JP2011226122A - Construction method of solar battery array - Google Patents

Abstract

PROBLEM TO BE SOLVED: To securely fix a plurality of solar battery modules 1 on a frame 2 without providing the solar battery modules 1 or the frame 2 with any special structure.SOLUTION: According to a construction method, in the frame 2 arranged on a laying face and each of the solar battery modules 1 including a solar battery submodule 11 and a frame 12, the solar battery modules 1 are mounted on the frame 2 with a solar-battery-module mount fitting 3 having a pressing portion that presses a base part 124 from a top thereof, an extending portion that extends toward a lower side of the base part 124, and a contact portion that extends to an adjacent one of the solar battery modules 1. When a fist one of the solar battery modules 1 is placed on the frame 2 and its base part 124 is fixed to the frame 2, and thereto a second one of the solar battery modules 1 is connected, the contact portion of the solar-battery-module mount fitting 3 attached to the second solar battery module 1 is made to abut on a lower side of the fixed base part 124 of the first solar battery module 1.

Description

  The present invention relates to a method for constructing a solar cell array for laying a plurality of solar cell modules fixed on a gantry without providing any special structure to the solar cell module or the gantry.

  In recent years, installation of solar cells has been promoted in every place such as public facilities and general households due to environmental concerns and policies. Since this solar cell uses sunlight, it is installed outdoors such as a roof or a rooftop. Further, in order to effectively use the installable surface, a solar cell array is often formed by arranging a plurality of solar cell modules in parallel.

As described above, it must be firmly fixed on the laying surface so as not to be blown away by wind and rain due to the situation of being installed outdoors.
Moreover, when forming a solar cell array, in order to spread a solar cell module in the limited space, it is better that there is as little extra space as possible.
Furthermore, since installation is performed even in dangerous places such as on a sloped roof, the work should be as simple as possible.

  In this respect, in Patent Documents 1 to 3, a mounting bar having a middle plate and two side plates parallel to each other on both sides of the middle plate, a middle plate, and two parallel to each other on both sides of the middle plate Using side plates and tap fittings having respective support pieces projecting upward from the side plates from the side plates, each side plate of the tap fitting is perpendicular to each side plate of the mounting bar. The tap metal fitting is placed inside the mounting bar, and each support piece of the tap metal is protruded from the hole in the middle plate of the mounting bar, and the structure is placed on the mounting bar by each support piece of the tap metal. A locking structure is disclosed. Furthermore, it is disclosed that a structure for engaging the structures or the structure and the gantry between the structures arranged adjacent to each other is provided.

JP 2008-208553 A JP 2008-208554 A JP 2009-41286 A

  In the technology described in each of the above patent documents, a structure for attaching a tap metal fitting to the gantry itself on which the structure is placed is provided. Therefore, in manufacturing the gantry, a process and cost for providing the structure are required. In addition, since an engagement structure is provided between adjacent structures, a gap is formed between adjacent structures. For this reason, when a structure is to be spread in a certain space, the gap becomes a useless space. Furthermore, even when constructing, after disposing another structure adjacent to one structure and then trying to perform an operation such as engagement between the structures, the already disposed structure is It gets in the way and workability is bad.

  On the other hand, when providing an engagement structure between adjacent structures, it is also conceivable to provide an engagement structure on a structure or a frame surrounding the structure. However, in this case as well, this leads to an increase in the process and cost for manufacturing the structure, and the engagement structure may be an obstacle when the structure is packed or transported.

  Therefore, the present invention provides a method for constructing a solar cell array for laying a plurality of solar cell modules fixed on a gantry without providing any special structure to the solar cell module or gantry. For the purpose.

In order to achieve the above object, a solar cell array construction method according to the present invention is provided on a laying surface, and a fixing portion for fixing the solar cell module is predetermined on an upper surface on which the solar cell module is placed. A frame formed at intervals, a solar cell submodule that receives light to generate power, a frame that surrounds the solar cell submodule in a frame shape, and a direction in which the frames are arranged on the frame among the side edges of the frame And a plate-like support portion extending from the opposite two side edges to the gantry side, and extending inward from the lower end of the support portion, being placed on the gantry, A solar cell module comprising: a frame provided with a plate-like base portion fixed on the gantry by a fixing portion; and a metal fitting for fixing the solar cell module on the gantry, wherein one plate Gold The plate has a shape that is folded at a predetermined location, and includes a pressing part that presses the base part of the solar cell module from the upper surface, and bends outward from one end of the pressing part, and extends to the lower surface side of the base part. And a contact portion that extends from the end portion of the extension portion to the adjacent solar cell module side and contacts the base portion of the adjacent solar cell module from the lower surface. A mounting method for mounting a plurality of the solar cell modules on the gantry by a mounting bracket, wherein the first solar cell module is placed on the gantry and one of the first solar cell modules is mounted. The step of fixing the base portion by the fixing portion of the gantry and the second solar cell module on the side of the base portion where the first solar cell module is fixed in the connecting direction on the gantry. The solar cell module is attached to one base portion of the second solar cell module on the base portion fixed to the first solar cell module when the support portions are arranged adjacent to each other. And a step of abutting the abutting portion of the mounting bracket from the lower surface side and fixing the other base portion of the second solar cell module on the gantry by the fixing portion of the gantry. And
Here, the continuous direction means a direction in which the solar cell modules are sequentially arranged on the mount via the solar cell module mounting bracket.

  In addition, when the second solar cell module is connected to the first solar cell module, one base portion of the second solar cell module is preliminarily connected to the pressing portion of the mounting bracket for the solar cell module. A step of attaching the solar cell module mounting bracket to the second solar cell module by sandwiching it between the extension portions may be further included.

  The solar cell module mounting bracket further includes an adhesive portion that extends upward from one end of the pressing portion and adheres to the support portion of the solar cell module, and the solar cell module mounting bracket is In the step of attaching to the second solar cell module, the adhesive portion may be bonded to the support portion via an adhesive tape or an adhesive.

  Further, in the step of attaching the solar cell module mounting bracket to the second solar cell module, an adhesive is filled between the extension portion and the contact portion, and the solar cell module mounting bracket is provided. May be bonded to the solar cell module.

  Further, the solar cell module has a smooth outer surface of the support portion of the frame. When the second solar cell module is connected to the first solar cell module, the first solar cell module is It is good also as what makes the support part of a solar cell module and said 2nd solar cell module contact | abut without gap.

  Moreover, the said base comprises the engaging piece in which the said fixing | fixed part can insert the said base, The base of said 1st solar cell module or said 2nd solar cell module is fixed to the said base When fixing by a part, it is good also as what inserts the said base part in the said engagement piece, and is engaged.

  The laying surface is inclined, and the step of fixing one base portion of the first solar cell module on the gantry includes the base portion on the water side of the first solar cell module as the gantry. Fixing the other base of the second solar cell module on the gantry by the fixing portion of the gantry, the step of fixing the second base portion of the second solar cell module on the gantry in the connecting direction on the gantry, When the second solar cell module is connected to the base portion fixed to the first solar cell module with the support portions adjacent to each other, the base portion to which the first solar cell module is fixed is connected. The extending portion of the solar cell module mounting bracket attached to the underwater base portion of the second solar cell module may be brought into contact with the lower surface side.

  In addition, an engagement claw that engages with an end portion of the base portion to which the adjacent solar cell module is fixed is formed at the tip of the contact portion of the solar cell module mounting bracket. A step of engaging an engaging claw of the mounting bracket for the solar cell module attached to one base portion of the second solar cell module with an end portion of the base portion fixed to the solar cell module It is good.

  Further, when mounting the first solar cell module on the gantry, a base portion located on the opposite side of the second solar cell module in the connecting direction among the end portions of the first solar cell module is provided. It is good also as what further has the process fixed on the said mount frame.

  In addition, when the solar cell modules are successively arranged and attached to the end when the solar cell modules are attached on the pedestal, the solar cell modules are attached on the pedestal and connected to the end. A step of attaching a metal fitting that abuts the end portion of the solar cell module from the outside and restricts the movement of the solar cell module in the connecting direction.

  According to the present invention, a plurality of solar cell modules can be securely fixed and laid on a gantry without providing a special structure for the solar cell module or the gantry without a gap.

It is a perspective view of the solar cell array laid by the construction method of the solar cell array which concerns on 1st embodiment of this invention. It is a schematic diagram which shows the connection structure of the group of solar cell modules laid by the construction method of the solar cell array which concerns on this embodiment. It is the (a) AA arrow directional view and (b) BB arrow directional view in the schematic diagram which shows the connection structure of the group of solar cell modules laid by the construction method of the solar cell array which concerns on this embodiment. . It is the elements on larger scale in the group of solar cell modules laid by the construction method of the solar cell array which concerns on this embodiment, Comprising: The <a> part in FIG. 3 is shown. It is the elements on larger scale in the group of solar cell modules laid by the construction method of the solar cell array which concerns on this embodiment, Comprising: The <b> part in FIG. 3 is shown. It is the elements on larger scale in the group of solar cell modules laid by the construction method of the solar cell array which concerns on this embodiment, Comprising: The <c> part in FIG. 3 is shown. It is the elements on larger scale in the group of solar cell modules laid by the construction method of the solar cell array which concerns on this embodiment, Comprising: The <d> part in FIG. 3 is shown. It is a figure which shows the solar cell module laid by the construction method of the solar cell array which concerns on this embodiment, Comprising: (a) Perspective view, (b) CC sectional drawing, (d) DD sectional drawing. It is a figure which shows the mount frame which mounts the solar cell module laid by the construction method of the solar cell array which concerns on this embodiment, Comprising: (a) The exploded perspective view which shows the attachment process of a fixing bracket, (b) Attaching a fixing bracket FIG. It is a perspective view which shows the fixture used together, when laying a solar cell module by the construction method of the solar cell array which concerns on this embodiment. It is a perspective view which shows the fixture used together, when laying a solar cell module by the construction method of the solar cell array which concerns on this embodiment. It is a perspective view which shows the mounting bracket for solar cell modules used in the construction method of the solar cell array which concerns on this embodiment. When laying a solar cell module by the solar cell array construction method according to the present embodiment, a step of attaching a fixing bracket to the underwater side base portion of the solar cell module laid most under the water among the group of solar cell modules FIG. When installing a solar cell module by the construction method of the solar cell array which concerns on this embodiment, it is sectional drawing which shows the process of attaching the solar cell module laid most under water among a group of solar cell modules to a mount frame. When laying a solar cell module by the solar cell array construction method according to the present embodiment, among the group of solar cell modules, the underwater side base portion of a solar cell module other than the solar cell module laid most under the water It is sectional drawing which shows the process of attaching the mounting bracket for solar cell modules to. It is sectional drawing which shows the process of connecting adjacent solar cell modules with the construction method of the solar cell array which concerns on this embodiment, Comprising: The part which is not mounted on a mount frame is shown, The state of the transition of a process is shown. , (A) and (b) in this order. It is sectional drawing which shows the process of connecting adjacent solar cell modules by the construction method of the solar cell array which concerns on this embodiment, Comprising: The part mounted on a mount frame is shown. When a solar cell module is laid by the solar cell array construction method according to the present embodiment, the fixing bracket is brought into contact with the water-side support portion of the solar cell module laid on the most water side among the group of solar cell modules. It is sectional drawing which shows the process of attaching. It is a perspective view which shows the mounting bracket for solar cell modules used in the construction method of the solar cell array which concerns on 2nd embodiment of this invention. When laying a solar cell module by the solar cell array construction method according to the present embodiment, among the group of solar cell modules, the underwater side base portion of a solar cell module other than the solar cell module laid most under the water It is sectional drawing which shows the process of attaching the mounting bracket for solar cell modules to (a) before attachment, (b) shows after attachment. It is sectional drawing which shows the process of connecting adjacent solar cell modules with the construction method of the solar cell array which concerns on this embodiment, Comprising: (a) shows before connection, (b) shows after connection. It is a perspective view which shows the mounting bracket for solar cell modules used in the construction method of the solar cell array which concerns on 3rd embodiment of this invention. It is sectional drawing which shows the process of connecting adjacent solar cell modules with the construction method of the solar cell array which concerns on this embodiment, Comprising: (a) shows before connection, (b) shows after connection. It is sectional drawing which shows the process of canceling | releasing engagement of the mounting bracket for solar cell modules used in the construction method of the solar cell array which concerns on this embodiment, Comprising: (a) shows before cancellation | release, (b) shows after cancellation | release. . It is a perspective view which shows another example of the mount frame which mounts the solar cell module laid by the construction method of the solar cell array which concerns on 1st to 3rd embodiment.

Next, the construction method of the solar cell array according to the first embodiment of the present invention will be described with reference to the drawings.
FIG.1 and FIG.2 has shown the state which laid the solar cell module 1 with the construction method of the solar cell array which concerns on this embodiment.
On the sloped roof that is the laying surface, a plurality of mounts 2 are attached in parallel to each other in the length direction from the water side to the water side.

On the other hand, the solar cell modules 1 are sequentially connected on the two mounts 2 with the continuous direction x from the water side to the water upper side (the length direction of the mount 2). Furthermore, a group of solar cell modules 1 laid in a row in the continuous direction x is laid in a plurality of rows in a direction orthogonal to the continuous direction x, whereby the solar cell modules 1 are laid vertically and horizontally. In addition, although the solar cell module 1 is laid in contact with the vertical and horizontal in this way, in this example, a direction in which the solar cell modules 1 are connected via the solar cell module mounting bracket 3 is referred to as a continuous direction x.
In the following description, for convenience of explanation, the first solar cell module 1, the second solar cell module 1,... It may be referred to as the nth solar cell module (n is a natural number of 2 or more).

  As shown in FIG. 2, FIG. 3 (a), and FIG. 4, the underwater side end portion of the first solar cell module 1 laid on the most underwater side is the portion placed on the gantry 2. The base portion 124 of the frame 12 is inserted into the insertion portion 4a of the presser fitting 6 fixed on the gantry 2 by the fastening screw 46b, and is fixed on the gantry 2. Thereby, the underwater side edge part of the 1st solar cell module 1 is being fixed on the mount frame 2 as a whole.

As shown in FIG. 2, FIG. 3A, and FIG. 5, the water-side end portion of all the solar cell modules 1 is the base portion 124 of the frame 12 in the portion placed on the mount 2. Is inserted into the insertion portion 6 a of the presser fitting 6 fixed on the gantry 2 by the fastening screw 61 b and fixed on the gantry 2.
On the other hand, the water-side end portions of the second to n-th solar cell modules 1 other than the first solar cell module 1 are not directly fixed on the gantry 2. As shown in FIGS. 2, 3 (b), and 6, the bottom end of the second to n-th solar cell modules 1 is the base portion of the frame 12 at a portion that is not placed on the gantry 2. 124 is pressed from the upper surface by the pressing portion 33 of the solar cell module mounting bracket 3, and the abutting portion 36 of the solar cell module mounting bracket 3 is adjacent to the base portion 124 of the adjacent solar cell module 1. It contacts from below. As a result, the upward movement of the solar cell module 1 is restricted.

  In addition, as shown in FIGS. 2, 3 (a), and 7, a portion placed on the gantry 2 at the water-side end of the nth solar cell module 1 laid on the most water-side. , The solar power module mounting bracket 5 mounted on the gantry 2 by the fastening screw 52b is in contact with the outside. This prevents the nth solar cell module 1 from moving upward.

In this regard, in the following, the water-side end of each solar cell module 1 is referred to as a fixed end directly fixed on the gantry 2 by the presser fitting 6, and the water-side end of the second to n-th solar cell modules 1 The part is referred to as a free end that is not directly fixed on the gantry 2.
As described above, each solar cell module 1 mounted on the gantry 2 is continuously connected to the solar cell module 1 mounted on the lower end along the continuous direction x (the length direction of the gantry 2). In the solar cell module 1, it is laid so that a fixed end and a free end may come alternately.

Next, each member constituting the group of solar cell modules 1 laid will be described.
As shown in FIG. 8A, the solar cell module 1 includes a hollow frame-like frame 12 and a solar cell submodule 11 attached within the frame 12.
The solar cell submodule 11 is a substrate that includes at least a solar cell element that generates power by receiving light, and is laminated with a cover glass or the like that appropriately protects the solar cell element.
The solar cell element applied to the present embodiment is a silicon crystalline (single crystal silicon, polycrystalline silicon), amorphous (amorphous silicon), compound (CIS, CdTe, GaAs, etc.), or organic solar cell. Any element or the like may be used, and the type is not particularly limited.

  The frame 12 is a frame that holds the solar cell submodule 11 and protects the laminated end face, and is made of a metal such as aluminum. The frame 12 is configured in a rectangular shape corresponding to the outer peripheral shape of the solar cell submodule 11 by connecting the ends of the four rod-shaped frame constituent members at right angles.

  Further, as shown in FIGS. 8B and 8C, the frame 12 holds the solar cell submodule 11 from the upper surface side, and the solar cell submodule 11 from the lower surface side. A lower surface side sandwiching portion 122, a plate-like support portion 123 extending from the end of the upper surface side sandwiching portion 121 and the lower surface side sandwiching portion 122 at a right angle to the lower side (the gantry 2 side), and a support portion It is formed from a plate-like base portion 124 that extends from the lower end portion of 123 at a right angle.

  Further, among the side edges of the frame 12, the support part 123 is connected to the solar cell submodule 11 at the two side edges (the eaves side end and the ridge side end) facing each other in the continuous direction x (the length direction of the gantry 2). Are supported on the gantry 2, and the base 124 is placed on the gantry 2.

  The vertical width of the gap formed in a frame shape by the upper surface side sandwiching portion 121 and the lower surface side sandwiching portion 122 is slightly larger than the thickness of the solar cell submodule 11, and forms a groove 12a that opens to the hollow portion side. ing. In the groove 12a, a filler such as butyl rubber is interposed, and the outer peripheral portion of the solar cell submodule 11 is inserted. Thereby, the solar cell submodule 11 and the frame 12 constitute the solar cell module 1 integrally.

  Further, the support portion 123 has a smooth outer surface and is configured to be perpendicular to the base portion 124. As a result, when the plurality of solar cell modules 1 are installed with the support portions 123 being adjacent to each other, the support portions 123 of the adjacent solar cell modules 1 are in contact with each other without any gaps, and without making a space without waste, The battery modules 1 can be continuously provided.

The gantry 2 is a bar-shaped member that is installed in parallel on a laying surface such as a roof and supports the solar cell modules 1 on the laying surface in pairs.
The gantry 2 is formed of a galvanized steel plate or the like, and as illustrated in FIG. 9, is formed in a vertically long rectangular column shape whose lower end is open. Moreover, the long hole 2a and the fastening hole 2b are formed in the upper surface part in which the solar cell module 1 is mounted, and a pair of fastening holes 2c are formed in the vicinity of the water-side end of the side surface part.

The long holes 2a are provided at regular intervals, and through these long holes 2a, insertion bolts are passed through predetermined metal fittings installed on the laying surface and tightened with nuts, so that the gantry 2 is laid. Fixed on the surface.
The fastening holes 2 b are provided on the mount 2 in correspondence with the fastening holes 61 a of the presser fitting 6 at intervals equal to the width of the solar cell module 1.
The fastening hole 2 c is a hole formed corresponding to the fastening hole 46 a of the fixing bracket 4 in order to attach the fixing bracket 4 (described later with reference to FIG. 10) for mounting the first solar cell module 1 on the mount 2. The fastening bolt 41b inserted into the fastening hole 46a of the mounting bracket 4 is inserted into the fastening hole 2c.

On the gantry 2, the presser fitting 6 is attached at a predetermined interval.
The presser fitting 6 is made of a galvanized steel plate or the like, and has a shape obtained by bending a single plate-like metal plate at a predetermined location.
The presser fitting 6 is mounted on the gantry 2, has a plate-like mounting portion 61 parallel to the upper surface of the gantry 2, a standing portion 62 that rises perpendicularly from an end portion of the mounting portion 61, and an end portion of the standing portion 62 The holding part 63 that extends parallel to the upper surface of the gantry 2 and on the water side (in the direction opposite to the mounting part 61), and the oblique installation that extends obliquely upward from the end of the holding part 63 to the water side It is formed from the part 64 and the contact part 65 extended upward from the edge part of the diagonally provided part 64 in the direction orthogonal to the mount frame 2.

On the attachment portion 61 of the presser fitting 6, two fastening holes 61a for inserting the fastening screw 61b and attaching the presser fitting 6 on the mount 2 are formed.
When mounting the presser fitting 6 on the gantry 2, first, the fastening hole 2 b on the gantry 2 and the fastening hole 61 a on the mounting portion 61 of the presser fitting 6 are made to correspond to each other, and the mounting portion 61 of the presser fitting 6 is mounted on the gantry. 2 is mounted.
Then, the fastening screw 61b is inserted through the fastening hole 61a and the fastening hole 2b and screwed into the nut. Thus, the gantry 2 and the presser fitting 6 are integrated, and an insertion portion 6 a for inserting the base portion 124 of the solar cell module 1 is formed between the upper surface of the pedestal 2 and the lower surface of the presser portion 63 of the presser fitting 6. Is done.

  The fixing bracket 4 shown in FIGS. 4 and 10 is attached to the lower end of the first solar cell module 1 laid on the most underwater side, and attached to the gantry 2, and the first solar cell module. 1 is a member for fixing the underwater side end portion 1 on the gantry 2.

  The fixing metal 4 is parallel to the support portion 123 of the first solar cell module 1, and has a plate-like adhesive portion 41 that adheres to the inside of the support portion 123, and a lower end of the adhesive portion 41, so that the first solar cell module The plate-like obliquely extending portion 42 extending obliquely downward toward the base portion 124 side, and extending from the end portion of the obliquely extending portion 42 to the inside of the base portion 124 (the side facing the adhesive portion 41) horizontally. A plate-shaped presser part 43, a standing part 44 that is bent and extended downward from the end part of the presser part 43, and an outer side (adhesion) from the lower end of the standing part 44 in parallel with the presser part 43. The plate-like extended portion 45 bent and extended perpendicularly to the portion 41 side, and the two edges that face each other in the direction perpendicular to the continuous direction x out of the edges of the extended portion 45, respectively, downward. It consists of a pair of side surface parts 46 bent at right angles and extending.

  A double-sided adhesive tape 41 a is attached to the bonding portion 41 to bond it to the inside of the underwater support portion 123 of the first solar cell module 1. With this double-sided adhesive tape 41a, the adhesive portion 41 can be adhered to the inside of the support portion 123 on the underwater side of the first solar cell module 1.

  Further, a fastening hole 46a for inserting a fastening screw 46b is formed in the vicinity of the center of the side surface portion 46. The fastening hole 46 a is formed at a location corresponding to the fastening hole 2 c of the gantry 2. When the fixing bracket 4 is attached to the gantry 2 with the gantry 2 sandwiched between the pair of side surfaces 46, the fastening screws 46b are inserted into the fastening holes 46a and the fastening holes 2c and screwed into the nuts. Thus, the fixing bracket 4 is attached to the gantry 2.

Further, an insertion portion 4 a having a width slightly larger than the thickness of the base portion 124 of the solar cell module 1 is formed between the pressing portion 43 and the extension portion 45.
The base portion 124 on the underwater side of the first solar cell module 1 is inserted into the insertion portion 4 a, and the inserted base portion 124 is sandwiched between the pressing portion 43 and the extension portion 45.

  The fixing bracket 5 shown in FIG. 7 and FIG. 11 is in contact with the water-side support part 123 of the n-th solar cell module 1 laid on the most water side from the outside, and is mounted on the gantry 2 to provide the n-th solar cell. This is a member for fixing the module 1 so as not to move upward.

  The fixing metal 5 includes a plate-like standing part 51 parallel to the water-side support part 123 of the n-th solar cell module 1 and a plate-like part extending from the lower end of the standing part 51 by bending at a right angle. It consists of a base 52.

  The base portion 52 has a fastening hole 52a through which a fastening screw 52b is inserted. The fastening hole 52a is formed at a location corresponding to the fastening hole 2b located on the outer side of the nth solar cell module 1 installed on the uppermost water side among the fastening holes 2b formed on the gantry 2. Then, the fixing bracket 5 is placed on the gantry 2 with the base portion 52 facing the water side, and the fastening screw 52b is inserted into the fastening hole 52a and the fastening hole 2b and screwed into the nut. A fixing metal 5 is attached on the gantry 2.

  As shown in FIGS. 6 and 12, the solar cell module mounting bracket 3 includes a base 124 on the water side of the (n−1) th solar cell module 1 from the first solar cell module 1 to constitute a fixed end, The base portions 124 on the lower side of the second solar cell module 1 to the n-th solar cell module 1 constituting the free end are integrally attached to the adjacent base portion 124 on the upper side of the water and the base portion 124 on the lower side of the water. It is a member which fixes each solar cell module 1 on the mount frame 2 so that it may not move upwards.

  The solar cell module mounting bracket 3 has a shape in which a single plate-like metal plate such as aluminum or stainless steel is folded at a predetermined location, and the first solar cell module 1 to the nth solar cell module 1 are under water. The plate-like adhesive portion 31 that is parallel to the support portion 123 on the side and adheres to the support portion 123 from the inside, and extends obliquely downward from the lower end of the adhesive portion 31 toward the base portion 124 side of each solar cell module 1. A plate-shaped oblique portion 32, and a plate-shaped presser portion 33 that extends from the end portion of the oblique portion 2 to the inner side (side facing the adhesive portion 31) and extends horizontally from the base portion 124; The upright portion 34 bent and extended downward from the end of the presser portion 33 at a right angle, and the lower end of the standup portion 34 bent at a right angle to the outside (adhesive portion 31 side) in parallel with the presser portion 33. Then, the base portion 1 of the solar cell module 1 to which the bonding portion 31 is bonded. 4 and a plate-like extension 35 extending to the lower surface of the solar cell module 1, and further extending from the end of the extension 35 in a direction opposite to the connecting direction x, The contact portion 36 extends to the lower surface of the side base portion 124 and contacts the lower surface of the water-side base portion 124 of the adjacent water-side solar cell module 1.

  A double-sided adhesive tape 31 a for adhering this to the inside of the support portion 123 on the underwater side of the solar cell module 1 is attached to the adhesive portion 31. With this double-sided adhesive tape 31 a, the adhesive portion 31 can be adhered to the inside of the support portion 123 on the underwater side of the solar cell module 1.

Further, an insertion portion 3 a having a width slightly larger than the thickness of the base portion 124 of the solar cell module 1 is formed between the presser portion 33 and the extending portion 35.
The insertion portion 3a is inserted with the base portion 124 under the water of the second solar cell module 1 to the nth solar cell module 1, and the inserted base portion 124 includes the presser portion 33 and the extension portion 35. It is pinched by.

As shown in FIG. 2, the solar cell module mounting bracket 3 is attached to a portion between adjacent solar cell modules 1 where the solar cell module 1 does not abut on the mount 2.
As shown in FIG. 6, when the solar cell module mounting bracket 3 is mounted between the underwater solar cell module 1 and the overwater solar cell module 1, The underwater base portion 124 is pressed from above by the presser portion 33, and the abutting portion 36 of the solar cell module mounting bracket 3 contacts the underwater surface base portion 124 of the underwater solar cell module 1 from the lower surface. Touch. As a result, the upward movement of the water-side solar cell module 1 that is the free end is restricted.

Next, a series of steps for laying the solar cell module 3 by the solar cell array construction method according to the present embodiment will be described.
First, as shown in FIG. 13, the fixture 4 is attached to the first solar cell module 1.
In this step, the base part 124 on the underwater side of the first solar cell module 1 is inserted into the insertion part 4 a of the fixing metal 4, and the inside of the support part 123 on the underwater side of the first solar cell module 1 is fixed. The adhesive part 41 of the metal fitting 4 is brought into contact. As a result, the inner surface of the support portion 123 and the adhesive portion 41 are adhered to each other by the double-sided adhesive tape 41 a, and the fixing bracket 4 is attached to the first solar cell module 1.

Then, as shown in FIG. 14, the presser fitting 6 is attached to a predetermined location in advance, and the first solar cell module 1 is attached to the gantry 2 that has been installed on the laying surface.
In this step, the underwater side end of the gantry 2 is sandwiched between the pair of side surface portions 46 of the fixing metal 4 so that the fastening hole 2 c of the gantry 2 and the fastening hole 46 a of the fixing metal 4 correspond to each other. At the same time, the water-side base portion 124 of the first solar cell module 1 is inserted into the insertion portion 6a of the presser fitting 6 from the water-side end at the water-side end of the gantry 2.
Then, as shown in FIG. 4, the fastening screw 46b is inserted through the fastening hole 46a and the fastening hole 2c, and screwed into the nut.
As a result, the lower end and the upper end of the first solar cell module are fixed on the gantry 2.

Next, the first solar cell module 1 is sequentially connected with the second solar cell module 1 to the nth solar cell module 1.
First, as shown in FIG. 15, for the second solar cell module 1, the solar cell module mounting bracket 3 is attached to the lower end portion.
In this step, the underwater support portion 123 of the second solar cell module 1 is inserted into the insertion portion 3a of the solar cell module mounting bracket 3 while the underwater base portion 124 of the second solar cell module 1 is inserted. The adhesive portion 31 of the solar cell module mounting bracket 3 is brought into contact with the inner surface. Accordingly, the adhesive portion 31 is adhered to the inner surface of the support portion 123 by the double-sided adhesive tape 31a, and the solar cell module mounting bracket 3 is attached to the second solar cell module 1.

  Then, as shown in FIG. 16, the outside of the water-side support portion 123 of the second solar cell module 1 is brought into contact with the outside of the water-side support portion 123 of the adjacent first solar cell module 1, and the first 2 The contact portion 36 of the solar cell module mounting bracket 1 attached to the solar cell module 1 is brought into contact with the base portion 124 of the first solar cell module 1 from the lower surface.

At this time, as shown in FIG. 17, the water base portion 124 of the second solar cell module 1 is inserted into the insertion portion 6 a of the presser fitting 6 from above the water on the gantry 2.
As a result, the lower end of the second solar cell module 1, which is the free end of the second solar cell module 1, is placed on the upper surface of the lower base portion 124 by the holding portion 33 of the mounting bracket 3 for the solar cell module 1 as shown in FIG. 6. At the same time, the contact portion 36 of the solar cell module mounting bracket 3 comes into contact with the base portion 124 of the first solar cell module 1 from the lower surface, so that the second solar cell module is moved upward. Movement is regulated.
Further, the water-side end portion of the second solar cell module 1 is fixed on the gantry 2 by the presser fitting 6 to constitute a fixed end.

Then, when all the solar cell modules 1 up to the nth solar cell module 1 laid on the uppermost water surface are mounted on the mount 2 in accordance with the mounting process of the second solar cell module 1 as described above, As shown in FIG. 18, the fixture 5 is attached to the outside of the water-side end of the nth solar cell module 1.
In this step, the outside of the standing portion 51 of the fixture 5 is brought into contact with the outside of the water-side support portion 123 of the nth solar cell module 1 and the base portion 52 of the fixture 5 is placed on the gantry 2. . Then, the fastening screw 52b is inserted into the fastening hole 52a drilled on the base portion 52 and the fastening hole 2b on the mount 2, and screwed into the nut.
Thereby, the solar cell module mounting bracket 1 is mounted on the mount 2 and the movement of the nth solar cell module 1 toward the water side (continuous connection direction x) is restricted. As a result, the free ends of all the solar cell modules 1 are restricted from moving upward and above the water, and are fixed on the gantry 2.

  By the solar cell array construction method according to the first embodiment described above, a plurality of solar cell modules 1 are placed on the gantry 2 without gaps without providing a special structure to the solar cell module 1 or the gantry. It can be securely laid. Moreover, it is easy to attach the solar cell module 1 simply by sliding it to the adjacent solar cell module 1 side under water.

Next, another example of the solar cell module mounting bracket used in the solar cell array construction method according to the second embodiment of the present invention will be described.
As shown in FIG. 19 to FIG. 21, the solar cell module mounting bracket 7 has a shape in which a single plate-like metal plate such as aluminum or stainless steel is folded at a predetermined location, and the first solar cell module 1. To the n-th solar cell module 1, the plate-like adhesive portion 71 that is parallel to the underwater support portion 123 and is bonded to the support portion 123 from the inside, and the lower end of the adhesive portion 71. A plate-like oblique portion 72 extending obliquely downward toward the base portion 124 side, and extending from the end portion of the oblique portion 72 to the inside of the base portion 124 horizontally (side facing the adhesive portion 71). The protruding plate-shaped presser portion 73, the standing portion 74 that is bent and extended downward from the end portion of the presser portion 73, and the lower end of the standing portion 74, the outer side in parallel with the presser portion 73 ( Bend at a right angle to the adhesive part 71 side), and the adhesive part 71 adheres The solar cell module 1 extends from the bottom surface of the base portion 124 of the solar cell module 1 and extends from the end of the extended portion 45 in a direction opposite to the continuous direction x. The urging portion 76 extends to the lower surface of the water-side base portion 124 of the module 1 and comes into contact with the lower surface of the water-side base portion 124 of the adjacent water-side solar cell module 1.

  Similar to the solar cell module mounting bracket 3, a double-sided adhesive tape 71 a for adhering it to the inside of the support portion 123 of the solar cell module 1 is attached to the adhesive portion 71. With this double-sided adhesive tape 71a, the contact portion 71 can be bonded to the inside of the support portion 123 of the first solar cell module 1.

Further, an insertion portion 7 a having a width slightly larger than the thickness of the base portion 124 of the solar cell module 1 is formed between the pressing portion 73 and the extending portion 75.
The underwater base portion 124 of the second solar cell module 1 to the nth solar cell module 1 is inserted into the insertion portion 7a.

The urging portion 76 is thicker than the extending portion 75, forms a step at the boundary portion with the extending portion 75, and its upper surface is higher than the upper surface of the extending portion 75.
When the solar cell module mounting bracket 7 is attached between the adjacent solar cell modules 1, the urging portion 76 pushes the water-side base portion 124 of the water-side solar cell module 1 upward from the lower surface. Energize. On the other hand, when viewed from the side of the solar cell module 1 on the water side to which the solar cell module mounting bracket 7 is attached, the presser portion 73 causes water to move by the difference in thickness between the biasing portion 76 and the extension portion 75. A force is applied so that the lower base 124 is pushed downward from the upper surface.

The laying process of the solar cell module 1 using the solar cell module mounting bracket 7 will be described with reference to FIGS.
First, in the same manner as in the first embodiment, the solar cell module mounting bracket 7 is attached to the underwater side end of the second to nth solar cell modules 1 in advance.
In this step, as shown in FIG. 20, the underwater side base portion 124 of the solar cell module 1 is inserted into the insertion portion 7 a of the solar cell module mounting bracket 7, and the adhesive portion 71 is connected to the solar cell module 1. This is brought into contact with the inner surface of the underwater support portion 123. As a result, the adhesive portion 71 and the inner surface of the underwater support portion 123 are adhered to each other by the double-sided adhesive tape 71 a, and the solar cell module mounting bracket 7 is attached to the solar cell module 1.

  Here, when the solar cell module mounting bracket 7 is attached to the underwater base portion 124 of the solar cell module 1, the stepped portion formed at the boundary portion between the extending portion 75 and the urging portion 76 is The support part 123 of the solar cell module 1 is engaged from the outside. By this engagement, the solar cell module mounting bracket 7 can be securely attached to the underwater base portion 124 of the solar cell module 1, and the base portion 124 is formed so that the extension portion 75 jumps up when engaged. It is possible to intuitively confirm that the attachment has been performed reliably by the sound or attachment feeling at this time.

Then, as shown in FIG. 21, the support portions 123 of the adjacent solar cell modules 1 are brought into contact with each other, and the urging portion 76 is placed on the water base of the adjacent solar cell module 1 on the lower side. The portion 124 is brought into contact with the lower surface.
Note that the water-side end portion of the solar cell module 1 to which the solar cell module mounting bracket 7 is attached is pressed by the water-side base portion 124 at the portion placed on the mount 2 as in the first embodiment. It is inserted into the insertion part 6a of the metal fitting 6 to constitute a fixed end.

  According to the above embodiment, since the upper surface of the urging portion 76 of the solar cell module mounting bracket 7 is formed higher than the upper surface of the extending portion 75, the amount of difference in height is below the water. The force which lifts up the water base part 124 of the solar cell module 1 on the side works. At the same time, the pressing portion 73 exerts a strong force to push the water-side base portion 124 of the water-side solar cell module 1 downward. Thereby, the free end of the solar cell module 1 on the water side is more strongly restricted from moving upward.

  The urging portion 76 of the solar cell module mounting bracket 7 used in the present embodiment is provided with a step at the boundary with the extending portion 75 and the upper surface and the lower surface are horizontal, but this is not restrictive. The upper surface of the urging portion 76 may be an inclined surface that gradually increases from the boundary portion with the extending portion 75 toward the outside.

Next, another example of the solar cell module mounting bracket used in the solar cell array construction method according to the third embodiment of the present invention will be described.
As shown in FIGS. 22 and 23, the solar cell module mounting bracket 8 has a shape in which a single plate-like metal plate such as aluminum or stainless steel is folded at a predetermined location, and the first solar cell module 1 To the n-th solar cell module 1, the plate-like adhesive portion 81 that is parallel to the underwater support portion 123 and is bonded to the support portion 123 from the inside, and the lower end of the adhesive portion 81. A plate-shaped oblique portion 82 extending obliquely downward toward the base portion 124 side, and extends from the end portion of the oblique portion 82 inwardly to the base portion 124 inward (side facing the adhesive portion 81). The protruding plate-shaped pressing portion 83, the standing portion 84 that is bent and extended downward from the end portion of the pressing portion 83, and the lower end of the standing portion 84, the outer side in parallel with the pressing portion 83 ( Bend at a right angle to the adhesive part 71 side), and the adhesive part 81 adheres An extended portion 85 extending to the lower surface of the base portion 124 of the solar cell module 1, and further extending from the end portion of the extended portion 85 in a direction facing the continuous direction x, and adjacent to the underwater solar cell. A contact portion 86 that extends to the lower surface of the water-side base portion 124 of the module 1 and contacts the lower surface of the water-side base portion 124 of the adjacent water-side solar cell module 1, and an end portion of the contact portion 86 And an engaging claw 87 protruding upward at a right angle.

  Similar to the solar cell module mounting bracket 3, a double-sided adhesive tape 81 a that adheres to the inside of the support portion 123 of the solar cell module 1 is attached to the adhesive portion 81. With this double-sided adhesive tape 81a, the adhesive portion 81 can be adhered to the inside of the support portion 123 of the first solar cell module 1.

Further, an insertion portion 8 a having a width slightly larger than the thickness of the base portion 124 of the solar cell module 1 is formed between the presser portion 83 and the extending portion 85.
The underwater base portion 124 of the second solar cell module 1 to the nth solar cell module 1 is inserted into the insertion portion 8a.

  When the solar cell module mounting bracket 8 is attached between the adjacent solar cell modules 1, the engaging claws 87 engage with the inner edge of the water-side base portion 124 of the water-side solar cell module 1, The water-side solar cell module 1 is restricted from moving in the water direction.

The laying process of the solar cell module 1 using the solar cell module mounting bracket 8 will be described with reference to FIG.
First, in the same manner as in the first embodiment, the solar cell module mounting bracket 8 is attached to the underwater side end of the second to nth solar cell modules 1 in advance. In this step, as shown in FIG. 22, the underwater side base portion 124 of the solar cell module 1 is inserted into the insertion portion 8 a of the solar cell module mounting bracket 8, and the adhesive portion 81 is connected to the solar cell module 1. This is brought into contact with the inner surface of the underwater support portion 123. Thereby, the contact part 81 and the inner surface of the underwater support part 123 are bonded by the double-sided adhesive tape 81 a, and the solar cell module mounting bracket 8 is attached to the solar cell module 1.

Then, the support portions 123 of the adjacent solar cell modules 1 are brought into contact with each other, and the contact portion 86 is brought into contact with the water-side base portion 124 of the adjacent underwater solar cell module 1 from the lower surface. .
At this time, the engaging claw 87 engages with the inner edge of the water-side base portion 124 of the adjacent solar cell module 1 on the water-side.
Note that the water-side end portion of the solar cell module 1 to which the solar cell module mounting bracket 8 is attached is pressed by the water-side base portion 124 at the portion placed on the gantry 2 as in the first embodiment. It is inserted into the insertion part 6a of the metal fitting 6 to constitute a fixed end.

  According to the above embodiment, the movement of the water-side solar cell module 1 to the water-side is restricted by the engaging claws 87 of the solar cell module mounting bracket 8, and each solar cell module 1 is moved in the water direction. Can be controlled. In addition, when adjacent solar cell modules 1 are connected in series, an engaging claw 87 that slides on the lower surface of the water-side base portion 124 of the water-side solar cell module 1 is attached to the inner end portion of the water-side base portion 124. When engaging, the contact portion 86 hits the lower surface of the water-side base portion 124 and makes a sound, so it can be intuitively determined whether or not the adjacent solar cell modules 1 are firmly connected to each other.

Furthermore, the engagement between the engagement claws 87 of the solar cell module mounting bracket 8 and the base portion 124 of the solar cell module 1 for the solar cell modules 1 connected in series by the solar cell array construction method according to the present embodiment. The process of canceling the match will be described.
As shown in FIG. 24, when the engagement by the solar cell module mounting bracket 8 is released, a release plate 88 is used.
The release plate 88 is a flat thin plate and is made of wood or metal.

When releasing the engagement, as shown in FIG. 24A, the release plate 88 is inserted from above between the support portions 123 in contact with each other between the adjacent solar cell modules 1. And the front-end | tip of the cancellation | release board 88 is made to contact | abut to the extension part 85 thru | or contact part 86 of the mounting bracket 8 for solar cell modules, and the extension part 85 thru | or contact part 86 is pushed down further.
When the extension portion 85 or the contact portion 86 is pushed down to a certain extent, as shown in FIG. 24B, the upper end of the engaging claw 87 is pushed down from the lower surface of the base portion 124 of the solar cell module 1, The engagement is released. In this state, when the solar cell module 1 on the water side is pulled in the water direction, the solar cell modules 1 that have been continuously provided are separated.

  The release plate 88 may have a thickness at one end that is gradually increased toward the other end. Accordingly, the release plate 88 can be smoothly inserted between the support portions 123 of the adjacent solar cell modules 1 with the thin end portion as the tip portion.

Finally, another embodiment of the gantry 2 used in the solar cell array construction method according to the first to third embodiments described above will be described with reference to FIG.
As shown in FIG. 25, the gantry 9 according to another example of the gantry 2 is formed of a galvanized steel plate or the like, similar to the gantry 2 described above, and has a vertically long rectangular column shape with an open lower end. Is formed.
A long hole 9a is formed in the upper surface portion of the gantry 9, and a fastening hole 9b is formed in the vicinity of the eaves side end portion of the side surface portion. The long hole 9a and the fastening hole 9b are respectively the same as the long hole 2a and the fastening hole 2c in the mount 2 described above.

Further, engagement pieces 91 are provided on the upper surface of the gantry 9 at a predetermined interval.
The engaging piece 91 is formed so as to protrude upward by cutting and raising the upper surface portion of the gantry 9. Therefore, the engagement piece 91 rises from the upper end surface of the gantry 9 and opens to the water side so that a slight gap is formed between the engagement piece 91 and the upper surface of the gantry 9. The base portion 124 of the solar cell module 1 can be inserted into the gap, whereby the solar cell module 1 can be fixed on the gantry 9.

In the laying of the solar cell module 1 by the solar cell array construction method according to the first to third embodiments described above, an inclined roof is used as the laying surface. It can be applied to a flat roof, and the laying surface is not particularly limited.
In this example, when the solar cell module mounting brackets 3, 7, 8 are bonded to the solar cell module 1, the solar cell module 1 mounting portion 123 and the solar cell module mounting brackets 3, 7, 8 are bonded. Although the parts 31, 71, 81 are bonded by the double-sided adhesive tapes 31a, 71a, 81a, the present invention is not limited to this, and may be bonded using an adhesive. In addition, the base portion 124 of the solar cell module 1, the presser portions 33, 73, 83, the standing portions 34, 74, 84, or the extending portions 35, 75, 85 are also attached to the part to be bonded. The base part 124 of the solar cell module 1 and the solar cell module mounting brackets 3, 7, 8 may be bonded by filling the plugs 3a, 7a, 8a with a filler. You may let them. Further, the fixing bracket 4 may be similarly bonded using an adhesive, and the base portion 124 of the solar cell module 1 and the pressing portion 43, the standing portion 44, or the extending portion 45 are bonded on both sides. It is good also as what is made to adhere by a tape or an adhesive agent.
Moreover, in this example, although the three solar cell module mounting brackets 3, 7, and 8 are attached between the adjacent solar cell modules 1, the number is not particularly limited.

DESCRIPTION OF SYMBOLS 1 Solar cell module 11 Solar cell submodule 12 Frame 12a Strip groove 121 Upper surface side clamping part 122 Lower surface side clamping part 123 Support part 124 Base part 2, 9 Base 2a, 9a Long hole 2b Fastening hole 2c, 9b Fastening hole 3, 7 , 8 Mounting bracket for solar cell module 3a, 7a, 8a Insertion part 31, 71, 81 Adhesion part 31a, 71a, 81a Double-sided adhesive tape 32, 72, 82 Slanting part 33, 73, 83 Holding part 34, 74, 84 Standing portion 35, 75, 85 Extending portion 36, 76, 86 Contact portion 4 Fixing bracket 4a Insertion portion 41 Adhesive portion 41a Double-sided adhesive tape 42 Slanting portion 43 Holding portion 44 Standing portion 45 Extending portion 46 Side surface 46a Fastening hole 46b Fastening screw 5 Fixing bracket 51 Standing portion 52 Base 52a Fastening hole 52b Fastening screw 6 Presser fitting 6a Insertion portion 61 Attached part 61a Fastening hole 61b Fastening screw 62 Standing part 63 Pressing part 64 Slanting part 65 Abutting part 87 Engaging claw 88 Release plate 9 Base 9a Long hole 9b Fastening hole 91 Engaging piece

Claims (10)

A pedestal installed on a laying surface, on a top surface on which the solar cell module is placed, a fixing portion for fixing the solar cell module formed at a predetermined interval;
A solar cell sub-module that receives light and generates power, a frame that surrounds the solar cell sub-module in a frame shape, and a side edge of the frame body, respectively, from two side edges that face each other in the connecting direction on the frame, respectively A plate-like support portion extending to the gantry side, and extending inward from the lower end of the support portion, is placed on the gantry, and is fixed on the gantry by the fixing portion of the gantry. In a solar cell module comprising a frame having a plate-like base,
A metal fitting for fixing the solar cell module on the gantry, comprising a shape in which a single plate-like metal plate is folded at a predetermined location, and a pressing portion for pressing the base portion of the solar cell module from the upper surface; Bending outward from one end of the presser and extending to the lower surface side of the base, and extending from the end of the extended part to the adjacent solar cell module side, A solar cell module mounting bracket having a contact portion that comes into contact with the base portion of the matching solar cell module from the lower surface,
A construction method for attaching a plurality of the solar cell modules on the mount,
The step of mounting the first solar cell module on the gantry and fixing one base portion of the first solar cell module by the fixing portion of the gantry,
When the second solar cell module is connected to the base portion on which the first solar cell module is fixed, with the support portions adjacent to each other, in the continuous arrangement direction on the gantry, The abutting portion of the mounting bracket for the solar cell module attached to the base portion of the second solar cell module is brought into contact with the base portion fixed to the solar cell module from the lower surface side, and the base is fixed. Fixing the other base of the second solar cell module on the gantry by the unit,
A method for constructing a solar cell array, characterized in that: When the second solar cell module is connected to the first solar cell module, one base portion of the second solar cell module is previously extended with the pressing portion of the mounting bracket for the solar cell module. A step of attaching the solar cell module mounting bracket to the second solar cell module,
The construction method of the solar cell array according to claim 1. The solar cell module mounting bracket further has an adhesive portion extending upward from one end portion of the pressing portion and adhering to the support portion of the solar cell module,
In the step of attaching the solar cell module mounting bracket to the second solar cell module, the adhesive portion is bonded to the support portion via an adhesive tape or an adhesive.
The construction method of the solar cell array of Claim 2. In the step of attaching the solar cell module mounting bracket to the second solar cell module, an adhesive is filled between the extension portion and the contact portion, and the solar cell module mounting bracket is Adhere to solar cell module,
The construction method of the solar cell array of Claim 2 or 3. The solar cell module has a smooth outer surface of the frame support,
When connecting the second solar cell module to the first solar cell module, the support portions of the first solar cell module and the second solar cell module are brought into contact with each other without gaps.
The construction method of the solar cell array according to any one of claims 1 to 4. In the gantry, the fixing part constitutes an engagement piece into which the base part can be inserted,
When the base portion of the first solar cell module or the second solar cell module is fixed by the fixing portion of the gantry, the base portion is inserted into the engagement piece and engaged.
The construction method of the solar cell array in any one of Claims 1 thru | or 5. The laying surface is inclined,
The step of fixing one base portion of the first solar cell module on the gantry includes fixing the water base portion of the first solar cell module on the gantry by the fixing portion of the gantry,
The step of fixing the other base portion of the second solar cell module on the pedestal by the fixing portion of the gantry includes the step of fixing the base of the first solar cell module in the connecting direction on the gantry. When the second solar cell module is connected to the portion side with the support portions adjacent to each other, the base portion fixed to the first solar cell module is placed under the water of the second solar cell module. Abutting the extended portion of the mounting bracket for the solar cell module attached to the base portion on the side from the lower surface side,
The construction method of the solar cell array according to any one of claims 1 to 6. At the tip of the contact portion of the solar cell module mounting bracket, an engaging claw that engages with the end of the base portion fixed to the adjacent solar cell module is formed,
Engaging the engaging claws of the mounting bracket for the solar cell module attached to the one base portion of the second solar cell module to the end portion of the base portion fixed to the first solar cell module; Further having
The construction method of the solar array according to any one of claims 1 to 7. When the first solar cell module is mounted on the gantry, the base portion located on the opposite side of the second solar cell module in the connecting direction among the end portions of the first solar cell module is the gantry. Further comprising fixing on
The construction method of the solar cell array according to any one of claims 1 to 8. When the solar cell modules are successively arranged and attached to the end of the solar cell module, the end of the solar cell module provided in the arrangement direction is attached to the end of the stand and attached to the end. A step of attaching a metal fitting that contacts the part from the outside and restricts the movement of the solar cell module in the continuous direction,
The construction method of the solar cell array according to any one of claims 1 to 9.

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