JP2012222215A - Solar cell module - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a solar cell module which improves the sealability.SOLUTION: A solar cell module includes a solar cell panel and a frame supporting the solar cell panel. The frame has an upper part, a base part connecting with the upper part so as to form an angle with the upper part, and a protruding part connecting with at least the side of the base part, which faces the solar cell panel, and obliquely extending in a direction that moves away from the upper part. An edge part of the solar cell panel is disposed in a recessed part sandwiched by the upper part and the protruding part. A sealing material fills a space between the solar cell panel and the upper part and at least a space between the solar cell panel and an upper surface of the protruding part.

Description

  The present invention relates to a solar cell module.

  Solar cells have the advantage that the amount of carbon dioxide emission per unit of power generation is small and fuel for power generation is unnecessary. Therefore, it is expected as an energy source for suppressing global warming, and among the solar cells that have been put into practical use, single-junction solar cells having a pair of pn junctions using single-crystal silicon or polycrystalline silicon are provided. It has become mainstream.

  As a technique related to such a solar cell, for example, Patent Document 1 discloses a solar cell submodule, a cover glass that covers a light receiving surface of the solar cell submodule, a space between the solar cell submodule and the cover glass, and a solar cell. The solar cell has a filler that adheres and holds the battery submodule and the cover glass, and an adsorbent that has hygroscopicity, and the adsorbent is disposed between the upper surface of the peripheral edge of the solar cell submodule and the cover glass. A battery module is disclosed. Patent Document 1 also discloses a solar cell module in which a seal material having moisture resistance is disposed between a cover glass and a substrate glass and a frame.

JP 2009-188357 A

  Since the solar cell module disclosed in Patent Document 1 uses an adsorbent having hygroscopicity, it is considered that corrosion of solar cells due to moisture can be suppressed. However, Patent Document 1 does not consider the difference in thermal expansion between the solar cell submodule and the frame even when the sealing material is arranged between the solar cell submodule and the frame. In the conventional solar cell module as disclosed in Patent Document 1, a gap is likely to be generated between the solar cell sub-module and the frame due to a temperature change in the use environment, and the sealing performance is likely to be deteriorated. When the sealing property is lowered, water easily enters, and the performance and life of the solar cell module are likely to be lowered. Therefore, it has been demanded to improve the sealing property.

  Then, this invention makes it a subject to provide the solar cell module which can improve sealing performance.

In order to solve the above problems, the present invention takes the following means. That is,
A first aspect of the present invention includes a solar cell panel and a frame that supports the solar cell panel, the frame including an upper portion and a base portion connected to the upper portion so as to have an angle with the upper portion, A convex portion connected to the side of the base facing the solar cell panel and extending obliquely in a direction away from the upper portion, and the edge of the solar cell panel is disposed in a concave portion sandwiched between the upper portion and the convex portion. The solar cell module is characterized in that a sealing material is filled between the solar cell panel and the upper portion and at least between the solar cell panel and the upper surface of the convex portion.

  In the first aspect of the present invention and the second aspect of the present invention to be described later, the “solar cell panel” includes, for example, a solar cell disposed between the substrate glass and the cover glass, Can be joined by a filler. In the first aspect of the present invention and the second aspect of the present invention to be described later, the upper portion and the base portion are connected at any point before and after bending by bending one member. The form may be sufficient and the form connected by joining a some member may be sufficient.

  In the first aspect of the present invention, the sealing material is filled between the solar cell panel and the upper portion of the frame, and at least between the solar cell panel and the upper surface of the convex portion of the frame. Here, when the temperature at which the frame expands, the amount of the sealing material filled between the solar cell panel and the upper part of the frame expands away from the upper part of the frame is determined by the convex part of the solar cell panel and the frame. The amount of the sealing material filled between the upper surface and the upper surface of the frame expands in a direction approaching the upper portion of the frame. Therefore, by adopting such a configuration, it is possible to press the solar cell panel against the sealing material disposed between the solar cell panel and the upper surface of the convex portion of the frame. By pressing the solar cell panel against the sealing material, it becomes possible to improve the sealing performance between the solar cell panel and the upper surface of the convex portion of the frame. Therefore, according to the first aspect of the present invention, the seal It is possible to provide a solar cell module capable of improving the performance.

  In the first aspect of the present invention, the sealing material is filled between the solar cell panel and the upper portion, and at least between the solar cell panel and the upper surface of the convex portion. The second sealing material is included, and the second sealing material preferably has a smaller linear expansion coefficient than the first sealing material. By adopting such a configuration, even if the temperature rises and the frame expands, the first sealing material having a linear expansion coefficient larger than that of the second sealing material expands, so that the solar cell panel becomes a convex portion of the frame It becomes easy to push to the side. Thereby, it becomes easy to press a solar cell panel against the 2nd sealing material arrange | positioned between a solar cell panel and the upper surface of the convex part of a flame | frame. By pressing the solar cell panel against the second sealing material, it becomes possible to improve the sealing performance of the second sealing material. Therefore, by adopting such a form, it becomes easy to improve the sealing performance.

  A second aspect of the present invention includes a solar cell panel and a frame that supports the solar cell panel, and the frame is inclined upward in a direction away from the upper part so as to face the upper part and the lower surface of the upper part. The edge of the solar cell panel is disposed in a recess sandwiched between the upper part and the base part, and between the solar cell panel and the upper part, and at least the surface of the base part facing the upper part It is a solar cell module characterized by being filled with a sealing material between the solar cell panel and the solar cell panel.

  In the second aspect of the present invention, the sealing material is filled between the solar cell panel and the upper portion of the frame, and at least between the surface (upper surface) of the base of the frame facing the upper portion of the frame and the solar cell panel. Is done. Here, when the temperature at which the frame expands, the amount of the sealing material filled between the solar cell panel and the upper part of the frame expands away from the upper part of the frame is the amount of the base of the solar cell panel and the frame. The amount of the sealing material filled between the upper surface and the upper surface is larger than the amount that expands toward the upper portion of the frame. Therefore, by setting it as this form, it becomes possible to press a solar cell panel against the sealing material arrange | positioned between a solar cell panel and the upper surface of the base of a flame | frame. By pressing the solar cell panel against the sealing material, it becomes possible to improve the sealing property between the solar cell panel and the upper surface of the base of the frame. Therefore, according to the second aspect of the present invention, the sealing property Can be provided.

  Moreover, in the second aspect of the present invention, the sealing material includes a first sealing material filled between the solar cell panel and the upper portion, and at least a base surface facing the upper portion and the solar cell panel. It is preferable that the 2nd sealing material with which it fills in between is contained, and a 2nd sealing material has a smaller linear expansion coefficient than a 1st sealing material. By adopting such a configuration, even if the temperature rises and the frame expands, the first sealing material having a larger linear expansion coefficient than the second sealing material expands, so that the solar cell panel is attached to the base of the frame. It becomes easy to push it to the upper surface side. Thereby, it becomes easy to press a solar cell panel against the 2nd sealing material arrange | positioned between a solar cell panel and the upper surface of the base of a flame | frame. By pressing the solar cell panel against the second sealing material, it becomes possible to improve the sealing performance of the second sealing material. Therefore, by adopting such a form, it becomes easy to improve the sealing performance.

  In the first aspect of the present invention and the second aspect of the present invention, the first sealing material preferably has a Young's modulus greater than that of the second sealing material. By setting it as this form, it becomes easy to improve a sealing performance over a long period of time.

  ADVANTAGE OF THE INVENTION According to this invention, the solar cell module which can improve sealing performance can be provided.

2 is a cross-sectional view illustrating a solar cell module 10. FIG. 3 is a cross-sectional view of the frame 2. FIG. 2 is a top view illustrating the solar cell module 10. FIG. It is sectional drawing of the flame | frame 2x. It is sectional drawing of the frame 2y.

  The present invention will be described below with reference to the drawings. In addition, the form shown below is an illustration of this invention and this invention is not limited to the form shown below.

  FIG. 1 is a cross-sectional view illustrating a solar cell module 10 of the present invention, and FIG. 2 is a cross-sectional view of a frame 2. In FIG. 1, the partial cross section of the solar cell module 10 is shown, and the upper side in FIG. 1 is the light receiving surface side. As shown in FIG. 1, the solar cell module 10 includes a solar cell panel 1 and a frame 2 that supports the edge of the solar cell panel 1. The solar cell panel 1 includes a substrate glass 1a and a cover glass 1b, a solar cell 1c formed on the surface of the substrate glass 1a, and a filler 1d that joins the substrate glass 1a and the cover glass 1b sandwiching the solar cell 1c. The compound semiconductor is used for the photoelectric conversion layer of the photovoltaic cell 1c. On the other hand, as shown in FIGS. 1 and 2, the frame 2 is connected to the upper part 2a disposed on the upper side of the cover glass 1b, and the upper part 2a and the base part 2b are connected to form an L-shape at the end of the upper part 2a. A projecting portion 2c connected to the base portion 2b facing the solar cell panel 1 and extending obliquely in a direction away from the upper portion 2a, and a recess portion 2d sandwiched between the upper portion 2a and the projecting portion 2c, have. In the solar cell module 10, the edge of the solar cell panel 1 is disposed in the recess 2d. And between the cover glass 1b and the upper part 2a, the 1st sealing material 3 (henceforth "silicone rubber 3") is the lower surface and side surface of the solar cell panel 1, and the upper surface of the convex part 2c. As well as between the side surface of the solar cell panel 1 and the base portion 2b, a second sealing material 4 (hereinafter sometimes referred to as “butyl rubber 4”) having a moisture-proof function is filled. In the solar cell panel 1, the cover glass 1b arranged on the upper side of the paper surface of FIG. 1 is larger than the substrate glass 1a so as to correspond to the shape of the convex portion 2c, and the edge of the cover glass 1b is around the substrate glass 1a. The corners of the substrate glass 1a and the cover glass 1b that are located and face the convex portion 2c are chamfered.

  FIG. 3 is a top view for explaining the solar cell module 10. As shown in FIG. 3, the solar cell panel 1 has a substantially square shape, and frames 2, 2, 2, and 2 are provided on each of the four sides of the solar cell panel 1. The frames 2, 2, 2, and 2 are screwed at the connecting portions at the four corners of the solar cell panel 1.

  As described above, in the solar cell module 10, the silicone rubber 3, 3,... Is filled between the cover glass 1b and the upper portions 2a, 2a,. Are filled with butyl rubber 4, 4,... Between the upper surfaces of 2c,... And between the side surfaces of the solar cell panel 1 and the bases 2b, 2b,. Here, the silicone rubber 3 has a larger linear expansion coefficient than the butyl rubber 4. Therefore, even when the temperature rises and the frame 2 expands when the solar cell module 10 is used, since the silicone rubber 3 expands more than the butyl rubber 4, the edge of the solar cell panel 1 is placed on the butyl rubber 4 side. Can be pressed. By maintaining the edge of the solar cell panel 1 against the butyl rubber 4 side, the pressure applied to the corner (the chamfered portion) of the solar cell panel 1 in contact with the butyl rubber 4 can be maintained. It becomes possible. Therefore, even when the temperature rises, it becomes possible to maintain the sealing performance (moisture resistance) by the butyl rubber 4 and improve the sealing performance as compared with the conventional solar cell module. By maintaining the sealing property (moisture resistance) by the butyl rubber 4, it becomes possible to prevent water from entering the solar battery cell 1 c from the outside. Therefore, according to the present invention, the performance and life are improved. The solar cell module 10 which can be made to provide can be provided.

  Further, the silicone rubber 3 has a higher resilience than the butyl rubber 4 (having a large Young's modulus). Therefore, according to the solar cell module 10, the sealing performance by the butyl rubber 4 can be improved over a long period of time. Therefore, according to the present invention, it is possible to provide the solar cell module 10 that can improve the performance over a long period of time and can extend the life.

  In the solar cell module 10, silicone rubbers 3, 3, etc. that also function as cushioning materials are arranged between the upper surface of the solar cell panel 1 and the upper parts 2 a, 2 a,. The butyl rubber 4, 4,... That also functions as a cushioning material is disposed between the portion and the convex portions 2c, 2c,... And the base portions 2b, 2b,. Therefore, even when a static load is applied to the solar cell panel 1 due to, for example, snow on the upper surface of the solar cell panel 1, it is possible to relieve stress that tends to concentrate on the edge of the solar cell panel 1. become. Therefore, since it becomes possible to suppress the damage of the solar cell panel 1 by setting it as this form, the lifetime improvement of a solar cell module can be achieved.

  Furthermore, in the solar cell module 10, the silicone rubber 3 can function as a dustproof / sandproof seal. By preventing intrusion of dust, sand, etc., damage to the glass supported by the frame 2 can be suppressed. Since it is possible to prevent a decrease in stress fracture strength by suppressing damage to glass, according to the present invention, a solar cell module 10 capable of preventing a decrease in stress fracture strength is provided. be able to.

  The solar cell module 10 having such characteristics includes, for example, a step of manufacturing the solar cell panel 1, a step of disposing a sealing material (silicone rubber 3 and butyl rubber 4) on the frame 2, and a frame in which the sealing material is disposed. 2 is attached to the edge of the solar cell panel 1.

  The process of manufacturing the solar cell panel 1 includes the process of manufacturing the solar cell 1c on the surface of the substrate glass 1a where the corners are not chamfered, the filler 1d and the surface of the substrate glass 1a and the solar cell 1c, It can be divided roughly into the process of arrange | positioning the cover glass 1b. The solar battery cell 1c can be manufactured using well-known methods, such as sputtering method, for example. After producing the solar battery cell 1c, a known filler represented by an uncrosslinked ethylene vinyl acetate (EVA) resin sheet or the like is disposed on the upper surface of the substrate glass 1a and the solar battery cell 1c. The cover glass 1b is disposed on the upper surface so that the surface of the cover glass 1b whose chamfered corners are in contact with the filler, vacuum laminated, and then pressed while heating. For example, the solar battery panel 1 having the substrate glass 1a, the solar battery cell 1c, the filler 1d, and the cover glass 1b can be manufactured through such a process.

  The step of disposing the sealing material on the frame 2 includes disposing the silicone rubber 3 on the lower surface of the upper part 2a that should face the cover glass 1b, and the surface of the convex part 2c and the base part 2b that should face the solar cell panel 1 And a step of disposing the butyl rubber 4 on the upper surface of the convex portion 2c facing and the surface of the base portion 2b facing the concave portion 2d.

  The step of attaching the frame 2 on which the sealing material is disposed to the edge of the solar cell panel 1 is performed, for example, by sticking the silicone rubber 3 disposed on the lower surface of the upper portion 2a to the upper surface of the cover glass 1b, and the convex portion. The butyl rubber 4 disposed on the upper surface of 2c and the surface of the base 2b facing the recess 2d is crushed at the chamfered corners of the solar cell panel 1, so that the frame 2, 2, After attaching 2 and 2, it can be set as the process of carrying out the screw fastening of the adjacent frames 2 and 2. FIG.

  In the solar cell module 10, a known glass substrate capable of forming the solar cell 1 c on the surface can be appropriately used as the substrate glass 1 a.

  Moreover, the cover glass 1b will not be specifically limited if the glass which has the light transmittance which makes the light irradiated from the paper upper side of FIG. 1 reach | attain to the photovoltaic cell 1c, A well-known cover glass is used suitably. Can be used.

  In addition, the form of the solar cell 1c is not particularly limited as long as it has a photoelectric conversion ability and can extract electric energy. The solar battery cell 1c can be formed, for example, by laminating a back electrode, a light absorption layer, a buffer layer, and a transparent electrode layer in this order.

In the present invention, examples of the constituent material of the back electrode include Mo, Al, Ti, and Ag. As the light absorption layer, a p-type semiconductor containing an Ib group element, an IIIb group element, and a VIb group element in the periodic table can be used. Such p-type semiconductors include Cu (In, Ga) Se ₂ (CIGS), Cu (In, Ga) (Se, S) ₂ (CIGSS), CuInS ₂ (CIS), and Cu (In, Al) Se. ₂ (CIAS), Cu ₂ ZnSnS ₄ (CZTS), Cu ₂ ZnSnSe ₄ , Cu ₂ ZnSn (S, Se ₄ ), and the like. Moreover, as a buffer layer, the well-known layer which can be used as a buffer layer arrange | positioned between the light absorption layer and electrode of a solar cell module can be used suitably. The constituent materials of such a layer include CdS, ZnS, In ₂ S ₃ , Zn (O, OH), ZnO, Zn (O, OH, S), In (O, OH), In ₂ O ₃ , In (O, OH, S), ZnMgO, etc. can be illustrated. Moreover, as a transparent electrode layer, the well-known transparent electrode which can be used as an electrode connected to the light absorption layer of a solar cell module can be used suitably. As a constituent material of such a transparent electrode, a known n-type semiconductor containing a group IIb element and a group VIb element (for example, ZnO to which B is added) can be exemplified.

  As the filler 1d, a known resin that can be used when sealing the power generation unit of the solar cell module can be appropriately used. Examples of such a resin include ethylene vinyl acetate (EVA) resin.

  The frame 2 can be made of a known material applicable to the frame of the solar cell module. Examples of such a material include aluminum. From the viewpoint of making it easy to increase the corrosion resistance, the frame 2 is preferably subjected to painting, chromate treatment, or the like.

  For the first sealing material 3, a material having heat resistance and water resistance that can withstand the use environment of the solar cell module 10 and having a larger linear expansion coefficient than the second sealing material 4 can be used. It is preferable to use a substance having a Young's modulus larger than that of the sealing material 4 of No. 2. Examples of such substances include silicone rubber and various natural rubbers, or those foamed for elasticity adjustment. Moreover, you may use an acrylic adhesive with the said rubber | gum from a viewpoint of making it the form which is easy to raise the manufacturing efficiency of a solar cell module. When an acrylic adhesive is used, this adhesive can be applied to the lower surface of the upper portion 2a.

The second sealing material 4 is made of a material that has heat resistance and water resistance that can withstand the use environment of the solar cell module 10, has low gas permeability, and has a smaller linear expansion coefficient than the first sealing material 3. Can be used. Examples of such substances include butyl rubber, nitrile rubber, urethane rubber, and fluororubber. Among these, it is preferable to use butyl rubber or urethane rubber that is easy to handle and has low gas permeability. The gas permeability of the second sealing material 4 is, for example, 10 [g / m ² · 24 h at a temperature of 40 ° C. and a relative humidity of 90% in accordance with a moisture permeability test method for moisture-proof packaging materials of JIS Z0208. In particular, it is preferably 0.5 [g / m ² · 24 h] or less.

  In the said description regarding this invention, although the form which has the substrate glass 1a and the cover glass 1b was mentioned, the solar cell module of this invention is not limited to the said form. The solar cell module of the present invention can be configured to use no cover glass, or can be configured to use a substance other than glass (for example, metal or resin) or the like for the substrate. However, it is preferable to make the solar cell module of the present invention into a form having a substrate glass and a cover glass from the viewpoint of enhancing the sealing property and preventing water from entering.

  Moreover, in the said description regarding this invention, although the cover glass 1b was larger than the substrate glass 1a and the edge of the cover glass 1b was located in the circumference | surroundings of the substrate glass 1a, the solar cell module of this invention was mentioned. Is not limited to this form. However, from the viewpoint of easily supporting the solar cell panel with the frame and improving the sealing property, the cover glass is larger than the substrate glass and the edge of the cover glass is positioned around the substrate glass. It is preferable that a cover glass and a substrate glass having a large size are provided.

  Moreover, in the said description regarding this invention, although mentioned about the form which arrange | positions only the 1st sealing material 3 between the lower surface of the upper part 2a, and the upper surface of the solar cell panel 1, the solar cell module of this invention is the said form. It is not limited. In the solar cell module of the present invention, in addition to the first sealing material, an elastic member represented by a spring or the like may be arranged between the upper lower surface of the frame and the upper surface of the solar cell panel. It is. When a spring is arranged between the upper lower surface of the frame and the upper surface of the solar cell panel, the spring can be made of a known metal or a known engineering plastic. In addition to this, the frame itself may be provided with a spring function.

  Moreover, in the said description regarding this invention, the 1st sealing material 3 is filled between the cover glass 1b and the upper part 2a, Between the lower surface and side surface of the solar cell panel 1, and the upper surface of the convex part 2c, and Although the embodiment in which the second sealing material 4 having a moisture-proof function is filled between the side surface of the solar cell panel 1 and the base portion 2b is illustrated, the solar cell module of the present invention is not limited to the embodiment. The solar cell module of the present invention includes, for example, between the cover glass 1b and the upper portion 2a, between the lower surface and side surface of the solar cell panel 1 and the upper surface of the convex portion 2c, and between the side surface and the base portion 2b of the solar cell panel 1. In the meantime, the second sealing material 4 having a moisture-proof function can be filled. Even in this form, when the temperature at which the frame 2 expands increases, the amount of the second sealing material 4 filled between the solar cell panel 1 and the upper portion 2a expands in the direction away from the upper portion 2a. The amount of the second sealing material 4 filled between the battery panel 1 and the upper surface of the convex portion 2c is larger than the amount that expands in the direction approaching the upper portion 2a. Therefore, even in such a form, the solar cell panel 1 can be pressed against the second sealing material 4 disposed between the solar cell panel 1 and the upper surface of the convex portion 2c. By pressing the solar cell panel 1 against the second sealing material 4 disposed between the solar cell panel 1 and the upper surface of the convex portion 2c, the sealing property between the solar cell panel 1 and the upper surface of the convex portion 2c is obtained. Since it becomes possible to improve, even if it is this form, the solar cell module which can improve a sealing performance can be provided. However, from the viewpoint of easily improving the sealing performance, the first sealing material 3 having a larger linear expansion coefficient than that of the second sealing material 4 is filled between the cover glass 1b and the upper portion 2a. And the 2nd sealing material 4 which has a moisture-proof function is filled between the lower surface and side surface of the solar cell panel 1, and the upper surface of the convex part 2c, and between the side surface and the base part 2b of the solar cell panel 1. The form is preferred.

  Moreover, in the said description regarding this invention, although the solar cell module 10 which has the flame | frame 2 which has the upper part 2a, the base 2b, and the convex part 2c was illustrated, the form of the flame | frame with which the solar cell module of this invention is equipped is an upper part. It is not limited to the form which has a base part and a convex part. Then, the other form of the flame | frame which can be equipped with the solar cell module of this invention is demonstrated, referring FIG.4 and FIG.5.

  FIG. 4 is a cross-sectional view illustrating a frame 2x that can be included in the solar cell module of the present invention, and FIG. 5 is a cross-sectional view illustrating a frame 2y that can be included in the solar cell module of the present invention. 4, the same reference numerals as those used in FIGS. 1 and 2 are attached to the same configuration as that of the frame 2, and the description thereof is omitted as appropriate. As shown in FIG. 4, the frame 2x includes an upper portion 2a, a base portion 2e connected to the upper portion 2a so as to face the lower surface of the upper portion 2a, and a recess sandwiched between the lower surface of the upper portion 2a and the upper surface of the base portion 2e. 2f. Further, as shown in FIG. 5, the frame 2y is sandwiched between an upper portion 2g, a base portion 2h connected to the upper portion 2g so as to face a lower surface of the upper portion 2g, and a lower surface of the upper portion 2g and an upper surface of the base portion 2h. And a recess 2i. The frame 2y is formed by bending one plate-like member. Even if the solar cell module of the present invention is provided with the frame 2x, for example, the edge of the solar cell panel is disposed in the recess 2f, and the first sealing material is provided between the upper surface of the solar cell panel and the lower surface of the upper portion 2a. By arranging the second sealing material between the lower surface and the side surface of the solar cell panel and the surface of the base 2e facing the recess 2f, it is possible to achieve the same effect as the solar cell module 10. Become. Moreover, even if the solar cell module of the present invention is provided with the frame 2y, for example, the edge of the solar cell panel is disposed in the recess 2i, and the first between the upper surface of the solar cell panel and the lower surface of the upper portion 2g. By arranging the sealing material and arranging the second sealing material between the lower surface and side surface of the solar cell panel and the surface of the base 2h facing the recess 2i, the same effect as that of the solar cell module 10 can be obtained. It becomes possible.

DESCRIPTION OF SYMBOLS 1 ... Solar cell panel 1a ... Substrate glass 1b ... Cover glass 1c ... Solar cell 1d ... Filler 2, 2x, 2y ... Frame 2a, 2g ... Upper part 2b, 2e, 2h ... Base 2c ... Convex part 2d, 2f, 2i ... Recessed part 3 ... First sealing material 4 ... Second sealing material 10 ... Solar cell module

Claims (5)

A solar cell panel, and a frame that supports the solar cell panel,
The frame is connected to the upper portion, a base portion connected to the upper portion so as to have an angle with the upper portion, and at least a side of the base portion facing the solar cell panel and extending obliquely in a direction away from the upper portion. A convex portion, and
An edge of the solar cell panel is disposed in a recess sandwiched between the upper part and the convex part,
A solar cell module, wherein a sealing material is filled between the solar cell panel and the upper portion, and at least between the solar cell panel and the upper surface of the convex portion. A first sealing material filled between the solar cell panel and the upper portion in the sealing material, and a second sealing material filled between at least the solar cell panel and the upper surface of the convex portion. Contains
The solar cell module according to claim 1, wherein the second sealing material has a smaller linear expansion coefficient than the first sealing material. A solar cell panel, and a frame that supports the solar cell panel,
The frame has an upper part and a base part obliquely connected to the upper part in a direction away from the upper part so as to face the lower surface of the upper part,
The edge of the solar cell panel is disposed in a recess sandwiched between the upper part and the base part,
A solar cell module, wherein a sealing material is filled between the solar cell panel and the upper portion, and at least between the surface of the base portion facing the upper portion and the solar cell panel. The sealing material is filled between the solar cell panel and the first sealing material filled between the solar cell panel and the upper portion, and at least between the solar cell panel and the surface of the base portion facing the upper portion. 2 sealing materials are included,
The solar cell module according to claim 3, wherein the second sealing material has a smaller coefficient of linear expansion than the first sealing material. The solar cell module according to claim 2, wherein the first sealing material has a Young's modulus greater than that of the second sealing material.