JP4608521B2 - Roof with solar cells - Google Patents

Description

  The present invention relates to a solar cell roof provided with a flat solar cell panel and having a plurality of roof surfaces.

  2. Description of the Related Art Conventionally, roofs with solar cells that convert sunlight into electric power have been used with a plurality of solar cell panels that are roof coverings arranged vertically and horizontally on the roof surface. The solar cell panel is generally formed in a rectangular shape, and is fixed to a support member attached to the ground under the roof along the inclination direction of the roof surface (see Patent Document 1 and the like).

  As a form of the roof with solar cells, a roof conforming to a gable roof in which the solar cell panels can be easily arranged along the inclination direction of the roof surface is generally used. In such a gable roof, if a rectangular solar cell panel is arranged on the roof surface, the solar cell panel is arranged on the entire roof surface without a gap, and a sufficient light receiving area can be secured.

JP-A-9-32206

In the above-mentioned roof with a solar cell, since the declination of the sun is lowered in winter, there is a problem that the illuminance of the roof surface arranged on the north side is significantly smaller than the roof surface arranged on the south side.
In order to secure a sufficient amount of light received, a single-flow roof with a roof surface inclined in one direction is conceivable. There is a problem that the height dimension becomes large and it is difficult to fit the building within the height limit.

  An object of the present invention is to provide a roof with a solar cell in which the difference in illuminance between a pair of roof surfaces is reduced and the height of the building is not significantly increased even if the light receiving area is secured.

The roof with solar cells according to claim 1 is a roof with solar cells provided with a pair of roof surfaces adjacent to each other via a ridge provided with a flat solar cell panel, the pair of roofs adjacent to each other A solar cell panel is disposed on one of the roof surfaces, a dormer for obtaining lighting is provided on a part of the other roof surface, and the solar cell disposed on the one roof surface on the upper surface of the dormer A solar cell panel is disposed adjacent to the panel.
A covered solar cell according to claim 2, Te solar cells Covered odor claim 1, prior SL one roof surface is disposed toward the south, the other roof surface is toward the north It is arranged.
The roof with solar cell according to claim 3 is the roof with solar cell according to claim 1 or 2, wherein the roof surface formed on the upper surface of the dormer extends horizontally from the ridge. It is characterized by that.
The roof with solar cell according to claim 4 is the roof with solar cell according to any one of claims 1 to 3,
The roof surface of the dormer is formed in a rectangular flat shape, and an edge on the ridge side of the roof surface of the dormer is in contact with an edge on the ridge side of the one roof surface .
Here, when the related invention is described with reference to the drawings, the roof with solar cells provided with a plurality of roof surfaces 13 to 15, 32, 33, 42, 43 provided with the flat solar cell panel 20. 10, 30, 40, and among the plurality of roof surfaces 13-15, 32, 33, 42, 43, a pair of roof surfaces 14, 15, 32, 33, 42, 43 adjacent to each other has a slope. It is different from each other.
Such a related invention is such that one roof surface 33 extends obliquely upward with a boundary line 31 between the pair of roof surfaces 32 and 33 as a boundary, and the gradient of one roof surface 33 is greater than that of the other roof surface 32. The first roof 30 with a gentle slope and the boundary line 11 between the pair of roof surfaces 14 and 15 as a boundary, one roof surface 15 extends obliquely downward, and the one roof surface 15 is the other The second roof 10 having a gentler slope than the roof surface 14 of the second roof 10 and a third roof 40 in which one roof surface 43 extends horizontally with a boundary line 41 between the pair of roof surfaces 42 and 43 as a boundary. Etc.

Here, when one of the pair of roof surfaces 14, 15, 32, 33, 42, 43 is disposed on the north side and the other is disposed on the south side, in the above-described first roof 30, one and the other roof surfaces 32, 33 are disposed. Both of them face the south side, so it is possible to secure a sufficient amount of light received on one roof surface 33, and the difference in illuminance between the pair of roof surfaces 32 and 33 is reduced. The height of the building 1A can be reduced as compared with a single-flow roof having the same light receiving area.
Further, in the above-described second roof 10, even if one roof surface 15 is arranged on the north side, the slope of one roof surface 15 is made gentler than that of the other roof surface 14, so A sufficient light receiving area can be secured, the difference in illuminance between the pair of roof surfaces 14 and 15 is reduced, and the boundary line 11 between the pair of roof surfaces 14 and 15 becomes a ridge, and the gradient of one roof surface 15 is Is made gentler than the slope of the other roof surface 14, so if the light receiving area of one roof surface 15 arranged on the north side is larger than the other roof surface 14 arranged on the south side, it is arranged on the north side and the south side. The difference in the amount of light received between the pair of roof surfaces 14, 15 is reduced, the difference in illuminance between the pair of roof surfaces 14, 15 is reduced, and a sufficient light receiving area is secured without increasing the height of the building 1. Will come to be.
Furthermore, in the above-described third roof 40, since one roof surface 43 extends horizontally, it is possible to sufficiently secure the light receiving area of one roof surface 43, and the pair of roof surfaces 42, 43 In order to reduce the difference in illuminance and increase the light receiving area of the entire roof surface, by increasing the light receiving area of one roof surface 43, a sufficient light receiving area is ensured without increasing the height of building 1B. Will come to be.
From the above, the difference in illuminance between the pair of roof surfaces 14, 15, 32, 33, 42, and 43 is reduced, and the solar cell roofs 10, 30, and 40 are provided even if the light receiving area is sufficiently secured. Buildings 1, 1A, 1B are not significantly taller.

In the above, it is desirable that one of the pair of roof surfaces 32, 33 extends obliquely upward from the boundary line 31 with the other roof surface 32, and the gradient thereof is gentler than the other gradient.
In this way, both the one and the other roof surfaces 32, 33 face the same direction, so even if one roof surface 33 is arranged on the north side, a sufficient amount of light is received on one roof surface 33. The difference in illuminance between the pair of roof surfaces 32 and 33 is reduced, and the height of the building 1A is higher than that of a single-flow roof with the same light receiving area even if the light receiving area of the entire roof surface is sufficiently secured. Can be lowered.

Further, it is desirable that one of the pair of roof surfaces 14 and 15 extends obliquely downward from a boundary line 11 with the other roof surface 14 and the gradient thereof is gentler than the other gradient.
In this way, the boundary line 11 where the one and the other roof surfaces 14 and 15 intersect becomes a ridge extending horizontally, so that the light receiving area of one roof surface 15 is larger than that of the other roof surface 14. The difference in the amount of light received between the pair of roof surfaces arranged on the north side and the south side can be reduced, the difference in illuminance between the pair of roof surfaces 14 and 15 is reduced, and the height of the building 1 is increased. Therefore, a sufficient light receiving area can be secured.

Further, it is desirable that one of the pair of roof surfaces 42 and 43 extends horizontally from a boundary line 41 with the other roof surface 42.
In this way, since one roof surface 43 extends horizontally, even if one roof surface 43 is arranged on the north side, it is possible to sufficiently secure the amount of light received by one roof surface 43, The difference in illuminance between the pair of roof surfaces 42 and 43 can be reduced, and even if the light receiving area of one roof surface 43 is increased, the height of the building 1B is not increased, and the light receiving area of the entire roof surface is sufficiently secured. Will come to be.

Moreover, it is desirable that the pair of roof surfaces 32 and 33 have different length dimensions in the wife direction.
Here, it is possible to set the roof surface that has a large length in the wife direction and can secure a large amount of received light as the other roof surface 32 arranged on the south side, so a large amount of received light is secured on the entire roof surface. As a result, more annual electric energy can be obtained than other types of roofs having the same light receiving area on the entire roof surface.

Further, it is desirable that a dormer 80 for obtaining lighting is provided on the roof surface 15 having a gentle slope among the pair of roof surfaces 14 and 15.
If such a dormer is an elongated dormer 80 extending along the boundary line 11 between the pair of roof surfaces 14 and 15, the solar cell panel 20 cannot be installed on one roof surface 15 due to the provision of the dormer 80. Even if this occurs, the solar cell panel 20 can be installed on the roof surface 81 of the dormer 80. Therefore, the light receiving area is secured on the roof surface 81 of the dormer 80, and one roof surface 15 A sufficient light receiving area is secured.

The solar cell roof is preferably the roof 91 of the penthouse 90.
Here, a penthouse 90 used as an elevator room or a staircase is installed on the rooftop of a building 1F such as a high-rise building, and the roof on which the penthouse 90 is provided has a solar panel. Even if it is a land roof that can not be installed, it is possible to install the solar panel 20 on the roof surfaces 93, 94 of the penthouse 90, so the amount of light received is secured using the roof 91 of the penthouse 90, The rooftop can be used effectively.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
[First related embodiment]
FIG. 1 shows a building 1 according to a first related embodiment related to the present invention. This building 1 includes a plurality of building units 3 installed on a foundation 2 and a roof 10 formed on these building units 3.
The building 1 is a unit type building constructed by combining a plurality of building units 3 formed in a box shape.
The roof 10 is a dormitory roof having a large ridge 11 as a boundary line between the horizontally extending roof surfaces 14 and 15 and a down ridge 12 extending obliquely downward from an end of the large ridge 11.
The roof 10 has a wife-side roof surface 13 formed in a triangular shape, and a girder-side roof surfaces 14 and 15 formed in a trapezoidal shape.
On the wife side and girder side roof surfaces 13 to 15, solar cell panels 20 that are roof covering materials that convert solar energy into electric power are arranged. Thereby, the roof 10 is a roof with a solar cell.
The solar battery panel 20 is formed in a rectangular shape and has a plurality of solar cells. In addition, non-power generation parts 16 and 17 formed by spreading roof coverings made of sheet metal, tiles, or the like are provided in a portion of the wife side roof surface 13 where the solar cell panels 20 are not arranged. Non-power generation portions 18 and 19 formed by spreading roof coverings made of sheet metal, tiles, or the like are provided in portions of the girder-side roof surface 14 where the solar cell panels 20 are not arranged.

As shown in FIG. 2, the girder-side roof surfaces 14 and 15 are arranged adjacent to each other with the main ridge 11 serving as the boundary line of the roof surfaces 14 and 15 as the boundary, and the gradients of these roof surfaces 14 and 15 are mutually different. It is different.
The girder-side roof surface 14 is a roof surface disposed on the south side, and extends obliquely downward from the main building 11. The slope of the roof surface 14 is steep. A length dimension L1 in the wife direction of the roof surface 14 is smaller than a length dimension S1 of the roof surface 15 described later. Thereby, the girder-side roof surface 14 can secure a large amount of received light, and can secure a large amount of received light on the entire roof surfaces 13 to 15.
The girder-side roof surface 15 is a roof surface arranged on the north side, and extends obliquely downward from the main building 11.
The slope of the roof surface 15 is gentler than the slope of the roof surface 14. Thereby, even if the roof surface 15 is arranged on the north side, a sufficient amount of received light is ensured.
The length dimension S1 of the roof surface 15 is larger than the length dimension L1 of the roof surface 14 as described above.

According to this first related embodiment, the following effects are obtained.
That is, the main building 11 that becomes the boundary line between the girder-side roof surfaces 14 and 15 extends horizontally, and the slope of the girder-side roof surface 15 is made gentler than the gradient of the roof surface 14, so the roof surface 15 is arranged on the north side. However, the amount of light received on the roof surface 15 is sufficiently secured, the difference in illuminance between the roof surfaces 14 and 15 can be reduced, and the light receiving area on the roof surface 14 can be reduced even if sufficient light reception area is secured. By increasing the size and reducing the light receiving area of the roof surface 15, the amount of light received on the entire roof surface can be secured, and the light receiving area can be sufficiently secured without increasing the height of the building 1.

[Second related embodiment]
3 and 4 show a second related embodiment related to the present invention.
In the second related embodiment, the dormitory roof 10 in the first related embodiment is a gable roof 30.
That is, the building 1A having the gable roof 30 is a two-story building. On the south side of the second floor of the building 1A, a trapezoidal building unit 4 having a trapezoidal cross section is arranged.
The gable roof 30 has a pair of roof surfaces 32 and 33 arranged adjacent to each other with the ridge 31 as a boundary.
The roof surfaces 32 and 33 are formed by a plurality of roof panels (not shown). The roof panel forming the roof surface 32 is supported on the upper surface of the trapezoidal building unit 4.
The roof panel forming the roof surface 33 is supported by a bundle, a bracket, and the like installed on the upper surface of the building unit 3 arranged on the second floor portion.
On the roof surfaces 32 and 33, solar cell panels 20 that are roofing materials are arranged. Thereby, the roof 30 is a roof with a solar cell.
Further, the roof surfaces 32 and 33 have different slopes of the roof surfaces 32 and 33.
As shown in FIG. 4, the roof surface 32 is a roof surface disposed on the south side, and extends obliquely downward with the ridge 31 as a boundary. The slope of the roof surface 32 is steep.
A length dimension L2 of the roof surface 32 in the wife direction is larger than a length dimension S2 of the roof surface 33 described later.
The roof surface 33 is a roof surface disposed on the north side, and extends obliquely upward with the ridge 31 as a boundary. Thereby, the light receiving surface of the roof surface 33 faces the south side.
The slope of the roof surface 33 is gentler than the slope of the roof surface 32. The length dimension S2 of the roof surface 33 in the wife direction is smaller than the length dimension L2 of the roof surface 32.

Also according to the second related embodiment, the same effects as the first related embodiment can be obtained, and the following effects can be added.
That is, since both the roof surfaces 32 and 33 are directed to the south side, a sufficient amount of light is received on the roof surface 33, and the difference in illuminance between the roof surfaces 32 and 33 can be reduced. Even if the light receiving area of the entire surface is sufficiently secured, the height of the building 1 can be made lower than that of a single-flow roof having the same light receiving area.

  In addition, since the length dimension L2 of the roof surface 32 in the wife direction is larger than the length dimension S2 of the roof surface 33, the light receiving area of the south side roof surface 32 that can secure the largest amount of received light can be increased. As a result, a large amount of received light is secured on the entire roof surface, and a larger amount of annual power can be obtained than roofs of other types having the same light receiving area on the entire roof surface.

[Third related embodiment]
5 and 6 show a third related embodiment relating to the present invention.
In the third related embodiment, the roof surface 33 extending obliquely upward with the ridge 31 as a boundary in the second related embodiment is used as a roof surface 43 extending horizontally with a boundary line 41 as a boundary.
That is, the building 1B having the roof 40 is a three-story building. On the third floor portion of the building 1B, a building unit 3, a trapezoidal building unit 5 formed in a trapezoidal cross section, and a triangular building unit 6 formed in a triangular cross section are arranged.
The roof 40 is a deformation having an inclined roof surface 42 extending obliquely downward from a boundary line 41 extending in the horizontal direction, and a horizontal roof surface 43 provided adjacent to the inclined roof surface 42 and extending horizontally from the boundary line 41. It is a gable roof.
A roof panel (not shown) that forms the roof surface 42 is supported on the upper surfaces of the building unit 3 and the trapezoidal building unit 5.
The roof panel (not shown) that forms the roof surface 43 is supported by the upper surfaces of the trapezoidal building unit 5 and the triangular building unit 6.
On the roof surfaces 42 and 43, the solar cell panels 20 that are roofing materials are arranged. Thereby, the roof 40 is a roof with a solar cell.

The inclined roof surface 42 is a roof surface disposed on the south side. The slope of the inclined roof surface 42 is steep. A length dimension L3 in the wife direction of the inclined roof surface 42 is larger than a length dimension S3 of a horizontal roof surface 43 described later.
The horizontal roof surface 43 is a roof surface arranged on the north side. The length dimension S3 in the wife direction of the horizontal roof surface 43 is smaller than the length dimension L3 of the inclined roof surface 42 as described above.

According to the third related embodiment as described above, the same effects as the second related embodiment can be obtained, and the following effects can be added.
That is, since the horizontal roof surface 43 extends horizontally, even if the horizontal roof surface 43 is arranged on the north side, a sufficient amount of light can be secured on the horizontal roof surface 43, and the illuminance of the roof surfaces 42, 43 is increased. In addition to reducing the difference between the two, and increasing the light receiving area of the entire roof surface, even if the light receiving area of the horizontal roof surface 43 is increased, the height of the building 1B does not increase, and the light receiving area of the entire roof surface is sufficient. Can be secured.

[Fourth related embodiment]
7 and 8 show a fourth related embodiment related to the present invention.
In the fourth related embodiment, the gable roof 30 in the second related embodiment is changed to a deformed dormitory roof 50 having descending ridges 52A and 52B.
That is, as shown in FIG. 7, the modified dormitory roof 50 has a wife side roof surface 53 formed in a pentagon shape, a girder side roof surfaces 54 and 55 formed in a trapezoid shape, and a top portion of the roof 50. And a rectangular top roof surface 56 formed.
On the wife side roof surface 53 and the girder side roof surfaces 54 and 55, the triangular solar cell panels 21 are arranged along the descending ridges 52A and 52B, and the rectangular solar cell panel 20 is provided in the remaining portion. It is arranged. On the top roof surface 56, rectangular solar cell panels 20 are arranged. As a result, the roof 50 is a roof with solar cells.
In addition, non-power generation portions 57 and 58 formed by rolling roof coverings made of sheet metal, tiles, and the like are provided in blank portions of the wife side roof surface 53 where the solar cell panels 20 and 21 are not arranged.

As shown in FIG. 8, the girder-side roof surface 54 is a roof surface disposed on the south side, and extends obliquely downward from a boundary line 51 with the top-side roof surface 56. This girder-side roof surface 54 has a steep slope. A length dimension L4 of the girder side roof surface 54 in the wife direction is larger than the length dimension S4 of the top roof surface 56.
The top roof surface 56 is disposed adjacent to all four roof surfaces 53 to 55. The top roof surface 56 extends obliquely upward from a boundary line 51 with the girder roof surface 54. The slope of the top roof surface 56 is gentler than the slope of the girder roof surface 54.

Also in this fourth related embodiment, as in the second related embodiment, both the girder-side roof surface 54 and the top-side roof surface 56 face the south side, so that the light receiving amount of the roof surface 56 is reduced. The difference in illuminance between both roof surfaces 54 and 56 can be reduced, and even if the light receiving area of the entire roof surface is sufficiently secured, compared to a single-flow roof with the same light receiving area. The height of the building 1C can be lowered.

[Fifth related embodiment]
9 and 10 show a fifth related embodiment related to the present invention.
In the fifth related embodiment, the gable roof 40 in the third related embodiment is a deformed dormitory roof 60 provided with descending ridges 62A and 62B.
That is, as shown in FIG. 9, the modified dormitory roof 60 has a wife side roof surface 63 formed in a pentagon shape, a girder side roof surfaces 64 and 65 formed in a trapezoidal shape, and a top portion of the roof 60. And a rectangular top roof surface 66 formed.
On the wife side roof surface 63 and the girder side roof surfaces 64 and 65, triangular triangular solar cell panels 21 are arranged along the descending ridges 62A and 62B, and the rectangular solar cell panel 20 is formed in the remaining portion. It is arranged. On the top roof surface 66, rectangular solar cell panels 20 are arranged. As a result, the roof 60 is a roof with solar cells.
Note that a non-power generation part 67 formed by rolling a roofing material made of sheet metal, tiles, or the like is provided in a blank portion of the wife side roof surface 63 where the solar cell panels 20 and 21 are not arranged.

As shown in FIG. 10, the girder-side roof surface 64 is a roof surface disposed on the south side, and extends obliquely downward from a boundary line 61 with the top-side roof surface 66. This girder-side roof surface 64 has a steep slope. A length dimension L5 of the girder side roof surface 64 in the wife direction is larger than the length dimension S5 of the top roof surface 66.
The top roof surface 66 is disposed adjacent to all four roof surfaces 63 to 65. The top roof surface 66 extends horizontally from a boundary line 61 with the girder roof surface 64.

Also in the fifth related embodiment, the top roof surface 66 extends in the horizontal direction as in the third related embodiment, so that the light receiving amount of the top roof surface 66 can be sufficiently secured. The difference in illuminance between the roof surfaces 64 and 66 can be reduced, and the height of the building 1D can be increased even if the light receiving area of the top roof surface 66 is increased in order to increase the light receiving area of the entire roof surface. The light receiving area of the entire roof surface can be sufficiently secured without being raised.

[Implementation form]
11 and 12 have been shown implementation of the invention.
The present implementation mode, the hipped roof 10 in the first related embodiment, is obtained by a hipped roof 70 provided with a dormer 80.
That is, a dormer 80 is provided on the girder-side roof surface 15 of the dormitory roof 70. The dormer 80 is provided in order to obtain daylight in the back of the hut formed in the building 1E. The dormer 80 is elongated and extends along the ridge 11.
A rectangular solar cell panel 20 is arranged on the roof surface 81 of the dormer 80. The roof surface 81 extends horizontally from the ridge 11.
In addition, the remaining part of the eaves side where the dormer 80 of the girder-side roof surface 15 is provided is not shaded by the remaining part of the eaves side of the roof surface 15 in the shade of the dormer 80. It has become.

By such a present implementation mode, in addition to the first related embodiment the same operation and effect can be obtained, it can be added the following advantages.
That is, since the solar cell panel 20 is installed on the roof surface 81 of the elongated dormer 80, even if a portion where the solar cell panel 20 cannot be installed on the beam side roof surface 15 due to the provision of the dormer 80, the roof of the dormer 80 is provided. A light receiving surface can be secured on the surface 81, and a sufficient light receiving area can be secured on the girder-side roof surface 15.
In addition, since the solar cell panel 20 is not installed on the eaves side portion of the roof surface 15, the eaves side portion is shaded by the dormer 80, and the amount of light received by the eaves side portion cannot be sufficiently obtained. It does not occur and the expensive solar cell panel 20 is not wasted.
Thereby, wasteful cost can be eliminated by not installing the expensive solar cell panel 20 at the eaves portion of the roof surface 15.

[ Sixth related embodiment]
FIG. 13 shows a sixth related embodiment relating to the present invention.
In the sixth related embodiment, the dormitory roof 10 in the first related embodiment is the roof 91 of the penthouse 90.
That is, the roof 7 of the building 1F is a walkable land roof. The flat roof 7 is formed by arranging flat roof units 8 on the upper surface of the building unit 3 on the uppermost floor constituting the building 1F.
The flat roof 7 is provided with a penthouse 90 serving as an elevator room and a staircase for entering and exiting the flat roof 7. The roof 91 of the penthouse 90 includes a roof surface 93 that extends obliquely downward from the boundary line 92 and a roof surface 94 that extends horizontally from the boundary line 92. The rectangular solar cell panels 20 are arranged on these roof surfaces 93 and 94.

According to the sixth related embodiment, in addition to the same operation and effect as the first related embodiment, the following effects can be added.
That is, since the solar panel 20 is installed on the roof surfaces 93 and 94 of the penthouse 90 used as an elevator room or a staircase to enter and exit the flat roof 7, the solar panel is installed on the roof provided by the penthouse 90. Even if it is a non-walkable land roof 7 that can not be walked, the roof 91 of the penthouse 90 can be used to secure the amount of received light and the rooftop can be used effectively.

In addition, this invention is not limited to the said embodiment, It contains the other structure etc. which can achieve the objective of this invention, and the deformation | transformation etc. which are shown below.
That is, the roof with solar cells is not limited to the roof 91 of the penthouse 90 provided on the roof 7 of the small building 1F such as a house, but is the roof of a penthouse provided on the roof of a large building such as a high-rise building. May be.

Moreover, as a form of the roof which has a roof surface extended diagonally downward from the boundary line of a pair of roof surface, it is not only a dormitory roof but a gable roof may be sufficient.
Furthermore, the form of the roof having the top roof surface 56 extending obliquely upward from the boundary line between the pair of roof surfaces is not limited to the deformed ridge roof 50, and may be a deformed gable roof.
The form of the roof having the top roof surface 66 extending horizontally from the boundary line between the pair of roof surfaces is not limited to the deformed dormitory roof 60 and may be a deformed gable roof.
The form of the roof having the dormer 80 is not limited to the dormitory roof 10 but may be a gable roof.
Furthermore, before you facilities embodiment, when it is desired to increase but not installed solar panels 20 to the rest of the eaves side dormer 80 is provided in the roof 15, the power generation amount even a little, the eaves The solar cell panel 20 may be installed in the remaining part on the side.

According to the solar cell roof of the present invention, the following effects can be obtained.
That is, according to the solar cell roof according to the related invention, when one of the pair of roof surfaces is arranged on the north side and the other is on the south side, in the first roof described above, both the one and the other roof surfaces are Because it faces the south side, it is possible to secure a sufficient amount of light received on one roof surface, and the difference in illuminance between the pair of roof surfaces is small. The height of the building can be reduced compared to the type roof.
In the above-mentioned second roof, even if one roof surface is arranged on the north side, the slope of one roof surface is made gentler than that of the other roof surface, so that the light receiving area of one roof surface is sufficient. The difference in illuminance between the pair of roof surfaces becomes smaller, and the boundary line between the pair of roof surfaces becomes the ridge 11, and the gradient of one roof surface is made gentler than the gradient of the other roof surface. Therefore, if the light receiving area of one roof surface arranged on the north side is made larger than the other roof surface arranged on the south side, the difference in the amount of light received between the pair of roof surfaces arranged on the north side and the south side becomes small. The difference in illuminance between the pair of roof surfaces is reduced, and a sufficient light receiving area can be secured without increasing the height of the building.
Furthermore, in the above-mentioned third roof, since one roof surface extends horizontally, it becomes possible to sufficiently secure the light receiving area of one roof surface, and the difference in illuminance between the pair of roof surfaces becomes small. Moreover, in order to increase the light receiving area of the entire roof surface, by increasing the light receiving area of one roof surface, it is possible to sufficiently secure the light receiving area without increasing the height of the building.
From the above, the difference in illuminance between the pair of roof surfaces is reduced, and even if a sufficient light receiving area is secured, the height of the building provided with the solar cell roof is not significantly increased.

  In addition, according to the solar cell roof according to the related invention, since the roof surface of one and the other faces in the same direction, even if one roof surface is arranged on the north side, the amount of light received by one roof surface is reduced. The difference in illuminance between the pair of roof surfaces can be reduced, and even if the light receiving area of the entire roof surface is sufficiently secured, the height of the building is higher than that of a single-flow roof with the same light receiving area. Can be lowered.

  Furthermore, according to the solar cell roof according to the related invention, since the boundary line where one and the other roof surfaces intersect with each other is a ridge extending horizontally, the light receiving area of one roof surface is larger than that of the other roof surface. By doing so, it becomes possible to reduce the difference in the amount of light received between the pair of roof surfaces arranged on the north side and the south side, and the difference in illuminance between the pair of roof surfaces is reduced, and the height of the building is not increased. A sufficient light receiving area can be secured.

  Further, according to the roof with solar cells according to the related invention, since one roof surface extends horizontally, even if one roof surface is arranged on the north side, a sufficient amount of light is received on one roof surface. The difference in illuminance between a pair of roof surfaces can be reduced, and even if the light receiving area of one roof surface is increased, the height of the building is not increased, and the light receiving area of the entire roof surface is sufficiently increased. It can be secured.

  Furthermore, according to the roof with solar cells according to the related invention, it is possible to set the roof surface that has a large length in the wife direction and can secure a large amount of received light as the other roof surface 14 disposed on the south side. Therefore, it becomes possible to secure a large amount of received light on the entire roof surface, and it is possible to obtain a larger amount of annual electric power than roofs of other types having the same light receiving area on the entire roof surface.

Further, according to the solar roof with cell according to the present matter onset bright, even if such a dough Ma impossible installed solar panels on one of the roof by the provided portion, a solar cell on the roof surface of the dormer Since a panel can be installed, a light receiving area can be secured even on the roof surface of the dormer, and a sufficient light receiving area can be secured on one roof surface.

  Furthermore, according to the roof with solar cells according to the related invention, a penthouse used as an elevator room or a staircase is installed on the rooftop of the building to enter and exit the rooftop, and the penthouse is provided on the roof. However, even if it is a walkable flat roof where solar panels cannot be installed, it is possible to install solar panels on the roof surface of the penthouse, so the amount of light received is secured using the roof of the penthouse, and the rooftop Effective use.

  The present invention can be used for a roof with a solar cell having a roof surface.

It is a perspective view which shows the building which concerns on 1st related embodiment of this invention. It is a side view which shows the roof which concerns on the same embodiment. It is a perspective view which shows the building which concerns on 2nd related embodiment of this invention. It is a side view which shows the roof which concerns on the same embodiment. It is a perspective view which shows the building which concerns on 3rd related embodiment of this invention. It is a side view which shows the roof which concerns on the same embodiment. It is a perspective view which shows the building which concerns on 4th related embodiment of this invention. It is a side view which shows the roof which concerns on the same embodiment. It is a perspective view which shows the building which concerns on 5th related embodiment of this invention. It is a side view which shows the roof which concerns on the same embodiment. The building according to implementation embodiments of the present invention is a perspective view showing. It is a side view which shows the roof which concerns on the same embodiment. It is a perspective view which shows the building which concerns on 6th related embodiment of this invention.

Explanation of symbols

10, 30, 40 Roof with solar cells
11, 31, 41 border
13-15, 32, 33, 42, 43 Roof surface
14, 15, 32, 33, 42, 43 A pair of roof surfaces
14, 32, 43 The other roof
15, 33, 43 One roof
20 Solar panel
80 Dormer
90 Penthouse
91 roof

Claims (4)

A solar cell roof provided with a pair of roof surfaces adjacent to each other through a ridge provided with a flat solar cell panel,
A solar cell panel is disposed on one roof surface of the pair of adjacent roof surfaces, and a dormer for obtaining lighting is provided on a part of the other roof surface, and the one roof is provided on an upper surface of the dormer. A solar cell roof, wherein a solar cell panel is disposed adjacent to a solar cell panel disposed on a surface. In the roof with a solar cell according to claim 1,
The one roof surface is disposed toward the south side, and the other roof surface is disposed toward the north side. In the roof with a solar cell according to claim 1 or 2,
The roof with solar cells, wherein the roof surface formed on the upper surface of the dormer extends horizontally from the ridge. In the roof with a solar cell according to any one of claims 1 to 3,
The roof surface of the dormer is formed in a rectangular planar shape, and the edge on the ridge side of the roof surface of the dormer is in contact with the edge on the ridge side of the one roof surface . roof.

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