JP5990721B1 - Roof mounting structure for solar cell module and snow melting module - Google Patents

Abstract

[Object] To provide a snow melting module that can be manufactured at low cost and efficiently, and a snow melting module that can be installed and installed at low cost on a roof. [Configuration] A heater having substantially the same outer shape except for the width dimension in the roof flow direction with respect to the solar cell portion, the upper sealing material, the lower sealing material, the front surface protective layer, and the rear surface protective layer of the solar cell module Part, upper sealing material, lower sealing material, surface protective layer, and back surface protective layer, and is a snow melting module that is laminated in the same manner as in the solar cell module. Moreover, it is a snow melting module provided with the flame | frame (including the part for attaching itself to a roof material) which has the substantially same external shape except the width dimension of the frame of a solar cell module and a roof flow direction. [Selection] Figure 1

Description

The present invention relates to a solar cell module for melting snow on a building roof where a solar cell module is installed, and a roof mounting structure for the snow melting module.

  Conventionally, with regard to buildings constructed in heavy snow areas, etc., a solar cell module has been arranged by placing a planar heater under the solar modules (solar cell panels) installed on the roof and generating heat from the planar heater. It has been proposed to melt the snow above (see Patent Document 1).

  Further, conventionally, as shown in FIGS. 9 (a) and 9 (b), for a building constructed in a heavy snowfall region or the like, a bar heater 32 is provided in a gap between a plurality of solar cell modules 31 installed on a roof. It has also been proposed to melt the snow on the gap between the solar cell modules 31 by using the rod heaters 32, thereby promoting the snow melting and snow sliding of the entire snow on the roof (Patent Literature). 2).

Utility Model Registration No. 3090961 JP 2004-278270 A

  However, when the planar heater is disposed below the plurality of solar cell modules on the roof, the solar cell module deteriorates early because the heat of the planar heater directly reaches the solar cell module. However, since the heat of the planar heater is transferred to the snow through the solar cell module, there is a problem that the snow melting effect is low.

  Further, when the method of installing the bar heater 32 in the gap between the plurality of solar cell modules 31 installed on the roof, the bar heater suitable for installation in the gap between the solar cell modules 31 is used. There is a problem that a great deal of cost is required for manufacturing or procuring 32, and the construction work for attaching the bar heater 32 to the gap on the roof is complicated and troublesome.

The present invention has been made paying attention to such a conventional technique, and the heat of the snow melting heater is directly applied to the solar cell module as in the conventional case, and the solar cell module is deteriorated at an early stage. To provide a solar cell module and a snow melting module roof mounting structure capable of producing a large snow melting effect by directly applying heat to the snow on the roof, and capable of being manufactured at low cost and efficiently With the goal. It is another object of the present invention to provide a roof mounting structure for a solar cell module and a snow melting module that can be efficiently installed by a worker on the roof.

According to the roof mounting structure of the solar cell module and the snow melting module according to the present invention, the solar cell module is disposed on the roof of the building, and a separate snow melting module is connected to the ridge side and / or the eaves side of the solar cell module. And a solar cell module and a snow melting module roof mounting structure, wherein the solar cell module includes a solar cell unit in which solar cells are arranged, An upper sealing material and a lower sealing material respectively disposed above and below the solar cell part, a surface protective layer disposed above the upper sealing material, and disposed below the lower sealing material. And a frame that holds the solar cell portion, the upper sealing material, the lower sealing material, the surface protective layer, and the back protective layer from the outer peripheral edge side, The snow melting module is disposed on the upper side of the heater part, the heater part having substantially the same outer shape except for the solar battery cell part of the solar battery module and the width dimension in the roof flow direction, and the upper seal of the solar battery module. An upper sealing material having substantially the same outer shape except for the width dimension of the stopper and the roof flow direction, and the lower sealing material of the solar cell module and the width of the roof flow direction, which is disposed below the heater portion A lower sealing material having substantially the same outer shape except for the dimensions, and a substantially identical outer shape, which is disposed above the upper sealing material, except for the surface protection layer of the solar cell module and the width dimension in the roof flow direction. A back surface protective layer having a substantially identical outer shape except for the width dimension in the roof flow direction and the back surface protective layer of the solar cell module, Heater part, upper side It consists of a frame that holds the stop material, the lower sealing material, the surface protective layer, and the back surface protective layer from the outer peripheral edge side, while the solar cell module and the snow melting module are separate from each other, The "internal structure consisting of each shape of the solar cell portion or heater portion, the upper sealing material, the lower sealing material, the surface protective layer, and the back surface protective layer and the stacking order of each other" The solar cell portion and the heater portion are arranged and are configured to be the same except for the width dimension in the roof flow direction.

In the roof mounting structure of the solar cell module and the snow melting module according to the present invention, the frame of the snow melting module also includes a portion for attaching itself (snow melting module) to the roof material, and the solar cell module. It may have substantially the same outer shape except for the width dimension of the frame and the roof flow direction.

As described above, in the roof mounting structure of the solar cell module and the snow melting module according to the present invention, each member constituting the snow melting module (heater portion (snow melting heater or a portion where it is disposed), upper sealing material, The outer shape of the lower sealing material, the surface protective layer, and the back surface protective layer) is changed to each member (solar cell part, upper sealing material, lower sealing material, surface protective layer) constituting the solar cell module, and It is configured to be substantially the same except for the width dimension of the back surface protective layer) and the roof flow direction (direction from the roof ridge side to the eaves bottom side), and the internal structure of the snow melting module (the order in which the respective members are stacked) Etc.) was configured to be substantially the same as the internal structure of the solar cell module. Therefore, according to the present invention, since the snow melting module can be manufactured by using the conventional solar cell module manufacturing line and manufacturing method almost as they are, a special manufacturing line or manufacturing for manufacturing the snow melting module is possible. It becomes unnecessary to prepare a method and the like, and the snow melting module can be manufactured at low cost and efficiently.

Further, according to the present invention, since the snow melting module is arranged on the ridge side and / or the eaves side of the solar cell module installed on the roof of the building, the heat from the snow melting heater is directly applied to the solar cell module. As a result, the solar cell module is not deteriorated at an early stage, and the heat from the snow melting module is directly transmitted to the snow on the roof, so that a great snow melting effect can be obtained.

Further, in the present invention, the outer shape of the frame of the snow melting module (including the component for attaching the frame to the roofing material) is substantially the same as the frame of the solar cell module except for the width dimension in the roof flow direction. When it is configured, an operator who intends to install the snow melting module on the roof material on the roof installs the conventional method and knowledge for attaching the solar cell module to the roof material. Therefore, it is not necessary to teach a new method or knowledge for installation of the snow melting module to the construction worker, and the installation of the snow melting module to the roofing material can be performed at low cost and efficiently. You can do it.

It is a figure for demonstrating a state when the snow melting module is arrange | positioned on the building roof in one Embodiment of this invention. (A) is a plan view of the snow melting module in the present embodiment (shown in a state where a colored sealing material is transmitted), (b) is a front view (the rear view is the same as this front view), (c ) Is a side view, and (d) is a bottom view (not showing a wiring cable connected to an external power source or the like). (A) is the sectional view on the A-A 'line of FIG. 2, (b) is the sectional view on the B-B' line of FIG. (A) is a plan view of the snow melting module in the present embodiment (also showing the colored upper sealing material), (b) is a plan view (showing the colored upper sealing material permeated), ( (c) is a side view, (d) is an enlarged front view (the rear view is the same as this front view), and (e) is a bottom view (wiring cable connected to an external power source etc.). Stuff). (A) is a perspective view on the plane side of the snow melting module in the present embodiment, and is a perspective view showing a state in which the colored upper sealing material is transmitted, and (b) is a perspective view on the plane side of the snow melting module according to the present embodiment. It is a figure and is a perspective view which also shows a colored upper side sealing material. (A) is a perspective view of the plane side of the snow melting module in this embodiment, (b) is the perspective view of the bottom face side. It is a schematic diagram for demonstrating the internal structure of the snow melting module in this embodiment. It is a disassembled perspective view for demonstrating the internal structure of the snow melting module in this embodiment. It is a figure which shows an example of the conventional solar cell module and snow melting apparatus which were installed on the roof.

Hereinafter, embodiments of the present invention will be described with reference to the drawings. FIG. 1 is a view for explaining a state when a snow melting module is arranged on a building roof in one embodiment of the present invention, and FIGS. 2A to 2D are plan views of the snow melting module in the present embodiment, respectively. (Shown in a state where the colored upper sealing material is permeated), front view (the rear view is the same as this front view), side view, and bottom view (showing a wiring cable connected to an external power source, etc.) 3 (a) is a cross-sectional view taken along the line AA 'of FIG. 2, FIG. 3 (b) is a cross-sectional view taken along the line BB' of FIG. 2, and FIGS. A plan view of the snow melting module in the embodiment (also showing the colored upper sealing material), a plan view (showing the colored upper sealing material permeated), a side view, and an enlarged front view ( The rear view is the same as this front view), and the bottom view (wiring cable connected to external power supply etc.) 5 (a) and 5 (b) are perspective views on the plane side of the snow melting module in this embodiment, respectively, and (a) is a perspective view showing the colored upper sealing material in a transparent state. (B) is a perspective view which also shows a colored upper side sealing material, Fig.6 (a) and (b) are the perspective views by the side of the plane of the snow melting module in this embodiment, and the perspective view by the side of a bottom, respectively.

  In FIG. 1, reference numeral 11 denotes a plurality of solar cell modules fixed to the roofing material so as to be arranged in the horizontal and vertical directions shown on the roof, 12 denotes a cover while being arranged in each gap between the solar cell modules 11, 13. Is a snow melting module fixed to the roof material so as to be arranged at the ridge side and the eaves bottom side of the plurality of solar cell modules 11, respectively.

  In the present embodiment, as shown in FIG. 1, the snow melting module 13 and the solar cell module 11 are configured to have substantially the same outer dimensions in the illustrated lateral direction (direction orthogonal to the roof flow direction). ing. Although not shown in FIG. 1, in the present embodiment, the snow melting module 13 and the solar cell module 11 have substantially the same outer dimensions in the thickness direction (direction orthogonal to the roof plane). It is configured. Although described later in detail, as described above, in the present embodiment, the snow melting module 13 is in the roof flow direction (the direction from the roof ridge side to the eaves lower side) with respect to the solar cell module 11 (including the frame). Except for the width dimension, it has a great feature in that it is configured to have substantially the same outer shape in the lateral direction and the thickness direction.

  Next, in FIGS. 2 to 6, 1 is a transparent glass plate (tempered glass plate) disposed on the upper side (the side away from the roofing material) of the snow melting module, and 2 is an upper sealing material (described later in FIG. 7). 4a), 3 is a tab (support member) that supports the sheet heater 2, and 4b is a lower side that is disposed on the lower side (roof material side) of the sheet heater 2. A lower sealing material (a sealing material for protecting the sheet heater 2), which is a sealing material made of, for example, an ionomer resin or the like, 5 is a lower side (roofing material side) of the lower sealing material 4b. Back sheet 6 made of a weather resistant film disposed on the outer periphery of the glass plate 1, the heater 2, the lower sealing material 4b, the back sheet 5 and the like in a state where they are laminated. For example, a metal frame such as aluminum A frame (frame body) 6a is a protrusion with a hook-like cross section formed at the outer lower end of the frame 6 (a portion in which a screw hole for fixing the frame 6 to the roof material is formed), 7 ( 3) is applied and filled to seal the gaps between the frame 6 and the glass plate 1, the heater 2, the lower sealing material 4b, the back sheet 5, and the like. The filler 8 (see FIG. 2 (d)) is a connector part for connecting the sheet heater 2 to an external power source or the like, and 8a (see FIGS. 4 (e) and 6 (b)) is the connector part 8. It is a wiring cable connected to.

  Next, the details of the internal structure of the snow melting module in the present embodiment will be described with reference to FIGS. The present embodiment is characterized in that the internal structure of the snow melting module is configured almost the same as the internal structure of the solar cell module installed on the roof in the vicinity of the snow melting module.

  In other words, the conventional solar cell module has a weather-resistant film backsheet, a transparent lower sealing material, and a solar cell portion (connected to each other in the lateral direction from the side close to the roof material to the direction away from the roof material. A plurality of solar cells or portions where they are arranged), a transparent upper sealing material, and a transparent glass plate are laminated in the above order.

  And the snow melting module according to the present embodiment also has substantially the same configuration in the outer shape and the internal structure, except for the solar cell module and the width dimension in the roof flow direction, that is, the roof material from the side close to the roof material. As shown in FIGS. 7 and 8, the weather-resistant film back sheet 5, the lower sealing material 4 b, the sheet heater 2, the upper sealing material 4 a, and the transparent glass plate 1, as shown in FIGS. A configuration in which the layers are stacked in the above order is employed (see also FIG. 1). The upper sealing material 4a is uncomfortable in appearance with the solar cell module 11 disposed so as to prevent the inner sheet-like heater 2 from being seen through from the surface side of the snow melting module. Is formed in a color similar to the color of the solar battery cells in the solar battery module 11, for example, black.

  In particular, as shown in FIG. 7, the internal structure of the snow melting module according to the present embodiment (the structure of each member and the order in which they are stacked, etc.) is a sheet-like heater. Except for the point that it is replaced with 2, it is basically the same as the internal structure of the solar cell module. In addition, as described above with reference to FIG. 1, the snow melting module 3 (including the frame 6) is different from the solar cell module 1 in the horizontal direction of FIG. 1 except for the width dimension in the roof flow direction (the vertical direction in the drawing). It is comprised so that it may have substantially the same outer shape in the thickness direction. Therefore, according to this embodiment, the snow melting module can be manufactured by using the conventional solar cell module manufacturing line and manufacturing method almost as they are, so that a special line or method for manufacturing the snow melting module can be used. It becomes unnecessary to prepare the snowmelt module, and the snowmelt module can be manufactured at low cost and efficiently.

  Further, in the present embodiment, a structure and a construction method for attaching and fixing the snow melting module to the roof material, a structure for attaching and fixing the solar cell module installed on the roof in the vicinity of the snow melting module to the roof material, and It is almost the same as the construction method.

  That is, a conventional solar cell module includes a back sheet made of the above weather-resistant film, a transparent lower sealing material (a sealing material for protecting solar cells), a solar cell portion, and a transparent upper sealing material. The transparent glass plates are held in a state of being laminated in the above order by a metal frame arranged so as to sandwich the outer peripheral edge thereof from the outside, and this frame is screwed to the roofing material, etc. It is attached on the roof by being fixed with. In addition, as described above with reference to FIG. 1, the snow melting module 3 (including the frame 6) is in the horizontal direction of FIG. 1 except for the width dimension in the roof flow direction (vertical direction in FIG. 1) in relation to the solar cell module 1. It is configured to have substantially the same outer shape in the direction and the thickness direction (including the outer shape of the protruding portion 6a in which screw holes for attachment to the roof material in the frame 6 are formed).

  Therefore, in this embodiment, each of the back sheet 5, the lower sealing material 4 b, the sheet heater 2, the upper sealing material 4 a, and the transparent glass plate 1 regarding the installation work of the snow melting module on the roof material. By fixing the metal frame 6 holding the outer peripheral side edge part from the outside by fixing the projecting part 6a (part where a screw hole etc. are formed) to the roofing material by screwing or the like, The installation method substantially the same as the installation construction method to the roof material in said solar cell module can be employ | adopted. Therefore, according to the present embodiment, an operator who intends to construct a snow melting module on the roof should apply the method and knowledge for attaching the conventional solar cell module to the roof material as it is. Therefore, it is not necessary for the construction worker to newly learn a special method or knowledge for installing the snow melting module, so that the snow melting module can be installed on the roof material at low cost and efficiently. become.

  In FIG. 8, 7a is between the frames 6 and between the frame 6 and each member (the back sheet 5, the lower sealing material 4b, the sheet heater 2, the upper sealing material 4a, and the transparent glass plate 1). For example, it is a filler (coating material) made of, for example, silicon resin for sealing the gap between the two. Moreover, in this Embodiment 1, although the sealing material colored in colors, such as black, is used as the upper sealing material 4a of the said sheet-like heater 2, this is the sheet-like heater 2, its wiring, etc. In the present invention, as in the solar cell module, a transparent sealing material that is not colored in black or the like is used. You may make it do.

  Although the embodiment of the present invention has been described above, the present invention is not limited to the embodiment described above, and various modifications and changes can be made. For example, in the above-described embodiment, the heater portion is a portion where one sheet-like heater 2 is disposed. However, in the present invention, the present invention is not limited to this. For example, a plurality of heating elements are connected to each other. It is good also as the part arrange | positioned and arranged in a substantially horizontal direction. Moreover, in the said embodiment, although the glass plate 1 was used as a surface protective layer arrange | positioned above the sheet-like heater part 2 and the upper side sealing material 4a, in this invention, the surface protective layer which consists of another raw material, for example, a plastic plate Etc. may be used. In the above embodiment, the back sheet 5 is used as the back surface protective layer disposed below the sheet heater 2 and the lower sealing material 4b. However, in the present invention, the protective layer made of various materials such as plastic is used. Of course, it can be used.

DESCRIPTION OF SYMBOLS 1 Glass plate 2 Sheet-like heater 3 Tab 4a Upper side sealing material 4b Lower side sealing material 5 Back sheet 6 Frame 6a Projection part 7, 7a Filler 8 Connector part 8a Wiring cable 11 Solar cell module 12 Cover 13 Snow melting module

Claims (2)

A solar cell module is arranged on a building roof , and a separate snow melting module is arranged on the ridge side and / or under the eaves side of the solar cell module and in a position close to the solar cell module. The roof mounting structure of the solar cell module and the snow melting module,
The solar cell module includes a solar cell portion in which solar cells are disposed, an upper sealing material and a lower sealing material that are respectively disposed above and below the solar cell portion, and an upper side of the upper sealing material. A surface protective layer disposed on the lower surface sealing material, a back surface protective layer disposed below the lower sealing material, the solar cell portion, the upper sealing material, the lower sealing material, the surface protective layer, and the back surface. It consists of a frame that holds the protective layer from the outer peripheral edge side ,
The snow melting module is disposed on the upper side of the heater part, the heater part having substantially the same outer shape except for the solar battery cell part of the solar battery module and the width dimension in the roof flow direction, and the upper seal of the solar battery module. An upper sealing material having substantially the same outer shape except for the width dimension of the stopper and the roof flow direction, and the lower sealing material of the solar cell module and the width of the roof flow direction, which is disposed below the heater portion A lower sealing material having substantially the same outer shape except for the dimensions, and a substantially identical outer shape, which is disposed above the upper sealing material, except for the surface protection layer of the solar cell module and the width dimension in the roof flow direction. A back surface protective layer having a substantially identical outer shape except for the width dimension in the roof flow direction and the back surface protective layer of the solar cell module, Heater part, upper side Sealing material, the lower sealing member, the surface protective layer, and comprises a back surface protective layer and a frame for holding from their outer peripheral edge portion,
While the solar cell module and the snow melting module are separate from each other, the “solar cell portion or heater portion arranged inside, the upper sealing material, the lower sealing material, the surface protective layer, and The `` internal structure consisting of each shape of the back surface protective layer and the stacking order of each other '' is configured to be the same except for the solar cell part or the heater part and the width dimension in the roof flow direction. The roof mounting structure of the solar cell module and the snow melting module . The frame of the snow melting module also includes a portion for attaching itself (snow melting module) to the roof material, and has substantially the same outer shape except for the width dimension of the solar cell module frame and the roof flow direction. The roof mounting structure of the solar cell module and the snow melting module according to claim 1, wherein