JP5750287B2 - Solar cell panel mount and solar cell device - Google Patents

Description

  The present invention relates to a solar cell panel mount for fixing a solar cell panel to an installation site such as a site or a roof while maintaining a predetermined posture, and a solar cell device equipped with the solar cell panel.

From the viewpoint of protecting the global environment, the use of electric power by solar cell power generation is attracting attention as clean energy. For example, a mode in which a solar cell panel is installed on the roof of a general house to assist electric power used in the home is well known.
In recent years, large-scale power generation using solar cells has been sought, and attempts have been made to supply a large amount of power by installing a large number of solar cell panels on a vast site.

Such a solar cell panel is preferably installed such that its surface is perpendicular to the direction of sunlight irradiation, and can be efficiently generated by being installed in this way.
Since the altitude of the sun varies depending on the location and season, a solar cell panel mount is known in which the inclination angle of the solar cell panel can be changed according to the installed location and season (see, for example, Patent Documents 1 and 2). .

JP-A-8-170790 JP 2005-64147 A

By the way, when a large number of solar cell panels are installed or a large number of solar cell panels are installed, the work of changing the inclination angle of the solar cell panel becomes a large-scale work. Therefore, there is a solar cell panel mount that can easily change the inclination angle of the solar cell panel. It is desired.
Further, when an operation of changing the inclination angle of the solar cell panel is performed, if the solar cell panel is subjected to an external force such as a twist, the solar cell panel may be damaged. Therefore, the solar cell panel has predetermined rigidity and strength. There is a demand for a solar panel mount that can be supported so that external force does not act on the panel.

  The present invention has been made in view of the above-described circumstances, and can easily change the inclination angle of the solar cell panel, has predetermined rigidity and strength, and supports the solar cell panel so that an external force does not act on the solar cell panel. An object of the present invention is to provide a solar cell panel mount and a solar cell device that can be used.

In order to achieve the above object, a solar cell panel frame according to the present invention is a solar cell panel frame that holds a solar cell panel at a predetermined inclination angle at an installation location, and is arranged at a predetermined interval from each other at the installation location. A plurality of leg portions, a support portion that is installed on each of the plurality of leg portions and rotatably supports the solar cell panel, and the rotating solar cell panel is locked at a predetermined inclination angle. An angle holding part for holding the angle holding part, and the angle holding part is fixed to the solar cell panel via a locking part installed on the leg part and a plurality of interposing members arranged at predetermined intervals. is possess a be-engaged portion to be locked in place in the locking portion, between the adjacent interposed member is provided a reinforcing member for reinforcing by connecting each other, reinforcing The member is a brace provided between adjacent intervention members. Provided, the brace is one end fixed to the vicinity of the locking portion, the other end is characterized in that it is fixed to the vicinity of the solar cell panel.
In the solar cell device according to the present invention, a solar cell panel is fixed to the solar cell panel mount.

  In the present invention, the solar cell panel includes a support unit that rotatably supports the solar cell panel, and an angle holding unit that holds and holds the rotating solar cell panel at a predetermined inclination angle. The inclination angle can be easily changed.

Also, between the adjacent disengaging intends through instrumentation member, and more and this the reinforcing member for reinforcing by connecting to each other are provided, the rigidity and strength of the solar cell panel cradle is secured.
This ensures that because the next Ri fit interposed member is possible to prevent the relative displacement, is force to the solar cell panel by relative displacement of adjacent Ri fit interposed member can be prevented from being affected.
Furthermore, since the solar cell panel can be rotated in a stable state, an operation of changing the inclination angle of the solar cell panel can be easily performed.

Also, reinforcement members are next example Bei braces provided between multiplexer intends through instrumentation member, brace has one end fixed to the vicinity of the locking portion, the other end GaFutoshi solar cell panel by being fixed in the vicinity, and can be reliably bonded to intermediate member to each other to brace adjacent, it is possible to prevent the relative displacement of adjacent interposed member, the external force acting in the array direction of the interposed member Can resist.

Moreover, in the solar cell panel mount according to the present invention, the locking portion has a recessed portion that can be locked by fitting the locked portion with the locked portion of the locked portion that rotates together with the solar cell panel. It is preferable that a plurality are formed along the track.
By being comprised in this way, a solar cell panel can be hold | maintained to a predetermined inclination angle by fitting a to-be-latched part in either of several recessed parts, and a to-be-latched part is fitted. The inclination angle of the solar cell panel can be easily changed by changing the recess.

According to the present invention, the present invention includes a support portion that rotatably supports the solar cell panel, and an angle holding portion that holds and holds the rotating solar cell panel at a predetermined inclination angle. Thus, the inclination angle of the solar cell panel can be easily changed.
Further, between the adjacent leg portions or between the adjacent intervention members, a reinforcing member that connects and reinforces each other is provided, so that the adjacent leg portions or the adjacent intervention members are relatively displaced. Therefore, it is possible to prevent the external force from acting on the solar cell panel due to the relative displacement of the adjacent leg portions or the adjacent interposed members, and the solar cell panel can be rotated in a stable state. The operation of changing the inclination angle of the solar cell panel can be easily performed.

(A) is a side view which shows an example of the solar cell apparatus by 1st Embodiment of this invention, (b) is a direction arrow view of (a). (A) is a front view explaining a support part, (b) is a side view of (a), (c) is an exploded perspective view of (a). It is a figure explaining the angle holding | maintenance part of 1st Embodiment. (A) is a side view which shows a mode that the inclination angle of the solar cell panel of the solar cell apparatus shown in FIG. 1 was changed, (b) is a b direction arrow line view of (a). (A) is a side view which shows an example of the solar cell apparatus by 2nd Embodiment of this invention, (b) is a c direction arrow directional view of (a). It is a figure explaining the angle holding | maintenance part of 2nd Embodiment. (A) is a side view which shows a mode that the inclination-angle of the solar cell panel of the solar cell apparatus shown in FIG. 5 was changed, (b) is a d direction arrow line view of (a). (A) is a side view which shows an example of the solar cell apparatus by 3rd Embodiment of this invention, (b) is an e direction arrow directional view of (a). It is a figure explaining the brace of 3rd Embodiment.

(First embodiment)
Hereinafter, a solar cell device according to a first embodiment of the present invention will be described with reference to FIGS. 1 to 4.
As shown in FIGS. 1A and 1B, the solar cell device 1A according to the present embodiment has a solar cell panel 2 and the solar cell panel 2 at a predetermined inclination angle with respect to an installation place 10 such as a site or a roof. A solar cell panel mount 3A to be held is provided.

  The solar cell panel 2 includes a glass plate and a large number of solar cell elements arranged on the surface of the glass plate. The solar cell panel 2 is formed in a plate shape as a whole, and the irradiation surface 2a to which the sunlight is irradiated is irradiated with sunlight. When configured, it is configured to generate electricity. In addition, the kind of solar cell panel 2 is not specifically limited, A well-known solar cell panel can be used.

Such a solar cell panel 2 is normally installed so that the irradiation surface 2a irradiated with sunlight faces upward in the south. And the solar cell panel 2 can generate electric power efficiently, so that the irradiation surface 2a is near perpendicular | vertical with respect to the direction of sunlight irradiation.
For this reason, in the solar cell device 1A according to the present embodiment, the solar cell panel mount 3A supports the solar cell panel 2 so that the solar cell panel 2 can rotate at a desired inclination angle facing southward. It is configured so that it can be locked at an inclination angle.
Here, the direction in which the solar cell panel 2 rotates is referred to as a rotation direction A, and will be described below as a direction of an arrow A in FIG.

Although not shown in the figure, the solar cell panels 2 are arranged in a plurality in a direction orthogonal to the rotation direction A (the direction of arrow B in FIG. 1B, hereinafter referred to as the east-west direction B). These are supported at the installation place 10 by two solar cell panel mounts 3A arranged at predetermined intervals in the east-west direction B, respectively.
Each solar cell panel 2 may be supported at the installation location 10 by three or more solar cell panel mounts 3A.

  3A of solar cell panel mounts are the leg part 11 supported by the installation place 10, the support part 12 which is attached to the upper end part 11a of the leg part 11, and supports the solar cell panel 2 so that rotation is possible, and the sun which rotates And an angle holding unit 13 that holds and holds the battery panel 2 at a predetermined inclination angle.

The leg portion 11 is spaced from the installation place 10 in a direction orthogonal to the arrangement direction (east-west direction B) of the solar cell panel mount 3A (the direction of arrow C in FIG. There are provided two reinforced concrete foundations 15 and 15 which are opened, and diagonal members 16 and 16 which are fixed to the foundations 15 and 15 and extend obliquely upward from the foundations 15 and 15, respectively. The two diagonal members 16, 16 are connected or close to each other at the upper end 16a. The upper end portions 16 a of the two diagonal members 16, 16 correspond to the upper end portion 11 a of the leg portion 11.
Here, of the two diagonal members 16, 16, the one disposed on the south side (the right side in FIG. 1A) is the first diagonal member 16A, and the one disposed on the north side is the second diagonal member 16B. This will be described below.

  Moreover, as shown in FIG.1 (b), between the 2nd diagonal materials 16B and 16B adjacent to the east-west direction B, it fixes to each upper end part 16a and the other lower end part 16b, and each extends in the diagonal direction. A pair of braces (reinforcing members) 19, 19 are provided. The pair of braces 19 and 19 connect and reinforce the second diagonal members 16B and 16B, prevent the second diagonal members 16B and 16B from being relatively displaced, and efficiently handle external forces acting in the east-west direction. Can resist.

The support part 12 is installed in the upper end part 11a of the two leg parts 11 and 11, and the cylindrical bearing 17 extended in the east-west direction B and the east-west direction B are extended as shown in FIG. 1 and FIG. The shaft 18 is formed in a rod shape, is inserted into the bearing 17, is rotatably held in the rotation direction A, and is fixed to the solar cell panel 2 (see FIG. 1).
In the present embodiment, one shaft portion 18 is inserted through both of the bearings 17 and 17 that are individually installed on the two solar cell panel mounts 3A and 3A (see FIG. 1B).

As shown in FIG. 2, the shaft portion 18 is formed in a cross-sectional shape smaller than the inner diameter of the bearings 17, 17, and the outer periphery portion 18 a has a circular shape that is substantially the same as the inner diameter of the bearing 17 and is inserted into the bearings 17, 17. When this is done, the plate material 18b that contacts the inner peripheral surface 17a of the bearing 17 is fixed. The plate member 18 b is configured to be rotatable in the rotation direction A along the inner peripheral surface 17 a of the bearing 17.
And since the axial part 18 is being fixed with the solar cell panel 2 (refer FIG. 1), if it rotates to the rotation direction A, the solar cell panel 2 will also be comprised so that it may also rotate to the rotation direction A. .

  Returning to FIG. 1, the angle holding unit 13 is fixed to the solar cell panel 2 through a locking unit 21 installed on the leg unit 11 and a plurality of interposing members 22 arranged at predetermined intervals. A locking portion 23 that is locked to the locking portion 21 at a predetermined position is provided.

  The intervention member 22 includes two rod-like members 24 and 25, and one end portions 24 a and 25 a of the rod-like members 24 and 25 are respectively provided on the surface 2 b opposite to the irradiation surface 2 a of the solar cell panel 2. It is fixed at a predetermined interval in the north-south direction C, and the other end portions 24b, 25b are connected to form a substantially L shape or a substantially V shape.

The interposed members 22 are arranged on both sides in the east-west direction B of the support portion 12, and the other end portions 24 b and 25 b of the rod-shaped members 24 and 25 of each interposed member 22 are connected to the locked portion 23. It is fixed.
The locked portion 23 is a rod-shaped member extending in the east-west direction B of the solar cell panel 2, and both end portions thereof are fixed to the interposed member 22.

As shown in FIGS. 1 and 3, the locking portion 21 is a pair of long plate-like members that are arranged on both sides of the first diagonal 16 </ b> A in the east-west direction B and have the surface direction as the vertical direction. The end 21a is pin-bonded to the first diagonal member 16A, and the other end 21b is configured to be detachable from the second diagonal member 16B. In addition, a pair of plate-shaped member of the latching | locking part 21 may be integrated, and may be comprised so that it can move separately.
The other end 21b of the locking portion 21 is configured to be detachable at two locations of the second diagonal member 16B, and the locked portion 23 is locked at one of the two locations. It is sometimes fixed and temporarily fixed to the other when changing the inclination angle of the solar cell panel 2.
The locking part 21 and the second diagonal member 16B are fixed or temporarily fixed by inserting a pin (not shown) through holes formed in the locking part 21 and the second diagonal member 16B.

The locking portion 21 is formed with a fixing hole 26a in the vicinity of the other end 21b, and a temporary holding hole 26b is formed closer to the one end 21a than the fixing hole 26a.
Further, the second diagonal member 16B is formed with a fixing hole 27a at a height substantially equal to the height at which one end 21a of the locking portion 21 is pin-joined, and temporarily extends above the fixing hole 27a. A retaining hole 27b is formed.

Then, by aligning the positions of the fixing hole portion 26a of the locking portion 21 and the fixing hole portion 27a of the second diagonal member 16B and inserting the pins into both the hole portions 26a and 27a, the locking portion 21 is It is fixed to the two diagonal members 16B. At this time, the locking portion 21 extends in a substantially horizontal direction.
Further, the other end portion 21b of the locking portion 21 is moved upward so that the positions of the temporary fixing hole portion 26b of the locking portion 21 and the temporary fixing hole portion 27b of the second diagonal member 16B are aligned with each other. , 27b are inserted through pins (not shown), whereby the locking portion 21 is temporarily fixed to the second diagonal member 16B. At this time, the locking portion 21 is inclined so that the other end portion 21b is positioned above the one end portion 21a.

The locking part 21 has a substantially arcuate end 21c when the other end 21b is fixed to the second diagonal member 16B, and the locked part 23 is formed on the end 21c. A plurality of recesses 28 into which can be fitted are formed. The arc of the end portion 21c is an arc centered on the shaft portion 18 of the support portion 12, and overlaps with the locus of rotation of the locked portion 23 when the solar cell panel 2 rotates. .
In the present embodiment, six recesses 28 are formed at the end 21 c of the locking portion 21. These concave portions 28 will be described below as a first concave portion 28a to a sixth concave portion 28f from the first diagonal material 16A side toward the second diagonal material 16B side.

Then, when the other end 21b is fixed to the second diagonal member 16B in a state where the locked portion 23 is fitted to any one of the six recesses 28, the locking portion 21 is The rotation of the locked portion 23 can be restrained and the position of the locked portion 23 can be fixed. Thereby, the position of the solar cell panel 2 to which the locked portion 23 is fixed can be fixed.
At this time, the inclination angle of the solar cell panel 2 can be adjusted by adjusting the position of the recess 28 into which the locked portion 23 is fitted.
The six recesses 28 a to 28 f of the locking part 21 may be arranged at equal intervals, or may be arranged at desired positions according to the inclination angle of the solar cell panel 2.

Next, a method for changing the inclination angle of the solar cell panel 2 will be described.
Here, the solar cell panel 2 is changed from a state inclined by 10 ° with respect to the horizontal plane as shown in FIG. 1 to a state inclined by 55 ° with respect to the horizontal plane as shown in FIG.
The solar cell panel 2 before changing the inclination angle shown in FIG. 1 has the engaged portion 23 fitted in the first recess 28a, and the solar cell panel 2 after changing the inclination angle shown in FIG. The part 23 is fitted in the sixth recess 28f.

First, the pin inserted through the fixing hole 26a of the locking portion 21 and the fixing hole 27a of the second diagonal member 16B is removed, and the locking between the locking portion 21 and the second diagonal member 16B is released.
Subsequently, the locking portion 21 is rotated upward about the one end portion 21a, and the positions of the temporary fixing hole portion 26b of the locking portion 21 and the temporary fixing hole portion 27b of the second diagonal member 16B are aligned, A pin is inserted into the temporary retaining holes 26b and 27b, and the locking portion 21 is temporarily fixed to the second diagonal member 16B.
Thereby, since the to-be-latched part 23 leaves | separates from the recessed part 28a of the latching | locking part 21, and the latching of the to-be-latched part 23 is cancelled | released, the interposed member 22 and the solar cell panel 2 with the to-be-latched part 23 are It becomes possible to rotate around the shaft portion 18 of the support portion 12.

Subsequently, the solar cell panel 2 is rotated so as to be 55 ° with respect to the horizontal plane, and the posture is maintained.
At this time, it is preferable to change the inclination angle of the solar cell panel 2 by holding the locked portion 23. And the solar cell panel 2 can be easily rotated by setting the distance from the support part 12 to the to-be-latched part 23 longer than the distance from the support part 12 to the irradiation surface 2a of the solar cell panel 2. it can.

Subsequently, the pin is removed from the temporary holding hole 26b of the locking part 21 and the temporary holding hole 27b of the second diagonal member 16B, and the locking part 21 is rotated downward. And while engaging the to-be-latched part 23 in the 6th recessed part 28f of the latching | locking part 21, and the position of the fixing hole part 26a of the latching | locking part 21, and the position of the fixing hole part 27a of the 2nd diagonal material 16B, And the fixing portion 21 is fixed to the second diagonal member 16B by inserting a pin through the fixing holes 26a and 27a.
Thereby, the to-be-latched part 23 is fixed and the solar cell panel 2 is fixed in a state where it is inclined 55 ° with respect to the horizontal plane.
In addition, the solar cell panel 2 can be installed in a desired inclination angle by selecting the recessed part 28 with which the to-be-latched part 23 is fitted.

Next, the effect of the solar cell panel mount 3A and the solar cell device 1A described above will be described with reference to the drawings.
In the solar cell panel mount 3 </ b> A and the solar cell device 1 </ b> A according to the present embodiment, a desired recess 28 is selected from the six recesses 28 a to 28 f formed in the locking portion 21 installed in the leg 11, and the solar cell is selected. Since the solar cell panel 2 can be installed at a desired inclination angle by fitting the locked portion 23 fixed to the panel 2, the inclination angle of the solar cell panel 2 can be easily changed.

Moreover, since the angle holding | maintenance part 13 which changes the inclination angle of the solar cell panel 2 is a simple mechanism, manufacturing cost can be held down.
Furthermore, since the braces 19 and 19 are attached between the adjacent second diagonal members 16B and 16B, the strength and rigidity of the solar cell panel mount 3A can be ensured.
Thereby, the relative displacement of the 2nd diagonal materials 16B and 16B is prevented, and the relative displacement of the adjacent support parts 12 and 12 is prevented. And when rotating the solar cell panel 2, since the adjacent support parts 12 and 12 displace relatively, an external force does not act on the solar cell panel 2, so that the solar cell panel 2 is easily rotated. In addition, the solar cell panel 2 can be prevented from being twisted.

Next, other embodiments will be described with reference to the accompanying drawings, but the same or similar members and parts as those in the first embodiment described above are denoted by the same reference numerals, and description thereof is omitted. A different configuration will be described.
(Second Embodiment)
As shown in FIG. 5, in the solar cell device 1B according to the second embodiment, the legs 31 of the solar cell panel mount 3B have two bases 15, 15 and two diagonal members 16A according to the first embodiment shown in FIG. , 16B in place of the leg 11 provided as a support column standing at the installation place 10.
And the latching | locking part 33 of the angle holding | maintenance part 32 is formed with the six recessed parts 28 with which the to-be-latched part 23 can fit similarly to 1st Embodiment. The locking portion 33 is configured to be detachable from a locking portion support member 34 in which one end portion 33 a is pin-joined to the leg portion 31 and the other end portion 33 b is joined to the leg portion 31.

The locking portion support member 34 is formed in a rod shape, one end 34 a is pin-joined to the leg portion 31 above the locking portion 33, and the other end 34 b is the other end of the locking portion 33. 33b is configured to be detachable.
Here, as shown in FIG. 6, the locking portion 33 is formed with one hole 35 at the other end 33b. In addition, two holes 36a and 36b are formed in the locking portion support member 34 with an interval in the extending direction at the other end 34b. Of the two holes 36a, 36b of the locking part support member 34, the hole 36a on the other end 34b side is used as a fixing hole 36a, and the hole 36b on the one end 34a side is used as a temporary holding hole. This will be described below as 36b.

Then, the hole portion 35 of the locking portion 33 and the fixing hole portion 36a of the locking portion support member 34 are combined, and a pin (not shown) is inserted into both of the hole portions 35 and 36a, whereby the locking portion 33 is fixed to the locking portion support member 34.
In addition, by combining the hole 35 of the locking portion 33 and the temporary holding hole 36b of the locking portion support member 34, a pin (not shown) is inserted into both the holes 35 and 36b, whereby the locking portion 33 is temporarily fixed to the locking portion support member 34.

  In order to change the inclination angle of the solar cell panel 2 in the second embodiment, first, the pin inserted into the hole 35 of the locking part 33 and the fixing hole 36a of the locking part support member 34 is removed, The stop portion 33 and the locking portion support member 34 are rotated so that the positions of the hole portion 35 of the locking portion 33 and the temporary holding hole portion 35b of the locking portion support member 34 are aligned and the pin is inserted. Thereby, the latching | locking part 33 is temporarily fastened.

Subsequently, the solar cell panel 2 is rotated so as to have a predetermined inclination angle, and the posture is maintained.
And the temporary holding of the latching | locking part 33 and the latching | locking part support material 34 is cancelled | released, and the latching | locking part 33 and the latching part support material 34 are fixed. Thereby, as shown in FIG. 7, the solar cell panel 2 can be supported at a predetermined inclination angle.

  The solar cell device 1B and the solar cell panel mount 3B according to the second embodiment have the same effects as those of the first embodiment.

(Third embodiment)
Next, a solar cell device and a solar cell panel mount according to a third embodiment will be described.
As shown in FIG. 8, in the solar cell device 1 </ b> C according to the third embodiment, the solar cell panel mount 3 </ b> C includes the same leg portions 31 and locking portions 33 as those in the second embodiment.
In the solar cell device 1 </ b> C according to the third embodiment, the interposition member 42 of the angle holding portion 41 is installed only on one side of the leg portion 31, and one locked portion 43 is a plurality of solar cell panels. It is installed so as to be installed on the gantry 3C.
The solar cell device 1C according to the third embodiment is assumed to be smaller than the solar cell devices 1A and 1B according to the first embodiment and the second embodiment.

And as shown in FIG. 9, the brace (reinforcement member) 44 is installed between the adjacent interposed members 42. The brace 44 is composed of two parts that connect two places in the vicinity of the solar cell panel 2 of the interposition member 42 and the vicinity of the locked portion 43 of the interposition member 42 disposed adjacent thereto.
Thereby, since the interposed member 42, the to-be-latched part 43, and a pair of braces 44 and 44 can form a substantially triangular pyramid, and it can prevent relative displacement mutually, when rotating the solar cell panel 2, In addition, it is possible to prevent the external force from acting on the solar cell panel 2 due to the relative deformation of the interposed member 42.

  The solar cell device 1C and the solar cell panel mount 3C according to the third embodiment have the same effects as those of the first embodiment.

As mentioned above, although embodiment of solar cell apparatus 1A-1C and solar cell panel mount 3A-3C by this invention was described, this invention is not limited to said embodiment, In the range which does not deviate from the meaning, it is appropriate. It can be changed.
For example, in the above-described embodiment, the solar cell devices 1A to 1C are arranged in the east-west direction so that the solar cell panel 2 faces southward, but the direction in which the solar cell devices 1A to 1C are installed is arbitrary. May be set.
In the first embodiment described above, the pair of braces 19, 19 are installed between the adjacent second diagonal members 16B. However, the pair of braces 19, 19 are installed between the adjacent first diagonal members 16A. Alternatively, one brace 19 may be installed instead of a pair.
Moreover, in 1st Embodiment and 3rd Embodiment mentioned above, although the braces 19 and 44 are provided in solar cell apparatus 1A, 1C, when the intensity | strength of solar cell apparatus 1A, 1C can be ensured, brace 19, It is good also as a form in which 44 is not provided.
Moreover, in 2nd Embodiment mentioned above, it is good also as a form which provides a brace between the adjacent leg parts 31. FIG.

DESCRIPTION OF SYMBOLS 1A-1C Solar cell apparatus 2 Solar cell panel 3A-3C Solar cell panel mount 10 Installation place 11,31 Leg part 12 Support part 13,32,41 Angle holding part 19,44 Brace (reinforcement member)
21, 33 Locking part 22, 42 Interposition member 23, 43 Locked part 28, 28 a to 28 f Recessed part 34 Locking part support material

Claims (3)

A solar panel base that holds the solar panel at a predetermined inclination angle at the installation location,
A plurality of legs arranged at predetermined intervals from each other at the installation location;
A support portion that is installed on each of the plurality of legs and rotatably supports the solar cell panel;
An angle holding part that holds and holds the rotating solar cell panel at a predetermined inclination angle;
The angle holding part is fixed to the solar cell panel via a locking part installed on the leg part and a plurality of interposing members arranged at a predetermined interval from each other, and is fixed to the locking part at a predetermined position. It possesses a be-engaged portion to be engaged in,
Between the adjacent interposing members, a reinforcing member that connects and reinforces each other is provided,
The reinforcing member includes a brace provided between the adjacent interposing members, and the brace has one end fixed in the vicinity of the locking portion and the other end fixed in the vicinity of the solar cell panel. A solar panel mount characterized by being made . The locking portion is formed with a plurality of recesses that can be locked by fitting the locked portion along the track of the locked portion that rotates together with the solar cell panel. The solar cell panel mount according to claim 1 . A solar cell device, wherein a solar cell panel is fixed to the solar cell panel mount according to claim 1 .

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