JP2013256778A - Installation structure for solar panels - Google Patents

Abstract

PROBLEM TO BE SOLVED: To efficiently install much more solar panels.SOLUTION: In an installation structure 2 for solar panels 1, a plurality of solar panels 1 are installed while being inclined with respect to an installation surface 3 to form a V shape in a side view. In this installation structure 2, the plurality of solar panels 1 are installed to continue the V shape. Furthermore, the installation structure 2 comprises metal plates 4 and metal fittings 6 for connecting the plurality of solar panels 1 with Λ-shaped peaks which are formed by continuing the V shape.

Description

  The present invention relates to a solar panel installation structure.

  2. Description of the Related Art Conventionally, there is a surplus power purchase system in which a power company purchases surplus power obtained by subtracting consumed power from generated power from a household or a company where a solar panel is installed (see Non-Patent Document 1). For non-residential installations set up by companies, etc., in July 2012, the law changed to shift from a conventional surplus power purchase system to a full-value purchase system (fixed price purchase system) that purchases all generated power. (See Non-Patent Document 2).

JP 2012-080018 A (see FIG. 3)

TEPCO, [online], Top page> Electricity charges and procedures: Individual customers> Electricity charges> Documents> Purchasing power from new energy, etc.> About surplus power purchase system for solar power generation [June 2012 Monthly search], Internet (URL: http://www.tepco.co.jp/e-rates/individual/shin-ene/taiyoukou/index-j.html) Ministry of Economy, Trade and Industry Agency for Natural Resources and Energy, [online], top page> Renewable energy> Purchase system, [Search June 4, 2012], Internet (URL: http://www.enecho.meti.go.jp/saiene/kaitori/index.html)

  The shift to the full purchase system for non-residential products is expected to increase the benefits for companies that have installed solar panels, such as increased revenue from power sales. In addition, the electricity bill is expected to rise due to the power shortage caused by the Fukushima Daiichi nuclear power plant accident, which was triggered by the Tohoku-Pacific Ocean Earthquake. For this reason, it is considered that companies that install solar panels, etc., install more solar panels and generate more electric power, so that they can generate a large amount of electricity sales and cover the rising electricity bill.

  However, solar panels are generally installed while being spaced apart from each other toward the south, and the number of installed solar panels is uniquely determined according to the installation area (see Patent Document 1). For this reason, in order to install more solar panels, it was necessary to increase the installation area.

  This invention is made | formed in view of the said subject, and it aims at providing the installation structure of the solar panel which makes it possible to install more solar panels efficiently.

  (1) The present invention is a solar panel installation characterized in that a plurality of solar panels are inclined with respect to the installation surface so as to form a V shape or an inverted C shape in a side view. Structure.

  When a plurality of solar panels are installed to be inclined toward one direction as in the prior art, it is necessary to separate them from each other so as to avoid shadows caused by the solar panels. On the other hand, according to the present invention, since a plurality of solar panels are installed so as to form a V shape or an inverted C shape in a side view, even if they are not separated from each other, shadows are caused by the solar panels. It does not occur. For this reason, more solar panels can be installed efficiently.

  Even when the sunlight incident on the solar panel is reflected, the reflected sunlight is irradiated toward another solar panel and received by the other solar panel. Thereby, the reflection loss by a solar panel can be reduced and more electric power can be generated. For this reason, the solar panel can be installed regardless of the orientation of the solar panel.

  In addition, when a plurality of solar panels are laid flat, dust adhering to the solar panels tends to remain as dirt. On the other hand, according to the present invention, since the solar panel is inclined and installed, the dust adhering to the solar panel falls downward due to its own weight and is not easily contaminated. In addition, according to the present invention, since the solar panel is installed at an inclination, the area required for installation can be reduced as compared with the case where the solar panel is installed flat, and more solar panels can be installed efficiently. .

  (2) The present invention also provides the solar panel according to (1) above, wherein the plurality of solar panels are installed so that the V shape or the inverted C shape is continuous. It is an installation structure.

  According to the above invention, since the solar panel forms a Λ shape or a C shape, it is unlikely to act to push up the solar panel even when wind is blown. Less susceptible to damage. For this reason, when installing on a flat roof, the outer periphery separation distance from the outer periphery of the said flat roof to a solar panel can be narrowed compared with the case where it inclines and installs toward one direction. As a result, more solar panels can be installed efficiently.

  (3) The present invention also provides a connecting member that connects a plurality of the solar panels with Λ-shaped or C-shaped ridges formed by continuation of the V-shaped or the inverted C-shaped. The solar panel installation structure according to (2) above, comprising:

  According to the above invention, the plurality of solar panels connected to each other by the connecting member support each other. Thereby, a solar panel can be installed, without providing the frame (base) used as a foundation. As a result, the number of parts and the time required for installation work can be reduced. For this reason, since a merit comes out at the time of installation, installation of a solar panel can be promoted. Specifically, the cost of parts excluding the solar panel can be reduced to 1/5 or less, and the weight of the parts excluding the solar panel can be reduced to 1/10 or less, compared with the case where a stand is provided. it can. Of course, the present invention may be provided with a gantry.

  (4) According to the present invention, the plurality of solar panels are installed so as to be continuous in the valley shape of the V-shaped or the inverted C shape, and the Λ-shaped or the inverted shape is used as the connecting member. A first connecting member for connecting a plurality of solar panels continuous in a ridge direction on one side forming a C-shape, and the other side forming the Λ-shape or the inverted C-shape The solar panel installation structure according to (3), further comprising: a second connection member that connects the solar panel to the solar panel on the one side so as to be individually removable.

  According to the said invention, the solar panel installed separately so that removal is possible can be removed, and the said solar panel and another solar panel can be maintained. And even if it is a case where a solar panel is removed, since another solar panel is mutually supporting, an intensity | strength problem does not arise.

  (5) The present invention also includes an installation member which is provided on the installation surface and installs the plurality of solar panels on the installation surface by being detachably hooked to the plurality of solar panels. It is the installation structure of the solar panel in any one of said (1)-(4).

  According to the said invention, the said solar panel can be installed in an installation surface only by hooking a solar panel. For this reason, installation work becomes easy.

  (6) The present invention also provides a blockade for closing a space formed between the back surface of the solar panel and the installation surface that forms the Λ shape or the inverted C shape from the side of the solar panel. It is an installation structure of the solar panel in any one of said (2)-(4) characterized by providing a member.

  According to the above invention, since the space formed below the solar panel is closed, there is no possibility that the wind blown to the solar panel acts to push up the solar panel, and it is less susceptible to wind damage. . For this reason, when installing on a flat roof, the outer periphery separation distance from the outer periphery of the said flat roof to a solar panel can be narrowed significantly compared with the case where it inclines and installs toward one direction. As a result, more solar panels can be installed efficiently.

  (7) In the present invention, the solar panel on one side forming the V shape or the inverted C shape is installed in a direction from northeast to southeast, and the V shape or the reverse shape is installed. The solar panel according to any one of (1) to (6) above, wherein the solar panel on the other side forming a square shape is installed in a direction from southwest to northwest. It is an installation structure.

  (8) The present invention also provides the solar panel installation structure according to (7) above, wherein an inclination angle of the solar panel with respect to a horizontal plane is 18 degrees or greater and 26 degrees or less.

  (9) In the present invention, the solar panel on one side forming the V shape or the inverted C shape is installed in a direction from southeast to southwest, and the V shape or the reverse shape is installed. The solar panel according to any one of (1) to (6) above, wherein the solar panel on the other side forming a square shape is installed in a direction from northwest to northeast. It is an installation structure.

  According to the solar panel installation structure described in (1) to (9) of the present invention, more solar panels can be efficiently installed.

It is an external appearance perspective view of the installation structure of the solar panel which concerns on this invention. It is a side view of the installation structure of a solar panel. (A) is an external appearance perspective view explaining the operation | work which attaches a solar panel to an installation surface, (B) is a figure which shows the shape of the bolt hole in a metal plate. It is side sectional drawing explaining the operation | work which attaches a solar panel to an installation surface, and shows the case where an installation surface is a tin roof. It is a sectional side view explaining the operation | work which attaches a solar panel to an installation surface, and shows the case where an installation surface is a concrete block. It is an external appearance perspective view explaining the operation | work which connects a solar panel. It is a sectional side view explaining the operation | work which connects a solar panel. It is a figure explaining Example 1, (A) is the schematic which shows the installation structure of a solar panel, (B) is a bar graph which shows monthly power generation amount, (C) is a graph which shows monthly power generation amount is there. It is a figure explaining Example 2, (A) is the schematic which shows the installation structure of a solar panel, (B) is a bar graph which shows monthly power generation amount, (C) is a graph which shows monthly power generation amount is there. It is a figure explaining a comparative example, (A) is the schematic which shows the installation structure of a solar panel, (B) is a bar graph which shows monthly power generation amount, (C) is a graph which shows monthly power generation amount. . It is the schematic which shows the installation structure of the solar panel which concerns on another embodiment. (A)-(C) are schematic which shows the modification of a metal plate. (A) And (B) is the schematic which shows the modification of a metal fitting.

  Hereinafter, a solar panel installation structure according to the present invention will be described in detail with reference to the drawings.

  First, the structure of the installation structure 2 of the solar panel 1 is demonstrated using FIGS. FIG. 1 is an external perspective view of an installation structure 2 for a solar panel 1. FIG. 2 is a side view of the installation structure 2 of the solar panel 1. FIG. 3A is an external perspective view illustrating an operation of attaching the solar panel 1 to the installation surface 3. FIG. 3B is a diagram showing the shape of the bolt holes in the metal plate 4. FIG. 4 is a side sectional view for explaining the operation of attaching the solar panel 1 to the installation surface 3, and shows a case where the installation surface 3 is a tin roof 3a. FIG. 5 is a side sectional view for explaining the work of attaching the solar panel 1 to the installation surface 3, and shows the case where the installation surface 3 is a concrete block 3b. FIG. 6 is an external perspective view for explaining the operation of connecting the solar panels 1. FIG. 7 is an external perspective view for explaining the operation of connecting the solar panels 1. In each of the drawings, illustration of some components is omitted as appropriate for simplification of the drawings.

  As shown in FIGS. 1 and 2, the plurality of solar panels 1 each have a rectangular shape. These solar panels 1 preferably have a weight that can be carried by one person. That is, the weight of the solar panel 1 is preferably about 15 kg to 20 kg per sheet. The strength of the solar panel 1 is preferably a strength that can withstand up to about 1 m of snow, and more preferably a strength that can withstand up to about 2 m of snow. For such a solar panel 1, a solar cell module (for example, CS5A series or CS6P series) marketed by Canadian Solar Japan Co., Ltd. (Shinjuku-ku, Tokyo) can be employed. In addition, although this embodiment demonstrates as an example the case where the solar panel 1 is installed using the flat roof as the installation surface 3, it is good also considering the ground and an inclined roof as the installation surface 3. FIG. Further, the installation surface 3 is not limited to a flat surface, and may be an uneven surface.

  In the present installation structure 2, a plurality of solar panels 1 are installed so as to be inclined with respect to the installation surface 3 so that the Λ shape is continuous in a side view. In other words, in the installation structure 2, the plurality of solar panels 1 are inclined with respect to the installation surface 3 to form a V shape in a side view and are installed so that the V shape is continuous. And in this installation structure 2, the several solar panel 1 is installed so that it may continue in the V-shaped valley direction (the direction which connects the lower left and upper right in FIG. 1, the depth direction in FIG. 2). .

Solar panels 1 of one side of which forms a V-shape is disposed toward a predetermined direction D _1. The solar panel 1 on the other side to form a V-shape, orientation D ₁ opposite to the orientation D _{2 (e.g.,} if the orientation D ₁ is the east, azimuth D ₂ West) is placed toward the.

From the first point of view, it is preferable that _one direction D ₁ is an orientation from northeast to southeast, and in this case, the other direction D ₂ is an orientation from southwest to northwest. Then, one of the orientation D ₁ is more preferably the azimuth from east-northeast to east-southeast, in this case, other orientation D ₂ is a direction from west-southwest to northwest. Also, one of the orientation D ₁ is most preferably from east this case, other orientation D ₂ becomes west.

Alternatively, from the viewpoint of Second, one of the orientation D ₁ is preferably orientation from southeast to southwest, in this case, other orientation D ₂ is a direction from northwest to northeast. One direction D ₁ is more preferably an orientation from south-southeast to south-southwest, and in this case, the other direction D ₂ is an orientation from north-northwest to north-northeast. Also, one of the orientation D ₁ is most preferably a south this case, other orientation D ₂ becomes north.

The inclination angle α of the solar panel 1 with respect to the horizontal plane is set according to the irradiation angle of the sunlight SL1, that is, the latitude of the place where the solar panel 1 is installed. Japan (especially Kanto) a case of installing the, one of the orientation D ₁ and the azimuth from northeast to southeast, when the orientation of the other azimuth D ₂ from the southwest to northwest, the inclination of the solar panel 1 The angle α is preferably 18 degrees or greater and 26 degrees or less, and more preferably 20 degrees or greater and 24 degrees or less.

  As shown in FIG. 3A, FIG. 4 and FIG. 5, this installation structure 2 has a pair of solar panels 1 on a metal plate 4 bolted to an installation surface 3 (a tin roof 3a, a concrete block 3b). Is detachably hooked to form a V-shape. That is, the metal plate 4 functions as an installation member that installs the plurality of solar panels 1 on the installation surface 3 by the plurality of solar panels 1 being detachably hooked.

  A metal fitting 5 for hooking on the metal plate 4 is bolted to the solar panel 1 as appropriate. The solar panel 1 is hooked across the two metal plates 4. The metal plate 4 has a shape that is bent at two positions by the same angle as the inclination angle α and has three surfaces. A bolt hole 4 a is appropriately formed in the middle surface of the metal plate 4. The metal plate 4 of the present embodiment is set to a length shorter than that of the solar panel 1, but may be set to the same length as the solar panel 1 to increase the strength. Note that the metal plates 4 on both sides in the valley direction (the lower left end and the upper right end in FIG. 3) are half the length of the other metal plates 4.

  As shown in FIG. 3B, the bolt hole 4a in the metal plate 4 has a shape in which one end of the long hole (the right end in the drawing) is a slightly large circle. The bolt inserted into the circular portion in the bolt hole 4a is fixed to the bolt hole 4a by sliding to the other end (left end in the drawing) of the long hole. Thereby, the fall of the bolt is prevented, and the operation becomes easy.

  Returning to FIG. 3A, FIG. 4 and FIG. On the two surfaces on both sides of the metal plate 4, rectangular holes 4b for hooking the solar panel 1 are appropriately formed. That is, the metal fitting 5 that is bolted to the solar panel 1 is inserted into and removed from the rectangular hole 4 b of the metal plate 4.

  As shown in FIGS. 6 and 7, the installation structure 2 connects a plurality of solar panels 1 with Λ-shaped peaks.

  The solar panel 1 on one side (lower right side in FIG. 6, right side in FIG. 7) forming the Λ-shape is connected to the solar panel 1 on the other side (upper left side in FIG. 6, left side in FIG. 7). The metal plate 4 for this is fixed with bolts as appropriate. The metal plate 4 is a component common to the metal plate 4 that is bolted to the installation surface 3, and the metal plate 4 that is bolted to the installation surface 3 is used in an inverted state. The metal plates 4 are fixed with a gap therebetween, forming a gap. This prevents heat from being trapped in the space between the back surface of the solar panel 1 and the installation surface 3. The rectangular hole 4 b in the metal plate 4 functions as a bolt hole for fixing the bolt to the solar panel 1. The bolt hole 4a in the metal plate 4 is used when a metal fitting 6 described later is bolted.

  The metal plate 4 serves as a first connecting member that connects the solar panels 1 that are continuous in the peak direction (the direction connecting the lower left and the upper right in FIG. 6, the depth direction in FIG. 7) on one side forming the Λ shape. Function. For this reason, the metal plate 4 is bolted across the two solar panels 1. However, the metal plates 4 at both ends in the ridge direction (the lower left end and the upper right end in FIG. 6) are half the length of the other metal plates 4 and are bolted to one solar panel 1.

  The solar panel 1 on the other side forming the Λ-shape is hooked on the metal plate 4 bolted to the installation surface 3 and is attached to the metal plate 4 bolted to the solar panel 1 on one side. 6 is detachably fixed. As a result, a Λ shape is formed. The metal fitting 6 is a part formed by bending a metal plate into a Z shape, and is bolted to the metal plate 4. Such a metal fitting 6 functions as a second connecting member for connecting the solar panel 1 on the other side forming the [Lambda] shape to the solar panel 1 on one side so as to be individually removable.

  [Embodiment 1] Next, Embodiment 1 in which the amount of electric power [kWh] generated by the solar panel 1 of the installation structure 2 is examined by computer simulation will be described with reference to FIG. FIG. 8A is a schematic diagram showing the installation structure 2 of the solar panel 1. FIG. 8B is a bar graph showing the monthly power generation amount. FIG. 8C is a graph showing the monthly power generation amount.

In the computer simulation, a solar cell module (model: CS6P-240P) marketed by Canadian Solar Japan Co., Ltd. was assumed as the solar panel 1. The solar cell module has a nominal maximum output P _max of 0.24 kW. The installation location was assumed in Yokohama City, Kanagawa Prefecture. The past data of Yokohama City was used for the amount of sunshine [kWh / m ² ] and the outside air temperature [° C.]. Then, as shown in FIG. 8A, the solar panels 1 of 52 north-south × 24 east-west (1248 in total) were installed so as to be V-shaped in the north-south direction. It is assumed that the solar panels 1 installed at both the north and south ends are securely fixed to the installation surface 3 by bolt fixing or the like. The inclination angle α of the solar panel 1 with the horizontal plane was 20 degrees. The simulation results are as shown in FIGS. 8B and 8C. Note that the amount of generated power (rated ratio) [kWh / kWp] in FIG. 8C is calculated by the amount of generated power [kWh] / (nominal maximum output Pmax (0.24 kW) × number of solar panels (1248)). It was. Annual power generation amounted to 276187 [kWh]. The annual crude oil equivalent reduction amount was 67113 [liters]. The annual carbon dioxide reduction amount was 98599 [kg].

  [Embodiment 2] Next, Embodiment 2 in which the amount of electric power [kWh] generated by the solar panel 1 of the installation structure 2 is examined by computer simulation will be described with reference to FIG. FIG. 9A is a schematic diagram showing the installation structure 2 of the solar panel 1. FIG. 9B is a bar graph showing the monthly power generation amount. FIG. 9C is a graph showing the monthly power generation amount.

  As shown in FIG. 9A, solar panels 1 of 52 east-west and 24 north-south (1248 in total) were installed so as to be V-shaped east-west. The other conditions were the same as in Example 1. The simulation results are as shown in FIGS. 9B and 9C. The annual power generation amounted to 2,76887 [kWh]. The annual crude oil equivalent reduction amount was 67284 [liter]. The annual carbon dioxide reduction amounted to 988849 [kg].

  [Comparative Example] Next, a comparative example in which the amount of electric power [kWh] generated by the solar panel 1 of the installation structure for comparison with the installation structure 2 is examined by computer simulation will be described with reference to FIG. FIG. 10A is a schematic diagram showing the installation structure of the solar panel 1. FIG. 10B is a bar graph showing the monthly power generation amount. FIG. 10C is a graph showing the monthly power generation amount.

  As shown in FIG. 10 (A), 13 sets are arranged in the north-south direction so that one plane unit is formed by 4 north-south x 24 east-west (total 96). In this way, all the solar panels 1 were installed inclined toward the south. That is, a total of 1248 solar panels 1 were installed. The other conditions were the same as in Example 1. The installation structure of the comparative example is a conventional general installation structure. The simulation results are as shown in FIGS. 10B and 10C. The annual power generation amounted to 313709 [kWh]. The annual crude oil equivalent reduction amount was 76231 [liter]. The annual carbon dioxide reduction amount was 111994 [kg].

  In the comparative example, in order to avoid the shadow on the relatively northern solar panel 1 caused by the relatively southern solar panel 1, the solar panels 1 are installed at intervals in the north-south direction. That is, a dead space is generated, and an installation area that is about twice as large as that of the first and second embodiments is required. For this reason, the number of solar panels 1 that can be installed in the comparative example is as small as about half that of Examples 1 and 2 when compared with the same installation area. For this reason, when it is set as the same installation area as Example 1 and 2, in a comparative example, an annual electric power generation amount is about 160000 [kWh], an annual crude oil conversion reduction amount is about 40000 [liter], and an annual carbon dioxide reduction amount is It is converted to about 60000 [kg].

  Thus, in Examples 1 and 2, the annual power generation [kWh] was as large as about 1.7 to 2 times as compared with the comparative example which is a conventional general installation structure. Moreover, in Examples 1 and 2, the maximum installation height of the solar panel 1 is as low as about one-fourth of the comparative example (the comparative example is equivalent to four sheets, the first and second examples are equal to one) Installation work and maintenance work are safe and easy.

  When a plurality of solar panels are installed to be inclined toward one direction (for example, south) as in the related art, it is necessary to separate them from each other so as to avoid shadows caused by the solar panels. On the other hand, according to the installation structure 2 of the solar panel 1, since a plurality of solar panels 1 are installed so as to form a V shape in a side view, even if they are not separated from each other, Will not occur. For this reason, more solar panels 1 can be installed efficiently.

  Even when the sunlight SL1 incident on the solar panel 1 is reflected, the reflected sunlight SL1 is irradiated toward the other solar panel 1 and received by the other solar panel 1. Thereby, the reflection loss by the solar panel 1 can be reduced, and more electric power can be generated. For this reason, the solar panel 1 can be installed regardless of the orientation in which the solar panel 1 is directed.

  In addition, when a plurality of solar panels are laid flat, dust adhering to the solar panels tends to remain as dirt. On the other hand, according to the installation structure 2 of the solar panel 1, since the solar panel 1 is installed at an inclination, the dust adhering to the solar panel 1 falls downward due to its own weight and is not easily contaminated. Moreover, according to the installation structure 2 of the solar panel 1, since the solar panel 1 is installed at an inclination, the area required for installation is reduced compared to the case of flat installation, and the solar panel is installed efficiently. be able to.

  Since the solar panel 1 forms a [Lambda] shape, even when wind is blown, the solar panel 1 is unlikely to act to push up the solar panel 1 and is not easily damaged by the wind. For this reason, when installing on a flat roof, the outer periphery separation distance from the outer periphery of the said flat roof to the solar panel 1 can be significantly narrowed compared with the case where it inclines and installs toward one direction. As a result, more solar panels can be installed efficiently.

  And the several solar panel 1 mutually connected with the metal plate 4 and the metal fitting 6 mutually supports. Thereby, the solar panel 1 can be installed without providing a framework (base) as a foundation. As a result, the number of parts and the time required for installation work can be reduced. For this reason, since a merit comes out at the time of installation, installation of the solar panel 1 can be promoted. Specifically, compared with the case where a stand is provided, the cost of parts excluding the solar panel 1 can be reduced to 1/5 or less, and the weight of the parts excluding the solar panel 1 can be reduced to 1/10 or less. be able to. Of course, it is also possible to provide a stand.

  Moreover, the solar panel 1 installed so that removal is possible separately can be removed, and the said solar panel 1 and other solar panels 1 can be maintained. Furthermore, even when the solar panel 1 is removed, the other solar panels 1 support each other, so that there is no problem with strength.

  The present invention is not limited to the above-described embodiments and examples, and various modifications can be made without departing from the spirit and technical idea thereof.

  That is, in the embodiment and the example described above, the position, size, shape, material, orientation, quantity, and the like of each component can be appropriately changed. For example, the size, shape, quantity, etc. of the solar panel 1 can be changed as appropriate. Moreover, the fixing structure to the installation surface 3 of the solar panel 1 and the connection structure of the solar panel 1 can be changed as appropriate.

  Or in the said embodiment and the said Example, it is provided with the obstruction | occlusion member which obstruct | occludes the space formed between the back surface and the installation surface 3 of the solar panel 1 which forms Λ-shape from the side of the said solar panel 1. It may be. Thereby, since the space formed under the solar panel 1 is closed, the wind blown to the solar panel 1 is not likely to act to push up the solar panel 1 and is less susceptible to damage from the wind. Become.

  Or in the said embodiment and the said Example, although the several solar panel 1 is installed so that V shape may continue, this invention is not limited to this, A plurality of solar panels 1 are reversed. You may install so that a C-shape may continue. In the embodiment and the example described above, the plurality of solar panels 1 are installed so that the Λ shape is continuous. However, the present invention is not limited to this, and the plurality of solar panels 1 You may install so that a character shape may continue. As a form in which a plurality of solar panels 1 are installed so that a C-shaped or inverted-C-shaped pattern is continuous, as shown in FIG. 11, a solar panel 1 that forms a C-shaped or inverted-C-shaped pattern A mode in which another solar panel 1 is installed in between is also included.

  Or in the said embodiment and the said Example, although the aspect which removes and maintains the solar panel 1 was demonstrated to the example, this invention is not limited to this, The solar panel 1 is attached so that rotation or a slide is possible. The solar panel 1 may be rotated or slid for maintenance.

  Alternatively, in the above-described embodiment and example, instead of the metal plate 4, the metal plates 41 and 42 as shown in FIGS. 12A and 12B, that is, the metal plates 41 whose ends are bent, 42 may be used. Thereby, the catching degree of the metal plate 4 with respect to the solar panel 1 can be increased. As a result, the solar panel 1 can be installed more firmly. Further, instead of the metal plate 4, a metal plate 43 as shown in FIG. 12C, that is, a metal plate 43 formed into a shape that is a combination of the metal plates 41 and 42 described above is used. It may be.

  Or in the said embodiment and Example, it replaces with the metal fitting 5 and end | ends in a bolt protrusion direction at the time of attachment to the metal fittings 51 and 52, ie, the solar panel 1, as shown to FIG. 13 (A) and FIG. 13 (B). You may make it use the metal fittings 51 and 52 by which the part was bent. Thereby, in the said embodiment and Example, when the solar panel 1 was hooked on the metal panel 4, the location which was supported at one point by the front-end | tip of a volt | bolt is by the bent edge part of metal fittings 51 and 52 with the front-end | tip of a volt | bolt. Supported (see FIGS. 4A and 4B). Thereby, the solar panel 1 can be stably hooked to the metal panel 4.

DESCRIPTION OF SYMBOLS 1 Solar panel 2 Installation structure 3 Installation surface 4,41,42,43 Metal plate (installation member, 1st connection member)
6 Bracket (second connecting member)
α Inclination angle D ₁ , D ₂ direction

(1) In the present invention, the V shape or the inverted C shape is formed so as to be inclined with respect to the installation surface , and the V shape or the inverted C shape is continuous in a side view. a plurality of solar panels to be installed in, connecting to the solar panel of a plurality, in shaped ridges of the V-shaped or the reverse Ha shape Λ-shaped type is formed by continuous or c A solar panel installation structure, characterized in that the connection member is disposed without a support column, and the plurality of solar panels support each other via the connection member. .

Furthermore , since the solar panel forms a Λ-shape or C-shape, it is unlikely to act to push up the solar panel even when wind is blown, and is not easily damaged by the wind. . For this reason, when installing on a flat roof, the outer periphery separation distance from the outer periphery of the said flat roof to a solar panel can be narrowed compared with the case where it inclines and installs toward one direction. As a result, more solar panels can be installed efficiently.

And the several solar panel mutually connected with the connection member mutually supports. Thereby, a solar panel can be installed, without providing the frame (base) used as a foundation. As a result, the number of parts and the time required for installation work can be reduced. For this reason, since a merit comes out at the time of installation, installation of a solar panel can be promoted. Specifically, the cost of parts excluding the solar panel can be reduced to 1/5 or less, and the weight of the parts excluding the solar panel can be reduced to 1/10 or less, compared with the case where a stand is provided. I can .

( 2 ) In the present invention, the plurality of solar panels are installed so as to be continuous in a valley direction of the V-shape or the inverted C-shape, and the Λ-shape or the reverse is used as the connecting member. A first connecting member for connecting a plurality of solar panels continuous in a ridge direction on one side forming a C-shape, and the other side forming the Λ-shape or the inverted C-shape The solar panel installation structure according to ( 1 ) above, further comprising a second connecting member that connects the solar panel to the solar panel on the one side so as to be individually removable.

(3) In the present invention, the solar panel on one side forming the V shape or the inverted C shape is installed in a direction from northeast to southeast, and the V shape or the reverse shape is installed. The solar panel on the other side forming the C-shape is installed in a direction from southwest to northwest, and an inclination angle with the horizontal plane of the solar panel is 18 degrees or more and 26 degrees or less. It is the installation structure of the solar panel as described in said (1) or (2).
(4) In the present invention, the solar panel on one side forming the V shape or the inverted C shape is installed in a direction from southeast to southwest, and the V shape or the reverse shape is installed. The solar panel installation structure according to (1) or (2) above, wherein the solar panel on the other side forming a square shape is arranged in a direction from northwest to northeast. is there.
(5) The present invention also includes an installation member which is provided on the installation surface and installs the plurality of solar panels on the installation surface by being detachably hooked to the plurality of solar panels. It is the installation structure of the solar panel in any one of said (1)-(4).

(6) The present invention also provides a blockade for closing a space formed between the back surface of the solar panel and the installation surface that forms the Λ shape or the inverted C shape from the side of the solar panel. It is an installation structure of the solar panel in any one of said ( 1 )-(4) characterized by providing a member.

According to the solar panel installation structure described in (1) to ( 6 ) of the present invention, more solar panels can be efficiently installed.

And the several solar panel 1 mutually connected with the metal plate 4 and the metal fitting 6 mutually supports. Thereby, the solar panel 1 can be installed without providing a framework (base) as a foundation. As a result, the number of parts and the time required for installation work can be reduced. For this reason, since a merit comes out at the time of installation, installation of the solar panel 1 can be promoted. Specifically, compared with the case where a stand is provided, the cost of parts excluding the solar panel 1 can be reduced to 1/5 or less, and the weight of the parts excluding the solar panel 1 can be reduced to 1/10 or less. it is possible.

(1) In the present invention, the V shape or the inverted C shape is formed so as to be inclined with respect to the installation surface, and the V shape or the inverted C shape is continuous in a side view. A plurality of solar panels installed in a plurality of solar panels are connected by Λ-shaped or C-shaped ridges formed by continuous V-shaped or inverted C-shaped. comprising a connecting member for the said coupling member is disposed without struts, the solar panel of the plurality sheets, have if supported each other via the connecting member, further, the plurality solar panels, the Installed continuously in the ridge shape of the Λ-shape or the C-shape, and as the connecting member, disposed on the ridge, the ridge direction on one side forming the Λ-shape or the C-shape A plurality of solar panels that are connected to each other, and A first connecting member on which the peak portion of the solar panel on the other side forming the Λ-shape or the C-shape is placed, and the first connecting member corresponding to each of the solar panels on the other side A second connecting member that is detachably fixed to the solar panel on the other side and is detachably connected to the solar panel on the other side. Each of the solar panels on the other side is fixed to the first connecting member with the second connecting member in a state where the peak portion is placed on the first connecting member. Those that are individually connected to the solar panel on the one side, and can be removed individually one by one by releasing the fixation of the second connecting member to the first member. It is characterized by It is a solar panel installation structure.

Moreover , the solar panel installed so that removal is possible separately can be removed, and the said solar panel and another solar panel can be maintained. And even if it is a case where a solar panel is removed, since another solar panel is mutually supporting, an intensity | strength problem does not arise.

( 2 ) In the present invention, the solar panel on one side forming the V shape or the inverted C shape is installed in a direction from northeast to southeast, and the V shape or the reverse shape is installed. The solar panel on the other side forming the C-shape is installed in a direction from southwest to northwest, and an inclination angle with the horizontal plane of the solar panel is 18 degrees or more and 26 degrees or less. and a installation structure of a solar panel according to the above (1).
( 3 ) In the present invention, the solar panel on one side forming the V shape or the inverted C shape is installed in a direction from southeast to southwest, and the V shape or the reverse shape is installed. The solar panel installation structure according to (1) above, wherein the solar panel on the other side forming a square shape is arranged in a direction from northwest to northeast.
( 4 ) The present invention also includes an installation member that is provided on the installation surface and that installs the plurality of solar panels on the installation surface by being detachably hooked to the plurality of solar panels. It is the installation structure of the solar panel in any one of said (1)-( 3 ).

( 5 ) The present invention also provides a blockade for closing a space formed between the back surface of the solar panel and the installation surface, which forms the Λ-shape or the inverted C-shape, from the side of the solar panel. It is an installation structure of the solar panel in any one of said (1)-( 3 ) characterized by providing a member.

According to the solar panel installation structure described in (1) to ( 5 ) of the present invention, more solar panels can be efficiently installed.

Claims (9)

It is characterized by installing a plurality of solar panels so as to be inclined with respect to the installation surface so as to form a V shape or a reverse C shape in a side view,
Solar panel installation structure. A plurality of the solar panels are installed so that the V-shaped or the inverted C-shaped is continuous,
The solar panel installation structure according to claim 1. A plurality of the solar panels are provided with a connecting member that connects the V-shaped or the inverted C-shaped ridge formed by continuation of the V-shaped or the inverted C-shaped,
The installation structure of the solar panel of Claim 2. The plurality of solar panels are installed so as to be continuous in the valley shape of the V-shaped or the inverted-C-shaped,
As the connecting member,
A first connecting member that connects the solar panels that are continuous in a ridge direction on one side to form the Λ shape or the inverted C shape;
A second connecting member that detachably connects the solar panel on the other side forming the Λ-shape or the inverted C-shape to the solar panel on the one side. To
The installation structure of the solar panel of Claim 3. It is provided on the installation surface, and the plurality of solar panels are detachably hooked, thereby including an installation member for installing the plurality of solar panels on the installation surface,
The installation structure of the solar panel in any one of Claims 1-4. A closing member that closes a space formed between a back surface of the solar panel that forms the Λ shape or the inverted C shape and the installation surface from a side of the solar panel is provided. ,
The installation structure of the solar panel in any one of Claims 2-4. The solar panel on one side forming the V shape or the inverted C shape is installed facing from the northeast to the southeast,
The solar panel on the other side forming the V-shape or the reverse C-shape is installed in a direction from southwest to northwest,
The installation structure of the solar panel in any one of Claims 1-6. The inclination angle of the solar panel made with the horizontal plane is 18 degrees or more and 26 degrees or less,
The installation structure of the solar panel of Claim 7. The solar panel on one side forming the V shape or the inverted C shape is installed in a direction from southeast to southwest,
The solar panel on the other side forming the V shape or the inverted C shape is installed in a direction from northwest to northeast,
The installation structure of the solar panel in any one of Claims 1-6.

Images