JP2011202489A - Structure for mounting solar cell panel - Google Patents

Abstract

PROBLEM TO BE SOLVED: To facilitate securing of a space that can avoid, even if a solar panel bends due to the load of accumulated snow, the back surface of a solar cell from being brought into contact with a frame.SOLUTION: The structure for mounting a solar cell panel 1 is configured such that when a frame body 3 to which a side edge 2a of the solar cell panel body 2 is fitted, is to be placed on the top surface 6a of the frame 6 disposed on a sheathing roof board 5 on a roof 4, a height adjustment spacer 7 is interposed between the top surface 6a of the frame 6 and the lower surface 3a of the frame body 3, so that the lower and upper surfaces of the spacer can serve, respectively, as a mounting surface 7a to be placed on the top surface 6a of the frame 6, and as a supporting surface 7b for supporting the lower surface 3a of the frame body 3.

Description

  The present invention relates to a solar cell panel mounting structure, and more particularly to a technology for mounting a frame of a solar cell panel that receives sunlight and converts its energy into electric power on a mount.

  A solar cell panel that receives sunlight by a solar cell and converts solar energy into electric power is known (see, for example, Patent Document 1).

  In this type of solar cell panel 1, as shown in FIG. 9A, the solar cell panel main body 2 and a frame body 3 to which a side edge of the solar cell panel main body 2 is fitted are provided. The frame 3 is fixed on the top plate 6 of the roof 4 by means of the gantry fixture 12, and the frame 3 is fixed to the upper surface of the gantry 6 using a fixing bracket 15. Generally, the solar cell panel 1 is structurally designed to withstand wind loads, snow loads, and the like. For example, the allowable deflection amount of the 210 W solar battery panel 1 is 37 mm, the deflection amount when a load of 3,600 Pa (3,000 Pa × safety factor 1.2) is applied, 36 mm, and the space from the solar cell back surface 2b to the mount 6 The distance D is designed to be about 27 mm.

JP 2000-297509 A

  However, conventionally, when snow has accumulated on the surface of the solar cell panel 1, as shown in FIG. 9 (b), a snow load is applied from the front surface side to the back surface, and the center side of the solar cell panel 1 is bent downward, There is a possibility that the back surface 2b of the solar cell may come into contact with the mount 6. Since the solar cell back surface 2b does not have such a high strength, it is desired to avoid contact with the gantry 6.

  The present invention has been made in view of the above circumstances, and an object of the present invention is to provide a solar cell panel that can avoid contact between the back surface of the solar cell and the gantry even when the solar cell panel is bent by a snow load. It is in providing a mounting structure.

  In order to solve the above-mentioned problem, the first invention is to mount a frame body that fits a side edge portion of a solar cell panel body on the upper surface of a base installed on a roof base plate, The solar cell panel mounting structure for mounting the frame body to the gantry using a frame, wherein the lower surface portion is placed on the upper surface of the gantry between the upper surface of the gantry and the lower surface of the frame body It is characterized in that a spacer for adjusting the height, which becomes a mounting surface and whose upper surface portion serves as a supporting surface for supporting the lower surface of the frame body, is inserted.

  According to a second invention, in the first invention, a pair of the spacers respectively disposed on the lower surface side of the frame body of the adjacent solar cell panel main body and a connecting portion that connects the pair of spacers to each other are integrated. It is characterized by comprising a structured spacer block.

  A third invention is characterized in that, in the first invention or the second invention, a wiring housing portion for housing a wiring cable for taking out electric power from the solar cell is integrally provided on the side surface portion side of the spacer. And

  According to a fourth invention, in the third invention, a wiring holding member for holding the wiring cable is provided in the wiring housing portion.

  In the present invention, by adjusting the height of the frame body with the spacer, even when the solar cell panel is bent due to a snow load, a space that can avoid contact between the back surface of the solar cell and the mount can be easily secured. Is.

An example of the solar cell panel attached using the spacer for height adjustment of embodiment of this invention is shown, (a) shows the state which the solar cell panel bent by the snow load, (b) is (a). It is an enlarged view of the principal part. The spacer block provided with a spacer same as the above is shown, (a) is a plan view, (b) is a side view, and (c) is a front view. It is explanatory drawing of the fixed state of the spacer and frame with respect to a mount frame same as the above. It is explanatory drawing at the time of using a spacer same as the above for the height adjustment of the frame on the ridge side. It is explanatory drawing at the time of using a spacer same as the above for the height adjustment of the eaves side frame. It is another embodiment, (a) is a plan view when a fin-like wiring storage portion is added to the spacer block, (b) is a side view. It is other embodiment, (a) is a top view at the time of adding an L-shaped wiring accommodating part to a spacer block, (b) is a side view. It is other embodiment, (a) is a top view at the time of adding a U-shaped wiring accommodating part to a spacer block, (b) is a side view. (A) shows the attachment state of the conventional solar cell panel, (b) is a figure which shows the state which the solar cell panel bent by the snow load, and contacted the mount frame.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

  FIG. 1A is a cross-sectional view showing a state in which the solar cell panel 1 attached using the height adjusting spacer 7 of the present embodiment is bent by a snow load, and FIG. FIG.

  The solar cell panel 1 includes a solar cell panel main body 2 and a frame 3 that fits the side edge 2a of the solar cell panel main body 2.

  The solar battery panel body 2 has a structure in which a plurality of solar battery cells are connected in series and sandwiched between tempered glass, an encapsulating resin and a weather resistant film.

  The frame body 3 is provided with a fitting portion 3c in which the side edge 2a of the solar cell panel body 2 is fitted at the upper end thereof, and a receiving recess 3b that is pressed by a presser fitting 11 described later at the lower end thereof. It protrudes in the direction opposite to the opening direction of 3c.

  The gantry 6 on which the solar cell panel 1 is installed is formed in a long rail shape made of a metal material. The gantry 6 is attached to a gantry fixture 12 fixed on the base plate 5 of the roof 4. A plurality of gantry fixtures 12 are provided at intervals in the lateral direction D (a direction orthogonal to the eave building direction B), and a plurality of gantry 6 extend in the eaves ridge direction B with respect to each gantry fixture 12. Installed in a state. A roof tile 13 is provided on the base plate 5 where the solar cell panel 1 is not provided.

  The frame body 3 of the solar cell panel 1 is fixed to the gantry 6 using a fixing bracket 15. As shown in FIG. 3, the fixing bracket 15 includes a root bolt 16 having a screw portion 16 a protruding above the mount 6 in a state where the head 16 b is locked to the mount 6, and a screw portion 16 a of the root bolt 16. The presser fitting 11 inserted into the receiving recess 3b (FIG. 1 (b)) provided at the lower end portion of the frame body 3 is inserted, and the nut 17 is used to tighten the presser fitting 11 from above.

  A height adjusting spacer 7 is interposed between the upper surface 6 a of the gantry 6 and the lower surface 3 a of the frame 3. The spacer 7 is made of a metal material and has a piece shape slightly longer than the width of the gantry 6. The spacer 7 is formed in a hollow rectangular shape, the lower surface is a mounting surface 7 a that is mounted on the upper surface 6 a of the gantry 6, and the upper surface is a support surface 7 b that supports the lower surface 3 a of the frame 3. It functions as a height adjustment leg of the frame 3.

  As shown in FIG. 2, the spacer 7 of this example includes a spacer block A in which a pair of spacers 7 and 7 parallel to each other are integrated via a connecting portion 8. The pair of spacers 7 and 7 are respectively arranged on the lower surface side of the frame 3 of the adjacent solar cell panel main body 2, and the connecting portion 8 is fastened and fixed to the gantry 6 by a drill screw 14 (FIG. 3). Yes.

  Next, a construction example for fixing the frame 3 and the spacer 7 to the gantry 6 will be described. As shown in FIG. 1B, the spacer block A is placed on the upper surface 6 a of the gantry 6 extending in the eaves-ridge direction B. At this time, the connecting portion 8 is fastened and fixed to the gantry 6 with a drill screw 14 (FIG. 3) so that the pair of spacers 7 and 7 are arranged in the eaves-ridge direction B. Next, the lower surface 3a of the frame body 3 of the solar cell panel body 2 adjacent in the eave building direction B is placed on the support surface 7b of each of the pair of spacers 7 and 7. On the other hand, as shown in FIG. 3, the threaded portion 16 a of the root angle bolt 16 protrudes from the lower side of the bolt hole of the gantry 6 to the upper side, and further, the root angle bolt through hole 50 (see FIG. 2) is penetrated and protruded above the connecting portion 8. The presser fitting 11 is fitted into the threaded portion 16a from above, and the lower end portions on both sides of the presser fitting 11 are respectively engaged with the receiving recesses 3b and 3b provided on the adjacent frame bodies 3 and 3, and the nut 17 is further provided thereon. Screw in. By tightening the nut 17, the lower end portions on both sides of the presser fitting 11 bite into the receiving recesses 3 b of the adjacent frame bodies 3, 3, so that the adjacent frame bodies 3 are strongly pressed toward the support surface 7 b of the spacer 7. The adjacent frame bodies 3 can be firmly fixed so as not to move with respect to the gantry 6 at the same time.

  FIG. 4 shows an example in which the height of the frame 3 located on the ridge side is adjusted by the spacer block A. In this case, the support surface 7b of one spacer 7 located on the ridge side is the ridge of the presser fitting 11. It is the receiving surface which receives the lower end part of the side.

  FIG. 5 shows an example in which the frame 3 positioned on the eave side is adjusted in height by the spacer block A, and the support surface 7b of one spacer 7 positioned on the eave side is the lower end on the eave side of the presser fitting 11. It is a receiving surface that receives the department. Reference numeral 20 in the figure denotes an end cover that covers the end of the gantry 6.

  Thus, by inserting the height adjusting spacer 7 having the above structure between the upper surface 6a of the gantry 6 and the lower surface 3a of the frame 3, the height of the frame 3 can be easily adjusted. The distance of the space from the back surface 2b to the gantry 6 is increased. As a result, as shown in FIG. 1A, even when the center side of the solar cell panel 1 is bent by a snow load, a space is secured by the spacer 7 so that the back surface 2b of the solar cell does not come into contact with the mount 6 and is damaged. Therefore, the contact between the solar cell back surface 2b and the gantry 6 can be avoided. Thereby, it is possible to prevent damage to the solar battery back surface 2b which is not strong in strength, cracking of the solar battery cell, and the like, and it can be used with confidence even in heavy snow areas.

  Moreover, since it is only necessary to insert a new spacer 7 between the existing gantry 6 and the existing frame 3 at the time of construction, the existing gantry 6 and the frame 3 can be used as they are without changing the design, and at a low cost. That's it. In addition, by using the spacer block A in which the pair of spacers 7 and 7 are connected and integrated, the number of parts of the spacer 7 can be reduced, and the construction can be saved and the cost can be further reduced.

  Other embodiments of the present invention are shown in FIGS. 6 to 8, a wiring housing portion 10 is integrally provided on the side surface portion 7c side of one spacer 7 of the spacer block A, and a wiring cable 9 for taking out electric power from the solar cell is provided in the wiring housing portion. 10 can be stored. The wiring cable 9 is electrically connected to a connector provided on the frame body 3 side, and is led to the indoor power supply side through the wiring housing portion 10. Here, the cross-sectional shape of the wiring storage portion 10 is either a fin shape as shown in FIG. 6, an L shape opened upward as shown in FIG. 7, or a U shape opened sideways as shown in FIG. 8. Also good. The wiring storage portion 10 extends over the entire length of the spacer 7 so that the wiring cable 9 can be accommodated and stored well. In the figure, 50 is a root bolt through hole.

  Further, a folding groove 51 is formed in the central portion of the connecting portion 8 of the spacer block A over the entire length of the connecting portion 8, and the connecting portion 8 can be separated at the central position along the folding groove 51. . Thereby, a pair of spacers 7 and 7 can be separated separately. Further, since the folding groove 51 is formed across the center of the root angle bolt through hole 50, after separating along the folding groove 51, the root angle bolt through hole 50 remains in a semicircular shape, and the root angle bolt 16 and the connecting portion 8. Can be prevented from interfering with.

  Further, as shown in FIG. 6, the wiring housing portion 10 can be provided with an insulation lock insertion hole 60 for holding the wiring cable 9. An insulation lock (not shown) serving as a wiring holding member is inserted into the insulation lock insertion hole 60 and is fastened in a state of being wound around the wiring cable 9, thereby easily holding the wiring cable 9 with respect to the wiring storage unit 10. be able to. Moreover, the insulation lock can be used to prevent the wiring cable 9 from being violated or disconnected in a strong wind, for example.

DESCRIPTION OF SYMBOLS 1 Solar cell panel 2 Solar cell panel body 2b Solar cell back surface 3 Frame body 3a Bottom surface of frame body 4 Roof 5 Base plate 6 Mounting frame 6a Upper surface of mounting frame 7 Spacer 7a Mounting surface 7b Support surface 7c Side surface portion 8 Connection portion 9 Wiring cable 10 Wiring storage part A Spacer block

Claims (4)

A solar cell in which a frame body that fits a side edge portion of a solar cell panel body is placed on an upper surface of a mount installed on a roof base plate, and the frame is attached to the mount using a fixing bracket In the panel mounting structure, the lower surface portion is a mounting surface placed on the upper surface of the gantry and the upper surface portion supports the lower surface of the frame body between the upper surface of the gantry and the lower surface of the frame body. A mounting structure for a solar cell panel, wherein a spacer for height adjustment serving as a support surface is inserted.   It is characterized by comprising a spacer block in which a pair of the spacers respectively disposed on the lower surface side of the frame body of the adjacent solar cell panel main body and a connecting portion for connecting the pair of spacers to each other are integrated. The solar cell panel mounting structure according to claim 1.   The solar cell panel mounting structure according to claim 1 or 2, wherein a wiring housing portion for housing a wiring cable for taking out electric power from the solar cell is integrally provided on a side surface portion side of the spacer.   The solar cell panel mounting structure according to claim 3, wherein a wiring holding member that holds the wiring cable is provided in the wiring storage portion.

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