JP6440644B2 - Solar cell module fixing member, solar cell module fixing structure, and solar cell module fixing method - Google Patents

Description

  The present invention relates to a solar cell module fixing member, a solar cell module fixing structure, and a solar cell module fixing method for fixing a solar cell module having a frame body on an outer periphery on a roof. .

  As a solar cell module fixed on a roof, a solar cell module having a frame attached to the outer periphery of a flat plate solar cell panel is known. As a fixing member for fixing such a solar cell module on the roof, the applicant of the present application has proposed a fixing member that can be fitted to the side surface of the frame body and can be mounted on the roof. (Patent Document 1).

  In the technique of Patent Document 1, the fixing member includes a base portion that is mounted on the roof, a shaft portion that extends upward from the base portion, and a ceiling portion that extends from the upper end of the shaft portion to both sides. A frame is fitted between the top and the top. In addition, the fixing member includes a projecting piece projecting in a direction facing each other from the base portion and the top portion on one side of the shaft portion.

  In the technique of this Patent Document 1, first, a fixing member is mounted on the roof with the protruding piece side facing the roof ridge side with respect to the shaft portion, and the base portion and the top portion facing the ridge side of the fixing member The frame body facing the eaves side of the solar cell module is fitted between. Next, after fitting the frame facing the opposite ridge side between the base part on the side where the protruding piece of another fixing member does not protrude and the top part, the base part is placed on the roof. Mount and install. Then, a frame body facing the eave side of another solar cell module is fitted between the base portion and the top portion facing the ridge side of the ridge side fixing member, and the above operation is repeated. Thereby, a some solar cell module can be fixed on a roof in order from the eaves side.

  When wind strikes the solar cell module fixed on the roof, a force that lifts the solar cell module from the roof acts on the solar cell module. With respect to this force, the technique of Patent Document 1 copes with the top portion of the fixing member and the screw screwed into the ridge-side frame through the shaft portion, and restricts the upward movement of the solar cell module. ing. Moreover, in the technique of patent document 1, the eaves-side frame body of the solar cell module located on the ridge side is in contact with the projecting piece of the fixing member, so A gap for absorbing thermal expansion of the battery module is formed.

  There is a need for a higher fixing strength of the solar cell module on the roof with respect to the technique of Patent Document 1. Moreover, in patent document 1, since the frame on the ridge side of the solar cell module is fixed to the shaft portion with screws, a force in the eave direction acts on the shaft portion in the inclined roof, and the shaft portion May be bent. Furthermore, in the technique of Patent Document 1, since the protruding piece with which the eaves-side frame body of the solar cell module abuts protrudes from both the base portion and the top portion, the load of the solar cell module on the ridge side is Since it is also applied to the side, a force applied to the eaves direction acts on the shaft portion due to the load applied to the projecting piece on the top side, and the shaft portion may be bent. If the shaft part is bent, the top part moves to the eaves side, so in the frame on the eaves side of the solar cell module, the degree of contact with the top part decreases, and the sun on the ridge There is a possibility that the fixing strength of the battery module may decrease.

Japanese Patent No. 4365450

  Therefore, in view of the above circumstances, the present invention has an object to provide a solar cell module fixing member, a solar cell module fixing structure, and a solar cell module fixing method capable of increasing the fixing strength of the solar cell module on the roof. It is what.

  In order to solve the above problems, the fixing member of the solar cell module according to the present invention is “a fixing member of the solar cell module for fixing the solar cell module having a frame body on the outer periphery on the roof”. The fixing member includes a flat plate-like first lower piece extending horizontally, a standing piece extending upward from one end of the first lower piece, and an upper end of the standing piece from the upper end. A first upper piece extending above the first lower piece, a flat plate-like second lower piece extending from the lower end of the standing piece to the opposite side of the first lower piece, and the standing piece A projecting portion projecting to the second lower piece side at a lower portion, a second upper piece extending from the upper end of the standing piece to the upper side of the second lower piece, the first lower piece and the second lower piece A plurality of leg pieces extending downward from the lower end of the leg pieces and extending along the first lower piece and the second lower piece. A flat bottom piece has, and a through hole extending through the first lower piece "is intended.

  Here, as the roof on which the solar cell module is fixed by the fixing member, it may be on the surface material of the roof such as sheet metal, slate, corrugated sheet, roof plate, and tile, or above the surface material of the roof. It is good also on the elongate crosspiece member attached.

  In addition, as fixing of the first frame body with the bolt to the first lower piece, “the first frame body has an insertion hole through which the male screw part of the bolt can pass, "Attaching and fixing a nut by screwing a nut into a male screw part that has passed through an insertion hole", "The first frame has a female screw hole to be screwed with the male screw part of the bolt, and from below the first lower piece The screw threadedly screwed male screw part into the female screw hole through the through hole "can be exemplified.

  The “leg piece” of the fixing member may be any one that extends downward from the first lower piece and the second lower piece, respectively, such as a standing piece of the first lower piece and the second lower piece. May extend downward from the end on the opposite side, or may extend downward from the middle of the first lower piece and the second lower piece.

  According to the fixing member of this configuration, with the bolt of the through hole penetrating the first lower piece in a state in which the frame of the solar cell module is fitted between the first lower piece and the first upper piece. The first lower piece and the frame can be fastened and fixed. In this state, by attaching the fixing member on the roof, the upward movement of the solar cell module can be regulated by a bolt (first lower piece), so the fixing strength of the solar cell module on the roof can be increased. The solar cell module can be made difficult to come off even in strong winds such as storms and typhoons.

  In addition, the fixing member is mounted on the roof with the second lower piece facing the ridge side with respect to the standing piece, and the frame of the solar cell module from the ridge side between the second lower piece and the second upper piece. The load of the solar cell module is received at a position close to the second lower piece of the standing piece through the protruding portion by fitting the body and making the side surface of the frame abut the protruding portion. Can do. Thereby, even if the load of the solar cell module on the building side acts on the standing piece, the standing piece is difficult to bend, so the second upper piece does not move to the eave side, and the eave side frame of the solar cell module In the body, the degree of contact with the second upper piece can be maintained, and there is no possibility that the fixing strength of the solar cell module is lowered.

  Subsequently, the fixing structure of the solar cell module according to the present invention is “a first frame in which the bottom piece of the fixing member is attached on a roof and faces the ridge side of the frame of the solar cell module. With the body inserted between the first lower piece and the first upper piece and in contact with the standing piece, the first lower piece and the first frame body are bolted through the through hole. The second frame that is fixed and faces the eaves side of the frame is fitted between the second lower piece and the second upper piece and is in contact with the protruding portion. '' Is.

  This is a solar cell module fixing structure in which a solar cell module having a frame body on the outer periphery is fixed on the roof using the fixing member. According to the fixing structure of the present configuration, the first frame on the ridge side of the solar cell module is fixed with bolts, and the fixing strength of the solar cell module on the roof can be further increased, and the solar cell module This load can be supported by the fixed member on the ridge side. Moreover, the load of the eaves side solar cell module is received by the protrusion at a position close to the second lower piece of the upright piece, and the upright piece is difficult to bend. Thereby, even if the load of the solar cell module on the building side acts on the standing piece, the second upper piece does not move to the eaves side. Therefore, there is no possibility that the fixing strength of the solar cell module is lowered.

  Next, the solar cell module fixing method according to the present invention is as follows: "The first frame body facing the ridge among the frame bodies of the solar cell module, the first lower piece of the fixing member, and the first The first lower piece and the first frame body are fixed with bolts through the through-holes in a state of being inserted between the upper piece and being in contact with the upright piece. The fixing member is attached to the first frame body between the second lower piece and the second upper piece of another fixing member attached on the roof in a state directed to the side. The second frame body facing the eaves side of the solar cell module is fitted and brought into contact with the protruding portion, and the bottom piece of the fixing member is mounted on the roof and attached.

  This is a solar cell module fixing method for fixing a solar cell module having a frame body on the outer periphery on the roof using the fixing member. According to the fixing method of this configuration, the above-described fixing structure can be constructed, and the solar cell module can be fixed on the roof in a state where the fixing strength is increased.

  As described above, as an effect of the present invention, a solar cell module fixing member, a solar cell module fixing structure, and a solar cell module fixing method capable of increasing the fixing strength of the solar cell module on the roof are provided. Can do.

It is a perspective view which shows the state which fixed the solar cell module on the roof as one Embodiment of this invention. It is side surface sectional drawing of FIG. 1 which abbreviate | omits and shows a part. (A) is a side view of the fixing member of the solar cell module which is one Embodiment of this invention, (b) is a front perspective view of (a), (c) is a rear perspective view of (a). is there. It is explanatory drawing which shows the attachment method of the solar cell module on a roof. It is explanatory drawing which shows the attachment method of the solar cell module following FIG.

  A solar cell module fixing member 10 (hereinafter simply referred to as a fixing member 10), a solar cell module fixing structure using the fixing member 10, and a solar cell module using the fixing member 10 according to an embodiment of the present invention. The fixing method will be described in detail with reference to FIGS. The fixing member 10 of this embodiment is for fixing the solar cell module 1 which has the frame 2 in the outer periphery on the roof (above the roofing material 5).

  First, the fixing member 10 of this embodiment will be described. As shown in FIG. 3, the fixing member 10 includes a flat plate-like first lower piece 11 that extends horizontally, a standing piece 12 that extends upward from one end of the first lower piece 11, A first upper piece 13 extending from the upper end of the piece 12 to the upper side of the first lower piece 11 and a flat plate-like second lower extending from the lower end of the standing piece 12 to the opposite side of the first lower piece 11. A piece 14, a projecting portion 15 projecting toward the second lower piece 14 at the lower part of the standing piece 12, a second upper piece 16 extending from the upper end of the standing piece 12 to the upper side of the second lower piece 14, A plurality of leg pieces 17 extending downward from the first lower piece 11 and the second lower piece 14 and connected to the lower ends of the leg pieces 17 and extending along the first lower piece 11 and the second lower piece 14. A flat bottom piece 18.

  The fixing member 10 has a through hole 11a that penetrates the first lower piece 11, an attachment hole 18a that penetrates the bottom piece 18, and a second position larger than the attachment hole 18a at a position immediately above the attachment hole 18a. And an insertion hole 14 a penetrating the lower piece 14.

  The fixing member 10 is obtained by cutting an aluminum alloy extrusion mold material having a constant cross-sectional shape to a length of 100 mm to 150 mm, and then cutting the through hole 11a, the mounting hole 18a, and the insertion hole 14a. .

  The first lower piece 11 has a slightly depressed upper surface in the vicinity of the standing piece 12. The upright piece 12 is bent in a state in which an intermediate portion in the vertical direction slightly bulges upward from the first lower piece 11. The first upper piece 13 is shorter than the first lower piece 11 and extends in parallel with the first lower piece 11. The first upper piece 13 is formed at a position slightly higher than the upper surface of the frame body 2 when the frame body 2 is placed on the first lower piece 11. That is, the space between the first lower piece 11 and the first upper piece 13 is formed to be slightly larger than the height of the frame body 2.

  The second lower piece 14 extends obliquely so as to be positioned upward as it moves away from the standing piece 12, then extends horizontally to the end, and extends longer than the first lower piece 11. The second lower piece 14 has the same height as the portion where the first lower piece 11 is recessed at the end on the upright piece 12 side, and the end away from the upright piece 12 is higher than the first lower piece 11. It is. The protruding portion 15 slightly protrudes from the standing piece 12 and is formed on a flat surface whose tip extends vertically.

  The upper surface of the second upper piece 16 coincides with the height of the upper surface of the first upper piece 13, and the lower surface is positioned below the lower surface of the first upper piece 13. The lower surface of the second upper piece 16 is formed at the same height as the upper surface of the frame body 2 when the frame body 2 is placed on the first lower piece 11. The second upper piece 16 has a tapered portion 16 a that is obliquely cut from the lower surface near the end portion away from the standing piece 12 to the end portion.

  The leg piece 17 extends downward from three portions of the first lower piece 11 and the second lower piece 14 in the vicinity of the standing piece 12 and the end portion of the second lower piece 14 away from the standing piece 12. ing. The bottom piece 18 connects the lower ends of the three leg pieces 17 together. The bottom piece 18 includes a pedestal 18b that bulges upward between the two leg pieces 17 on the second lower piece 14 side.

  The through-hole 11a is located at a position between the portion of the first lower piece 11 where the leg piece 17 extends and the end portion away from the standing piece 12, and in a direction extending with a constant cross-sectional shape (hereinafter referred to as extrusion). Penetrating at the center position). The mounting holes 18a penetrate through the pedestal portion 18b of the leg piece 18 at a position farther away from the standing piece 12 than the second upper piece 16, and are formed at equal intervals in the pushing direction. The insertion hole 14a is a part corresponding to each of the three attachment holes 18a in the second lower piece 14, and is formed in a square hole shape with four rounded corners. The insertion hole 14 a has an inner circumference that is larger than the head of the mounting screw 8.

  Next, the solar cell module 1 fixed on the roof by the fixing member 10 will be described. The solar cell module 1 is mainly composed of a flat plate solar cell panel 3 whose outer periphery in plan view is formed in a rectangular shape, and a frame 2 attached to each side of the solar cell panel 3. The frame 2 is attached to the first frame 2A attached to one of the long sides of the solar cell panel 3, the second frame 2B attached to the opposite long side, and the two short sides. And a third frame 2C attached to the end portions of the first frame 2A and the second frame 2B. The first frame 2A, the second frame 2B, and the third frame 2C have the same cross-sectional shape.

  As shown in FIG. 2 and the like, the frame body 2 has a frame-shaped main body portion 2a having an outer side surface extending in a straight line and an inner side surface extending in a crank shape and closed in cross section. And a holding portion 2b that extends upward continuously from the outer side surface of the main body portion 2a and then bends upward from the upper surface of the main body portion 2a; And an extending portion 2c extending in a flat plate shape. The frame 2 extends with a constant cross-sectional shape, and is formed of an aluminum alloy extrusion mold.

  Of the four frame bodies 2, the first frame body 2 </ b> A and the second frame body 2 </ b> B are formed with a through-hole 2 d that penetrates the extending portion 2 c. A plurality of through holes 2d are formed in the extending portion 2c so as to be separated in a direction along the long side of the solar cell module 1. The distance from the outer side surface of the main body 2a is the same as the distance from the standing piece 12 to the through hole 11a in the fixing member 10, and the inner diameter of the through hole 2d is the same as that of the through hole 11a. In the present embodiment, two through holes 2d are formed in advance in each of the first frame body 2A and the second frame body 2B.

  Then, the fixing method to the roof of the solar cell module 1 using said fixing member 10 is demonstrated. In the present embodiment, a flat waterproof sheet 20 made of butyl rubber is pasted on the lower surface of the bottom piece 18 of the fixing member 10 in advance.

  First, in a state where the first frame 2A of the solar cell module 1 is inserted between the first lower piece 11 and the first upper piece 13 of the fixing member 10 and brought into contact with the standing piece 12, the fixing member 10 is inserted. Is slid along the first frame body 2A so that the through hole 2d of the first frame body 2A and the through hole 11a of the first lower piece 11 are matched. Then, the male screw part 6a of the bolt 6 is passed through the through hole 11a and the through hole 2d from below, and the nut 7 is screwed and tightened to the tip of the male screw part 6a. The extending portion 2c of the first frame 2A is fastened and fixed.

  Two fixing members 10 are fixed to the first frame 2 </ b> A with the bolts 6 for one solar cell module 1. In the present embodiment, the two fixing members 10 are fixed in the vicinity of both ends in the longitudinal direction of the first frame 2A. Moreover, the fixing member 10 is fixed to each 1st frame 2A with respect to all the solar cell modules 1 fixed on a roof.

  Before the fixing member 10 is mounted on the roof, the first lower piece 11 and the first frame 2A are fixed by the bolt 6 so that the first lower piece 11 is fixed by the bolt 6 after the fixing member 10 is mounted on the roof. Compared to the case where the first frame 2A is fixed, the space below the first lower piece 11 for passing the bolt 6 through the through hole 11a and the through hole 2d can be sufficiently secured. The fixing operation between the first lower piece 11 and the first frame 2A using the bolt 6 is easy. The fixing operation of the fixing member 10 to the first frame 2A with the bolt 6 is desirably performed before the solar cell module 1 is carried on the roof.

  Next, a plurality of (three in the example of FIG. 1) fixing members 10 and the second lower piece 14 are installed at the position closest to the eaves side of the portion for fixing the solar cell module 1 on the inclined roof. In a state of being directed to the side, it is placed on the roofing material 5 in a straight line in the lateral direction of the roof (see FIG. 4A). Thereafter, each fixing member 10 is mounted on the roof with the mounting screw 8 through the insertion hole 14a, the mounting hole 18a, and the waterproof sheet 20 from above. The fixing members 10 are attached on the roof at the same interval as the two fixing members 10 attached to the first frame 2 </ b> A, and are also attached to the central position between the two fixing members 10.

  In this embodiment, since the roofing material 5 is comprised with the sheet metal, there are few restrictions with respect to an attachment position, and the fixing member 10 can be attached to arbitrary positions.

  Then, the second frame 2B of the solar cell module 1 is fitted between the second lower piece 14 and the second upper piece 16 from the roof ridge side with respect to the fixing member 10 mounted on the roof. At the same time, the side surface of the second frame 2 </ b> B is brought into contact with the projecting portion 15, and the fixing member 10 attached to the first frame 2 </ b> A is placed on the roof material 5. At this time, since the taper portion 16a is formed in the second upper piece 16, the second frame 2B is inserted and fitted in a state where the solar cell module 1 is inclined with respect to the upper surface of the roof. (See FIG. 4 (b)).

  In this embodiment, since the 2nd lower piece 14 inclines, when the solar cell module 1 which inserted the 2nd frame 2B in the inclined state is made into the state parallel to the inclination of a roof, the 2nd frame 2B The extending portion 2c is elastically deformed. Thus, the second frame 2B is tightly fitted between the second lower piece 14 and the second upper piece 16 by the elastic force of the extending portion 2c. In the present embodiment, the extending portion 2c is elastically deformed, but the second lower piece 14 may be elastically deformed, and both the second lower piece 14 and the extending portion 2c are elastic. It may be deformed.

  Before the fixing member 10 attached to the first frame 2A is placed on the roofing material 5, the first of the new fixing member 10 is placed at the center position between the two fixing members 10 in the first frame 2A. The state between the lower piece 11 and the first upper piece 13 is made to be in a state where the upright piece 12 is brought into contact therewith. This fixing member 10 is not fixed to the first frame 2 </ b> A by the bolt 6. After that, the three fixing members 10 are placed on the roofing material 5 and mounted on the roof with the mounting screws 8 through the mounting holes 18a (see FIG. 4C).

  Subsequently, the second frame 2B of the solar cell module 1 on the next ridge side is fitted between the second lower piece 14 and the second upper piece 16 of the fixing member 10 attached earlier, and the same as described above. By repeating the work, the first frame 2A side of the solar cell module 1 on the ridge side is fixed on the roof by the fixing member 10 (see FIG. 5). Thereby, while being able to fix the solar cell module 1 on a roof, the fixing structure where the solar cell module 1 is fixed on the roof can be constructed | assembled.

  Thus, according to the present embodiment, the first lower piece 11 and the first frame 2A are fastened and fixed by the bolt 6 through the through hole 11a penetrating the first lower piece 11, and the solar cell module 1 can be regulated by the bolt 6 (first lower piece 11), so that the fixing strength of the solar cell module 1 on the roof can be further increased, even in strong winds such as storms and typhoons. The solar cell module 1 can be made difficult to come off.

  Further, since the first lower piece 11 and the first frame 2A are fastened and fixed by the bolt 6, the relative movement between the fixing member 10 and the first frame 2A in the longitudinal direction of the first frame 2A is restricted. can do. Therefore, the movement of the roof of the solar cell module 1 in the lateral direction can be restricted by the fixing member 10.

  Further, with the second lower piece 14 facing the ridge side with respect to the standing piece 12, the fixing member 10 is mounted on the roof, and is fitted between the second lower piece 14 and the second upper piece 16 from the ridge side. Since the side surface of the combined second frame 2B is brought into contact with the protruding portion 15, the load of the solar cell module 1 is received at a position close to the second lower piece 14 through the protruding portion 15 and the standing piece 12. be able to. Thereby, even if the load of the solar cell module 1 on the ridge side acts on the standing piece 12, the standing piece 12 becomes difficult to bend. Therefore, the second upper piece 16 does not move to the eaves side. In the second frame 2B on the eaves side, the degree of engagement with the second upper piece 16 can be maintained, and there is no possibility that the fixing strength of the solar cell module 1 is reduced.

  Furthermore, the first frame 2A fixed to the first lower piece 11 with the bolt 6 is mounted on the inclined roof in a state facing the roof ridge side, and is fixed by the fixing member 10 via the bolt 6. The solar cell module 1 is fixed so as to be pulled up from the building side. Thereby, it becomes possible to support the load of the solar cell module 1 by both the fixing member 10 on the ridge side and the fixing member 10 on the eaves side, and the load of the solar cell module 1 is evenly distributed to the roof. Can do. Therefore, the load of the plurality of solar cell modules 1 arranged in the inclination direction of the roof can be distributed to the roof side substantially uniformly in each fixing member 10, and the load on the roof due to the uneven load can be reduced. .

  In addition, on the first frame body 2A side on the ridge side of the solar cell module 1, the first lower piece 11 and the first frame body 2A are fixed by the bolt 6 before the fixing member 10 is mounted on the roof. Thereby, compared with the case where it fixes with the volt | bolt 6 after attaching the fixing member 10 on a roof, the space below the 1st lower piece 11 for letting the volt | bolt 6 pass to the through-hole 11a and the through-hole 2d Can be ensured sufficiently, and the first lower piece 11 and the first frame 2A can be easily fixed by the bolt 6.

  Further, since the space between the first lower piece 11 and the first upper piece 13 is formed slightly larger than the height of the frame body 2, the first frame body 2 </ b> A is replaced with the first lower piece 11 and the first upper piece. 13 and can be easily inserted, and the fixing work of the fixing member 10 to the first frame 2A can be easily performed.

  Furthermore, in this embodiment, in the first frame 2A and the second frame 2B of the solar cell module 1, it corresponds to the center position between the two fixing members 10 fixed to the first frame 2A by the bolts 6. The fixing member 10 that is not fixed to the frame body 2 by the bolt 6 is arranged at the site that is fixed and fixed on the roof. Thereby, in the solar cell module 1, the vertical bending of the center position of the first frame 2A and the second frame 2B can be prevented, and the fixing strength of the solar cell module 1 can be further increased. Moreover, fluttering of the solar cell module 1 due to strong wind can be suppressed.

  Moreover, since the solar cell modules 1 are fixed in order from the eaves side to the ridge side with respect to the inclined roof, the work of fixing the plurality of solar cell modules 1 on the roof is easily performed. be able to. Moreover, since an operator will work in the state which faced the eaves side on the roof, it can work, confirming the downward direction (eave side), and can improve the safety | security of fixing work.

  Although the present invention has been described with reference to the preferred embodiments, the present invention is not limited to the above-described embodiments, and various improvements and design changes can be made without departing from the scope of the present invention. It is.

  For example, in the above-described embodiment, the example in which the leg piece 17 does not extend downward from the end portion (tip portion) of the fixing member 10 away from the standing piece 12 of the first lower piece 11 is shown. However, the leg piece 17 may extend downward from the tip of the first lower piece 11.

  Further, in the above embodiment, the example in which the fixing member 10 on the most eave side is the second lower piece 14 directed toward the ridge side with respect to the standing piece 12 is shown, but the embodiment is not limited to this. The first lower piece 11 and the second frame 2 </ b> B may be fixed by the bolt 6 while the first fixing piece 10 is directed toward the ridge with respect to the standing piece 12.

  Furthermore, in the above-described embodiment, the example in which the fixing member 10 is attached to the roofing material 5 is shown on the roof. However, the present invention is not limited to this, and the fixing member 10 is fixed to the elongated beam member attached to the roof. The solar cell module 1 may be fixed on the roof by attaching the member 10.

DESCRIPTION OF SYMBOLS 1 Solar cell module 2 Frame 2A 1st frame 2B 2nd frame 3 Solar cell panel 5 Roof material 6 Bolt 7 Nut 8 Mounting screw 10 Fixing member 11 First lower piece 11a Through-hole 12 Standing piece 13 First upper piece 14 2nd lower piece 14a Insertion hole 15 Protrusion part 16 2nd upper piece 16a Taper part 17 Leg piece 18 Bottom piece 18a Mounting hole 18b Base part 20 Waterproof sheet

Claims (3)

A solar cell module fixing member for fixing a solar cell module having a frame body on the outer periphery on the roof,
The fixing member is
A first flat bottom plate extending horizontally;
A standing piece extending upward from one end of the first lower piece;
A first upper piece extending above the first lower piece from the upper end of the standing piece;
A plate-like second lower piece extending from the lower end of the upright piece to the opposite side of the first lower piece;
A projecting portion projecting toward the second lower piece side at the lower portion of the standing piece;
A second upper piece extending from the upper end of the upright piece to above the second lower piece;
A plurality of leg pieces extending downward from the first lower piece and the second lower piece;
A flat bottom piece connected to the lower end of the leg piece and extending along the first lower piece and the second lower piece;
A fixing member for a solar cell module, comprising: a through hole penetrating the first lower piece. A solar cell module fixing structure in which a solar cell module having a frame body on the outer periphery using the fixing member according to claim 1 is fixed on a roof,
The bottom piece of the fixing member is mounted on the roof;
In the state where the first frame facing the ridge among the frames of the solar cell module is inserted between the first lower piece and the first upper piece and is in contact with the standing piece, The first lower piece and the first frame body are fixed by bolts through the through hole,
A solar cell, wherein a second frame facing the eaves side of the frame is fitted between the second lower piece and the second upper piece and is in contact with the protruding portion. Module fixing structure. A solar cell module fixing method for fixing a solar cell module having a frame body on the outer periphery on the roof using the fixing member according to claim 1,
The first frame body facing the ridge side of the frame body of the solar cell module is inserted between the first lower piece and the first upper piece of the fixing member to contact the standing piece In this state, the first lower piece and the first frame body are fixed by a bolt through the through hole,
Fixing the first frame body between the second lower piece and the second upper piece of another fixing member mounted on the roof with the second lower piece directed toward the building The second frame body facing the eaves side of the solar cell module to which the member is attached is fitted and brought into contact with the protruding portion, and the bottom piece of the fixing member is placed on the roof. A method for fixing a solar cell module, wherein the solar cell module is fixed.

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