JP2011208383A - Eaves edge cover for solar battery panel - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an eaves edge cover of a new structure, capable of lessening the force of water of rainwater flowing from the top face of a solar battery panel to an eaves edge.SOLUTION: The eaves edge cover 10 for a solar battery includes: a fitting piece 11 fitted to the top of the solar battery panel 2 substantially in the parallel state; a descending step part 13 connected to the eaves side end part 11a of the fitting piece 11; and a cover piece 12 extending downward from an eaves side end part 13a of the descending step part 13.

Description

  The present invention relates to an improvement of an eaves edge cover of a solar cell panel that is attached to an eaves side end portion of a solar cell panel and covers and hides a side end surface of the eave side end portion.

  When installing a solar cell panel on a roof such as a house, it is common to attach a decorative eaves edge cover to the eaves side end of the solar cell panel (see, for example, Patent Document 1). According to such an eaves end cover, since the side end surface of the eaves side end part of the solar cell panel is covered and concealed, the beauty of the eaves end side is not impaired.

JP 07-153984 A

  By the way, in order to obtain more electric energy from the solar cell panel, it is necessary to increase the installation area. Therefore, it is generally performed to install a solar cell panel having a larger area by bringing the eaves side end of the solar cell panel closer to the eaves.

  However, when the solar panel is installed as close to the eaves in this way, the panel surface is a mirror surface, so the momentum of the rainwater flowing on the upper surface of the panel becomes stronger on the downstream side and exceeds the eaves cover from the upper surface of the panel. Many of the rainwater that flowed down over the eaves.

  The present invention has been proposed in view of such circumstances, and an object of the present invention is to provide an eaves edge cover having a new structure that can weaken the water flow of rainwater flowing from the upper surface of the solar cell panel to the eaves edge.

  In order to achieve the above object, the eaves edge cover of the solar cell panel according to claim 1 is attached to an eave side end portion of the solar cell panel and covers the side end surface of the eave side end portion. In the cover, an attachment piece attached in a state substantially parallel to the upper surface of the solar cell panel, a descent step portion provided continuously with an eave side edge portion of the attachment piece, and an eave side edge of the descent step portion And a cover piece extending downward from the portion.

  The eaves edge cover of the solar cell panel according to claim 2 has a drain hole formed in the descending step portion.

  The eaves edge cover of the solar cell panel according to claim 3 has a plurality of drain holes formed in a staggered pattern.

  The eaves tip cover of the solar cell panel according to claim 4 is formed of a curved plate body in which a cover piece bulges toward the eaves side.

  The eaves edge cover of the solar cell panel according to claim 5 has a structure in which when the attachment piece is attached to the solar cell panel, the cover piece is inclined down toward the inner side of the solar cell panel.

  According to the eaves tip cover of the solar cell panel according to claim 1, since the descent step portion is connected to the eave side edge of the mounting piece, the rain water flowing from the upper surface of the solar cell panel is dropped. To weaken the momentum and allow it to flow into the cover piece.

  According to the eaves tip cover of the solar cell panel according to claim 2, since the drainage hole is formed in the descending step portion, it is possible to drop most of the rainwater flowing into the descending step portion downward from the drainage hole, Furthermore, the water can be weakened.

  According to the eaves tip cover of the solar cell panel according to claim 3, since the drain holes are formed in a plurality of rows in a staggered manner, most of the flowing rainwater can be reliably drained.

  According to the eaves tip cover of the solar cell panel according to claim 4, since the cover piece made of the curved plate body bulges toward the eaves side, even when the water force cannot be sufficiently weakened by the descending step portion, It does not jump out from the eaves-side end of the mounting piece, and rainwater can be caused to fall on the roof surface along the cover piece. Moreover, since the cover piece has a shape that curves and bulges to the eave side, the appearance can be improved.

  According to the eaves tip cover of the solar cell panel according to claim 5, since the cover piece is inclined down to the inner side of the solar cell panel, rain water falling from the drain hole of the descending step portion is reflected on the back surface of the cover piece. Therefore, the momentum of rainwater that falls from the drainage hole can be weakened.

It is a perspective view which shows the example of installation of the eaves edge cover of the solar cell panel of this invention, and the solar cell panel which is the attachment object. (A) is a fragmentary perspective view which shows one Embodiment of the same eaves edge cover, (b) is sectional drawing. (A), (b) is a perspective view which shows the attachment procedure of the eaves-edge cover. It is sectional drawing which shows the attachment state of the eaves edge cover. (A)-(c) is sectional drawing which shows the other example of the eaves edge cover of the solar cell panel of this invention, (d) is sectional drawing which shows the use condition of the eaves edge cover shown in (c). It is sectional drawing of the use condition of the eaves end cover which shows the further another example of the eaves end cover of the solar cell panel of this invention.

  Embodiments of the present invention will be described below with reference to the accompanying drawings.

  FIG. 1 is a perspective view showing an installation example of an eaves edge cover (hereinafter, abbreviated as an eaves edge cover) of a solar cell panel of the present invention and a solar cell panel that is an attachment target thereof. Fig.2 (a) is a fragmentary perspective view which shows one Embodiment of the eaves edge cover, FIG.2 (b) is sectional drawing. FIGS. 3A and 3B are perspective views showing a procedure for attaching the eaves tip cover. FIG. 4 is a cross-sectional view showing an attached state of the eaves tip cover.

  The solar cell panel 2 shown in FIG. 1 is installed through a mount 3 disposed on a roof surface 1 on which tiles and slate are spread. In addition, the code | symbol 8 in FIG. 1 is the eaves wall installed in an eaves edge.

  The solar cell panel 2 is composed of a module body in which a plurality of panel bodies are assembled in a rectangular shape, and is installed on the roof surface 1 in units of the module body. An eaves edge cover 10 is attached to the edge of the eaves side end 2a of the module body, and a frame body 4 is attached to the other three sides.

  The eaves edge cover 10 includes an attachment piece 11 attached in a state substantially parallel to the upper surface of the solar cell panel 2, a descending step portion 13 connected to the eaves side edge portion 11a of the attachment piece 11, and a descending step. The cover 13 has a structure that extends downward from the eaves side edge 13 a of the portion 13. As shown in the drawing, the lowering step portion 13 is composed of a lowering portion 13b and a step portion 13c, and has a shape in which the corners of the attachment piece 11 and the cover piece 12 are recessed. Further, as shown in FIG. 4, the stepped portion 13 c of the descending stepped portion 13 is preferably formed so as to be inclined upward toward the cover piece 12 while being attached to the solar cell panel 2.

  Further, a plurality of drain holes 13d are formed in the step 13c of the descending step 13 as shown in FIG. In FIG. 1, the lowering step portion 13 is not shown, and in FIG. 3, the drainage hole 13d formed in the lowering step portion 13 is not shown.

  Each of the plurality of drain holes 13d is preferably formed in a staggered manner in a plurality of rows (two rows in the illustrated example) along the longitudinal direction of the eaves edge cover 10 as individual holes are round holes. By providing the drainage holes 13d in this way, rainwater that flows from the solar cell panel 2 side (building side) over the eaves cover 10 can be drained. The drain holes 13d do not have to be arranged in the longitudinal direction, but are desirably formed in a staggered manner over the entire length in the longitudinal direction in order to enhance the drainage effect. In order to further enhance the drainage effect, long holes that do not decrease in strength may be arranged.

  Further, the attachment piece 11 is provided with an attachment long hole 11 c for fixing to the mount 3 with the bolt 6.

  On the other hand, the cover piece 12 extends downward from the eaves side edge portion 13a of the step portion 13c of the descending step portion 13, has a shape inclined with an obtuse angle with the mounting piece 11, and the eaves tip cover 10 In the state which attached to the solar cell panel 2, as shown in FIG. 4, it becomes the dimension and shape which can cover up the side end surface of the eaves side edge part 2a.

  Further, on the back side of the cover piece 12, a reinforcing piece 12a for reinforcement, and a fitting portion 12b fitted to an attachment aid 15 (see FIG. 3) for attaching and fixing the eaves edge cover 10 to the gantry 3; Are integrally formed. In addition, although the reinforcement piece 12a shown in this example is not an essential element for the eaves edge cover 10, it is desirable to prepare for preventing damage such as breakage. Moreover, it cannot be overemphasized that the thing of various shapes can be employ | adopted about the fitting part 12b by the attachment structure to the mount frame 3 which is attachment object.

  The eaves edge cover 10 is fixed to the gantry 3 according to the procedure shown in FIGS.

  That is, first, a plurality of mounts 3 made of C-shaped channel-shaped hollow bar-like bodies are arranged and fixed on the roof, and a long eaves-end fixing bracket 5 is attached to the eaves side front end portion of the mounts 3. The eaves-end fixing bracket 5 includes a mounting table 5a on which the mounting piece 11 of the eaves-end cover 10 can be placed. The mounting table 5a is inserted through the hollow portion 3a of the mounting table 3 with a bolt 6 via a groove 3b. Hole 5aa is opened.

  Further, a positioning piece 5b (a part corresponding to the back leg of the eaves and the backrest connected to the top of the eaves) is formed at the rear part of the eaves-end fixing bracket 5. Further, at the upper end of the positioning piece 5b, the mounting table 5a and Is formed with a fitting piece 5c bent in the opposite direction, and the eaves-side end portion 2a of the solar cell panel 2 can be accommodated in a space formed by the fitting piece 5c, the positioning piece 5b, and the mount 3. It has become. Further, the positioning piece 5b can determine the installation position of the eaves edge cover 10.

  A side-view Z-shaped attachment aid 15 is attached in advance to the back side of the attachment elongated hole 11 c of the attachment piece 11 of the eaves cover 10. With the attachment aid 15, the eaves cover 10 is attached to the gantry 3. It can be installed without shifting between the mounting table 5a of the eaves-end fixing bracket 5 fixed to the front end portion of the gantry 3 and the mounting table 5a.

  After placing the eaves cover 10 in the correct position, the nut 7 is screwed onto the bolt 6 protruding upward through the insertion hole 5aa of the eaves fixing bracket 5 and the attachment long hole 11c of the attachment piece 11 of the eaves cover 10. Thus, the frame 3 is fixed.

  The eaves cover 10 fixed in this way is arranged in a state in which the mounting piece 11 is substantially parallel to the upper surface of the solar cell panel 2, and the lower end of the cover piece 12 is in the state of being close to the roof surface 1, and as a result The end surface of the front end portion of the gantry 3 and the side end surface of the eaves side end portion 2a of the solar cell panel 2 installed on the gantry 3 are covered.

  As described above, the eaves tip cover 10 shown in the present embodiment has the descending step portion 13 in which a plurality of drain holes 13d are formed continuously provided from the eave side edge portion 11a of the attachment piece 11, so that the ridge side Further, the rainwater flowing along the upper surface of the solar cell panel 2 is weakened while flowing through the descending step portion 13. Moreover, since the step part 13c of the descent | fall step part 13 is ascending and rising to the eaves side, a water force is further weakened. The rainwater collected in the stepped portion 13c of the descending stepped portion 13 from the upstream in this way falls downward from a drain hole 13d formed in the stepped portion 13c (see FIG. 4. The white arrow in the figure indicates the flow of rainwater. ing).

  Since the eaves end cover 10 has such a structure, the rainwater flowing to the eaves end cover 10 does not jump over the cover piece 12, and most of the rainwater is from the drain hole 13 d of the descending step portion 13. Since it flows down, the rainwater flow that reaches the downstream side of the roof surface 1 is sufficiently weakened. Thus, by using the eaves tip cover 10 provided with the descending step portion 13, it is possible to prevent the rainwater flowing on the upper surface of the solar cell panel 2 from jumping over the eaves 8 (see FIG. 1).

  Moreover, since the eaves edge cover 10 shown in this embodiment makes the angle which the attachment piece 11 and the cover piece 12 make an obtuse angle, and makes the cover piece 12 inclining and descending with respect to the roof surface 1, the descent | fall step part 13 Even if the water is not weakened sufficiently by the rain and the rainwater tries to jump forward from the eaves side edge portion 11a of the mounting piece 11, the rainwater that has jumped out can be received on the inclined surface before falling onto the roof surface 1. And thereby weaken the water.

  In particular, as in the eaves tip cover 10 shown in FIGS. 5 (a) and 5 (b), when the cover piece 12 is formed of a curved plate body and bulges toward the eave side, the descent step portion 13 has sufficient water flow. Even when it is not weakened, it can be slowly dropped onto the roof surface 1 while being transmitted to the curved and bulged plate surface of the cover piece 12 without causing the running water to jump out. Further, according to the cover piece 12 having such a curved shape, the curved surface can give a soft impression when viewed from the front side of the eaves side. 5A, only the cover piece 12 has a curved shape, and the eaves cover 10 of FIG. 5B has a curved shape in which the attachment piece 11 and the cover piece 12 are integrated.

  Moreover, the eaves edge cover 10 shown in FIG.5 (c) is formed so that the angle which the attachment piece 11 and the cover piece 12 make may become an acute angle, and as shown in FIG.5 (d), the cover piece 12 is a solar cell panel. 2, the rain water flowing from the drain hole 13d of the descending step portion 13 can be received by the back surface of the cover piece 12, and as a result, the water force can be further weakened.

  In the three examples shown in FIG. 5, the structure of the back surface of the eaves edge cover 10 and the mounting reinforcement 15 (see FIG. 4 and the like) are omitted. Further, in FIG. 5, the same components as those of the eaves edge cover 10 shown in FIG.

  FIG. 6 is a sectional view of the eaves end cover in use, showing still another example of the eaves end cover of the solar cell panel of the present invention.

  In the eaves edge cover 10 of this example, a plurality of steps (two steps in the example) are continuously formed with a lowering step portion 13 including a lowering portion 13b and a step portion 13c. This can further weaken the momentum of rainwater. In addition, as shown in FIG. 6, it is desirable that the respective step portions 13c and 13c are inclined upward toward the eaves side and further include a plurality of drain holes 13d and 13d.

DESCRIPTION OF SYMBOLS 1 Roof surface 2 Solar cell panel 2a Eave side edge 10 Solar cell eaves edge cover 11 Attachment piece 11a Eave side edge part 11c Elongation hole 12 Cover piece 12a Reinforcement piece 12b Fitting part 13 Lowering step part 13a Eave side edge Edge 13b Descent part 13c Step part 13d Drain hole

Claims (5)

In the eaves end cover of the solar cell panel that is attached to the eaves side end of the solar cell panel and covers the side end surface of the eaves side end,
From the mounting piece attached in a state substantially parallel to the upper surface of the solar cell panel, a descending step portion connected to the edge side of the eave side of the mounting piece, and an eave side edge portion of the descending step portion An eaves edge cover for a solar cell panel, comprising a cover piece extending downward. In claim 1,
A solar cell panel eaves end cover in which a drainage hole is formed in the descending step portion. In claim 1 or 2,
The eaves cover of a solar cell panel, wherein the drain holes are formed in a plurality of rows in a staggered manner. In any one of Claims 1-3,
The cover piece is an eaves tip cover of a solar cell panel, which is composed of a curved plate bulging toward the eaves side. In any one of Claims 1-3,
The said cover piece is a eaves edge cover of a solar cell panel which becomes a structure which inclines and descends to the inner side of this solar cell panel, when the said attachment piece is attached to the said solar cell panel.

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