JP2020094453A - Solar power generation system - Google Patents

Abstract

To provide a solar power generation system capable of improving the design while increasing a light receiving area of a solar cell module.SOLUTION: The solar power generation system comprises a first solar cell module, a second solar cell module 1b that is installed side by side with the first solar cell module in a row direction and has a dimension in a step direction orthogonal to the row direction that is smaller than that of the first solar cell module, a first fixing member 21 for fixing the second solar cell module 1b to an installation location, and a gap adjusting member 3 for adjusting the gap between the first fixing member 21 and the second solar cell module 1b in the second direction.SELECTED DRAWING: Figure 5

Description

The present invention relates to a solar power generation system including a plurality of solar cell modules.

A solar power generation system is known in which a plurality of solar cell modules are arranged side by side on a roof of a house, a roof of a building, or the like. In such a photovoltaic power generation system, in order to obtain a larger amount of power generation in an installation place with a limited space, the solar cell modules should be spread over the installation site and installed to secure a wide light receiving area for the solar cell module. Is generally done.

For example, Patent Document 1 discloses a method of installing a rectangular solar cell module and a triangular solar cell module in a hipped roof having a triangular shape, a trapezoidal shape, or the like. In this method, solar cell modules of the same size and rectangular shape are installed side by side in the direction of inclination of the roof and the direction orthogonal to the direction of inclination, and in a triangular space formed between the rectangular solar cell module and the alighting building. By installing the triangular solar cell module, the light receiving area of the solar cell module is increased.

Further, as another method of ensuring a large light receiving area of the solar cell module, there is a method of installing only the rectangular solar cell module in the installation place. In this method, a plurality of solar cell modules with different dimensions along the inclination direction are prepared, and the combination and the number of solar cell modules having different dimensions are adjusted according to the shape and area of the installation place, thereby It is spread all over the place of installation.

JP, 2002-194866, A

However, when the solar cell modules having different dimensions along the inclination direction are arranged side by side in the direction orthogonal to the inclination direction, the adjacent solar cell modules are displaced in the inclination direction. This deviation becomes larger as the number of solar cell modules along the tilt direction increases, so that there is a problem that the appearance is deteriorated and the design is deteriorated.

The present invention has been made in view of the above, and an object of the present invention is to obtain a solar power generation system capable of improving the designability while increasing the light receiving area of the solar cell module.

In order to solve the above-mentioned problems and to achieve the object, a photovoltaic power generation system according to the present invention includes a first solar cell module, the first solar cell module and the first solar cell module, which are arranged side by side in a first direction. A second solar cell module whose dimension along a second direction orthogonal to the second solar cell module is smaller than the first solar cell module, a fixing member for fixing the second solar cell module to an installation location, the fixing member and the second An interval adjusting member that adjusts an interval with the solar cell module along the second direction.

According to the present invention, there is an effect that the designability can be improved while increasing the light receiving area of the solar cell module.

The perspective view which shows the solar power generation system which concerns on Embodiment 1 of this invention. Exploded perspective view showing the solar cell module according to Embodiment 1. The top view which shows the solar cell module which concerns on Embodiment 1. 1 is a perspective view showing a solar cell module and fixing means according to Embodiment 1. FIG. It is a figure which shows the fixing structure of the solar cell module which concerns on Embodiment 1, Comprising: VV sectional view taken on the line of FIG. It is a figure which shows the solar power generation system which concerns on a comparative example, Comprising: The top view which shows the state which installed the solar cell module in which the step size and row direction dimension differ in the row direction. The top view which shows typically a part of solar power generation system of FIG. It is a figure which shows the solar power generation system which concerns on Embodiment 1, Comprising: The top view which shows the state which installed the solar cell module in which the dimension in a row|column direction and the dimension in a row direction differ in the row direction. The top view which shows typically a part of solar power generation system of FIG. Sectional drawing which shows the fixing structure of the 1st solar cell module which concerns on Embodiment 1. Sectional drawing which shows the fixing structure of the 2nd solar cell module which concerns on Embodiment 1. It is sectional drawing which shows the fixing structure of the 2nd solar cell module of the solar power generation system which concerns on Embodiment 2 of this invention, Comprising: The figure equivalent to the VV sectional view shown in FIG. It is sectional drawing which shows the fixing structure of the 2nd solar cell module of the solar power generation system which concerns on Embodiment 3 of this invention, Comprising: It is a figure equivalent to the VV sectional view taken on the line shown in FIG.

Below, the photovoltaic power generation system concerning the embodiment of the present invention is explained in detail based on a drawing. The present invention is not limited to this embodiment.

Embodiment 1.
FIG. 1 is a perspective view showing a photovoltaic power generation system according to Embodiment 1 of the present invention.

As shown in FIG. 1, the solar power generation system 100 includes a plurality of solar cell modules 1 and a fixing unit 2 that fixes the solar cell modules 1 to an installation location. The installation location is, for example, the roof of a house or the roof of a building. The installation surface of the installation location may be a horizontal surface or an inclined surface. In the following description, the “column direction”, which is the first direction, is the left-right direction when the solar power generation system 100 is viewed from the front. In addition, the “step direction”, which is the second direction, is a direction that is orthogonal to the column direction within the installation surface where the solar cell modules 1 are installed.

In the example of FIG. 1, two solar cell modules 1 are installed side by side in the row direction. Although not shown in FIG. 1, a plurality of solar cell modules 1 are installed in the step direction. The size of the solar cell module 1, the number in the row direction, and the number in the row direction may be appropriately changed according to the shape and area of the installation place. Here, when distinguishing a plurality of solar cell modules 1, one solar cell module 1 installed side by side in the row direction is referred to as a first solar cell module 1a, and the other solar cell module 1 is referred to as a second solar cell module 1a. It is referred to as a battery module 1b.

The second solar cell module 1b is installed side by side with the first solar cell module 1a in the row direction. The dimension Lb of the second solar cell module 1b along the step direction is smaller than the dimension La of the first solar cell module 1a along the step direction. Each of the first solar cell module 1a and the second solar cell module 1b has a solar cell panel 11 and a holding frame 12 that holds an outer edge of the solar cell panel 11.

FIG. 2 is an exploded perspective view showing the solar cell module according to the first embodiment. FIG. 3 is a plan view showing the solar cell module according to the first embodiment. As shown in FIGS. 2 and 3, the solar cell panel 11 is a plate-shaped member having a rectangular shape in plan view. The long side of the outer edge of the solar cell panel 11 is parallel to the column direction. The short side of the outer edge of the solar cell panel 11 is parallel to the step direction. The solar battery panel 11 includes a plurality of solar battery cells 11a arranged in an array. The solar battery cell 11a is a photoelectric conversion unit that converts sunlight into electric power. The plurality of solar battery cells 11a are connected in series or in parallel. Although illustration is omitted, glass, which is a transparent substrate, is arranged on the light receiving surface 11b of the solar cell 11a. Although illustration is omitted, the solar battery panel 11 seals the plurality of solar battery cells 11a with an electrically insulating material such as ethylene vinyl acetate (EVA) resin or polyethylene terephthalate (PET) resin. Is formed.

The holding frame 12 is a metal member attached over the entire circumference of the outer edge of the solar cell panel 11. The holding frame 12 is formed in a rectangular frame shape that fits the outer shape of the solar cell panel 11. The holding frame 12 includes two first holding frames 12a attached to the long sides of the outer edges of the solar cell panel 11, and two second holding frames 12b attached to the short sides of the outer edges of the solar cell panel 11. Have.

FIG. 4 is a perspective view showing the solar cell module and the fixing means according to the first embodiment. 5: is a figure which shows the fixing structure of the solar cell module which concerns on Embodiment 1, Comprising: It is the VV sectional view taken on the line of FIG. The fixing means 2 is means for fixing the solar cell module 1 to the installation place. The fixing means 2 includes a first fixing member 21 and a second fixing member 22.

The second fixing member 22 is a metal member that is arranged immediately below the solar cell module 1 and is fixed on the installation surface. The second fixing member 22 extends along the step direction. The longitudinal direction of the second fixing member 22 is orthogonal to the longitudinal direction of the first holding frame 12a. The second fixing member 22 is a channel steel having an open upper side.

Although FIG. 4 illustrates the case where one solar cell module 1 is fixed to the two second fixing members 22 provided at intervals in the column direction, one solar cell module 1 is This does not mean that the number of second fixing members 22 to be fixed is limited. Although not shown, the plurality of solar cell modules 1 are fixed to the second fixing member 22 side by side in the step direction.

The second fixing member 22 has a bottom wall portion 22a, two side wall portions 22b, two upper wall portions 22c, and two ridge portions 22d.

The bottom wall portion 22a is a plate-shaped portion extending along the step direction. The bottom wall portion 22a is formed in a rectangular shape that is long in the step direction in a plan view. The bottom wall portion 22a is placed on the installation surface. Although illustration is omitted, in the present embodiment, a wood screw is passed through the hole formed in the bottom wall portion 22a, and the wood screw passed through the hole is screwed into the installation surface to fix the second fixing member 22 to the installation surface. There is.

The two side wall portions 22b are plate-shaped portions that rise vertically toward the solar cell module 1 from both ends of the bottom wall portion 22a along the column direction. The two side wall portions 22b face each other with a space therebetween in the column direction. In the following description, the direction from one side wall 22b to the other side wall 22b may be referred to as the inside. The inner surface of the side wall 22b may be referred to as the inner surface.

The upper wall portion 22c is a portion that protrudes inward from the upper end portion of the side wall portion 22b. A gap is provided between the two upper wall portions 22c.

The protruding portion 22d is a portion that protrudes inward from a portion of the inner surface of the side wall portion 22b that is below the upper wall portion 22c. A gap is provided between the two protruding portions 22d. A gap is provided between the ridge portion 22d and the upper wall portion 22c. As shown in FIG. 5, a plate-shaped auxiliary fixing member 23 is inserted between the upper wall portion 22c and the ridge portion 22d. The auxiliary fixing member 23 is formed with a screw hole 23a. The width of the auxiliary fixing member 23 along the column direction is smaller than the distance between the two side wall portions 22b and larger than the distance between the two upper wall portions 22c and the distance between the two protruding portions 22d.

As shown in FIG. 4, the first fixing member 21 is a metal member for fixing the solar cell module 1 to the second fixing member 22. The first fixing member 21 is installed at each position where the first holding frame 12a and the second fixing member 22 intersect. As shown in FIG. 5, the first fixing member 21 is formed by bending a single metal plate into a crank shape. The 1st fixed member 21 has the fixed part 21a, the support part 21b, and the contact part 21c.

The fixing portion 21 a is a plate-shaped portion fixed on the second fixing member 22. The fixed portion 21a is formed in a rectangular shape in plan view. The fixed portion 21a is bridged over the two upper wall portions 22c. A hole 21d is formed in the fixed portion 21a.

The support portion 21b is a plate-shaped portion that stands up from the end portion of the fixed portion 21a in the step direction that is located on the solar cell module 1 side and that supports the spacing adjustment member 3 described later. The support portion 21b is formed in a rectangular shape in a front view. The first holding frame 12a has a holding frame side wall 12c parallel to the supporting portion 21b. The support portion 21b is arranged at a position that coincides with the holding frame side wall 12c in the step direction.

The contact portion 21c is a plate-shaped portion that extends from the upper end of the support portion 21b toward the solar cell module 1 and contacts the holding frame 12 from the light receiving surface 11b side. The contact portion 21c is formed in a rectangular shape in plan view. In the present embodiment, the first fixing member 21 is fixed to the second fixing member 22 by screwing the bolt 24, which is passed through the hole 21d of the fixing portion 21a, into the screw hole 23a of the auxiliary fixing member 23. That is, the first fixing member 21 is fixed to the second fixing member 22 via the auxiliary fixing member 23. Further, since the first fixing member 21 is fixed to the second fixing member 22, the contact portion 21c of the first fixing member 21 contacts the holding frame 12 from the light receiving surface 11b side.

A gap adjusting member 3 is provided between the support portion 21b of the first fixing member 21 and the holding frame side wall 12c of the second solar cell module 1b. Specifically, the space adjusting member 3 is sandwiched between the supporting portion 21b and the holding frame side wall 12c which is the second direction edge portion. The holding frame side wall 12c of the second solar cell module 1b constitutes an edge portion of the outer edge of the second solar cell module 1b located in the step direction. The space|interval adjustment member 3 is a plate-shaped member which adjusts the space|interval along the step direction of the 1st fixing member 21 and the 2nd solar cell module 1b. In addition, the space|interval adjustment member 3 is not arrange|positioned between the 1st fixing member 21 and the 1st solar cell module 1a. The interval adjusting member 3 is made of metal in the present embodiment, but may be made of resin. Although one space adjusting member 3 is arranged between the support portion 21b and the holding frame side wall 12c in the present embodiment, a plurality of space adjusting members 3 may be arranged. That is, the space adjusting member 3 is composed of one plate-shaped member in the present embodiment, but may be composed of a plurality of plate-shaped members. A dimension X of the distance adjusting member 3 along the step direction is smaller than a protrusion length Z of the contact portion 21c along the step direction.

Next, the function and effect of the solar power generation system 100 will be described.

First, a photovoltaic power generation system 200 according to a comparative example will be described with reference to FIGS. 6 and 7. FIG. 6: is a figure which shows the solar power generation system which concerns on a comparative example, and is a top view which shows the state which installed the solar cell module in which the dimension of a row|column direction and the dimension of a row|line direction differ in the row direction. FIG. 7: is a top view which shows typically a part of solar power generation system of FIG. 8: is a figure which shows the solar power generation system which concerns on Embodiment 1, Comprising: It is a top view which shows the state which installed the solar cell module in which the dimension in a row|column direction and the dimension in a row|column direction are arranged in a row|line direction. FIG. 9 is a plan view schematically showing a part of the solar power generation system in FIG. 6 and 8, the fixing means 2 is omitted for convenience of description. 7 and 9, the fixing means 2 is omitted and only the outline of the solar cell module 1 is shown for convenience of description.

As shown in FIG. 6 and FIG. 7, the photovoltaic power generation system 200 according to the comparative example includes a first solar cell module 1a and a second solar cell module 1b. In the example of FIG. 6, the first solar cell modules 1a are installed in three rows in the row direction×three rows in the row direction, for a total of nine pieces, and the second solar cell modules 1b are arranged in the row direction in one row×the row direction. There are 3 rows of 3 in total. The photovoltaic power generation system 200 according to the comparative example does not include the space adjusting member 3. In general, solar cell modules are prepared in various sizes, so if a solar cell module with a small dimension along the column direction is selected, the solar cell module may have a smaller dimension along the step direction. .. Also in the comparative example, the dimension Pb along the column direction of the second solar cell module 1b is smaller than the dimension Pa along the column direction of the first solar cell module 1a, and along the step direction of the second solar cell module 1b. The dimension Lb is smaller than the dimension La along the step direction of the first solar cell module 1a. Here, the dimension difference between the dimension La of the first solar cell module 1a along the step direction and the dimension Lb of the second solar cell module 1b along the step direction is Y. Further, the number of the first solar cell module 1a and the second solar cell module 1b along the step direction is M.

When the first solar cell module 1a and the second solar cell module 1b having different dimensions along the step direction are arranged side by side in the column direction, the adjacent first solar cell module 1a and the second solar cell module 1b are arranged in the step direction. One or both outer edges along the side are offset in the step direction. In the comparative example, the first solar cell module 1a and the second solar cell module 1b are arranged so that the outer edge on the lower side of the paper, which is one outer edge along the step direction, is aligned, so the first solar cell module 1a and the second solar cell module 1a are arranged. With the battery module 1b, the outer edge on the upper side of the paper surface is displaced in the step direction by the dimensional difference Y. This deviation increases as the number M of the first solar cell module 1a and the second solar cell module 1b along the step direction increases. Specifically, when the first solar cell module 1a and the second solar cell module 1b are sequentially installed from the lower side of the paper surface of FIG. 7, the first solar cell module 1a and the second solar cell module 1b that are installed last are the paper surfaces. A deviation of Y=the number of sheets M=YM occurs between the upper outer edges. Therefore, the appearance is deteriorated and the design is impaired.

On the other hand, as shown in FIG. 9, the photovoltaic power generation system 100 according to the present embodiment adjusts the distance between the first fixing member 21 and the second solar cell module 1b in the step direction. By providing the member 3, the relative position of the second solar cell module 1b in the step direction with respect to the first solar cell module 1a can be easily adjusted. Therefore, even if the number of the first solar cell module 1a and the second solar cell module 1b along the step direction increases, the number of the first solar cell module 1a and the second solar cell module 1b that are adjacent in the row direction is increased. The relative position can be fixed. Specifically, in the example of FIG. 9, the outer edges of the first solar cell module 1a and the second solar cell module 1b on the lower side of the drawing are aligned on the same straight line. Further, the first solar cell module 1a and the second solar cell module 1b have a uniform distance D along the step direction of the outer edge on the upper side of the paper surface. As a result, even when the solar cell modules 1 having different dimensions along the step direction are used, it is possible to give the viewer of the photovoltaic power generation system 100 a sense of unity and improve the design. That is, the gap in the step direction between the first solar cell module 1a and the second solar cell module 1b, which have different dimensions along the step direction, can be easily adjusted by the space adjusting member 3 and the solar power generation system 100 can be easily adjusted. The designability can be improved. 9 shows the gap adjusting member 3 for easy understanding, the gap adjusting member 3 is actually provided between the supporting portion 21b and the holding frame side wall 12c shown in FIG. It is covered by the contact portion 21c. As a result, the distance adjusting member 3 cannot be visually recognized from the outside, so that the distance adjusting member 3 does not deteriorate the design.

As shown in FIG. 8, in the first embodiment, since the dimension La of the first solar cell module 1a along the step direction is different from the dimension Lb of the second solar cell module 1b along the step direction, the installation location is different. The installation length along the step direction of the photovoltaic power generation system 100 can be appropriately adjusted according to the shape and area of the. That is, more solar cell modules 1 can be installed by freely combining the number of the first solar cell modules 1a and the second solar cell modules 1b according to the shape and area of the installation location in the step direction and installing them in the step direction. It becomes possible to spread it in the installation place. Thereby, the light receiving area of the solar cell module 1 can be increased.

As shown in FIG. 8, in the first embodiment, the installation location is different because the dimension Pa of the first solar cell module 1a along the row direction is different from the dimension Pb of the second solar cell module 1b along the row direction. The installation length of the photovoltaic power generation system 100 along the column direction can be appropriately adjusted according to the shape and area of the solar power generation system 100. That is, more solar cell modules 1 can be installed by freely combining the number of the first solar cell modules 1a and the second solar cell modules 1b according to the shape and area of the installation location in the row direction and installing them in the row direction. It becomes possible to spread it in the installation place. Thereby, the light receiving area of the solar cell module 1 can be increased. The dimension Pa of the first solar cell module 1a along the row direction may be the same as the dimension Pb of the second solar cell module 1b along the row direction.

As shown in FIG. 8, in the first embodiment, the number of the solar battery cells 11a installed along the column direction in the first solar battery module 1a is the same as that along the column direction in the second solar battery module 1b. This is different from the number of installed solar cells 11a. The number of solar cells 11a installed along the step direction in the first solar cell module 1a is equal to the number of solar cells 11a installed along the step direction in the second solar cell module 1b. Is becoming Further, in the first embodiment, the first solar battery module 1a and the second solar battery module 1b use the solar battery cells 11a having different sizes. The first solar cell module 1a and the second solar cell module 1b have different sizes in the row direction and the step direction. By combining the solar cell modules 1 having different sizes also in the row direction, the installation length of the photovoltaic power generation system 100 along the row direction can be appropriately adjusted according to the shape and area of the installation place. .. That is, by freely combining the numbers of the first solar cell modules 1a and the second solar cell modules 1b according to the shape and area of the installation location in the column direction, more solar cell modules 1 can be spread over the installation location. It will be possible. Therefore, the light receiving area of the solar cell module 1 can be increased. In addition, the 1st solar cell module 1a and the 2nd solar cell module 1b may use the solar cell 11a with the same dimension along the column direction or the dimension along the step direction. In this case, the difference in the number of solar cells 11a installed along the column direction in the solar cell module 1, the difference in the number of solar cells 11a installed along the row direction, and the difference between the solar cells 11a Between the first solar cell module 1a and the first solar cell module 1a depending on the difference in the interval between the first solar cell module 1a and the column direction, the distance from the solar cell 11a located at the end of the solar cell module 1 in the row direction or the column direction to the holding frame 12, and the like. 2 A difference in size from the solar cell module 1b occurs.

In the first embodiment, the metal interval adjusting member 3 is used. As a result, for example, as compared with the case where a resin-made space adjusting member is used, a dimensional change due to deterioration over time is less likely to occur, so that a stable space adjusting function can be exerted for a long period of time.

Here, with reference to FIG. 9, the dimension X of the distance adjusting member 3 along the step direction will be described in detail. The dimension X along the step direction of the space adjusting member 3 may be changed as appropriate, but in the present embodiment, the dimension La along the step direction of the first solar cell module 1a and the step direction of the second solar cell module 1b. Is the same as the dimension difference Y from the dimension Lb along the line. For this reason, the gap between the first solar cell module 1a and the second solar cell module 1b, which are adjacent to each other in the row direction, along the step direction can be accurately adjusted by the interval adjusting member 3. When using a plurality of interval adjusting members 3, the sum of the dimension X along the step direction of the interval adjusting members 3 is calculated as the dimension La along the step direction of the first solar cell module 1a and the second solar cell module 1b. It may be the same as the dimension difference Y from the dimension Lb along the step direction.

The dimension X of the interval adjusting member 3 along the step direction is a dimension difference Y between the dimension La of the first solar cell module 1a along the step direction and the dimension Lb of the second solar cell module 1b along the step direction. May be different from. In this case, the dimension of the distance adjusting member 3 along the step direction is X, the dimension La of the first solar cell module 1a along the step direction and the dimension Lb of the second solar cell module 1b along the step direction. When the size difference is Y and the number of the first solar cell module 1a and the second solar cell module 1b along the step direction is M, the equation (1) of Y>(Y−X)M may be established. preferable. Here, the number M of the first solar cell modules 1a and the second solar cell modules 1b along the step direction is the same. Further, the number of the space adjusting members 3 is the same as the number M of the first solar cell modules 1a and the second solar cell modules 1b along the step direction. In the example of FIG. 9, one space|interval adjustment member 3 is added to the outer edge of the lower side of the paper of the 2nd solar cell module 1b located most on the lower side of the paper, and the 3nd 2nd solar cell module 1b is shifted to the upper side of the paper. By doing so, the number M of the first solar cell modules 1a and the second solar cell modules 1b along the step direction and the number of the interval adjusting members 3 can be the same. In addition, the number of the space|interval adjustment members 3 is the number of the space|interval adjustment members 3 per set in the step direction, when the 1st solar cell module 1a and the 2nd solar cell module 1b of 2 sheets which are located in a line direction are made into 1 group. Refers to. By determining the dimension X along the step direction of the space adjusting member 3 that satisfies the above formula (1), the space between the first solar cell module 1a and the second solar cell module 1b in the entire photovoltaic power generation system 100 is determined. The generated deviation in the step direction can be less than the dimensional difference Y for one sheet between the first solar cell module 1a and the second solar cell module 1b. Therefore, the gap adjustment member 3 can adjust the deviation between the first solar cell module 1a and the second solar cell module 1b that are adjacent to each other in the row direction.

Further, the dimension of the space adjusting member 3 along the step direction is X, and the dimension difference between the dimension La of the first solar cell module 1a along the step direction and the dimension Lb of the second solar cell module 1b along the step direction. When Y and the number of the space adjusting members 3 are N and N is a natural number, it is preferable that the equation (2) of Y=NX is satisfied. Here, the number N of the distance adjusting members 3 is such that, when two first solar cell modules 1a and second solar cell modules 1b arranged in the row direction are set as one set, the number of the distance adjusting members 3 per set is the step direction. Refers to the number of. In the example of FIG. 9, one space|interval adjustment member 3 is arrange|positioned in the step direction about the 1st solar cell module 1a and 2nd solar cell module 1b of one set. For example, if the dimension difference Y between the dimension La of the first solar cell module 1a along the step direction and the dimension Lb of the second solar cell module 1b along the step direction is 10 mm, and the number N of the interval adjusting members 3 is one. The dimension X of the interval adjusting member 3 along the step direction is X=10 mm/1=10 mm from the above formula (2). Accordingly, the dimension X of the space adjusting member 3 along the step direction is determined by the dimension difference between the dimension La of the first solar cell module 1a along the step direction and the dimension Lb of the second solar cell module 1b along the step direction. It can be Y or less. Therefore, the gap adjustment member 3 can adjust the deviation between the first solar cell module 1a and the second solar cell module 1b that are adjacent to each other in the row direction.

The dimensional difference Y between the dimension La of the first solar cell module 1a along the step direction and the dimension Lb of the second solar cell module 1b along the step direction varies depending on the dimension or the number of the solar cells 11a. In addition to being intentionally provided from the beginning, it may occur due to design differences or the like. In the latter example, the first solar battery module 1a in which 10 solar battery cells 11a are arranged in the column direction×6 in the row direction and the second solar battery module 11a in which 9 solar battery cells 11a are arranged in the column direction×6 in the column direction are arranged. A case where the solar cell module 1b is manufactured and the first solar cell module 1a has a long side of 1657 mm×short side of 994 mm and the second solar cell module 1b has a long side of 1470 mm×short side of 990 mm can be mentioned. That is, even if the number of cells on the short side is the same, a dimensional difference of 4 mm may occur.

FIG. 10 is a sectional view showing a fixing structure of the first solar cell module according to the first embodiment. FIG. 11 is a cross-sectional view showing the fixing structure of the second solar cell module according to the first embodiment. The protrusion length Z along the step direction of the contact portion 21c shown in FIGS. 10 and 11 is a dimension common to the first solar cell module 1a and the second solar cell module 1b, and is, for example, 12 mm. The dimensional difference of 4 mm described above is smaller than the protrusion length Z=12 mm along the step direction of the contact portion 21c. Therefore, the distance adjusting member 3 having a dimension X of 4 mm along the step direction is arranged between the support portion 21b and the holding frame side wall 12c, and the second solar cell module 1b is dimensioned by 4 mm in the direction away from the support portion 21b. Even when the difference is shifted by the difference, the contact portion 21c surely contacts the first holding frame 12a. Therefore, the first fixing member 21 having the same size can be used for the first solar cell module 1a and the second solar cell module 1b. In addition, when 10 pieces of the first solar cell module 1a and the second solar cell module 1b having a dimensional difference of 4 mm are arranged in the step direction, the total deviation is 4 cm. Even in such a case, the gap can be adjusted by using the interval adjusting member 3.

Embodiment 2.
12: is sectional drawing which shows the fixing structure of the 2nd solar cell module of the solar power generation system which concerns on Embodiment 2 of this invention, Comprising: It is a figure equivalent to the VV sectional view taken on the line shown in FIG. .. The photovoltaic power generation system 100A according to the second embodiment differs from the first embodiment described above in that the gap adjusting member 3 is fixed to the first fixing member 21. In the second embodiment, the same parts as those in the first embodiment described above are designated by the same reference numerals and the description thereof will be omitted.

As shown in FIG. 12, the support portion 21b of the first fixing member 21 is formed with a through hole 21e penetrating in the step direction. The interval adjusting member 3 is formed with a through hole 31 penetrating in the step direction. A screw 4 for fixing the support portion 21b and the distance adjusting member 3 is inserted into the through hole 21e of the supporting portion 21b and the through hole 31 of the distance adjusting member 3. In addition, at least one through hole 21e and 31 may be provided, but a plurality of through holes 21e and 31 may be provided at intervals in the vertical direction or the column direction. According to the second embodiment, since the distance adjusting member 3 is fixed to the first fixing member 21, the positional deviation of the distance adjusting member 3 can be prevented.

Embodiment 3.
13: is sectional drawing which shows the fixing structure of the 2nd solar cell module of the solar power generation system which concerns on Embodiment 3 of this invention, Comprising: It is a figure corresponded to the VV line sectional view shown in FIG. .. The solar power generation system 100B according to the third embodiment is different from the first embodiment described above in that the first fixing member 21 is provided with the convex portion 21f. In the third embodiment, the same parts as those in the first embodiment described above are designated by the same reference numerals and the description thereof will be omitted.

As shown in FIG. 13, the supporting portion 21 b of the first fixing member 21 is provided with a convex portion 21 f that projects toward the space adjusting member 3. The convex portion 21f may be integral with or separate from the first fixing member 21. The separate convex portion 21f is, for example, a dowel. At least one convex portion 21f may be provided, but in the third embodiment, two convex portions 21f are provided at intervals in the vertical direction. The cross section of the protrusion 21f shown in FIG. 13 is rectangular. The protruding end of the convex portion 21f is in contact with the space adjusting member 3. According to the third embodiment, when the distance adjusting member 3 is sandwiched between the first fixing member 21 and the second solar cell module 1b, the convex portion 21f causes the distance adjusting member 3 and the first fixing member 21 to move. Since the friction coefficient between them becomes high, it is possible to prevent the position adjustment of the interval adjusting member 3.

It is also possible to provide a convex portion projecting toward the first fixing member 21 toward the space adjusting member 3 and bring the convex portion into contact with the first fixing member 21. In addition, a concave portion in which the convex portion is inserted may be provided on one of the space adjusting member 3 and the first fixing member 21 where the convex portion is not provided. Moreover, you may provide a convex part in both the space|interval adjustment member 3 and the 1st fixing member 21. In this case, the positions of the convex portions of the space adjusting member 3 and the convex portions of the first fixing member 21 are shifted so that the convex portions of the space adjusting member 3 are brought into contact with the first fixing member 21 and the first fixing member 21 The protrusion may be brought into contact with the space adjusting member 3.

The configurations described in the above embodiments are examples of the content of the present invention, and can be combined with another known technique, and the configurations of the configurations are not departing from the scope of the present invention. It is also possible to omit or change parts.

DESCRIPTION OF SYMBOLS 1 solar cell module, 1a 1st solar cell module, 1b 2nd solar cell module, 2 fixing means, 3 spacing adjustment member, 11a solar cell, 12c holding frame side wall (2nd direction edge part), 21 1st fixing member , 21f convex part, 100, 100A, 100B solar power generation system, dimensions along the step direction of the La first solar cell module, dimensions along the step direction of the Lb second solar cell module, Pa of the first solar cell module Dimension along the column direction, Pb Dimension along the column direction of the second solar cell module.

Claims (11)

A first solar cell module,
A second solar cell module that is installed side by side with the first solar cell module in a first direction and has a dimension along a second direction orthogonal to the first direction that is smaller than that of the first solar cell module;
A fixing member for fixing the second solar cell module to an installation location,
An interval adjusting member that adjusts an interval between the fixing member and the second solar cell module along the second direction,
A solar power generation system comprising: The second solar cell module has a second direction edge portion located in a second direction of the outer edge of the second solar cell module,
The fixing member has a support portion arranged at a position that coincides with the second direction edge portion in the second direction,
The solar power generation system according to claim 1, wherein the spacing adjustment member is provided between the support portion and the second direction edge portion. The dimension of the distance adjusting member along the second direction is the same as the dimension difference between the dimension of the first solar cell module along the first direction and the dimension of the second solar cell module along the first direction. It exists, The solar power generation system of Claim 1 or Claim 2 characterized by the above-mentioned. The dimension of the distance adjusting member along the second direction is X, and the dimension difference between the dimension of the first solar cell module along the first direction and the dimension of the second solar cell module along the first direction is Y. The solar power generation system according to claim 1 or 2, wherein, when the number of the gap adjusting members in the step direction is N, and N is a natural number, the equation of Y=NX is satisfied. The dimension of the distance adjusting member along the second direction is X, and the dimension difference between the dimension of the first solar cell module along the first direction and the dimension of the second solar cell module along the first direction is Y. The formula of Y>(Y−X)M holds, where M is the number of the second solar cell modules along the second direction. Solar power system. The dimension along the 1st direction of the said 1st solar cell module differs from the dimension along the 1st direction of the said 2nd solar cell module, The any one of Claim 1 to 5 characterized by the above-mentioned. The described solar power generation system. The number of solar cells installed along the first direction in the first solar cell module may be different from the number of solar cells installed along the first direction in the second solar cell module. The solar power generation system according to any one of claims 1 to 6, which is characterized. The photovoltaic power generation system according to claim 1, wherein the space adjusting member is made of metal. The said space|interval adjustment member is being fixed to the said fixed member, The photovoltaic power generation system of any one of Claim 1 to 8 characterized by the above-mentioned. 10. At least one of the gap adjusting member and the fixing member is provided with a convex portion that projects toward the other of the gap adjusting member and the fixing member. The solar power generation system according to item. The solar power generation system according to any one of claims 1 to 9, wherein the space adjusting member is configured by a plurality of plate-shaped members.