JP7456053B1 - Solar panel installation structure, solar panel power generation system, and solar panel power generation method - Google Patents

Abstract

[Problem] To enable new solar panels to be installed without requiring a large installation space, and to generate electricity using not only newly installed solar panels but also existing solar panels. [Solution] A solar panel installation structure 12 includes a first solar panel 18 installed on an installation surface, and a second solar panel 20 installed above the first solar panel 18 and transmitting light. , and a holding member that holds the second solar panel 20 above the first solar panel 18. [Selection diagram] Figure 1

Description

The technology disclosed in the present application relates to a solar panel installation structure.

Patent Document 1 includes a solar cell panel, a horizontal beam and a vertical beam on which the solar cell panel is placed, and a first arm and a second arm that support the vertical beam via a locking member. A solar cell system 1 is described. Further, in Patent Document 1, the first arm is attached at an angle greater than 0° with respect to the disclosure vertical direction, and the first arm is attached at an angle greater than 0° with respect to the vertical direction on the opposite side of the first arm. A base section is described that includes a mounting section for attaching a second arm that is inclined to the base.

Patent Document 2 describes a first solar panel that generates electricity using light in the short wavelength region of sunlight, a concentrator made of a material with an infrared absorption function, and a system that mainly uses the first solar panel. A solar power generation system is described that includes a second solar panel that generates power with light in a wavelength range that is not used for power generation. In this solar power generation system, the light transmitted through the first solar panel is collected by a concentrator and irradiated onto the second solar panel to generate electricity.

JP 2015-21332 Publication Japanese Patent Application Publication No. 2000-156518

For example, when the power generation capacity of solar panels decreases over time, it is conceivable to add and install new solar panels. Furthermore, even if the power generation capacity of solar panels has not decreased, it is possible to increase the overall power generation amount by adding and installing new solar panels. However, when new solar panels are installed side by side with existing solar panels, a large installation space is required when viewed from above.

With the techniques described in Patent Document 1 and Patent Document 2, there is no point of view of increasing the power generation amount of the solar panel without increasing the installation space of the solar panel.

In consideration of the above facts, this application proposes that it is possible to install new solar panels without requiring a large installation space, and that it is possible to generate electricity using not only newly installed solar panels but also existing solar panels. purpose.

The solar panel installation structure of the first aspect includes a first solar panel installed on an installation surface, a second solar panel installed above the first solar panel and transmitting light, and a second solar panel installed above the first solar panel and transmitting light. and a holding member that holds the second solar panel above the first solar panel.

In this solar panel installation structure, the second solar panel is installed above the first solar panel installed on the installation surface, and is held by the holding member. The second solar panel transmits light. The light that has passed through the second solar panel reaches the first solar panel, and the first solar panel also generates electricity. It is possible to generate electricity with both the first solar panel and the second solar panel. Moreover, since the second solar panel is installed above the first solar panel, a large installation space is not required in plan view for installation of the second solar panel.

In a second aspect, in the first aspect, the second solar panel is arranged to overlap the first solar panel.

By arranging the second solar panel so as to overlap the first solar panel, there is no need to process the installation surface when installing the second solar panel on the installation surface. Since there is no gap between the first solar panel and the second solar panel, the overall height can be reduced, and lifting of the second solar panel due to wind or the like can be suppressed.

In a third aspect, in the first or second aspect, the holding member includes an adhesive that adheres the first solar panel and the second solar panel.

The adhesive allows the second solar panel to be firmly fixed to the first solar panel.

The adhesive can be arranged, for example, in a shape surrounding the first solar panel. Thereby, the second solar panel can be fixed around the entire circumference of the first solar panel.

Further, for example, for a rectangular first solar panel, the adhesive can be placed along two opposing sides of the first solar panel. Thereby, when the first solar panel and the second solar panel thermally expand and there is a difference in size between the first solar panel and the second solar panel, this difference can be absorbed.

In a fourth aspect, in the third aspect, the adhesive is placed so as to avoid the light receiving range of the first solar panel.

The adhesive does not narrow the substantial light-receiving range of the first solar panel, and the light-receiving range of the first solar panel can be effectively utilized.

In a fifth aspect, in the first or second aspect, the holding member includes a clamping tool that clamps the first solar panel and the second solar panel in the thickness direction.

The clamping tool allows the second solar panel to be easily fixed to the first solar panel.

In a sixth aspect, in any one of the first to fifth aspects, the first solar panel has higher bending rigidity than the second solar panel.

Compared to a configuration in which the first solar panel has low bending rigidity, bending of the first solar panel is suppressed in a state where the first solar panel supports the second solar panel.

In a seventh aspect, in any one of the first to sixth aspects, the second solar panel has a smaller mass per unit area than the first solar panel.

Compared to a configuration in which the second solar panel is not lightweight, the impact on the first solar panel and the installation surface can be reduced.

In an eighth aspect, according to any one of the first to seventh aspects, the solar panel includes a support member that supports the first solar panel on the installation surface.

The first solar panel can be supported by the support member. It is possible to realize a configuration in which there is no need to remove and discard the first solar panel including the supporting member.

In the solar panel power generation system of the ninth aspect, a first solar panel installed on an installation surface, a second solar panel installed above the first solar panel and transmitting light, and a second solar panel installed above the first solar panel and transmitting light; It has a holding member that holds two solar panels above the first solar panel, and a recovery member that collects the power generated by the first solar panel and the second solar panel.

In this solar panel power generation system, the second solar panel is installed above the first solar panel installed on the installation surface, and is held by a holding member. The second solar panel transmits light. The light that has passed through the second solar panel reaches the first solar panel, and the first solar panel also generates electricity. It is possible to generate electricity with both the first solar panel and the second solar panel. The power generated by the first solar panel and the second solar panel can be recovered by the recovery member. Moreover, since the second solar panel is installed above the first solar panel, no installation space is required for installing the second solar panel.

In the solar panel power generation method of the tenth aspect, the power generated by the first solar panel installed on the installation surface and the second solar panel installed above the first solar panel and transmitting light in the thickness direction The power generated by the panel is recovered by a recovery member.

In this solar panel power generation method, the second solar panel transmits light. The light that has passed through the second solar panel reaches the first solar panel, and the first solar panel also generates electricity. It is possible to generate electricity with both the first solar panel and the second solar panel. The power generated by the first solar panel and the second solar panel is recovered by a recovery member. Since the second solar panel is installed above the first solar panel, no installation space is required for installing the second solar panel.

With the technology of the present disclosure, it is possible to newly install a solar panel without requiring a large installation space, and it is possible to generate electricity using not only the newly installed solar panel but also the existing solar panel.

FIG. 1 is a perspective view showing a solar panel installation structure and a solar panel power generation system according to the first embodiment. FIG. 2 is an exploded perspective view showing the solar panel installation structure and solar panel power generation system of the first embodiment. FIG. 3 is a perspective view showing the solar panel installation structure of the first embodiment in a state in the middle of manufacturing. FIG. 4 is a perspective view showing the solar panel installation structure of the first embodiment in a state in the middle of manufacturing. FIG. 5 is a side view showing the solar panel installation structure of the first embodiment. FIG. 6 is a partially enlarged sectional view showing the solar panel installation structure of the first embodiment. FIG. 7 is a partially enlarged sectional view showing the solar panel installation structure of the second embodiment. FIG. 8 is a partially enlarged sectional view showing the solar panel installation structure of the third embodiment. FIG. 9 is an exploded perspective view showing a solar panel installation structure and a solar panel power generation system according to the fourth embodiment. FIG. 10 is a perspective view showing a modified solar panel installation structure and a solar panel power generation system. FIG. 11 is a perspective view showing a solar panel installation structure and a solar panel power generation system according to the fifth embodiment. FIG. 12 is an exploded perspective view showing a solar panel installation structure and a solar panel power generation system according to the fifth embodiment. FIG. 13 is a perspective view showing a solar panel installation structure and a solar panel power generation system according to the sixth embodiment. FIG. 14 is an exploded perspective view showing a solar panel installation structure and a solar panel power generation system according to the sixth embodiment. FIG. 15 is a perspective view showing a solar panel installation structure and a solar panel power generation system according to the seventh embodiment. FIG. 16 is an exploded perspective view showing a solar panel installation structure and a solar panel power generation system according to the seventh embodiment.

Hereinafter, an example of an embodiment of the present application will be described in detail with reference to the drawings. In addition, in this specification, the first embodiment, third embodiment, fourth embodiment, fifth embodiment, sixth embodiment, and seventh embodiment shall be read as reference examples. .

FIGS. 1 and 2 show a perspective view of a solar panel power generation system 14 to which the solar panel installation structure 12 of the first embodiment is applied.

The solar panel installation structure 12 of the first embodiment includes a pedestal 16, a first solar panel 18, a second solar panel 20, and an adhesive 22. The pedestal 16 is a pedestal that supports the first solar panel 18. The pedestal 16 is an example of a support member. The pedestal 16 is installed on the installation surface 24. That is, the first solar panel 18 is installed on the installation surface 24 via the pedestal 16. The installation surface 24 may be, for example, the ground or the upper surface of the roof of a building. Note that the first solar panel 18 may be directly installed on the installation surface 24 without using the mount 16. For example, a concrete foundation may be cast in the ground, and the first solar panel 18 may be installed on this foundation.

In the example shown in FIG. 2, the pedestal 16 has a lower frame 16A, an upper frame 16B, and four pillars 16C. The lower frame 16A is a rectangular frame-shaped portion fixed to the installation surface 24. A plurality of pillars 16C (four in total, one from each of the four corners in the example of FIG. 2) are erected upward from the lower frame 16A. The upper frame 16B is a rectangular frame-shaped portion on which the first solar panel 18 is placed. The length of the support column 16C is set so that the upper frame 16B is inclined at a predetermined inclination angle θ (see FIG. 5) with respect to the lower frame 16A. The first solar panel 18 is fixed to the pedestal 16 using fixing tools such as bolts.

The first solar panel 18 is formed into a rectangular plate shape. In the illustrated example, one surface (single surface) of the first solar panel 18 is a light-receiving surface. The first solar panel 18 is not limited to one in which one side is a light-receiving surface, and for example, both surfaces may be light-receiving surfaces. On the light receiving surface of the first solar panel 18, a light receiving range 18B is provided in a rectangular range inside the four sides. The first solar panel 18 generates power by receiving light in the light receiving range 18B. The first solar panel 18 is fixed to the pedestal 16 so that the light-receiving surface faces upward.

In this embodiment, the first solar panel 18 has a predetermined thickness T1 (see FIG. 6). The first solar panel 18 has a predetermined bending rigidity, and is prevented from being unintentionally bent due to gravity or the like while being supported by the pedestal 16.

The first solar panel 18 is provided with a power supply cable 28 . Electric power generated by the first solar panel 18 is recovered by the power supply cable 28 and supplied to external equipment. External devices include, for example, storage batteries, electrical devices that consume power, and the like. The power supply cable 28 is an example of a collection member of the technology of the present disclosure.

In the illustrated example, the second solar panel 20 is formed into a rectangular plate shape like the first solar panel 18. The second solar panel 20 is not limited to a plate shape, but may be a sheet shape or a film shape. One surface of the second solar panel 20 is a light receiving surface. On the light receiving surface of the second solar panel 20, a light receiving range 20B is provided in a rectangular range inside the four sides. The second solar panel 20 generates power by receiving light in the light receiving range 20B. The second solar panel 20 is installed above the first solar panel 18 so that its light-receiving surface faces upward.

In this embodiment, the thickness T2 (see FIG. 6) of the second solar panel 20 is thinner than the thickness T1 of the first solar panel 18. Therefore, the first solar panel 18 has relatively higher bending rigidity than the second solar panel 20. Moreover, the mass per unit area of the second solar panel 20 is smaller than the mass per unit area of the first solar panel 18. That is, the second solar panel 20 is lighter in weight than the first solar panel 18.

The second solar panel 20 is also provided with a power supply cable 30 similarly to the first solar panel 18 . Electric power generated by the second solar panel 20 is recovered by the power supply cable 30 and supplied to external equipment. The technology of the present disclosure is configured such that power can be collected by both the power supply cable 28 of the first solar panel 18 and the power supply cable 30 of the second solar panel 20 and supplied to external equipment.

The second solar panel 20 is arranged to overlap the first solar panel 18. The second solar panel 20 is bonded to the first solar panel 18 with an adhesive 22. The adhesive 22 is an example of the holding member of the disclosed technology.

As shown in FIGS. 3 and 4, the adhesive 22 is applied along the four sides of the first solar panel 18 in a rectangular frame shape. That is, the adhesive 22 has a closed rectangular shape when viewed in the normal direction of the light-receiving surface of the first solar panel 18 . Although the thickness of the adhesive 22 is illustrated in FIGS. 5 and 6, the thickness of the adhesive 22 is actually thin, and the second solar panel 20 is not in contact with the first solar panel 18. ing.

In the technique of the present disclosure, the adhesive 22 is applied while avoiding the light receiving range 18B of the first solar panel 18. That is, the adhesive 22 is arranged so as not to cover the light receiving range 18B of the first solar panel 18.

In the examples shown in FIGS. 2 to 4, the adhesive 22 application area as a whole has a closed rectangular shape when viewed in the normal direction of the first solar panel 18. In the example shown in FIGS. When the area to which the adhesive 22 is applied has a closed shape as described above, an air vent hole may be provided at at least one location. Providing an air vent hole at the bottom in the vertical direction can prevent rainwater from entering through the hole. Further, a filter may be attached to this hole to prevent foreign matter from entering. Furthermore, the adhesive 22 may be applied along two opposing sides of the four sides of the first solar panel 18. In this way, by applying the adhesive 22 along the two opposing sides of the first solar panel 18, the first solar panel 18 and the second solar panel 20 are thermally expanded, and the first solar panel If there is a difference in size between the panel 18 and the second solar panel 20, this difference can be absorbed. For example, in the modified solar panel installation structure 112 and the solar panel power generation system 114 shown in FIG. It is applied horizontally along the Further, although not shown, the adhesive 22 may be applied vertically along the left and right sides of the first solar panel 18.

The second solar panel 20 transmits light in the thickness direction. Specifically, the second solar panel 20 The solar panel 20 transmits light. As long as this condition is met, the wavelength range of the transmitted light may be part of the wavelength range of visible light. For example, if the first solar panel 18 and the second solar panel 20 have different peak wavelengths that contribute to power generation, the first solar panel 18 uses light in the wavelength range that contributes to power generation more. If the second solar panel 20 is transparent, both the first solar panel 18 and the second solar panel 20 can efficiently generate power. Moreover, the term "transmission" used herein does not only mean that light is completely transmitted, but also, for example, the light transmittance may be 30% or more, preferably 50% or more.

Next, the operation of this embodiment, the manufacturing method of the solar panel installation structure, and the solar panel power generation method will be explained.

In the solar panel installation method of this embodiment, as shown in FIG. 3, the first solar panel 18 is already installed on the pedestal 16. That is, the first solar panel 18 is installed on the installation surface 24 via the frame 16.

A second solar panel 20 is installed above the first solar panel 18. Specifically, as shown in FIG. 4, an adhesive 22 is applied along the four sides of the first solar panel 18, and the adhesive 22 connects the first solar panel 18 and the second solar panel. 20. Note that the adhesive 22 is applied while avoiding the light receiving range 18B of the first solar panel 18.

Thereby, the second solar panel 20 is arranged to overlap the first solar panel 18. Since sunlight enters the light receiving range 20B of the second solar panel 20, the second solar panel 20 can generate electricity. Moreover, since the second solar panel 20 transmits sunlight SL, the transmitted sunlight SL also reaches the light receiving range 18B of the first solar panel 18. When the sunlight SL enters the light receiving range 18B of the first solar panel 18, the first solar panel 18 also generates power. That is, by installing the second solar panel 20, a configuration in which both the second solar panel 20 and the first solar panel 18 generate electricity is realized as the solar panel power generation system 14.

Then, the cables for feeding power to external devices are set to serve as both the power feeding cable 28 of the first solar panel 18 and the power feeding cable 30 of the second solar panel 20. Thereby, the power generated by both the second solar panel 20 and the first solar panel 18 can be supplied to external equipment.

The second solar panel 20 is arranged to overlap the first solar panel 18. When installing the second solar panel 20 on the installation surface 24, processing of the installation surface 24 may be required, but with the technology of the present disclosure, such processing is not necessary. Moreover, since the structure has no gap between the first solar panel 18 and the second solar panel 20, the height of the solar panel installation structure 12 as a whole can be reduced. Further, it is possible to suppress the floating of the second solar panel 20 due to wind flowing into the gap between the first solar panel 18 and the second solar panel 20.

In the first embodiment, the first solar panel 18 and the second solar panel 20 are bonded together using an adhesive 22. The adhesive 22 allows the second solar panel 20 to be firmly bonded to the first solar panel 18 .

Moreover, the adhesive 22 is provided around the entire circumference of the first solar panel 18. That is, the second solar panel 20 can be fixed around the entire circumference of the first solar panel 18.

The adhesive 22 is applied while avoiding the light receiving range 18B of the first solar panel 18. That is, the sunlight SL heading toward the light receiving range 18B of the first solar panel 18 is made to enter the light receiving range 18B without being blocked by the adhesive 22. Thereby, the first solar panel 18 can generate electricity by effectively using the light receiving range 18B.

The bending rigidity of the first solar panel 18 is higher than that of the second solar panel 20. Therefore, compared to the case where the bending rigidity of the first solar panel 18 is lower than the bending rigidity of the second solar panel 20, the bending stiffness in the state where the first solar panel 18 supports the second solar panel 20 is is suppressed.

The mass per unit area of the second solar panel 20 is smaller than the mass per unit area of the first solar panel 18. That is, the second solar panel 20 has a similar area and is lighter than the first solar panel 18. Therefore, compared to a configuration in which the second solar panel 20 is not lightweight, the influence of the load of the second solar panel 20 acting on the first solar panel 18 and the installation surface 24 can be reduced.

Next, a second embodiment will be described. In the second embodiment, the same elements, members, etc. as in the first embodiment are given the same reference numerals as in the first embodiment, and detailed explanation thereof will be omitted.

As shown in FIG. 7, in the solar panel installation structure 42 of the second embodiment, a bracket 44 is used as the holding member of the technology of the present disclosure instead of the adhesive 22 of the first embodiment. The bracket 44 is an example of a holding member of the technology of the present disclosure, and is also an example of a clamping tool.

The bracket 44 is a flat, substantially U-shaped member that is elongated as a whole when viewed in cross section as shown in FIG. The brackets 44 are arranged above and below the first solar panel 18 so that their longitudinal direction matches the width direction of the first solar panel 18 .

The distance between the lower piece 44A and the upper piece 44B of the bracket 44 is slightly narrower than the combined thickness of the upper frame 16B of the pedestal 16, the first solar panel 18, and the second solar panel 20. However, by elastically pushing apart the upper piece 44B and the lower piece 44A, it is possible to sandwich the upper frame 16B, the first solar panel 18, and the second solar panel 20 in the thickness direction. .

The upper piece 44B of the bracket 44 is shaped so as not to cover the light receiving range 18B of the second solar panel 20.

In the second embodiment having such a configuration, it is possible to hold the second solar panel 20 above the first solar panel 18 using the bracket 44. Since the second solar panel 20 can be held above the first solar panel 18 by simply holding the upper frame 16B, the first solar panel 18, and the second solar panel 20 in the thickness direction using the bracket 44, The work of installing the second solar panel 20 is easy.

Next, a third embodiment will be described. Also in the third embodiment, the same elements, members, etc. as in the first embodiment are given the same reference numerals as in the first embodiment, and detailed explanation thereof will be omitted.

As shown in FIG. 8, in the solar panel installation structure 52 of the third embodiment, instead of the adhesive 22 of the first embodiment and the bracket 44 of the second embodiment as the holding member of the technology of the present disclosure, A string member 54 is used. The string member 54 is an example of the holding member of the technology of the present disclosure.

The string member 54 is a string or tape having a length that can be wrapped around the upper frame 16B of the pedestal 16, the first solar panel 18, and the second solar panel 20 when viewed in the cross section shown in FIG. It is a shaped member. The string member 54 is provided with a fastening member so that it can be wound around the upper frame 16B, the first solar panel 18, and the second solar panel 20 to maintain the annular state. . Examples of fastening members include buckles, hook-and-loop fasteners, adhesive tapes, staplers, pins, and the like. Furthermore, the ends of the string member 54 may be tied together without using these fastening members.

In the third embodiment having such a configuration, it is possible to hold the second solar panel 20 above the first solar panel 18 using the string member 54. The length of the string member 54 to be wound around the upper frame 16B, the first solar panel 18, and the second solar panel 20 can be adjusted. The second solar panel 20 can be held above the first solar panel 18 depending on the thickness.

Next, a fourth embodiment will be described. Also in the fourth embodiment, the same elements, members, etc. as in the first embodiment are given the same reference numerals as in the first embodiment, and detailed explanation thereof will be omitted.

As shown in FIG. 9, in the solar panel installation structure 62 and the solar panel power generation system 64 of the fourth embodiment, the adhesive 22 of the first embodiment and the adhesive 22 of the second embodiment are used as the holding members of the technology of the present disclosure. A second mount 66 is used in place of the bracket 44 of the third embodiment and the string member 54 of the third embodiment. The second mount 66 is also an example of a support member.

The second pedestal 66 is formed larger than the pedestal 16 so as to surround the outside of the pedestal 16 when viewed in the normal direction of the installation surface 24 . Specifically, the lower frame 66A and the upper frame 66B of the second pedestal 66 are formed into rectangles larger than the lower frame 16A and the upper frame 16B of the pedestal 16. Further, the length of the support column 66C of the second mount 66 is set so that the upper frame 66B of the second mount 66 can support the second solar panel 20 above the first solar panel 18. The second solar panel 20 is supported by the second pedestal 66 above the first solar panel 18 with a slight gap between the second solar panel 20 and the first solar panel 18 . Substantially, there is no gap between the first solar panel 18 and the second solar panel 20, and the second solar panel 20 is arranged to overlap the first solar panel 18.

In the fourth embodiment having such a configuration, it is possible to hold the second solar panel 20 above the first solar panel 18 using the second mount 66. Since the second mount 66 supports the second solar panel 20, it is possible to realize a structure in which the load of the second solar panel 20 is not applied to the first solar panel 18. Also in the fourth embodiment, the second solar panel 20 can be installed without removing or discarding the first solar panel 18 and the mount 16 and without requiring a large installation space.

In the above example, the size of the first solar panel 18 when viewed in the normal direction and the size of the second solar panel 20 when viewed in the normal direction are approximately the same. On the other hand, as in each embodiment shown below, even if the size of the first solar panel 18 when viewed in the normal direction and the size of the second solar panel 20 when viewed in the normal direction are different, good. Also in each of the following embodiments, the same members, elements, etc. as in the first embodiment are given the same reference numerals as in the first embodiment, and detailed explanation thereof will be omitted.

In the solar panel installation structure 72 and the solar panel power generation system 74 of the fifth embodiment shown in FIG. It is. In the example shown in FIG. 11, the first solar panel 18 and the second solar panel 20 are approximately equal in length (length in the direction orthogonal to the width direction), but the length in the width direction (length in the width direction) is approximately the same. The second solar panel 20 is approximately half of the first solar panel 18. Two second solar panels 20 are arranged side by side on one first solar panel 18.

In the example shown in FIG. 12, the shape of the adhesive 22 applied in the fifth embodiment is a rectangular frame shape along the four sides of the first solar panel 18. Instead, for example, similar to the modification shown in FIG. 11, the adhesive 22 is applied laterally along the upper and lower sides, which are two opposing sides of the four sides of the first solar panel 18. It's okay. Alternatively, focusing on the second solar panel 20 instead of the first solar panel 18, the coating may be applied in the vertical direction at the left and right side positions of the second solar panel 20.

In the solar panel installation structure 82 and solar panel power generation system 84 of the sixth embodiment shown in FIG. 13, one second solar panel 20 has a corresponding size to two first solar panels 18. It is. In the example shown in FIG. 13, the first solar panel 18 and the second solar panel 20 are approximately equal in length (length in the direction orthogonal to the width direction), but the length in the width direction (length in the width direction) is approximately the same. The second solar panel 20 is approximately twice as large as the first solar panel 18. One second solar panel 20 is placed on the two first solar panels 18 that are arranged side by side in the horizontal direction.

In the example shown in FIG. 14, the shape of the adhesive 22 applied in the sixth embodiment is a rectangular frame shape along each of the four sides of the two first solar panels 18. Instead, for example, similar to the modification shown in FIG. 11, the adhesive 22 is applied laterally along the upper and lower sides, which are two opposing sides of the four sides of the first solar panel 18. It's okay. Alternatively, focusing on the second solar panel 20 instead of the first solar panel 18, the coating may be applied in a rectangular frame shape along the four sides of the second solar panel 20.

In the solar panel installation structure 92 and the solar panel power generation system 94 of the seventh embodiment shown in FIG. It is. In the example shown in FIG. 15, the first solar panel 18 and the second solar panel 20 are approximately equal in length (length in the direction orthogonal to the width direction), but the length in the width direction (length in the width direction) is approximately the same. The second solar panel 20 is approximately 1.5 times as large as the first solar panel 18. Two second solar panels 20 are arranged on the three first solar panels 18 that are arranged side by side in the horizontal direction.

In the example shown in FIG. 16, the shape of the adhesive 22 applied in the seventh embodiment is a rectangular frame shape along each of the four sides of the two second solar panels 20. Alternatively, focusing on the first solar panel 18 instead of the second solar panel 20, the coating may be applied in a rectangular frame shape along the four sides of the first solar panel 10. Further, for example, similar to the modification shown in FIG. 11, the adhesive 22 may be applied laterally along the upper and lower sides, which are two opposing sides of the four sides of the first solar panel 18. .

When the adhesive 22 is applied as shown in FIG. 16, a part of the adhesive 22 is applied on the light receiving surface (light receiving range 18B) of the first solar panel 18 in the center. That is, in the central first solar panel 18, a part of the light receiving range 18B is shaded by the adhesive 22. In this case, the first solar panel 18 at the center may not be used for power generation, and the first solar panels 18 on both sides in the width direction may be used for power generation. When the first solar panel 18 in the center is not used for power generation, for example, the power supply cable 28 of the first solar panel 18 in the center is not connected to an external device, and the first solar panel 18 on both sides in the width direction The power supply cable 28 may be connected to an external device so that the generated power can be extracted. Of course, even if the first solar panel 18 in the center is shaded by the adhesive 22, this does not prevent the first solar panel 18 in the center from being used for power generation.

In addition, in the seventh embodiment, in a configuration in which the adhesive 22 is applied laterally along the upper and lower sides of the first solar panel 18, as in the modification shown in FIG. portion of the solar panel 18 no longer covers the light receiving range 18B of the first solar panel 18.

In the technology of the present disclosure, the second solar panel 20 may be installed further above the second solar panel 20 installed on the first solar panel 18. In this configuration, two second solar panels 20 are arranged one on top of the other, and the first solar panel 18 can generate electricity using sunlight that has passed through these two second solar panels 20. In addition, when the second solar panel 20 installed on the first solar panel 18 deteriorates, the deteriorated second solar panel 20 is removed and a new second solar panel 20 is replaced with the first solar panel 20. It may be installed on the solar panel 18.

In the technology of the present disclosure, the installation surface 24 to which the solar panel installation structure is applied is not limited to the ground and the roof of a building. For example, instead of the ground and the roof of a building, it may be a fixed structure. Alternatively, the first solar panel 18 may be installed on the installation surface 24 without using the pedestal 16.

In the solar panel installation structure according to the technology of the present disclosure, by generating power from the solar panels installed using this solar panel installation structure, it replaces power generation by burning fossil fuels and reduces _CO2 emissions. This has the effect of reducing

12 Solar panel installation structure 14 Solar panel power generation system 16 Frame (an example of supporting member)
18 First solar panel 18B Light receiving range of the first solar panel 20 Second solar panel 20B Light receiving range of the second solar panel 22 Adhesive (an example of a holding member)
24 Installation surface 28, 30 Power supply cable 42 Solar panel installation structure 44 Bracket (an example of a clamping tool, an example of a holding member)
52 Solar panel installation structure 54 String member (an example of holding member)
62 Solar panel installation structure 64 Solar panel power generation system 66 Second mount (an example of a support member, an example of a holding member)
72 Solar panel installation structure 74 Solar panel power generation system 82 Solar panel installation structure 84 Solar panel power generation system 92 Solar panel installation structure 94 Solar panel power generation system

Claims (5)

A support member installed on the installation surface,
a first solar panel supported by the support member;
a second solar panel that is installed above the first solar panel to overlap the first solar panel and transmits light;
In a state where the support member, the first solar panel, and the second solar panel are stacked, a clamping tool is included that elastically clamps the overlapping portion in the thickness direction, and the second solar panel is stacked on the second solar panel. A holding member held above the first solar panel;
A solar panel installation structure with The solar panel installation structure according to claim 1, wherein the first solar panel has higher bending rigidity than the second solar panel. The solar panel installation structure according to claim 1, wherein the second solar panel has a smaller mass per unit area than the first solar panel. A support member installed on the installation surface,
a first solar panel supported by the support member;
a second solar panel that is installed above the first solar panel to overlap the first solar panel and transmits light;
In a state where the support member, the first solar panel, and the second solar panel are stacked, a clamping tool is included that elastically clamps the overlapping portion in the thickness direction, and the second solar panel is stacked on the second solar panel. A holding member held above the first solar panel;
a recovery member that recovers the power generated by the first solar panel and the second solar panel;
A solar panel power generation system with The power generated by the first solar panel supported by the support member on the installation surface;
Elastically clamping in the thickness direction at a portion overlapping with the support member and the first solar panel by a holding member that is installed above the first solar panel and includes a clamping tool. power generated by a second solar panel that is held above the first solar panel and transmits light;
A solar panel power generation method that collects energy using a collection member.