 7 is curved so as to follow the upper surface of the base 51 from the panel main body 2G. The panel main body 2G arranged at the lowermost part is arranged at an angle that opens downward with respect to the wind shielding surface 7a of the lower wind shielding plate 7, and the panel main body 2G and the wind shielding surface 7a have a predetermined interval. It is arranged with a gap.

  Further, the panel main body 2 (2A to 2G) has an elongated wing plate shape whose lower surface side is formed in a streamlined manner, so that a downward force (on the panel itself due to a pressure difference of air passing through the upper and lower surfaces of the panel ( Downforce) will occur. Therefore, since the photovoltaic power generation panel 1B is pressed downward by the panel via the gantry body 5B, it is possible to more reliably suppress the panel itself or the cradle from being lifted.

In this case, as shown in FIG. 12 (a), when wind blows from the rear of the photovoltaic power generation panel 1A, air flows on the lower surfaces of the rectifying plates 3A to 3C provided on the upper side of the panel, which is the windward side. E flows in, the air E is guided to the wind shield surface 6a of the upper wind shield 6 and moves to the outlet 4 side, and the forced air is directed from the outlet 4 toward the panel surface 2a of the panel body 2A provided at the top. Will be blown out. Further, in the panel bodies 2B to 2G excluding the uppermost panel body 2A, the wind blown from the rear of the panel through the flow path S between the panel bodies 2 and 2 positioned above and below is directed toward the panel surface 2a. Passing through, this passing air also becomes a forced air flowing along the panel surface 2a.
Furthermore, since it becomes possible to collect more winds by the upper wind shield 6, it is possible to increase the air volume (wind speed) of the forced wind, and the effects of the cleaning action and the temperature rise restraining action of the panel surface 2 a. Can be increased.

  Moreover, as shown in FIG.12 (b), when a wind blows from the front of the photovoltaic power generation panel 1A, the air E passes along the panel surface 2a of each panel main body 2A-2G, and each panel main body 2 Into the rear flow path S (the outlet 4 in the uppermost panel body 2A) and discharged to the rear side of the panel body 2. That is, by providing the flow path S and the outlet 4, the air E easily flows along each panel surface 2 a, and this passing air becomes a forced air.

As mentioned above, although embodiment of the solar power generation panel by this invention was described, this invention is not limited to said embodiment, In the range which does not deviate from the meaning, it can change suitably.
For example, in the embodiment described above, the photovoltaic power generation panels 1, 1A, 1B are supported by the gantry main bodies 5, 5A, 5B. However, the configuration is not limited to the configuration in which the gantry main bodies 5, 5A, 5B are provided. . For example, as shown in FIG. 13, it is also possible to arrange the panel body 2 (2A to 2G) directly on the inclined roof 55 of a building such as a house.
In addition, 1 C of photovoltaic power generation panels shown in FIG. 13 are the south side of the mountain-shaped inclined roof 55 (from the roof top part in FIG. 13) in the wing board-shaped panel main bodies 2A-2F by 3rd Embodiment mentioned above by side view. It is an example employ | adopted as 55 A of 1st inclination parts of the left side. And the two baffle plates 3 (3A, 3B) are provided, and the 2nd inclination part 55B of the north side (right side from a roof top part in FIG. 9) has the function of a windshield. In this case, if each of the panel main bodies 2A to 2F is arranged with a space with respect to the first inclined portion 55A, the wind flows through the flow path S formed between the panel main bodies 2 and 2 to each other. 2 will be distributed through the rear side and the front side. Therefore, this passing air also becomes a forced air flowing along the panel surface 2a, and suppresses the floating caused by the negative pressure of the photovoltaic power generation panel 1A as in the first to third embodiments described above. It has the effect of being able to do it.

In the second embodiment, the three rectifying plates 3A to 3C are provided. However, the number of rectifying plates to be installed is only required to be at least one in the upper portion of the panel, and is set to an arbitrary number. It is possible.
The lower wind shielding plate 7 and the lower rectifying plate 8 may be omitted as appropriate.

  Furthermore, the configuration of the panel body 2, the rectifying plate 3, and the wind shielding plate, such as the shape, material, orientation, and mounting position (the distance between the wind shielding plate and the rectifying plate, the arrangement interval between the rectifying plates), etc. It can be set as appropriate according to conditions such as the size of the panel, the shape of the gantry body 5, the shape of the roof, or the natural conditions (for example, a place where there is a lot of strong winds).

  In addition, it is possible to appropriately replace the components in the above-described embodiments with known components without departing from the spirit of the present invention.

DESCRIPTION OF SYMBOLS 1, 1A, 1B, 1C Photovoltaic power generation panel 2, 2A-2G Panel main body 2a Panel surface 2b Panel back surface 3, 3A-3C Rectifier plate 4 Outlet 5, 5A, 5B Base frame body 5a Upper corner 6 Upper wind shield 7 Lower air shield 8 Lower rectifier E Air S Flow path R Back space of the panel

Claims (3)

A plurality of louver-like panel bodies in which adjacent ones are arranged vertically with a gap between each other;
A rectifying plate provided on the panel upper side of the panel body located at the top;
A blowout port that discharges air from the rear of the panel provided on the current plate so as to circulate along the panel surface of the panel body located at the uppermost portion;
With
The space on the panel surface side communicates with the space on the back side of the panel through the gap between the panel bodies ,
The panel body provided at the uppermost part is provided with a wind shield extending from the upper part of the panel toward the lower rear side of the panel,
The said baffle plate is arrange | positioned at intervals with respect to the wind-shielding surface of the said wind-shielding plate, The solar power generation panel characterized by the above-mentioned. The solar panel according to claim 1 , wherein a lower wind shielding plate extending downward from a lower portion of the panel is provided in the panel body located at the lowest level. A plurality of louver-like panel bodies in which adjacent ones are arranged vertically with a gap between each other;
A rectifying plate provided on the panel upper side of the panel body located at the top;
A blowout port that discharges air from the rear of the panel provided on the current plate so as to circulate along the panel surface of the panel body located at the uppermost portion;
With
The space on the panel surface side communicates with the space on the back side of the panel through the gap between the panel bodies,
The panel body located on the upper side among the panel bodies adjacent to each other above and below is disposed on the panel rear side with respect to the panel body located on the lower side,
The lower end portion of the panel body located on the rear side of the panel is superimposed above the upper end portion of the panel body adjacent to the front side of the panel with a flow path in a direction perpendicular to the panel surface direction. solar power panel.

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