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JP6806443B2 - Drainer - Google Patents
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JP6806443B2 - Drainer - Google Patents

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JP6806443B2
JP6806443B2 JP2016004911A JP2016004911A JP6806443B2 JP 6806443 B2 JP6806443 B2 JP 6806443B2 JP 2016004911 A JP2016004911 A JP 2016004911A JP 2016004911 A JP2016004911 A JP 2016004911A JP 6806443 B2 JP6806443 B2 JP 6806443B2
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water receiving
solar cell
receiving portion
cell module
structure according
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JP2017125343A (en
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顕 清水
顕 清水
鈴木 秀雄
秀雄 鈴木
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Solar Frontier KK
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Solar Frontier KK
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    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02BCLIMATE CHANGE MITIGATION TECHNOLOGIES RELATED TO BUILDINGS, e.g. HOUSING, HOUSE APPLIANCES OR RELATED END-USER APPLICATIONS
    • Y02B10/00Integration of renewable energy sources in buildings
    • Y02B10/10Photovoltaic [PV]
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02EREDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
    • Y02E10/00Energy generation through renewable energy sources
    • Y02E10/50Photovoltaic [PV] energy

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  • Roof Covering Using Slabs Or Stiff Sheets (AREA)

Description

本発明は、太陽電池モジュールと共に施工される水切り板に関する。 The present invention relates to a drainer plate constructed together with a solar cell module.

一般に太陽電池モジュールは、例えば特許文献1に示されるように、屋根の上に縦横に複数並べて設置される。 Generally, as shown in Patent Document 1, for example, a plurality of solar cell modules are installed vertically and horizontally on a roof.

特開2013−231308号公報Japanese Unexamined Patent Publication No. 2013-231308

図7のように、屋根300に複数の太陽電池モジュール120を隣接して搭載した太陽電池モジュールアレイ100では、雨水はアレイ100の傾斜に沿って流れ落ちる。しかし、雨水は初めモジュール120の表面に沿って流下するが、途中でモジュール120のフレーム124に妨げられるため、図中に点線矢印で示すように、水下側に行くに従ってモジュール120同士が隣接する部分(縦目地部)に多く集まってくる。集まった雨水は縦目地から屋根300の上に流れ落ち、屋根材を伝わって軒下へと流れていくが、この部分には他の部分より多くの雨水が流れるため、水垢等の汚れ(水垂れ痕)も他の部分より多く付着する。このように、縦目地の水下延長方向(すなわち軒先方向)にある屋根材302とその他の部分にある屋根材304とで、水垂れ痕の濃淡に差が生じるため、水垂れ痕のムラとなって建物の美観を大きく損ねてしまう。 As shown in FIG. 7, in the solar cell module array 100 in which a plurality of solar cell modules 120 are mounted adjacent to the roof 300, rainwater flows down along the inclination of the array 100. However, rainwater initially flows down along the surface of the module 120, but is obstructed by the frame 124 of the module 120 on the way. Therefore, as shown by the dotted arrow in the figure, the modules 120 are adjacent to each other as they go down the water. Many gather in the part (vertical joint). The collected rainwater flows down from the vertical joints onto the roof 300 and flows down the eaves along the roofing material, but since more rainwater flows in this part than in other parts, stains such as scale (water dripping marks) ) Also adheres more than other parts. In this way, there is a difference in the shade of the water dripping marks between the roofing material 302 in the water extension direction (that is, the eaves tip direction) of the vertical joint and the roofing material 304 in the other part. It greatly spoils the aesthetics of the building.

本発明は、上記の点に鑑みてなされたものであり、その目的の1つは、太陽電池モジュールアレイが設置された屋根材における水垂れ痕のムラを抑制することにある。 The present invention has been made in view of the above points, and one of the objects thereof is to suppress unevenness of water dripping marks in a roofing material in which a solar cell module array is installed.

上述した課題を解決するために、本発明の一態様は、太陽電池モジュールと共に施工される水切り板であって、板材の一部に、前記太陽電池モジュールから流下した水を受け止めるための水受け部を備え、前記板材の他の一部に、前記板材の表面を伝わる前記水受け部からの水流を散水させるための複数の貫通孔を有した散水部を備え、前記水受け部は、太陽電池モジュールアレイの縦目地の軒側端部下方に配置される、水切り板である。 In order to solve the above-mentioned problems, one aspect of the present invention is a drain plate constructed together with the solar cell module, and a water receiving portion for receiving water flowing down from the solar cell module on a part of the plate material. The other part of the plate material is provided with a sprinkling portion having a plurality of through holes for sprinkling water flow from the water receiving portion propagating on the surface of the plate material, and the water receiving portion is a solar cell. It is a drain plate placed below the eaves side end of the vertical joint of the module array.

また、本発明の他の一態様は、上記一態様において、前記散水部の複数の貫通孔は、前記太陽電池モジュールアレイの横方向に並んで設けられている水切り板である。 Further, in another aspect of the present invention, in the above aspect, the plurality of through holes of the watering portion are draining plates provided side by side in the solar cell module array.

また、本発明の他の一態様は、上記一態様において、前記水受け部は、貫通孔を有さない板面である水切り板である。 Further, in another aspect of the present invention, in the above aspect, the water receiving portion is a draining plate which is a plate surface having no through hole.

また、本発明の他の一態様は、上記一態様において、前記板材は、軒側に向かって凸の湾曲面で構成されている水切り板である。 Further, in another aspect of the present invention, in the above aspect, the plate material is a draining plate formed of a curved surface that is convex toward the eaves side.

また、本発明の他の一態様は、上記一態様において、前記散水部は、前記水受け部に対して前記太陽電池モジュールアレイの横方向に位置している水切り板である。 Further, in another aspect of the present invention, in the above aspect, the watering portion is a draining plate located laterally to the water receiving portion of the solar cell module array.

また、本発明の他の一態様は、上記一態様において、前記水受け部の両側に前記散水部が設けられている水切り板である。 Further, another aspect of the present invention is a draining plate in which the watering portions are provided on both sides of the water receiving portion in the above aspect.

また、本発明の他の一態様は、上記一態様において、前記水受け部の両側に対称に前記散水部が設けられている水切り板である。 Further, another aspect of the present invention is a draining plate in which the watering portions are symmetrically provided on both sides of the water receiving portion in the above aspect.

また、本発明の他の一態様は、上記一態様において、前記貫通孔は、前記水受け部に近いほど開口面積が小さく、前記水受け部から遠いほど開口面積が大きい水切り板である。 In another aspect of the present invention, in the above aspect, the through hole is a draining plate having a smaller opening area as it is closer to the water receiving portion and a larger opening area as it is farther from the water receiving portion.

また、本発明の他の一態様は、上記一態様において、前記貫通孔は、前記水受け部に近いほど疎らに、前記水受け部から遠いほど密に配置されている水切り板である。 Further, another aspect of the present invention is a draining plate in which the through holes are arranged sparsely as they are closer to the water receiving portion and densely as they are farther from the water receiving portion.

また、本発明の他の一態様は、上記一態様において、前記板材は、前記水受け部から前記散水部の方向へ水が流れるように傾斜を有する水切り板である。 Further, in another aspect of the present invention, in the above aspect, the plate material is a draining plate having an inclination so that water flows from the water receiving portion to the sprinkling portion.

また、本発明の他の一態様は、上記一態様において、前記水受け部に突起が設けられている水切り板である。 Further, another aspect of the present invention is a draining plate provided with a protrusion on the water receiving portion in the above aspect.

本発明によれば、太陽電池モジュールアレイが設置された屋根材における水垂れ痕のムラを抑制することができる。 According to the present invention, unevenness of water dripping marks in the roofing material on which the solar cell module array is installed can be suppressed.

屋根300の上に設置された太陽電池モジュールアレイ100と本発明の一実施形態に係る水切り板200を示す。The solar cell module array 100 installed on the roof 300 and the drainer plate 200 according to the embodiment of the present invention are shown. 水切り板200を太陽電池モジュールアレイ100側から見た俯瞰図と、側面図を示す。A bird's-eye view and a side view of the drainer plate 200 as viewed from the solar cell module array 100 side are shown. 屋根300に設置された太陽電池モジュールアレイ100と水切り板200を側面から見た様子を示す。A side view of the solar cell module array 100 and the drainer plate 200 installed on the roof 300 is shown. 屋根300に設置された太陽電池モジュールアレイ100と水切り板200を側面から見た様子を示す。A side view of the solar cell module array 100 and the drainer plate 200 installed on the roof 300 is shown. 本発明の実施形態に係る水切り板200における散水部230のバリエーションを示す。The variation of the sprinkling part 230 in the draining plate 200 which concerns on embodiment of this invention is shown. 本発明の実施形態に係る水切り板200の形状に関するバリエーションを示す。A variation on the shape of the drainer plate 200 according to the embodiment of the present invention is shown. 屋根300の上に設置された従来の太陽電池モジュールアレイ100を示す。The conventional solar cell module array 100 installed on the roof 300 is shown.

以下、図面を参照しながら本発明の実施形態について詳しく説明する。 Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

図1は、屋根300の上に設置された太陽電池モジュールアレイ100と本発明の一実施形態に係る水切り板200を示す。説明の便宜上、図中に示されるようにXYZ軸を定める。Y軸は、屋根300の傾斜に平行な方向であり、+Y方向が屋根の低い側、即ち軒側を示し、−Y方向が屋根の高い側を示す。X軸は、屋根300の傾斜に垂直な方向である。Z軸は、鉛直方向、又は屋根300の面に垂直な方向である。 FIG. 1 shows a solar cell module array 100 installed on a roof 300 and a drainer plate 200 according to an embodiment of the present invention. For convenience of explanation, the XYZ axes are defined as shown in the figure. The Y-axis is a direction parallel to the inclination of the roof 300, and the + Y direction indicates the lower side of the roof, that is, the eaves side, and the −Y direction indicates the higher side of the roof. The X-axis is the direction perpendicular to the slope of the roof 300. The Z axis is the vertical direction or the direction perpendicular to the plane of the roof 300.

太陽電池モジュールアレイ100は、個々の太陽電池モジュール120をX方向及びY方向にそれぞれ複数並べて配置したものである。太陽電池モジュール120は、太陽電池パネル122とフレーム124を含む。太陽電池パネル122は、例えば、CIS系、CIGS系、単結晶シリコン系、薄膜シリコン系、有機半導体系など、様々な構造のものを適用することができる。フレーム124は、太陽電池パネル122の矩形の外周を取り囲んで太陽電池パネル122を保持する、例えばアルミ等の金属からなる枠材である。図1ではX、Y方向にそれぞれ3つ、合計9個の太陽電池モジュール120が並べられているが、太陽電池モジュール120の数はこれより多くてもよいし、少なくてもよい。 In the solar cell module array 100, a plurality of individual solar cell modules 120 are arranged side by side in the X direction and the Y direction, respectively. The solar cell module 120 includes a solar cell panel 122 and a frame 124. As the solar cell panel 122, for example, those having various structures such as CIS type, CIGS type, single crystal silicon type, thin film silicon type, and organic semiconductor type can be applied. The frame 124 is a frame material made of metal such as aluminum, which surrounds the rectangular outer circumference of the solar cell panel 122 and holds the solar cell panel 122. In FIG. 1, a total of nine solar cell modules 120 are arranged, three in each of the X and Y directions, but the number of solar cell modules 120 may be larger or smaller than this.

太陽電池モジュール120は、フレーム124を介して屋根300に取り付けられている。屋根300の表面には、太陽電池モジュール120を固定するための縦桟(架台)310が備え付けられている。縦桟310は、最上段(屋根300の一番高い側)の太陽電池モジュール120の上端位置から最下段(屋根300の一番低い側)の太陽電池モジュール120の下端位置までにわたって、Y方向に延在している。図1の例では、Y方向に並んだ3つの太陽電池モジュール120を、2本の縦桟310が支える構造となっている。各太陽電池モジュール120のフレーム124と縦桟310には、互いに対応する箇所に不図示の取付部がそれぞれ設けられており、両者の取付部を例えばボルトとナットで締結することによって、太陽電池モジュール120が縦桟310に固定される。 The solar cell module 120 is attached to the roof 300 via the frame 124. A vertical rail (mount) 310 for fixing the solar cell module 120 is provided on the surface of the roof 300. The vertical rail 310 extends in the Y direction from the upper end position of the solar cell module 120 on the uppermost stage (the highest side of the roof 300) to the lower end position of the solar cell module 120 on the lowermost stage (the lowest side of the roof 300). It is postponed. In the example of FIG. 1, the three solar cell modules 120 arranged in the Y direction are supported by two vertical rails 310. The frame 124 and the vertical rail 310 of each solar cell module 120 are provided with mounting portions (not shown) corresponding to each other, and the solar cell modules are fastened by fastening the mounting portions with bolts and nuts, for example. 120 is fixed to the vertical rail 310.

最下段の太陽電池モジュール120の更に軒側(+Y側)には、本発明の一実施形態に係る水切り板200が設置される。水切り板200は、金属や樹脂からなる板材に複数の貫通孔205を有して構成されている。板材は、横方向(X軸方向)に長い形状を有する。貫通孔205は、板材の長手方向であるX軸方向に沿って複数並んで設けられているが、太陽電池モジュール120の繋ぎ目(縦目地)に対向する部分210には、貫通孔が設けられていない。この部分210は、後述するように太陽電池モジュールアレイ100の表面から流れ落ちる水を受け止める水受け部210として働く。貫通孔205は更に、板材の短手方向に複数列設けられてもよい。図1では2列の貫通孔205が描かれている。このように縦横に網目状に配列された複数の貫通孔205は、後述するように、水切り板200の板面上を伝わって流れる水を屋根300の側へ分散して流下させる散水部230を形成する。 A drainer plate 200 according to an embodiment of the present invention is installed on the eaves side (+ Y side) of the lowermost solar cell module 120. The drainer plate 200 is configured to have a plurality of through holes 205 in a plate material made of metal or resin. The plate material has a long shape in the lateral direction (X-axis direction). A plurality of through holes 205 are provided side by side along the X-axis direction, which is the longitudinal direction of the plate material, but through holes are provided in the portion 210 facing the joint (vertical joint) of the solar cell module 120. Not. As will be described later, this portion 210 functions as a water receiving portion 210 that receives water flowing down from the surface of the solar cell module array 100. Further, a plurality of rows of through holes 205 may be provided in the lateral direction of the plate material. In FIG. 1, two rows of through holes 205 are drawn. As will be described later, the plurality of through holes 205 arranged vertically and horizontally in a mesh pattern provide a sprinkling portion 230 that disperses and flows down the water flowing on the plate surface of the draining plate 200 toward the roof 300. Form.

水切り板200の板材は、軒側に向かって凸となるように湾曲した形状を有する。そのため、水切り板200の太陽電池モジュールアレイ100と対向する面には、長手方向(X軸方向)に連続して延びる窪み260が形作られている。図1に示される水切り板200では、板材は滑らかに湾曲して、窪み260の内面は滑らかな曲面となっている。あるいはまた、一枚の平らな板材を鈍角に数回折り曲げたものを水切り板200の板材とし、窪み260の内面が、長手方向にわたって平坦ないくつかの平面からなる構成としてもよい。 The plate material of the drainer plate 200 has a shape curved so as to be convex toward the eaves side. Therefore, a recess 260 extending continuously in the longitudinal direction (X-axis direction) is formed on the surface of the drainer plate 200 facing the solar cell module array 100. In the draining plate 200 shown in FIG. 1, the plate material is smoothly curved, and the inner surface of the recess 260 is a smooth curved surface. Alternatively, one flat plate material may be bent at an obtuse angle several times to form the plate material of the draining plate 200, and the inner surface of the recess 260 may be composed of several flat surfaces flat in the longitudinal direction.

図2は、水切り板200を太陽電池モジュールアレイ100側から見た俯瞰図と、側面図を示す。上述したように、水受け部210は、貫通孔を有しない板面である。水切り板200は、この水受け部210が太陽電池モジュールアレイ100の縦目地の軒側下方にくるように位置合わせされて、取付部270を介して(例えばボルトとナットによって)縦桟310に取付固定される。水受け部210の横(水切り板200の長手方向側)には散水部230が設けられ、散水部230には網目状に複数の貫通孔205が形成されている。水切り板200は、太陽電池モジュールアレイ100の側に窪み260を有するように、軒側が凸に湾曲している。 FIG. 2 shows a bird's-eye view and a side view of the drainer plate 200 as viewed from the solar cell module array 100 side. As described above, the water receiving portion 210 is a plate surface having no through hole. The drainer plate 200 is aligned so that the water receiving portion 210 is below the eaves side of the vertical joint of the solar cell module array 100, and is attached to the vertical rail 310 via the attachment portion 270 (for example, by bolts and nuts). It is fixed. A water sprinkling portion 230 is provided on the side of the water receiving portion 210 (on the longitudinal direction side of the draining plate 200), and a plurality of through holes 205 are formed in the water sprinkling portion 230 in a mesh pattern. The drainer plate 200 has a convexly curved eaves side so as to have a recess 260 on the side of the solar cell module array 100.

図3は、屋根300に設置された太陽電池モジュールアレイ100と水切り板200を側面から見た様子を示す。屋根300の表面には固定台座320が設けられ、この固定台座320に縦桟310が備え付けられている。上述したように、太陽電池モジュール120(フレーム124)は縦桟310に対して固定されている。また縦桟310の軒側(+Y方向側)の先端には、水切り板200が取付部270(図3では不図示)を介して取り付けられている。なお、図4に示されるように、縦桟310の軒側の端部と水切り板200を覆い隠すために、化粧用のスタートカバー(軒先カバーとも称する)400を水切り板200の上から縦桟310に取り付けた構成としてもよい。また、水切り板200は、縦桟310ではなく、太陽電池モジュール120やスタートカバー400に取り付けた構成としてもよい。 FIG. 3 shows a side view of the solar cell module array 100 and the drainer plate 200 installed on the roof 300. A fixed pedestal 320 is provided on the surface of the roof 300, and the fixed pedestal 320 is provided with a vertical rail 310. As described above, the solar cell module 120 (frame 124) is fixed to the vertical rail 310. A drainer plate 200 is attached to the tip of the vertical rail 310 on the eaves side (+ Y direction side) via an attachment portion 270 (not shown in FIG. 3). As shown in FIG. 4, in order to cover the eaves-side end of the vertical rail 310 and the drainer plate 200, a cosmetic start cover (also referred to as an eaves front cover) 400 is placed on the drainer plate 200 from above the vertical rail. It may be configured to be attached to 310. Further, the drainer plate 200 may be attached to the solar cell module 120 or the start cover 400 instead of the vertical rail 310.

以上のように構成された水切り板200を太陽電池モジュールアレイ100の軒側に設置することによる作用を説明する。図1に示されるように、太陽電池モジュールアレイ100上に降った雨は、太陽電池モジュールアレイ100の表面を屋根300の傾斜に沿って下方へ流れ(矢印R1)、横目地を伝って(矢印R2)縦目地へ集まってくる(矢印R3)。こうして、図3の点線矢印に示されるように、最下段の太陽電池モジュール120間の縦目地からは、集められた多量の雨水が流れ落ちて、水切り板200の水受け部210に当たる。水切り板200は横方向(X軸方向)に延びた窪み260を有しているので、水受け部210に当たった雨水は、図1に示されるように、窪み260の延在方向(X軸方向)に沿って散水部230へ導かれ(矢印R4)、散水部230の網目状の複数の貫通孔205を通して屋根300の上へと流下する(矢印R5)。このように、太陽電池モジュールアレイ100の縦目地から集中的に流れ落ちた雨水は、水切り板200の散水部230によって広範囲に屋根300上へ散水される。その結果、雨水は屋根300上を拡散して流れるので、水垂れ痕のムラを抑制することができる。 The operation of installing the drainer plate 200 configured as described above on the eaves side of the solar cell module array 100 will be described. As shown in FIG. 1, the rain falling on the solar cell module array 100 flows downward along the inclination of the roof 300 (arrow R1) on the surface of the solar cell module array 100 and travels along the horizontal joint (arrow). R2) Gather at vertical joints (arrow R3). In this way, as shown by the dotted arrow in FIG. 3, a large amount of collected rainwater flows down from the vertical joints between the solar cell modules 120 at the bottom and hits the water receiving portion 210 of the draining plate 200. Since the drainer plate 200 has a recess 260 extending in the lateral direction (X-axis direction), rainwater that hits the water receiving portion 210 has a recess 260 extending in the extending direction (X-axis direction) as shown in FIG. It is guided to the sprinkler 230 along the direction (direction) (arrow R4) and flows down onto the roof 300 through the plurality of mesh-like through holes 205 of the sprinkler 230 (arrow R5). In this way, the rainwater that has intensively flowed down from the vertical joints of the solar cell module array 100 is widely sprinkled onto the roof 300 by the sprinkling portion 230 of the draining plate 200. As a result, rainwater diffuses and flows on the roof 300, so that unevenness of water dripping marks can be suppressed.

図5は、本発明の実施形態に係る水切り板200における散水部230のバリエーションを示す。図5(A)において、散水部230Aは、同サイズで等間隔に並んだ複数の貫通孔205を有する。図5(B)では、散水部230Bの複数の貫通孔205は等間隔に配置されているが、各貫通孔205のサイズ(開口面積)は、水受け部210に近いほど小さく、水受け部210から遠いほど大きくなっている。また図5(C)では、散水部230Cの複数の貫通孔205は全て同じサイズを有しているが、水受け部210に近いほど間隔が疎らに、水受け部210から遠いほど間隔が密に配置されている。散水部230B及び230Cのいずれにおいても、水受け部210に近く水量の多い場所では雨水が水切り板200を通り抜けにくく、水受け部210から遠く水量の少ない場所では雨水が水切り板200を通り抜けやすい。したがって、図5(B)及び(C)の各水切り板200は、それぞれの散水部230B、230Cから屋根300の上へ雨水をより均一に散水することができ、それにより、効果的に水垂れ痕のムラを抑制することができる。 FIG. 5 shows a variation of the sprinkler portion 230 in the drainer plate 200 according to the embodiment of the present invention. In FIG. 5A, the sprinkler 230A has a plurality of through holes 205 of the same size and arranged at equal intervals. In FIG. 5B, the plurality of through holes 205 of the sprinkler portion 230B are arranged at equal intervals, but the size (opening area) of each through hole 205 is smaller as it is closer to the water receiving portion 210, and the water receiving portion The farther it is from 210, the larger it becomes. Further, in FIG. 5C, the plurality of through holes 205 of the watering portion 230C all have the same size, but the closer to the water receiving portion 210, the more sparsely spaced, and the farther from the water receiving portion 210, the denser the spacing. Is located in. In both the sprinkler portions 230B and 230C, rainwater is difficult to pass through the draining plate 200 in a place close to the water receiving portion 210 and has a large amount of water, and rainwater is likely to pass through the draining plate 200 in a place far from the water receiving portion 210 and having a small amount of water. Therefore, each of the draining plates 200 of FIGS. 5 (B) and 5 (C) can more uniformly sprinkle rainwater from the sprinkling portions 230B and 230C onto the roof 300, thereby effectively dripping. It is possible to suppress unevenness of marks.

図6は、本発明の実施形態に係る水切り板200の形状に関するバリエーションを示す図であり、太陽電池モジュールアレイ100側から水切り板200を見た正面図を表している。但し、斜線部は図2中に示したAA線の位置における断面を表す。図6(A)の水切り板200Aは、図1に示されるように太陽電池モジュール120が横に3つ並んだ幅に対応した長手方向の長さを有する。図6(B)、(C)、(D)の各水切り板200B、200C、200Dは、水切り板200Aのほぼ半分の長手方向の長さを有し、それぞれ太陽電池モジュールアレイ100の軒側に2つ横に並べて設置される。図6(A)、(B)において、水切り板200A及び200Bの窪み260の底面260aは、長手方向の全体にわたって平坦な面である。図6(C)の水切り板200Cでは、窪み260の底面260aが、水受け部210から散水部230へ向かって傾斜した形状に構成されている。そのため、太陽電池モジュールアレイ100の縦目地から水受け部210へ落下する雨水(太い点線矢印)を、円滑に散水部230の方向へ流すことができる。また図6(D)の水切り板200Dでは、窪み260の底面260aは平坦面であるが、水受け部210に山型の突起265が設けられている。この構成においても同様に、突起265の存在によって雨水を円滑に散水部230の方向へ流すことができる。 FIG. 6 is a diagram showing variations regarding the shape of the drainer plate 200 according to the embodiment of the present invention, and shows a front view of the drainer plate 200 as viewed from the solar cell module array 100 side. However, the shaded area represents the cross section at the position of the AA line shown in FIG. As shown in FIG. 1, the drainer plate 200A of FIG. 6A has a length in the longitudinal direction corresponding to the width in which three solar cell modules 120 are arranged side by side. The draining plates 200B, 200C, and 200D of FIGS. 6 (B), (C), and (D) have approximately half the length in the longitudinal direction of the draining plates 200A, and are located on the eaves side of the solar cell module array 100, respectively. Two are installed side by side. In FIGS. 6A and 6B, the bottom surface 260a of the recess 260 of the drainer plates 200A and 200B is a flat surface over the entire longitudinal direction. In the drainer plate 200C of FIG. 6C, the bottom surface 260a of the recess 260 is configured to be inclined from the water receiving portion 210 toward the sprinkling portion 230. Therefore, rainwater (thick dotted arrow) falling from the vertical joint of the solar cell module array 100 to the water receiving portion 210 can be smoothly flowed in the direction of the sprinkling portion 230. Further, in the drainer plate 200D of FIG. 6D, the bottom surface 260a of the recess 260 is a flat surface, but the water receiving portion 210 is provided with a mountain-shaped protrusion 265. Similarly, in this configuration, the presence of the protrusion 265 allows rainwater to flow smoothly in the direction of the sprinkler portion 230.

以上、本発明の実施形態を説明したが、本発明はこれに限定されず、その要旨を逸脱しない範囲内において様々な変更が可能である。 Although the embodiments of the present invention have been described above, the present invention is not limited to this, and various modifications can be made without departing from the gist thereof.

例えば、上述した実施形態の水切り板200のように、水受け部には貫通孔が無い方が好ましいが、水受け部に貫通孔が設けられていても構わない。そのような構成であっても、水受け部に当たった雨水は散水部へ導かれ、散水部の貫通孔から流下するため、水切り板が無い場合に比べて水垂れ痕のムラを抑制することができる。 For example, it is preferable that the water receiving portion has no through hole as in the draining plate 200 of the above-described embodiment, but the water receiving portion may be provided with a through hole. Even with such a configuration, rainwater that hits the water receiving part is guided to the sprinkling part and flows down from the through hole of the sprinkling part, so unevenness of the water dripping mark can be suppressed as compared with the case where there is no draining plate. Can be done.

100 太陽電池モジュールアレイ
120 太陽電池モジュール
122 太陽電池パネル
124 フレーム
200 水切り板
205 貫通孔
210 水受け部
230 散水部
260 窪み
265 突起
270 取付部
300 屋根
310 縦桟
320 固定台座
400 スタートカバー
100 Solar cell module array 120 Solar cell module 122 Solar cell panel 124 Frame 200 Drain plate 205 Through hole 210 Water receiving part 230 Sprinkling part 260 Depression 265 Protrusion 270 Mounting part 300 Roof 310 Vertical rail 320 Fixed pedestal 400 Start cover

Claims (11)

複数の太陽電池モジュールからなる太陽電池モジュールアレイと、前記太陽電池モジュールアレイと共に施工される水切り板と、を備える水切り構造であって、
前記水切り板は、
板材の一部に、前記太陽電池モジュールアレイから流下した水を受け止めるための水受け部を備え、
前記板材の他の一部に、前記板材の表面を伝わる前記水受け部からの水流を散水させるための複数の貫通孔を有した散水部を備え、
前記板材のさらに他の一部に、被取付け部材に取り付けられる取付部を備え、
前記水受け部と前記散水部は、前記取付部よりも下方に位置しており、
前記水受け部は、前記太陽電池モジュールアレイの縦目地の軒側端部において、前記太陽電池モジュールアレイよりも低い位置に配置される、
水切り構造
A drainage structure including a solar cell module array composed of a plurality of solar cell modules and a drainage plate installed together with the solar cell module array .
The drainer plate
A part of the plate material is provided with a water receiving portion for receiving the water flowing down from the solar cell module array .
The other part of the plate material is provided with a water sprinkling portion having a plurality of through holes for sprinkling water flow from the water receiving portion propagating on the surface of the plate material.
Still another part of the plate material is provided with a mounting portion to be mounted on the member to be mounted.
The water receiving portion and the sprinkling portion are located below the mounting portion.
The water receiving unit, the eaves side end portion of the vertical joints of the solar cell module array, is disposed at a position lower than the solar cell module array,
Draining structure .
前記散水部の複数の貫通孔は、前記太陽電池モジュールアレイの横方向に並んで設けられている、請求項1に記載の水切り構造The draining structure according to claim 1, wherein the plurality of through holes of the watering portion are provided side by side in the solar cell module array. 前記水受け部は、貫通孔を有さない板面である、請求項1又は2に記載の水切り構造The draining structure according to claim 1 or 2, wherein the water receiving portion is a plate surface having no through hole. 前記板材は、軒側に向かって凸の湾曲面で構成されている、請求項1から3のいずれか1項に記載の水切り構造The draining structure according to any one of claims 1 to 3, wherein the plate material is formed of a curved surface that is convex toward the eaves side. 前記散水部は、前記水受け部に対して前記太陽電池モジュールアレイの横方向に位置している、請求項1から4のいずれか1項に記載の水切り構造The draining structure according to any one of claims 1 to 4, wherein the watering portion is located laterally to the water receiving portion of the solar cell module array. 前記水受け部の両側に前記散水部が設けられている、請求項5に記載の水切り構造The draining structure according to claim 5, wherein the watering portions are provided on both sides of the water receiving portion. 前記水受け部の両側に対称に前記散水部が設けられている、請求項6に記載の水切り構造The draining structure according to claim 6, wherein the watering portions are provided symmetrically on both sides of the water receiving portion. 前記貫通孔は、前記水受け部に近いほど開口面積が小さく、前記水受け部から遠いほど開口面積が大きい、請求項1から7のいずれか1項に記載の水切り構造The draining structure according to any one of claims 1 to 7, wherein the through hole has a smaller opening area as it is closer to the water receiving portion and a larger opening area as it is farther from the water receiving portion. 前記貫通孔は、前記水受け部に近いほど疎らに、前記水受け部から遠いほど密に配置されている、請求項1から8のいずれか1項に記載の水切り構造The draining structure according to any one of claims 1 to 8, wherein the through holes are arranged sparsely as they are closer to the water receiving portion and densely as they are farther from the water receiving portion. 前記板材は、前記水受け部から前記散水部の方向へ水が流れるように傾斜を有する、請求項1から9のいずれか1項に記載の水切り構造The draining structure according to any one of claims 1 to 9, wherein the plate material has an inclination so that water flows from the water receiving portion toward the sprinkling portion. 前記水受け部に突起が設けられている、請求項1から10のいずれか1項に記載の水切り構造The draining structure according to any one of claims 1 to 10, wherein a protrusion is provided on the water receiving portion.
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