JP2001207605A - Solar battery modules and setting structure therefor - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide solar battery modules in which required kinds of shapes of the solar battery modules can be reduced, when the solar battery modules are bedded on a hipped-roof even to a corner ridge thereof, and to provide a setting structure thereof. SOLUTION: The solar battery modules are arranged on roof surfaces 51 of the hipped roof 50, in which the corner ridge 52 thereof forms 45 degrees with respect to a ridge direction X and a span direction Y when projected on a horizontal plane P. Out of the solar battery modules, a solar battery module 1, when arranged on the roof surface 51 and projected on the horizontal plane P, is formed like such a right triangle that its hypotenuse 10 is arranged almost along the corner ridge 52, that one side other than the hypotenuse 10 is in parallel with the ridge direction X, and that the other side other than the hypotenuse 10 is in parallel with the span direction Y.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a solar cell module installed on a roof of a ridge and a structure for installing the same.

[0002]

2. Description of the Related Art There is a case where a solar cell module is laid all over a corner building to cover a corner building for the purpose of increasing the power generation capacity or preventing the aesthetic appearance of the roof from being impaired. In this case, together with the rectangular solar cell module, a triangular solar cell module installed along the corner building is required. Here, the dimensions of the rectangular solar cell module are generally determined by standards that are not related to the roof shape. When the dimensions of the triangular solar cell module to be installed along the corner building are determined in accordance with such a rectangular solar cell module, the solar cell module required to spread the solar cell module over the entire roof of the wing is determined. There has been a problem that the shapes are various.

As an example of determining the size of a solar cell module in consideration of the roof shape, there is a technique disclosed in Japanese Patent Application Laid-Open No. 10-183915. This is such that when the solar cell module is installed on a sloped roof surface, the shape projected on the horizontal plane is substantially square. However, the above-mentioned prior art does not refer to a triangular solar cell module installed at a portion along a corner ridge of a wing roof. Therefore, the above-mentioned prior art does not show a solution to the above-mentioned problem that occurs when the solar cell modules are laid on the wing roof to the corner ridge.

[0004] Therefore, when the solar cell modules are laid all over the ridge roof to the corner ridge and installed, the shape of the triangular solar cell module installed along the corner ridge is changed to the shape of the ridge roof or another rectangular shape. It is conceivable to reduce the number of required types of solar cell modules by making them correspond to the shapes of the solar cell modules described above.

[0005]

SUMMARY OF THE INVENTION The present invention has been made in view of the above circumstances, and is required when a solar cell module is installed on a roof of a building by laying down to a corner building. It is an object of the present invention to provide a solar cell module and its installation structure that can reduce the number of types.

[0006]

Means for Solving the Problems To solve the above problems, a solar cell module 1 according to claim 1 (for example, FIG. 1)
The solar cell module disposed on the roof surface 51 of the ridge roof 50 in which the corner ridge 52 forms an angle of 45 degrees when projected on the horizontal plane P with respect to the girder direction X and the inter-beam direction Y. In a state where the solar cell module 1 is arranged on the roof surface 51 and projected on a horizontal plane P,
The hypotenuse 10 is formed in a right-angled triangle such that the hypotenuse 10 substantially extends along the corner ridge 52, one side other than the hypotenuse 10 is parallel to the girder direction X, and the other side other than the hypotenuse 10 is parallel to the inter-beam direction Y. It is characterized by being.

The solar cell module 1 according to claim 1
Are arranged on the roof surface 51 having a predetermined slope. When the slope of the roof surface 51 is set to a / 10, as described in claim 2, the shortest side 11 of the right triangle is It is assumed that the length W and the length H of the side 12 perpendicular to the shortest side are set in a relationship of H = W × √ (100 + a ² ) / 10.

According to the solar cell module 1 of the first or second aspect, the corner ridge 52 forms an angle of 45 degrees with the row direction X and the inter-beam direction Y when projected on the horizontal plane P. When laying the solar cell modules on the roof surface 51 of the roof 50 up to the corner ridge 52, the solar cell modules 1 are placed on the roof surface 51 and projected on a horizontal plane P while 10 is the corner building 5
2 and one side other than the hypotenuse 10 is in the column direction X.
And the other side other than the hypotenuse 10 is formed in a right-angled triangle such that it is parallel to the inter-beam direction Y.
Solar cell modules arranged side by side along the corner building 52,
The solar cell module 1 according to claim 1 or 2 can be unified. Therefore, there is no need to prepare various types of solar cell modules, and the manufacture of the solar cell module can be simplified.

According to a third aspect of the present invention, in the solar cell module 2 (see FIG. 1 for example), the corner ridge 52 forms an angle of 45 degrees with the girder direction X and the inter-beam direction Y when projected on the horizontal plane P. A solar cell module disposed on a roof surface 51 of a ridge roof 50, wherein the solar cell module 2 is
The rectangular shape is formed such that one side is parallel to the girder direction X and the other side is parallel to the inter-beam direction Y while being arranged on the roof surface 51 and projected on the horizontal plane P. The length of the side 21 and the length of the long side 22 are respectively equal to the length of the shortest side 11 of the right triangle forming the solar cell module 1 according to claim 1 or 2, and the length of the side 12 perpendicular to the shortest side. Is set as follows.

The solar cell module 1 according to claim 3
Is arranged on the roof surface 51 having a predetermined slope. When the slope of the roof surface 51 is set to a / 10, the length of the short side 21 of the rectangular shape is set as described in claim 4. It is assumed that the length W and the length H of the long side 22 are set to have a relationship of H = W × √ (100 + a ² ) / 10.

According to the solar cell module 2 of the third or fourth aspect, the corner ridge 52 forms an angle of 45 degrees when projected onto the horizontal plane P with respect to the row direction X and the inter-beam direction Y. When the solar cell modules are laid on the roof surface 51 of the roof 50 up to the corner ridge 52 and installed, the solar cell modules 2 are arranged on the roof surface 51 and projected on a horizontal plane P. Is formed in a rectangular shape such that is parallel to the row direction X and the other side is parallel to the inter-beam direction Y, and the lengths of the short side 21 and the long side 22 of the rectangle are respectively defined in claim 1 or 2. Since the length of the shortest side 11 of the right-angled triangle constituting the solar cell module 1 is set to be equal to the length of the side 12 perpendicular to the shortest side, the right-angled triangle is juxtaposed along the corner ridge 52. Item 1 or 2 each sun Pond module 1, ... next to the, the solar cell module arranged in the girder direction X or Harima direction Y,
The solar cell module 2 according to the third or fourth aspect can be unified. Therefore, there is no need to prepare various types of solar cell modules, and the manufacture of the solar cell module can be simplified.

In the solar cell module installation structure according to the fifth aspect (see, for example, FIG. 3), the corner ridge 52 forms an angle of 45 degrees with the girder direction X and the inter-beam direction Y when projected on the horizontal plane P. In addition, the solar cell modules 1,... According to claim 2 are provided on the roof surface 51 of the ridge roof 50, the roof surface 51 of which has a gradient of a / 10.
3. A plurality of oblique sides 10 are arranged side by side substantially along the corner building 52, and are arranged side by side along the corner building 52.
The solar cell modules 2,... According to claim 4 are arranged side by side next to the respective solar cell modules 1,.

According to the installation structure of the solar cell module according to the fifth aspect, the corner ridge 52 forms an angle of 45 degrees with the girder direction X and the inter-beam direction Y when projected on the horizontal plane P, Two types of the solar cell modules 1,..., And the solar cell modules 2,..., According to claim 2, on the roof surface 51 of the ridge roof 50 having a roof surface 51 having a gradient of a / 10. With only the solar cell module of the above, the solar cell module can be spread and installed up to the corner building 52. In other words, the corner ridge 5 is placed on the roof surface 51 of the ridge roof 50 at an angle of 45 degrees when projected on the horizontal plane P with respect to the girder direction X and the inter-beam direction Y.
The solar cell module according to claim 2 and the solar cell module according to claim 4, wherein the solar cell modules required when the solar cell modules are spread and installed up to 2 are provided for each type of the slope a / 10 of the roof surface 51. The solar cell module 2 and the two types of solar cell modules can be unified. Therefore, there is no need to prepare various types of solar cell modules, and the manufacture of the solar cell module can be simplified.

[0014]

DESCRIPTION OF THE PREFERRED EMBODIMENTS Embodiments of the solar cell module and the installation structure thereof according to the present invention will be specifically described below with reference to the drawings. FIG. 1 is a perspective view showing an example of the solar cell module of the present invention and an installation structure thereof, and FIGS. 2 and 3 are plan views showing an example of the solar cell module of the present invention.

First, as shown in FIG. 1, the installation structure of the solar cell module according to the present embodiment has a structure in which the corner ridge 52 is projected at a 45-degree angle with respect to the girder direction X and the inter-beam direction Y in a state of being projected on a horizontal plane P. While making an angle, the roof surface 51 is a / 10 = 4
The solar cell modules 1 are arranged on the roof surface 51 of the ridge roof 50 having a slope of / 10.
A plurality of oblique sides 10 are arranged substantially along the corner building 52, and the solar cell modules 2, 2 arranged side by side along the corner building 52
, Are arranged side by side in order and configured roughly.

Each of the solar cell modules 1 and 2 has a predetermined output by connecting a plurality of single-crystal silicon solar cells 31,..., 32,. In addition, it is sealed in a flat case made of glass or the like for environmental resistance.

As shown in FIGS. 1 and 2, the solar cell module 1 is disposed on the roof surface 51 and has a horizontal plane P.
When the oblique side 10 is substantially along the corner ridge 52, one side other than the oblique side 10 is parallel to the girder direction X, and the other side other than the oblique side 10 is parallel to the inter-beam direction Y in the state where , And is formed in a right-angled triangle.

Here, the building provided with the ridge roof 50 is constructed with a reference size of 910 mm, and the length W of the shortest side 11 of the right triangle is set to be the same as this reference size. The length H of the side 12 perpendicular to the shortest side 11 is set to H = W × √ (100 + a ² ) / 10, that is, 980 mm.

Further, the solar cell module 2 is shown in FIG.
As shown in FIG. 3 and a rectangle arranged on the roof surface 51 and projected on a horizontal plane P, one side is parallel to the girder direction X and the other side is parallel to the inter-beam direction Y. The length of the short side 21 and the length of the long side 22 of the rectangle are respectively the length of the shortest side 11 of the right triangle forming the solar cell module 1 according to claim 1 or 2 and the right angle with the shortest side. It is set and configured to be equal to the length of the side 12.

The length W of the rectangular short side 21 is set to 910 mm, which is a standard dimension of a building provided with the roof 50. The length H of the long side 22 of the rectangle
Is H = W × Ｗ (100 + a ² ) / 10 That is, it is set to 980 mm.

As described above, according to the solar cell module 1 of the present embodiment, the ridge roof in which the corner ridge 52 forms an angle of 45 degrees with the row direction X and the inter-beam direction Y when projected on the horizontal plane P. When the solar cell modules are spread and installed on the roof surface 51 of the floor 50 to the corner ridge 52, the solar cell modules 1 are placed on the roof surface 51 and projected on the horizontal plane P while the hypotenuse 10 Are formed in a right-angled triangle substantially along the corner ridge 52, one side other than the hypotenuse 10 is parallel to the girder direction X, and the other side other than the hypotenuse 10 is parallel to the inter-beam direction Y. The solar cell modules arranged side by side along the corner building 52 can be unified into the solar cell module 1. Therefore, there is no need to prepare various types of solar cell modules, and the manufacture of the solar cell module can be simplified.

Further, according to the solar cell module 2 of the present embodiment, the ridge roof in which the corner ridge 52 forms an angle of 45 degrees when projected on the horizontal plane P with respect to the row direction X and the inter-beam direction Y. When the solar cell modules 2 are laid down on the roof surface 51 of the floor 50 to the corner ridge 52 and installed, the solar cell modules 2 are arranged on the roof surface 51 and projected on a horizontal plane P, and one side thereof is The rectangular shape is formed such that it is parallel to the row direction X and the other side is parallel to the inter-beam direction Y, and the lengths of the short side 21 and the long side 22 of the rectangle constitute the solar cell module 1. Since the length of the shortest side 11 of the right triangle and the length of the side 12 perpendicular to the shortest side are set to be equal to each other, the side of each of the solar cell modules 1,... , Column direction X or between beams The solar cell module arranged in direction Y, it is possible to unify the solar cell module 2. Therefore, there is no need to prepare various types of solar cell modules, and the manufacture of the solar cell module can be simplified.

Further, according to the installation structure of the solar cell module of the present embodiment, the corner ridge 52 forms an angle of 45 degrees with the girder direction X and the inter-beam direction Y when projected on the horizontal plane P. , And only two types of solar cell modules, ie, solar cell modules 1,... And solar cell modules 2, are provided on the roof surface 51 of the ridge roof 50 whose roof surface 51 has a gradient of a / 10 = 4/10. Thus, the solar cell modules can be spread and installed up to the corner building 52. That is, the corner ridge 52 is moved in the girder direction X and the beam direction Y,
When the solar cell module is spread and installed on the roof surface 51 of the ridge roof 50 forming an angle of 45 degrees in a state projected on the horizontal plane P to the corner ridge 52, the solar cell module required Modules 1 and 2 can be unified into two types of solar cell modules. Therefore, there is no need to prepare various types of solar cell modules, and the manufacture of the solar cell module can be simplified.

The present invention is not limited to the above-described embodiment, but may be made within the scope of the present invention.
Various improvements and design changes may be made. For example,
In the installation structure of the solar cell module according to the above embodiment, the solar cell modules 1,... And the solar cell modules 2 are arranged on the roof surface 51 of the ridge roof 50 having a roof surface 51 having a slope of 4/10. However, the installation structure of the solar cell module of the present invention is not limited to this, and the roof surface has a gradient a / 10 other than 4/10 (for example, 3/10).
The solar cell module according to claim 2 and the solar cell module according to claim 4 are juxtaposed on the roof surface of a ridge roof having (/ 10/10, 3.5 / 10, 4.5 / 10, 5/10). It may be done. Also in this case, when the solar cell modules are laid on the roof surface of the wing roof to the corner building and installed, the required solar cell modules are charged for each type of the slope a / 10 of the roof surface. The solar cell module according to the second aspect and the solar cell module according to the fourth aspect can be unified into two types of solar cell modules. Further, the length W of the shortest side 11 of the solar cell module 1 and the short side 21 of the solar cell module 2 of the above embodiment
Is the reference dimension of the building with the roof 50
Although it is set to 10 mm, the present invention is not limited to this, and may be appropriately set to any size other than the reference size of the building according to the size of the eaves of the roof. Further, the solar cell modules 1 and 2 of the above-described embodiment have single-crystal silicon solar cells 31 and 32 mounted thereon.
Instead of this, a device equipped with a polycrystalline silicon solar cell, an amorphous silicon solar cell, or the like may be used. In addition, it is needless to say that specific detailed structures can be appropriately changed.

[0025]

According to the solar cell module according to the first or second aspect, the corner ridge forms an angle of 45 degrees with respect to the girder direction and the inter-beam direction when projected on a horizontal plane, When the solar cell modules are spread and installed up to the corner building, the solar cell modules are arranged on the roof surface and projected on a horizontal plane, with the hypotenuse substantially along the corner building and one side other than the hypotenuse. Are formed in a right-angled triangle such that is parallel to the row direction and one side other than the hypotenuse is parallel to the inter-beam direction, so that the solar cell modules arranged side by side along the corner building are arranged in parallel. Or, it can be unified to the solar cell module described in 2. Therefore, there is no need to prepare various types of solar cell modules, and the manufacture of the solar cell module can be simplified.

According to the solar cell module of the third or fourth aspect, the corner ridge forms an angle of 45 degrees with respect to the girder direction and the inter-beam direction when projected on a horizontal plane. When the photovoltaic modules are spread and installed up to the ridge, the photovoltaic modules are arranged on the roof surface and projected on a horizontal plane, with one side parallel to the girder direction and the other side parallel to the inter-beam direction. Are formed in a rectangle, and the length of the short side and the length of the long side of the rectangle are respectively the length of the shortest side and the shortest side of the right triangle forming the solar cell module according to claim 1 or 2. 3. The solar cell module according to claim 1 or 2, which is arranged along the corner building in a row direction or a beam-to-beam direction, since the length is set to be equal to the length of the right-angled side. Solar cell module It can be unified to claim 3 or 4 solar cell module according. Therefore, there is no need to prepare various types of solar cell modules, and the manufacture of the solar cell module can be simplified.

According to the installation structure of the solar cell module according to the fifth aspect, the corner ridges are arranged in the row direction and the inter-beam direction.
The solar cell module according to claim 2 and the solar cell module according to claim 4, wherein the solar cell module according to claim 2 is formed on a roof surface of a ridge roof having an angle of 45 degrees when projected on the horizontal plane P and having a roof surface having a gradient of a / 10. With only two types of solar cell modules, ie, a solar cell module, the solar cell modules can be spread and installed to the corner building. That is, when the corner ridge is installed on the roof surface of the ridge roof forming an angle of 45 degrees in a state projected on a horizontal plane with respect to the girder direction and the inter-beam direction, the solar cell modules are spread to the corner ridge and installed. The solar cell module according to claim 2, wherein required solar cell modules are provided for each type of the slope a / 10 of the roof surface.
The two types of solar cell modules can be unified with the described solar cell module. Therefore, there is no need to prepare various types of solar cell modules, and the manufacture of the solar cell module can be simplified.

[Brief description of the drawings]

FIG. 1 is a perspective view showing an example of a solar cell module of the present invention and an installation structure thereof.

FIG. 2 is a plan view showing an example of the solar cell module of the present invention.

FIG. 3 is a plan view showing another example of the solar cell module of the present invention.

[Explanation of symbols]

 1, 2 solar cell module 10 oblique side 11 shortest side 12 side perpendicular to shortest side 21 short side 22 long side 50 building roof 51 roof surface 52 corner building P horizontal plane X girder direction XY beam direction Y

Continued on the front page (72) Inventor Naoko Oya 2-4-5 Takaido Higashi, Suginami-ku, Tokyo Misawa Home Co., Ltd. F-term (reference) 2E108 AA02 AS01 GG16 KK04 LL01 MM00 NN07 5F051 BA03 EA01 JA02 JA09

Claims (5)

[Claims] 1. A solar cell module disposed on a roof surface of a ridge roof, wherein a corner ridge forms an angle of 45 degrees when projected on a horizontal plane with respect to a girder direction and an inter-beam direction, The solar cell module is arranged on the roof surface and projected on a horizontal plane, with the hypotenuse substantially along the corner building, one side other than the hypotenuse becomes parallel to the girder direction, and the other side other than the hypotenuse is A solar cell module formed in a right-angled triangle so as to be parallel to a direction between beams. 2. The solar cell module according to claim 1, wherein the slope of the roof surface is set to a / 10, and the length W of the shortest side of the right triangle and the length of the side perpendicular to the shortest side. A solar cell module, wherein H is set to satisfy the following relationship: H = W × √ (100 + a ² ) / 10. 3. A solar cell module disposed on a roof surface of a ridge roof, wherein the corner ridge forms an angle of 45 degrees when projected on a horizontal plane with respect to a girder direction and an inter-beam direction, The solar cell module is arranged on the roof surface and projected on a horizontal plane, and one side is parallel to the girder direction and the other side is parallel to the inter-beam direction. The length of the short side and the length of the long side are respectively set to be equal to the length of the shortest side of the right triangle forming the solar cell module according to claim 1 or the length of the side perpendicular to the shortest side. A solar cell module comprising: 4. The solar cell module according to claim 3, wherein the slope of the roof surface is set to a / 10, and the length W of the short side and the length H of the long side of the rectangle are H = A solar cell module characterized by being set in a relation of W × √ (100 + a ² ) / 10. 5. The corner ridge forms an angle of 45 degrees with respect to the girder direction and the inter-beam direction when projected on a horizontal plane, and the roof surface has a slope of a / 10 on the roof surface of the ridge roof. 3. The solar cell module according to claim 2, wherein a plurality of the solar cell modules according to claim 2 are arranged side by side with the oblique sides of the solar cell modules substantially along the corner building, and the solar cell modules according to claim 2 arranged along the corner building. A solar cell module installation structure, wherein the solar cell modules according to claim 4 are arranged side by side next to the module.