JP2006037643A - Installation structure of solar battery module - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To install a solar battery module with a roof material on a roof with good appearance, to manufacture the solar battery module at low cost and easily, and to facilitate installation of the solar battery module. <P>SOLUTION: In this solar battery module installation structure, a module installation area for installing the solar battery module is provided between a pair of ridge lines positioned on both sides in the lateral direction of the roof, and the module installation area is loaded with a plurality of rectangular module installation sections in the longitudinal direction. The respective solar battery modules are set uniform in longitudinal width and lateral width, and as to the lateral length of the module installation section, a segment connecting the upper vertexes of both sides in the lateral direction is set close to the inclination of the adjacent ridge line, and at least one of the plurality of module installation sections is composed of a multiple-stage installing part in which the solar battery modules adjacent to each other in the longitudinal direction are installed in two or more stages in the longitudinal direction without shifting in the lateral direction. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a solar cell module installation structure that is installed together with a roof material on a roof such as a dormitory roof.

  As shown in FIG. 23, a module installation region B is provided between a pair of corner ridge lines A located on both sides of a roof 31 such as a dormitory roof, and a plurality of solar cell modules 32 are provided in the module installation region B. In the installation structure of the solar cell module 32 that is installed vertically and horizontally, for example, the vertical width of the plurality of solar cell modules 32 is set to be the same as the vertical working dimension of the roof material 3 and the plurality of solar cells The horizontal width of the module 32 is set to an integral multiple of the working dimension in the horizontal direction of the roof material 33 so that the plurality of solar cell modules 32 are not shifted in the vertical direction with respect to the roof material 33 in the module installation region B. In some cases, the roof 31 is installed so as to correspond to the horizontal direction, whereby the installation of the roof material 33 and the installation of the solar cell module 32 are made to correspond to each other so that the appearance of the roof 31 is improved.

In this type of conventional solar cell module installation structure, a plurality of solar cell modules 31 on both sides in the lateral direction of the module installation region B are arranged substantially parallel to the adjacent corner ridge line A, and the aesthetic appearance of the roof 31 is impaired. In order to avoid this, as the solar cell module 32 to be installed in the module installation region B, a plurality of types of solar cell modules including a short solar cell module and a long solar cell module are provided and installed in the module installation region B. (For example, Patent Document 1, Patent Document 2, and Patent Document 3).
JP 2002-138633 A JP 2002-138737 A JP 2002-138638 A

However, since a plurality of types of solar cell modules 32 of a short solar cell module and a long solar cell module are installed in the conventional case, it is necessary to manufacture a plurality of types of solar cell modules 32. Was cumbersome and expensive to manufacture. Moreover, since there are a plurality of types of solar cell modules 32 having different widths, the construction of the solar cell module 32 is very troublesome.
In view of the above problems, the present invention allows a solar cell module to be installed on a roof together with a roof material in an appearance and appearance, and can be manufactured inexpensively and easily, and the installation of the solar cell module is also easy. It is something that can be obtained.

The technical means of the present invention for solving this technical problem includes a module installation area in which a solar cell module is installed between a pair of ridges located on both sides of a roof in the lateral direction, and the module installation area has a plurality of rectangular shapes. It is a solar cell module installation structure in which module installation sections consisting of shapes are stacked vertically,
The vertical width and horizontal width of each solar cell module are set to be the same, and the horizontal length of the module installation section is set so that the line segment connecting the upper vertices on both sides in the horizontal direction approaches the slope of the adjacent ridgeline. Set,
At least one of the plurality of module installation sections is that the solar cell modules adjacent in the vertical direction are configured by a multi-stage installation unit that is installed in a plurality of stages in the vertical direction without shifting in the horizontal direction.

Another technical means of the present invention resides in that the module installation area is composed of a combination of a plurality of types of module installation sections having different numbers of installation stages in the vertical direction of the solar cell module.
Another technical means of the present invention is that a plurality of types of module installation sections are repeatedly installed in the vertical direction.
Another technical means of the present invention is that the vertical width of the solar cell module is set to an integral multiple of the vertical working dimension of the roofing material.

In addition, according to another technical means of the present invention, the lateral width of the solar cell module is set to an integral multiple of the lateral working dimension of the roofing material, and the lateral displacement width of the module installation sections adjacent in the longitudinal direction is The roofing material is set to an integral multiple of 1/2 of the lateral working dimension of the roofing material, and a half-tile roofing material that is 1/2 of the lateral working dimension of the roofing material is provided. The roof material or semi-tile roof material is installed adjacent to the direction.
In addition, another technical means of the present invention is to provide a solar cell module in each module installation section so that line segments connecting the upper vertices on both sides in the horizontal direction of each module installation section are arranged substantially parallel to adjacent ridge lines. The number of installation stages in the vertical direction and the width in the horizontal direction between the module installation sections are set.

  According to the present invention, the arrangement of the solar cell modules on both sides in the lateral direction of the module installation area can be brought close to the inclination of the adjacent corner ridge line, and the solar cell modules are installed on the roof together with the roofing material in a good appearance. be able to. Moreover, since the solar cell module to be installed on the roof may be one type of solar cell module having the same width and height, the solar cell module can be manufactured inexpensively and easily, and the solar cell module can be easily installed. It becomes like this.

Hereinafter, the present invention will be described according to the illustrated embodiments.
In FIG. 1, reference numeral 1 denotes a dormitory roof of a building such as a house. The dormitory roof 1 is formed, for example, with a 5-inch gradient, and is a pair located on both ends of the dormitory roof 1 in the lateral direction (column direction). The pair of corner ridge lines A are arranged symmetrically with respect to the vertical line at the center in the horizontal direction of the roof 1 (symmetrical to the left and right). A module installation area B is provided between a pair of corner ridge lines A of the dormitory roof 1. A large number of roofing materials 3 are provided around the module installation area B of the dormitory roof 1, and the roofing materials 3 adjacent to each other in the vertical direction are only ½ of the lateral working dimension W1. It is installed in a staggered pattern so that it is shifted laterally. In the module installation area B, a large number of solar cell modules 4 are installed vertically and horizontally, whereby a large number of solar cell modules 4 are installed on the dormitory roof 1 together with a large number of roofing materials 3. Each solar cell module 4 in the module installation area B is installed corresponding to the horizontal direction so as not to be displaced in the vertical direction with respect to the roof material 3.

  Each roof material 3 is a normal roof material having a function as a roof tile. For example, as shown in FIGS. 4 to 6, a pair of wave-shaped convex portions 7 and 8 in the horizontal direction and a ridge on one side in the horizontal direction. Part 9, lower engaging convex part 10 on the upper end in the vertical direction, upper engaging convex part 11 on the upper end in the vertical direction, contact convex part 12 on the lower end in the vertical direction, and a fitting recess provided on the lower surface on the lower end in the vertical direction 13, and the lower engaging convex part 10 of the roofing material 3 is engaged with the horizontal rail 16 of the base plate 15 to contact the roofing material 3 as shown in FIG. The convex portion 12 side is superposed on the roof material 3 adjacent to the lower side in the vertical direction, and, as shown in FIG. 5, the corrugated portion of the roof material 3 adjacent to the one side in the horizontal direction as shown in FIG. 7 and the wave-shaped convex portion 7 is arranged on the flange 9 of the roof material 3 adjacent to the other side in the horizontal direction, and the upper roof material 3 adjacent in the vertical direction is fitted. Joint recess 13 It is to be fitted from above corrugated protrusions 7, 8 of the lower roof member 3.

Each roofing material 3 has a working dimension D1 in the vertical direction (roof flow direction) set to, for example, 280 mm, and a working dimension W1 in the horizontal direction (column direction) set to, for example, 303 mm or 306 mm.
Each solar cell module 4 in the module installation area B is of a roof material integrated type that also has a function as a roof tile that can be rolled up without a rail on the field board 15 in the same manner as a normal roof material. As shown in FIG. 3, a plurality of solar cells 19 formed by encapsulating solar cells with glass are supported by a metal frame or the like and configured in a rectangular shape. The solar cell module 4 has a vertical width (in the roof flow direction). The dimension (D2) is set to 280 mm, for example, and the horizontal width (dimension in the column direction) W2 is set to 909 mm or 918 mm, for example. Accordingly, the vertical width D2 of the solar cell module 4 is set to be the same as the working dimension D1 in the longitudinal direction of the roof material 3 (an integral multiple (1 times) of the working dimension D1). The lateral width W2 of the solar cell module 4 is set to 3 times (integer multiple) the lateral working dimension W1 of the roofing material 3. In addition, the large number of solar cell modules 4 are the same type and the same type of solar cell modules, and the vertical width D2 of each solar cell module 4 is set to be the same, and each solar cell module 4 widths W2 are set to be the same.

As shown in FIG. 1, the module installation area B is formed in a substantially trapezoidal shape or a triangle between a pair of corner ridge lines A, and in this module installation area B, a large number of solar cell modules 4 are arranged on the lower end side in the vertical direction. 2 so that the number of the solar cell modules 4 in the horizontal direction is gradually reduced every two steps, and the large number of solar cell modules 4 in the module installation region B are vertically lined in the horizontal center of the roof 1 together with a pair of corner ridge lines A. Are arranged symmetrically with respect to each other.
That is, from the lower side of the module installation region B, seven solar cell modules 4 are installed in the first and second stages in the horizontal direction, and the third and fourth stages are arranged in the horizontal direction. One solar cell module 4 is installed, five solar cell modules 4 are installed side by side in the fifth and sixth stages, and four solar cells are arranged side by side in the seventh and eighth stages. The battery module 4 is installed, the three solar cell modules 4 are arranged in the horizontal direction in the ninth and tenth stages, and the two solar cell modules are arranged in the horizontal direction in the eleventh and twelfth stages. 4 is installed, and one solar cell module 4 is installed in the horizontal direction on the 13th stage which is the uppermost stage of the module installation area B.

  Therefore, the two-stage installation part 23a (multiple-stage installation part 23) in which the solar cell modules 4 adjacent to each other in the vertical direction are installed in two stages (multiple stages) in the vertical direction without being shifted in the horizontal direction is the module installation region B. From the lower stage, between the first and second stages of the solar cell module 4, between the third and fourth stages, between the fifth and sixth stages, and between the seventh and eighth stages. Between the 9th stage and the 10th stage, and between the 11th stage and the 12th stage. In addition, the laterally offset installation part 24 in which the solar cell modules 4 adjacent in the vertical direction are installed in a lateral direction is arranged from the lower side of the module installation region B to the second and third stages of the solar cell module 4. Between the 4th stage and the 5th stage, Between the 6th stage and the 7th stage, Between the 8th stage and the 9th stage, Between the 10th stage and the 11th stage, It is comprised between the 13th stage.

Adjacent to both sides in the vertical direction (in the case of the embodiment shown in FIG. 1, there is no solar cell module 4 adjacent to the upper side, so the lower side) by the 13th stage solar cell module 4 that is the uppermost stage of the module installation region B. A one-stage installation portion 25 that is shifted laterally with respect to the matching solar cell module 4 is configured.
The module installation area B is obtained by stacking a plurality of rectangular module installation sections d in the vertical direction, and each of the plurality of module installation sections d is configured by the multi-stage installation section 23 or the one-stage installation section 25. The module installation area B is configured by a combination of a plurality of types of module installation sections d (multiple-stage installation units 23, 1-stage installation units 25) having different numbers of installation stages in the vertical direction of the solar cell module 4. Module installation division d is repeatedly installed in the vertical direction.

The lateral displacement width L of the solar cell modules 4 adjacent in the longitudinal direction of the lateral displacement installation portion 24, that is, the lateral displacement width L of the module installation section d adjacent in the longitudinal direction is the lateral direction of the roof material 3. Is set to 3 times, which is an integral multiple of 1/2 of the working dimension W1. And the roof material 21 comprised with the said roof material 3 comprised with the single-layer tile or the semi-tile is installed in the module installation area | region B adjacent to the horizontal direction.
The roof material 21 composed of the half tile includes a left roof material 21L composed of the left half tile shown in FIGS. 7 to 9 and a right roof material 21R composed of the right half tile shown in FIGS. The left roof material 21L and the right roof material 21R are similar to the roof material 3 made of a single tile, and the corrugated convex portions 7 and 8, the flange portion 9, the lower engaging convex portion 10, and the upper engaging convex portion. A vertical working dimension D3 of the roofing material 3 made of a single roof tile is set to be the same as the vertical working dimension D1. The working dimension W3 in the direction is set to ½ of the working dimension W1 in the lateral direction of the roofing material 3 composed of one tile. The roofing material 21 composed of these half tiles is a little more expensive than the roofing material 3 composed of a single tile, but is commercially available at a considerably lower price than the solar cell module 4.

  As described above, a part of the plurality of module installation sections d is configured by the multistage installation section 23 in which the solar cell modules 4 adjacent in the vertical direction are installed in a plurality of stages in the vertical direction without being shifted in the horizontal direction, By stacking a plurality of module installation sections d in the vertical direction, the solar cell modules 4 on both sides in the horizontal direction of the module installation area B are arranged, that is, the upper apexes a on both sides in the horizontal direction of each module installation section d (FIG. 1). The line segment C connecting (see) is close to the slope of the adjacent corner ridge line A. Further, the number of installation stages in the vertical direction of the solar cell module 4 in the multistage installation section 23 is set to two stages, and the lateral displacement dimension L in the lateral displacement installation section 24 is set to 3 times 1/2 of the working dimension W1. That is, the number of installation stages in the vertical direction of the solar cell module 4 in each module installation section d is set to one stage or two stages, and the lateral shift width L between the module installation sections d is set as a working dimension W1. Is set to 3 times 1/2 of the module installation region B, the plurality of solar cell modules 4 on both lateral sides of the module installation region B are arranged substantially parallel to the adjacent corner ridge line A, and Line segments C connecting the upper apexes a on both sides in the horizontal direction are arranged substantially parallel to the adjacent corner ridge lines A, respectively.

  Here, for example, arranging in parallel with the corner ridge line A means, for example, the upper apex a (see FIG. 1) on both lateral sides of each module installation section d (each multi-stage installation section 23 or one-stage installation section 25). And the corner ridge line A on the side adjacent to this line segment C are substantially parallel to each other. The term “substantially parallel” includes the case where the line segment C is inclined with respect to the corner ridge line A within a range of ± 5 °. Further, the line segment C may be bent zigzag in the middle. In this case, even if each part of the line segment C bent zigzag is inclined ± 5 ° or more with respect to the corner ridge line A, the line segment C As a whole, there are those that are inclined with respect to the corner ridge line A within a range of ± 5 °.

  According to the above-described embodiment, a part of the plurality of module installation sections d is configured by the multi-stage installation unit 23 and stacked in the vertical direction, so that the solar cell modules 4 on both sides in the horizontal direction of the module installation region B can be obtained. Is set close to the inclination of the adjacent corner ridge line A, the number of installation stages in the vertical direction of the solar cell modules 4 in the multi-stage installation part 23 is set to two, and the horizontal direction between the module installation categories d Is set to be three times as long as 1/2 of the working dimension W1, so that the solar battery modules 4 on both sides in the horizontal direction of the module installation region B are substantially parallel to the adjacent corner ridge line A. Since the plurality of solar cell modules 4 in the module installation region B are made to correspond to each other in the horizontal direction so as not to be shifted in the vertical direction with respect to the roof material 3, Not only the appearance is improved, but also by arranging the solar cell modules 4 on both sides of the solar cell module 4 in the lateral direction (column direction) substantially parallel to the corner ridge line A of the corner roof 1, the solar cell module 4 Can be made to have a harmonious and unified appearance from the entire corner roof 1.

In addition, unlike the prior art, it is not necessary to install a plurality of types of solar cell modules, which are short solar cell modules and long solar cell modules, in the module installation region B, and a large number of solar cell modules 4 have the same shape and Since they are the same type of solar cell modules having the same size, the solar cell module 4 can be manufactured inexpensively and easily, and the solar cell module 4 can be easily constructed.
In addition, since a large number of solar cell modules 4 in the module installation region B are arranged in line symmetry (left-right symmetry) with respect to the vertical line at the center in the horizontal direction of the roof 1 along with the pair of corner ridge lines A. Therefore, the arrangement of the solar cell module 4 is simplified, the installation of the solar cell module 4 in the module installation region B is further simplified, and the installation of the solar cell module 4 can be facilitated.

  Further, the lateral displacement width L between the solar cell modules 4 adjacent to each other in the longitudinal direction of the lateral displacement installation portion 24 is set to an integral multiple of 1/2 of the lateral working dimension W1 of the roofing material 3, and the module installation area Since the roof material 3 composed of a single tile or the roof material 21 composed of a semi-tile is installed adjacent to the B solar cell module 4 in the lateral direction, The roof material 3 or the half-tile roof material 21 may be used, and it is not necessary to cut the roof material halfway at the construction site or the like. From this point, the roof material 3, 21 or the roof 1 of the solar cell module 4 is also provided. It is easier to install on the roof, making it less economical to produce roofing waste.

  FIG. 13 shows another embodiment. From the lower side of the module installation area B, eight solar cell modules 4 are installed side by side in the first stage and horizontally in the second stage to the fourth stage. Seven solar cell modules 4 are installed side by side, six solar cell modules 4 are installed side by side in the fifth row, and five are arranged in the third row in the sixth to eighth rows. One solar cell module 4 is installed, four solar cell modules 4 are installed side by side on the ninth stage, and three solar cell modules 4 are arranged side by side on the third stage from the 10th stage to the 12th stage. Are installed, and two solar cell modules 4 are installed side by side in the 13th stage which is the uppermost stage of the module installation area B.

  Accordingly, the three-stage installation portion 23b (multiple-stage installation portion 23) in which the solar cell modules 4 adjacent to each other in the vertical direction are installed in three stages (multiple stages) in the vertical direction without shifting in the horizontal direction is the module installation region B. From the lower side, the solar cell module 4 is configured between the second stage to the fourth stage, the sixth stage to the eighth stage, and the tenth stage to the twelfth stage. Further, the laterally offset installation part 24 in which the solar cell modules 4 adjacent to each other in the vertical direction are installed to be laterally offset from the lower stage side of the module installation area B is formed between the first stage and the second stage of the solar cell module 4. Between the 4th stage and the 5th stage, Between the 5th stage and the 6th stage, Between the 8th stage and the 9th stage, Between the 9th stage and the 10th stage, The lateral displacement dimension L of the lateral displacement installation part 24 is set to 3 times 1/2 of the working dimension W1. Further, the first-stage installation portion 25 in which the one-stage solar cell module 4 is installed so as to be laterally displaced with respect to the solar cell modules 4 adjacent on both sides in the vertical direction is from the lower side of the module installation area B to the sun. The battery module 4 includes first, fifth, ninth and thirteenth stages.

  Thus, a part of the plurality of module installation sections d is configured by a multi-stage installation section 23 in which the solar cell modules 4 adjacent in the vertical direction are installed in a plurality of stages in the vertical direction without shifting in the horizontal direction. By stacking a plurality of module installation sections d in the vertical direction, the solar cell modules 4 on both sides of the module installation area B are arranged side by side, that is, a line connecting the upper vertices a on both lateral sides of each module installation section d. The minute C is brought close to the slope of the adjacent corner ridge line A. In addition, by setting the number of installation stages in the vertical direction of the solar cell modules 4 in the multistage installation section 23 to 3 and setting the lateral displacement dimension L in the lateral displacement installation section 24 to 3 times 1/2 of the working dimension W1. That is, the number of installation stages in the vertical direction of the solar cell module 4 in each module installation section d is set to one or three stages, and the lateral shift width L between the module installation sections d is set to 1 / of the working dimension W1. 2 is set to be three times that of the module installation region B, so that the plurality of solar cell modules 4 on both sides in the horizontal direction are arranged substantially parallel to the adjacent corner ridge line A, A line segment C connecting the upper vertices a is arranged so as to be substantially parallel to the adjacent corner ridge line A. In other respects, the configuration is the same as in the case of the above-described embodiment, and the same effects as in the case of the above-described embodiment are achieved.

  FIG. 14 shows another embodiment. From the lower side of the module installation region B, eight solar cell modules 4 are installed side by side in the first stage, and horizontally in the second stage to the second stage to the third stage. Seven solar cell modules 4 are installed side by side, six solar cell modules 4 are installed side by side in the fourth row, and five rows are arranged in the second row in the fifth to sixth steps. One solar cell module 4 is installed, four solar cell modules 4 are installed side by side in the seventh row, and three solar cell modules 4 are arranged in the second row in the eighth to ninth steps. Is installed, two solar cell modules 4 are installed side by side on the 10th stage, and one solar cell is installed horizontally on the 2nd stage of the 11th to 12th stages, which is the uppermost stage of the module installation area B. Module 4 is installed.

  Therefore, the two-stage installation part 23a (multiple-stage installation part 23) in which the solar cell modules 4 adjacent to each other in the vertical direction are installed in two stages (multiple stages) in the vertical direction without being shifted in the horizontal direction is the module installation region B. From the lower stage, between the second and third stages of the solar cell module 4, between the fifth and sixth stages, between the eighth and ninth stages, and between the eleventh and twelfth stages. Each is configured between. Further, the laterally offset installation part 24 in which the solar cell modules 4 adjacent to each other in the vertical direction are installed to be laterally offset from the lower stage side of the module installation area B is formed between the first stage and the second stage of the solar cell module 4. Between the third stage and the fourth stage, between the fourth stage and the fifth stage, between the sixth stage and the seventh stage, between the seventh stage and the eighth stage, and the ninth stage Between the 10th stage and the 10th stage and the 11th stage, respectively, the lateral displacement dimension L of the lateral displacement installation part 24 is set to 3 times 1/2 of the working dimension W1. Furthermore, the first-stage installation part 25 in which the one-stage solar cell module 4 is installed so as to be shifted laterally with respect to the solar cell modules 4 adjacent on both sides in the vertical direction is from the lower side of the module installation area B to the sun. The battery module 4 includes the first, fourth, seventh, and tenth stages.

  Thus, a part of the plurality of module installation sections d is configured by a multi-stage installation section 23 in which the solar cell modules 4 adjacent in the vertical direction are installed in a plurality of stages in the vertical direction without shifting in the horizontal direction. By stacking a plurality of module installation sections d in the vertical direction, the solar cell modules 4 on both sides of the module installation area B are arranged side by side, that is, a line connecting the upper vertices a on both lateral sides of each module installation section d. The minute C is brought close to the slope of the adjacent corner ridge line A. Further, by setting the number of installation stages in the vertical direction of the solar cell modules 4 in the multistage installation section 23 to 2 and setting the lateral displacement dimension L in the lateral displacement installation section 24 to 3 times 1/2 of the working dimension W1. That is, the number of installation stages in the vertical direction of the solar cell module 4 in each module installation section d is set to one or two, and the lateral shift width L between the module installation sections d is set to 1 / of the working dimension W1. 2 is set to be three times that of the module installation region B, so that the plurality of solar cell modules 4 on both sides in the horizontal direction are arranged substantially parallel to the adjacent corner ridge line A, A line segment C connecting the upper vertices a is arranged so as to be substantially parallel to the adjacent corner ridge line A. In other respects, the configuration is the same as in the case of the above-described embodiment, and the same effects as in the case of the above-described embodiment are achieved.

  FIG. 15 shows another embodiment, in which the lateral width W2 of the solar cell module 4 is set to four times (integer multiple) the lateral working dimension W1 of the roofing material 3. From the lower side of the module installation area B, six solar cell modules 4 are installed side by side in the first stage to the second stage, the second stage, and the third stage to the fifth stage are arranged in the horizontal direction. 5 solar cell modules 4 are installed, and 4 solar cell modules 4 are installed side by side in the 2nd stage from the 6th stage to the 7th stage, and the 3rd stage from the 8th stage to the 10th stage. The three solar cell modules 4 are installed side by side, the two solar cell modules 4 are installed side by side in the two stages of the 11th to 12th stages, and the 13th stage which is the uppermost stage of the module installation area B One solar cell module 4 is installed in the horizontal direction on the 2nd to 14th stages.

  Therefore, the two-stage installation part 23a (multiple-stage installation part 23) in which the solar cell modules 4 adjacent to each other in the vertical direction are installed in two stages (multiple stages) in the vertical direction without being shifted in the horizontal direction is the module installation region B. From the lower stage side, between the first stage and the second stage of the solar cell module 4, between the sixth stage and the seventh stage, between the eleventh stage and the twelfth stage, the thirteenth stage and the 14th stage. Each is configured between. Further, the three-stage installation portion 23b (multiple-stage installation portion 23) in which the solar cell modules 4 adjacent to each other in the vertical direction are installed in three stages (a plurality of stages) in the vertical direction without being shifted in the horizontal direction is the module installation region B. From the lower stage side, the solar cell module 4 is configured between the third stage to the fifth stage and between the eighth stage to the tenth stage. In addition, the laterally offset installation part 24 in which the solar cell modules 4 adjacent in the vertical direction are installed in a lateral direction is arranged from the lower side of the module installation region B to the second and third stages of the solar cell module 4. Between the 5th and 6th stages, between the 7th and 8th stages, between the 10th and 11th stages, and between the 12th and 13th stages, The lateral displacement dimension L of the lateral displacement installation part 24 is set to 4 times 1/2 of the working dimension W1.

  Thus, a part of the plurality of module installation sections d is configured by a multi-stage installation section 23 in which the solar cell modules 4 adjacent in the vertical direction are installed in a plurality of stages in the vertical direction without shifting in the horizontal direction. By stacking a plurality of module installation sections d in the vertical direction, the solar cell modules 4 on both sides of the module installation area B are arranged side by side, that is, a line connecting the upper vertices a on both lateral sides of each module installation section d. The minute C is brought close to the slope of the adjacent corner ridge line A. Further, the number of installation stages in the vertical direction of the solar cell module 4 in the multistage installation section 23 is set to two or three stages, and the lateral displacement dimension L in the lateral displacement installation section 24 is set to four times 1/2 of the working dimension W1. In other words, the number of installation stages in the vertical direction of the solar cell module 4 in each module installation section d is set to two or three stages, and the lateral shift width L between the module installation sections d is set as a working dimension W1. Is set to 4 times 1/2 of the module installation region B, the plurality of solar cell modules 4 on both lateral sides of the module installation area B are arranged substantially parallel to the adjacent corner ridge line A, and Line segments C connecting the upper apexes a on both sides in the horizontal direction are arranged substantially parallel to the adjacent corner ridge lines A, respectively. In other respects, the configuration is the same as in the case of the above-described embodiment, and the same effects as in the case of the above-described embodiment are achieved.

  FIG. 16 shows another embodiment, in which the lateral width W2 of the solar cell module 4 is set to four times (integer multiple) the lateral working dimension W1 of the roofing material 3. From the lower side of the module installation area B, six solar cell modules 4 are installed side by side in the second stage from the first stage to the second stage, and are arranged in the second direction from the third stage to the second stage. 5 solar cell modules 4 are installed, and 4 solar cell modules 4 are installed side by side in the 3rd stage from the 5th stage to the 7th stage, and the 2nd stage from the 8th stage to the 9th stage. The three solar cell modules 4 are installed side by side, and the two solar cell modules 4 are installed side by side in the second to tenth to eleventh stages, and the uppermost stage of the module installation region B is the 12th stage. One solar cell module 4 is installed in the horizontal direction on the third to the 14th stages.

  Therefore, the two-stage installation part 23a (multiple-stage installation part 23) in which the solar cell modules 4 adjacent to each other in the vertical direction are installed in two stages (multiple stages) in the vertical direction without being shifted in the horizontal direction is the module installation region B. From the lower side, between the first stage and the second stage of the solar cell module 4, between the third stage and the fourth stage, between the eighth stage and the ninth stage, the tenth stage and the eleventh stage Each is configured between. Further, the three-stage installation portion 23b (multiple-stage installation portion 23) in which the solar cell modules 4 adjacent to each other in the vertical direction are installed in three stages (a plurality of stages) in the vertical direction without being shifted in the horizontal direction is the module installation region B. From the lower stage side, the solar cell module 4 is configured between the 5th stage to the 7th stage and the 12th stage to the 14th stage. In addition, the laterally offset installation part 24 in which the solar cell modules 4 adjacent in the vertical direction are installed in a lateral direction is arranged from the lower side of the module installation region B to the second and third stages of the solar cell module 4. Between the 4th stage and the 5th stage, between the 7th stage and the 8th stage, between the 9th stage and the 10th stage, and between the 11th stage and the 12th stage, The lateral displacement dimension L of the lateral displacement installation part 24 is set to 4 times 1/2 of the working dimension W1.

  Thus, a part of the plurality of module installation sections d is configured by a multi-stage installation section 23 in which the solar cell modules 4 adjacent in the vertical direction are installed in a plurality of stages in the vertical direction without shifting in the horizontal direction. By stacking a plurality of module installation sections d in the vertical direction, the solar cell modules 4 on both sides of the module installation area B are arranged side by side, that is, a line connecting the upper vertices a on both lateral sides of each module installation section d. The minute C is brought close to the slope of the adjacent corner ridge line A. Further, the number of installation stages in the vertical direction of the solar cell module 4 in the multistage installation section 23 is set to two or three stages, and the lateral displacement dimension L in the lateral displacement installation section 24 is set to four times 1/2 of the working dimension W1. In other words, the number of installation stages in the vertical direction of the solar cell module 4 in each module installation section d is set to two or three stages, and the lateral shift width L between the module installation sections d is set as a working dimension W1. Is set to 4 times 1/2 of the module installation region B, the plurality of solar cell modules 4 on both lateral sides of the module installation area B are arranged substantially parallel to the adjacent corner ridge line A, and Line segments C connecting the upper apexes a on both sides in the horizontal direction are arranged substantially parallel to the adjacent corner ridge lines A, respectively. In other respects, the configuration is the same as in the case of the above-described embodiment, and the same effects as in the case of the above-described embodiment are achieved.

FIG. 17 shows another embodiment, in which the lateral width W2 of the solar cell module 4 is set to 5 times (integer multiple) the lateral working dimension W1 of the roofing material 3. From the lower side of the module installation area B, four solar cell modules 4 are installed side by side in the first to third stages of the third stage, and arranged in the fourth to sixth stages of the third stage in the horizontal direction. Three solar cell modules 4 are installed, and two solar cell modules 4 are installed side by side in the third row from the seventh to the ninth row, and the third row from the tenth to the twelfth row. One solar cell module 4 is installed.
Accordingly, the three-stage installation portion 23b (multiple-stage installation portion 23) in which the solar cell modules 4 adjacent to each other in the vertical direction are installed in three stages (multiple stages) in the vertical direction without shifting in the horizontal direction is the module installation region B. From the lower stage side, between the first stage to the third stage of the solar cell module 4, between the fourth stage to the sixth stage, between the seventh stage to the ninth stage, and between the tenth stage to the 12th stage. Each is composed. Further, the laterally offset installation part 24 in which the solar cell modules 4 adjacent to each other in the vertical direction are installed in the lateral direction is arranged from the lower side of the module installation region B to the third and fourth stages of the solar cell module 4. Between the 6th stage and the 7th stage, and between the 9th stage and the 10th stage, and the lateral displacement dimension L of the lateral displacement installation portion 24 is set to 5 times 1/2 of the working dimension W1. Has been.

  Thus, a part of the plurality of module installation sections d is configured by a multi-stage installation section 23 in which the solar cell modules 4 adjacent in the vertical direction are installed in a plurality of stages in the vertical direction without shifting in the horizontal direction. By stacking a plurality of module installation sections d in the vertical direction, the solar cell modules 4 on both sides of the module installation area B are arranged side by side, that is, a line connecting the upper vertices a on both lateral sides of each module installation section d. The minute C is brought close to the slope of the adjacent corner ridge line A. Further, by setting the number of installation stages in the vertical direction of the solar cell module 4 in the multistage installation section 23 to 3 stages, and setting the lateral displacement dimension L in the lateral displacement installation section 24 to 5 times 1/2 of the working dimension W1. That is, the number of installation stages in the vertical direction of the solar cell module 4 in each module installation section d is set to three, and the lateral shift width L between the module installation sections d is 5 which is 1/2 of the working dimension W1. By setting it to be double, the plurality of solar cell modules 4 on both sides in the horizontal direction of the module installation area B are arranged substantially in parallel with the adjacent corner ridge line A, and the upper apexes on both sides in the horizontal direction of each module installation section d Line segments C connecting a are arranged so as to be substantially parallel to the adjacent corner ridge lines A, respectively. In other respects, the configuration is the same as in the case of the above-described embodiment, and the same effects as in the case of the above-described embodiment are achieved.

FIG. 18 shows another embodiment, in which the lateral width W2 of the solar cell module 4 is set to 5 times (integer multiple) the lateral working dimension W1 of the roofing material 3. From the lower side of the module installation area B, four solar cell modules 4 are installed side by side in the first stage to the second stage in the second stage, and arranged in the third stage to the sixth stage in the horizontal direction. Three solar cell modules 4 are installed, and two solar cell modules 4 are installed side by side in the second row of the 7th to 8th rows, and the horizontal direction is placed in the 4th row of the 9th to 12th rows. One solar cell module 4 is installed.
Therefore, the two-stage installation part 23a (multiple-stage installation part 23) in which the solar cell modules 4 adjacent to each other in the vertical direction are installed in two stages (multiple stages) in the vertical direction without being shifted in the horizontal direction is the module installation region B. From the lower stage side, the solar cell module 4 is configured between the first stage and the second stage and between the seventh stage and the eighth stage. Further, a four-stage installation portion 23c (multiple-stage installation portion 23) in which the solar cell modules 4 adjacent to each other in the vertical direction are installed in four stages (a plurality of stages) in the vertical direction without shifting in the horizontal direction is provided in the module installation area B. From the lower stage side, the solar cell module 4 is configured between the third to sixth stages and the ninth to twelfth stages. In addition, the laterally offset installation part 24 in which the solar cell modules 4 adjacent in the vertical direction are installed in a lateral direction is arranged from the lower side of the module installation region B to the second and third stages of the solar cell module 4. Between the 6th stage and the 7th stage, and between the 8th stage and the 9th stage, and the lateral displacement dimension L of the lateral displacement installation part 24 is set to 5 times 1/2 of the working dimension W1. Has been.

  Thus, a part of the plurality of module installation sections d is configured by a multi-stage installation section 23 in which the solar cell modules 4 adjacent in the vertical direction are installed in a plurality of stages in the vertical direction without shifting in the horizontal direction. By stacking a plurality of module installation sections d in the vertical direction, the solar cell modules 4 on both sides of the module installation area B are arranged side by side, that is, a line connecting the upper vertices a on both lateral sides of each module installation section d. The minute C is brought close to the slope of the adjacent corner ridge line A. Further, the number of installation stages in the vertical direction of the solar cell module 4 in the multistage installation section 23 is set to 2 or 4, and the lateral displacement dimension L in the lateral displacement installation section 24 is set to 5 times 1/2 of the working dimension W1. In other words, the number of installation stages in the vertical direction of the solar cell module 4 in each module installation section d is set to two or four, and the lateral shift width L between the module installation sections d is set to the working dimension W1. Is set to 5 times the half of the module installation area B, the plurality of solar cell modules 4 on both sides in the lateral direction are arranged in parallel with the adjacent corner ridge line A, and each module installation section d Line segments C connecting the upper apexes a on both sides in the horizontal direction are arranged substantially parallel to the adjacent corner ridge lines A, respectively. In other respects, the configuration is the same as in the case of the above-described embodiment, and the same effects as in the case of the above-described embodiment are achieved.

FIG. 19 shows another embodiment, in which the lateral width W2 of the solar cell module 4 is set to 5 times (integer multiple) the lateral working dimension W1 of the roofing material 3. From the lower side of the module installation area B, four solar cell modules 4 are installed side by side in the first to third stages of the third stage, and arranged in the fourth to seventh stages of the fourth stage in the horizontal direction. The three solar cell modules 4 are installed, and the two solar cell modules 4 are installed side by side in the third row of the eighth to tenth rows, and the four rows of the eleventh to fourteenth rows. One solar cell module 4 is installed.
Accordingly, the three-stage installation portion 23b (multiple-stage installation portion 23) in which the solar cell modules 4 adjacent to each other in the vertical direction are installed in three stages (multiple stages) in the vertical direction without shifting in the horizontal direction is the module installation region B. From the lower stage side, the solar cell module 4 is configured between the first stage to the third stage and between the eighth stage to the tenth stage. Further, a four-stage installation portion 23c (multiple-stage installation portion 23) in which the solar cell modules 4 adjacent to each other in the vertical direction are installed in four stages (a plurality of stages) in the vertical direction without shifting in the horizontal direction is provided in the module installation area B. From the lower stage side, the solar cell module 4 is configured between the 4th stage to the 7th stage and the 11th stage to the 14th stage. Further, the laterally offset installation part 24 in which the solar cell modules 4 adjacent to each other in the vertical direction are installed in a lateral direction is arranged from the lower side of the module installation region B to the third and fourth stages of the solar cell module 4. Between the 7th stage, the 8th stage, the 10th stage and the 11th stage, and the lateral displacement dimension L of the lateral displacement installation part 24 is set to 5 times 1/2 of the working dimension W1. Has been.

  Thus, a part of the plurality of module installation sections d is configured by a multi-stage installation section 23 in which the solar cell modules 4 adjacent in the vertical direction are installed in a plurality of stages in the vertical direction without shifting in the horizontal direction. By stacking a plurality of module installation sections d in the vertical direction, the solar cell modules 4 on both sides of the module installation area B are arranged side by side, that is, a line connecting the upper vertices a on both lateral sides of each module installation section d. The minute C is brought close to the slope of the adjacent corner ridge line A. Further, the number of installation stages in the vertical direction of the solar cell module 4 in the multistage installation section 23 is set to 3 or 4, and the lateral displacement dimension L in the lateral displacement installation section 24 is set to 5 times 1/2 of the working dimension W1. That is, the number of installation stages in the vertical direction of the solar cell module 4 in each module installation section d is set to three or four stages, and the lateral shift width L between the module installation sections d is set as the working dimension W1. Is set to 5 times the half of the module installation area B, the plurality of solar cell modules 4 on both sides in the lateral direction are arranged in parallel with the adjacent corner ridge line A, and each module installation section d Line segments C connecting the upper apexes a on both sides in the horizontal direction are arranged substantially parallel to the adjacent corner ridge lines A, respectively. In other respects, the configuration is the same as in the case of the above-described embodiment, and the same effects as in the case of the above-described embodiment are achieved.

  FIG. 20 shows another embodiment, in which the lateral width W2 of the solar cell module 4 is set to 5 times (integer multiple) the lateral working dimension W1 of the roofing material 3. From the lower side of the module installation area B, five solar cell modules 4 are installed side by side in the first stage, and four solar cell modules 4 are arranged side by side in the third stage from the second stage to the fourth stage. Are installed, and three solar cell modules 4 are installed in the third row from the fifth stage to the seventh stage, and two solar cells are arranged in the third row from the eighth stage to the tenth stage. The module 4 is installed, and one solar cell module 4 is installed in the horizontal direction on the 11th to 13th stages.

  Accordingly, the three-stage installation portion 23b (multiple-stage installation portion 23) in which the solar cell modules 4 adjacent to each other in the vertical direction are installed in three stages (multiple stages) in the vertical direction without shifting in the horizontal direction is the module installation region B. From the second stage, between the second stage to the fourth stage of the solar cell module 4, between the fifth stage to the seventh stage, between the eighth stage to the tenth stage, and between the eleventh stage to the thirteenth stage, respectively. It is configured. Further, the laterally offset installation part 24 in which the solar cell modules 4 adjacent to each other in the vertical direction are installed to be laterally offset from the lower stage side of the module installation area B is formed between the first stage and the second stage of the solar cell module 4. Between the fourth stage and the fifth stage, between the seventh stage and the eighth stage, between the tenth stage and the eleventh stage. It is set to 5 times 1/2 of the dimension W1. Furthermore, the first-stage installation part 25 in which the one-stage solar cell module 4 is installed so as to be shifted laterally with respect to the solar cell modules 4 adjacent on both sides in the vertical direction is from the lower side of the module installation area B to the sun. It is constituted by the first stage of the battery module 4.

  Thus, a part of the plurality of module installation sections d is configured by a multi-stage installation section 23 in which the solar cell modules 4 adjacent in the vertical direction are installed in a plurality of stages in the vertical direction without shifting in the horizontal direction. By stacking a plurality of module installation sections d in the vertical direction, the solar cell modules 4 on both sides of the module installation area B are arranged side by side, that is, a line connecting the upper vertices a on both lateral sides of each module installation section d. The minute C is brought close to the slope of the adjacent corner ridge line A. Further, by setting the number of installation stages in the vertical direction of the solar cell module 4 in the multistage installation section 23 to 3 stages, and setting the lateral displacement dimension L in the lateral displacement installation section 24 to 5 times 1/2 of the working dimension W1. That is, the number of installation stages in the vertical direction of the solar cell module 4 in each module installation section d is set to one or three stages, and the lateral shift width L between the module installation sections d is set to 1 / of the working dimension W1. By setting it to 5 times 2, the solar battery modules 4 in the plurality of stages on both sides in the horizontal direction of the module installation area B are arranged substantially parallel to the adjacent corner ridge line A, and both sides in the horizontal direction of each module installation section d. A line segment C connecting the upper vertices a is arranged so as to be substantially parallel to the adjacent corner ridge line A. In other respects, the configuration is the same as in the case of the above-described embodiment, and the same effects as in the case of the above-described embodiment are achieved.

  FIG. 21 shows another embodiment, in which the vertical width D2 of the solar cell module 4 is set to double (integer multiple) the vertical working dimension D1 of the roof material 3, and the horizontal width W2 of the solar cell module 4 is the roof. It is set to 5 times (integer multiple) the lateral working dimension W1 of the material 3. From the lower side of the module installation area B, four solar cell modules 4 are installed side by side in the first stage, and three solar cell modules 4 are arranged side by side in the second stage to the second stage to the third stage. Are installed, two solar cell modules 4 are installed side by side in the fourth stage, and one solar cell module 4 is installed in the second stage in the fifth to sixth stages.

  Therefore, the two-stage installation part 23a (multiple-stage installation part 23) in which the solar cell modules 4 adjacent to each other in the vertical direction are installed in two stages (multiple stages) in the vertical direction without being shifted in the horizontal direction is the module installation region B. From the lower stage side, the solar cell module 4 is configured between the second stage and the third stage, and between the fifth stage and the sixth stage. Further, the laterally offset installation part 24 in which the solar cell modules 4 adjacent to each other in the vertical direction are installed to be laterally offset from the lower stage side of the module installation area B is formed between the first stage and the second stage of the solar cell module 4. Between the third stage and the fourth stage, between the fourth stage and the fifth stage, the lateral displacement dimension L of the lateral displacement installation part 24 is set to 5 times 1/2 of the working dimension W1. Has been. Furthermore, the first-stage installation part 25 in which the one-stage solar cell module 4 is installed so as to be shifted laterally with respect to the solar cell modules 4 adjacent on both sides in the vertical direction is from the lower side of the module installation area B to the sun. The battery module 4 includes the first and fourth stages.

  Thus, a part of the plurality of module installation sections d is configured by a multi-stage installation section 23 in which the solar cell modules 4 adjacent in the vertical direction are installed in a plurality of stages in the vertical direction without shifting in the horizontal direction. By stacking a plurality of module installation sections d in the vertical direction, the solar cell modules 4 on both sides of the module installation area B are arranged side by side, that is, a line connecting the upper vertices a on both lateral sides of each module installation section d. The minute C is brought close to the slope of the adjacent corner ridge line A. In addition, by setting the number of installation stages in the vertical direction of the solar cell modules 4 in the multistage installation section 23 to 2 and setting the lateral displacement dimension L in the lateral displacement installation section 24 to 5 times 1/2 of the working dimension W1. That is, the number of installation stages in the vertical direction of the solar cell module 4 in each module installation section d is set to one or two, and the lateral shift width L between the module installation sections d is set to 1 / of the working dimension W1. By setting it to 5 times 2, the solar battery modules 4 in the plurality of stages on both sides in the horizontal direction of the module installation area B are arranged substantially parallel to the adjacent corner ridge line A, and both sides in the horizontal direction of each module installation section d. A line segment C connecting the upper vertices a is arranged so as to be substantially parallel to the adjacent corner ridge line A. In other respects, the configuration is the same as in the case of the above-described embodiment, and the same effects as in the case of the above-described embodiment are achieved.

FIG. 22 shows another embodiment, and the pair of ridge lines A are asymmetrically formed by the corner ridge line and the ridge line, and correspondingly, a large number of solar cell modules 4 in the module installation region B are also Arranged on the roof 1 asymmetrically.
The lateral width W2 of the solar cell module 4 is set to 4 times (integer multiple) the lateral working dimension W1 of the roofing material 3. From the lower side of the module installation area B, three solar cell modules 4 are installed side by side in the first stage to the second stage, the second stage, and the third stage to the fifth stage are arranged in the horizontal direction. 5 solar cell modules 4 are installed, and two solar cell modules 4 are installed side by side in the second row of the sixth stage to the seventh stage, and the horizontal direction is arranged in the third stage of the eighth stage to the tenth stage. Two solar cell modules 4 are installed side by side, and one solar cell module 4 is installed in the horizontal direction on the 11th to 12th stages, and the 13th stage, which is the uppermost stage of the module installation area B, One solar cell module 4 is installed in the horizontal direction on the second stage of the fourteenth stage.

  Therefore, the two-stage installation part 23a (multiple-stage installation part 23) in which the solar cell modules 4 adjacent to each other in the vertical direction are installed in two stages (multiple stages) in the vertical direction without being shifted in the horizontal direction is the module installation region B. From the lower stage side, between the first stage and the second stage of the solar cell module 4, between the sixth stage and the seventh stage, between the eleventh stage and the twelfth stage, the thirteenth stage and the 14th stage. Each is configured between. Further, the three-stage installation portion 23c (multiple-stage installation portion 23) in which the solar cell modules 4 adjacent to each other in the vertical direction are installed in three stages (multiple stages) in the vertical direction without shifting in the horizontal direction is provided in the module installation region B. From the lower stage side, the solar cell module 4 is configured between the third stage to the fifth stage and between the eighth stage to the tenth stage. In addition, the laterally offset installation part 24 in which the solar cell modules 4 adjacent in the vertical direction are installed in a lateral direction is arranged from the lower side of the module installation region B to the second and third stages of the solar cell module 4. Between the 5th and 6th stages, between the 7th and 8th stages, between the 10th and 11th stages, and between the 12th and 13th stages, The lateral displacement dimension L of the lateral displacement installation part 24 is set to 4 times 1/2 of the working dimension W1.

  Thus, a part of the plurality of module installation sections d is configured by a multi-stage installation section 23 in which the solar cell modules 4 adjacent in the vertical direction are installed in a plurality of stages in the vertical direction without shifting in the horizontal direction. By stacking a plurality of module installation sections d in the vertical direction, the solar cell modules 4 on both sides of the module installation area B are arranged side by side, that is, a line connecting the upper vertices a on both lateral sides of each module installation section d. The minute C is brought close to the slope of the adjacent ridge line A. Further, the number of installation stages in the vertical direction of the solar cell module 4 in the multistage installation section 23 is set to two or three stages, and the lateral displacement dimension L in the lateral displacement installation section 24 is set to four times 1/2 of the working dimension W1. In other words, the number of installation stages in the vertical direction of the solar cell module 4 in each module installation section d is set to two or three stages, and the lateral shift width L between the module installation sections d is set as a working dimension W1. Is set to 4 times 1/2 of the module installation region B, the plurality of stages of the solar cell modules 4 on both sides in the lateral direction are arranged substantially parallel to the adjacent ridge line A, and the horizontal direction of each module installation section d A line segment C connecting the upper vertices a on both sides is arranged substantially parallel to the adjacent ridge line A. The other points are the same as those in the above embodiment, and the solar cell module 4 is arranged symmetrically, and the solar cell module 4 can be easily constructed. The same effect as in the case of.

  In the case of the embodiment of FIG. 22, the plurality of stages of solar cell modules 4 on both sides in the horizontal direction of the module installation region B are arranged substantially parallel to the adjacent ridge line A on the left side in the horizontal direction of the module installation region B. As in the case of the other embodiments described above, the line segment C connecting the upper vertices a on both lateral sides of each multi-stage installation portion 23 and the ridge line A on the side adjacent thereto are substantially parallel. As for the right side in the horizontal direction of the module installation area B, the right end of the second stage installation part 23a and the left end of the third stage installation part 23b are parallel to the right ridge line A. Since both the line segment C1 connecting the right end of the two-stage installation part 23a and the line segment C2 connecting the right end of the three-stage installation part 23b are parallel to the right-side ridge line A adjacent thereto, Right side of module installation area B Can solar cell module 4 several stages is recognized that in a row parallel to the adjacent edge lines A, be something good appearance of the appearance that take unified and harmony.

In the above-described embodiment, the roof material 3 is composed of a single corrugated roof tile, but instead, the roof material 3 is composed of a single roof tile, such as a thin flat roof tile or a thick flat roof tile. You may make it do.
Moreover, in the said embodiment, although the horizontal width W2 of the solar cell module 4 is set to the integral multiple of the horizontal working dimension W1 of the roofing material 3, it replaces with this and the horizontal width W2 of the solar cell module 4 is set to the roof. You may make it set to the dimension unrelated to the working dimension W1 of the horizontal direction of the material 3. FIG. Further, the roof material 3 cannot be specified in a horizontal and / or vertical dimension that is long in the horizontal direction or the vertical direction, or that is cut to an arbitrary length in the horizontal direction or the vertical direction and installed on the roof 1. You may make it use such a thing.

Moreover, in the said embodiment, although the multistage installation part 23 and the lateral deviation installation part 24 are provided in multiple numbers by the vertical direction of the module installation area B, it replaces with this, and the magnitude | size and shape of the module installation area B are replaced with this. Alternatively, depending on the number of stages of the solar cell modules 4 in the multistage installation section 23, the multistage installation section 23 or the lateral displacement installation section 24 may be provided one by one in the vertical direction of the module installation area B.
Further, the slope of the roof 1 is not limited to a five-dimensional gradient, and may be a six-dimensional gradient or other gradients.

  It can be used for a solar cell module installed together with a roofing material on a roof such as a dormitory roof of a building such as a house.

It is a front view of the dormitory roof which shows one embodiment of this invention. It is a front view of the roof material and solar cell module of the dormitory roof. It is a side view of the solar cell module. It is a front view of the roof material. It is bottom sectional drawing which shows the installation state of the roof material. It is side surface sectional drawing which shows the installation state of the roof material. It is a top view of the roof material comprised with the left half tile. It is bottom sectional drawing of the roof material comprised with the left half tile. It is a bottom view of the roof material comprised with the left half tile. It is a bottom view of the roof material comprised with the right half tile. It is bottom sectional drawing of the roof material comprised with the right half tile. It is a bottom view of the roof material comprised with the right half tile. It is a front view of the dormitory roof which shows other embodiment. It is a front view of the dormitory roof which shows other embodiment. It is a front view of the dormitory roof which shows other embodiment. It is a front view of the dormitory roof which shows other embodiment. It is a front view of the dormitory roof which shows other embodiment. It is a front view of the dormitory roof which shows other embodiment. It is a front view of the dormitory roof which shows other embodiment. It is a front view of the dormitory roof which shows other embodiment. It is a front view of the dormitory roof which shows other embodiment. It is a front view of the dormitory roof which shows other embodiment. It is a front view of the dormitory roof which shows a prior art example.

Explanation of symbols

1 rooftop 3 roofing material 4 solar cell module 21 roof material 23 composed of half-tile tile 2 stage installation part 24 lateral displacement installation part 25 1 stage installation part D1 longitudinal working dimension W1 lateral working dimension D2 longitudinal width W2 lateral width

Claims (6)

A module installation area (B) for installing the solar cell module (4) is provided between a pair of ridge lines (A) located on both sides in the lateral direction of the roof (1), and the module installation area (B) has a plurality of rectangular shapes. It is a solar cell module installation structure in which the module installation division (d) is vertically stacked,
The vertical width (D2) and the horizontal width (W2) of each solar cell module (4) are set to be the same, and the horizontal length of the module installation section (d) is the upper vertex (a) on both sides in the horizontal direction. Are set so that the line segment (C) connecting the two approaches the slope of the adjacent ridge line (A),
At least one of the plurality of module installation sections (d) is configured by a multistage installation section (23) in which a plurality of solar cell modules (4) adjacent in the vertical direction are installed in a plurality of stages in the vertical direction without shifting in the horizontal direction. The installation structure of the solar cell module characterized by being made.   2. The sun according to claim 1, wherein the module installation area (B) is composed of a combination of a plurality of types of module installation sections (d) having different number of installation stages in the vertical direction of the solar cell module (4). Battery module installation structure.   The installation structure of the solar cell module according to claim 2, wherein a plurality of types of module installation sections (d) are repeatedly installed in the vertical direction.   The vertical width (D2) of the solar cell module (4) is set to an integral multiple of the vertical working dimension (D1) of the roofing material (3). The installation structure of the solar cell module described.   The horizontal width (W2) of the solar cell module (4) is set to an integral multiple of the horizontal working dimension (W1) of the roofing material (3) and the horizontal direction of the module installation section (d) adjacent in the vertical direction. The deviation width (L) is set to an integral multiple of 1/2 of the lateral working dimension (W1) of the roofing material (3), and 1 of the lateral working dimension (W1) of the roofing material (3). A half-tile roofing material (21) to be / 2 is provided, and the roofing material (3) or the half-tile roofing material (21) is installed adjacent to the horizontal direction of the module installation section (d). The installation structure of the solar cell module according to any one of claims 1 to 4.   In each module installation section (d), the line segments (C) connecting the upper vertices (a) on both sides in the horizontal direction of each module installation section (d) are aligned substantially parallel to the adjacent ridge lines (A). The number of installation stages in the vertical direction of the solar cell module (4) and the lateral displacement width (L) between the module installation sections (d) are set. An installation structure of the solar cell module according to claim 1.

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