JP6789178B2 - Solar cell module - Google Patents

Description

The present invention relates to a solar cell module having an antiglare function against reflected light on the surface of the solar cell module on the light receiving surface side.

At present, expectations for renewable energy are increasing worldwide, and solar cells in particular are attracting attention as a representative example. However, as the spread of solar cells has progressed, environmental problems caused by the installation of solar cell modules have also come to be recognized. A typical problem caused by the installation of the solar cell module is light pollution to the surroundings due to the reflected light from the solar cell module.

In the solar cell module, a light transmissive substrate, a sealing material, a plurality of solar cells electrically connected by tab wiring, a sealing material, and a back sheet are stacked and laminated from the light receiving surface side. Has a structure. In the solar cell module, power is generated in the solar cell by incident light on the solar cell. In addition, since the solar cell module is installed outdoors such as on the roof of a building, pressure due to snow and wind is applied. Therefore, in many cases, a glass material having high transmittance and high strength is used for the light-transmitting substrate used as a protective member for the surface of the solar cell module.

In a glass material, when light is incident perpendicularly to a flat glass surface, almost no light reflection occurs. On the other hand, when light is incident on a flat glass surface in an oblique direction, light transmitted through the glass surface and light reflected by the glass surface are generated. The amount of reflected light reflected on the glass surface is the amount obtained by subtracting the amount of light transmitted through the glass and the amount of light absorbed by the glass from the amount of incident light incident on the glass surface. There are specular reflection and diffuse reflection in the reflection of light on the glass surface. Specular reflection is a reflection in which the incident angle and the reflection angle are equal and the reflected rays are parallel rays. Diffuse reflection, on the other hand, is reflection in which incident light is reflected at various angles and in various directions.

Depending on the installation location or season of the solar cell module, the reflected light on the light transmissive substrate of the solar cell module, that is, the reflected light on the surface of the solar cell module on the light receiving surface side becomes considerably large and is in the vicinity. It becomes a factor that causes light damage to. In particular, the reflected light due to specular reflection becomes a very dazzling state in the vicinity.

As a method for preventing glare from the reflected light from the surface of such a solar cell module, Patent Document 1 describes a part of sunlight on at least the front surface side of the front and back surfaces of a plate-shaped surface member to which sunlight is incident. It is disclosed that a light scattering means for scattering light is provided. In Patent Document 1, the light scattering means is formed by attaching a sheet having a wave-shaped cross section to a surface member. Further, as the light scattering means having a wavy cross section, one having a wavy cross section, one having a plurality of quadrangular pyramid-shaped protrusions or recesses arranged, or one made of frosted glass. In such a case, it is possible to diffusely reflect sunlight in various directions, and it is said that the light diffusion performance of the light scattering means is improved.

Japanese Unexamined Patent Publication No. 2001-189479

However, according to the technique of Patent Document 1, the light scattering means and the light receiving surface grid electrode depend on the positional relationship between the shape of the convex portion or the concave portion of the light scattering means and the light receiving surface grid electrode of the solar cell. There is a problem that interference fringes are generated and the appearance of the solar cell module is deteriorated.

The present invention has been made in view of the above, and suppresses deterioration of appearance due to the generation of interference fringes while maintaining an antiglare function against reflected light on the surface of the solar cell module on the light receiving surface side. The purpose is to obtain a possible solar cell module.

In order to solve the above-mentioned problems and achieve the object, the solar cell module according to the present invention includes a plurality of light receiving surface grid electrodes arranged in parallel in the surface on the light receiving surface side of the semiconductor substrate having a pn junction. The solar cell is provided with a light transmitting substrate which is arranged in parallel with the semiconductor substrate on the light receiving surface side of the solar cell and has an uneven structure on the surface of one surface on the light receiving surface side. The convex or concave portion of the concavo-convex structure is composed of an aggregate of polygonal pyramids having a polygonal bottom surface in the plane of the light transmitting substrate, and the light receiving surface grid electrode and the bottom surface of the polygonal pyramid are viewed perpendicular to the light transmitting substrate. All sides of the are non-parallel.

According to the present invention, it is possible to suppress the deterioration of the appearance due to the generation of interference fringes while maintaining the antiglare function against the reflected light on the surface of the solar cell module on the light receiving surface side.

Top view of the solar cell module according to the first embodiment of the present invention as viewed from the light receiving surface side. It is sectional drawing of the main part which shows the solar cell module which concerns on Embodiment 1 of this invention, and is the sectional view II-II in FIG. Top view of the solar cell in the solar cell module according to the first embodiment of the present invention as viewed from the light receiving surface side. Top view of the solar cell in the solar cell module according to the first embodiment of the present invention as viewed from the back surface side. Top view of the glass plate constituting the light receiving surface side protective member of the solar cell module according to the first embodiment of the present invention. Perspective view of the case where the uneven structure of the glass plate constituting the light receiving surface side protective member of the solar cell module according to the first embodiment of the present invention is convex. An enlarged perspective view showing the uneven structure of the glass plate according to the first embodiment of the present invention. FIG. 5 is an enlarged cross-sectional view showing the uneven structure of the glass plate according to the first embodiment of the present invention. Top view showing the positional relationship between the light receiving surface grid electrode of the solar cell and the hexagonal pyramid of the light receiving surface side protective member in the solar cell module according to the first embodiment of the present invention. FIG. 5 is a plan view showing the positional relationship between the light receiving surface grid electrode of the solar cell and the hexagonal pyramid of the light receiving surface side protective member in the solar cell module according to the first embodiment of the present invention, and is an enlarged view of a main part of FIG. A plan view showing the positional relationship between the light receiving surface grid electrode of the solar cell and the flat surface portion of the light receiving surface side protective member in the solar cell module according to the first embodiment of the present invention. The figure which shows an example of the situation where the interference fringe occurs in the solar cell module which concerns on Embodiment 1 of this invention. The figure which shows another example of the situation where the interference fringe occurs in the solar cell module which concerns on Embodiment 1 of this invention. A flowchart showing a procedure of a method for manufacturing a solar cell module according to a first embodiment of the present invention. Top view showing the uneven structure of the light receiving surface side protective member of the solar cell module according to the second embodiment of the present invention. Top view showing the positional relationship between the light receiving surface grid electrode of a solar cell and the concavo-convex structure of the light receiving surface side protective member in the solar cell module according to the second embodiment of the present invention. An enlarged perspective view showing the uneven structure of the glass plate according to the third embodiment of the present invention. FIG. 5 is an enlarged cross-sectional view showing the uneven structure of the glass plate according to the third embodiment of the present invention.

Hereinafter, the solar cell module according to the embodiment of the present invention will be described in detail with reference to the drawings. The present invention is not limited to this embodiment. Further, in the drawings shown below, the scale of each member may differ from the actual scale for easy understanding. The same applies between the drawings.

Embodiment 1.
FIG. 1 is a plan view of the solar cell module 1 according to the first embodiment of the present invention as viewed from the light receiving surface side. FIG. 2 is a sectional view of a main part showing the solar cell module 1 according to the first embodiment of the present invention, and is a sectional view taken along line II-II in FIG. FIG. 3 is a plan view of the solar cell 11 in the solar cell module 1 according to the first embodiment of the present invention as viewed from the light receiving surface side. FIG. 4 is a plan view of the solar cell 11 in the solar cell module 1 according to the first embodiment of the present invention as viewed from the back surface side.

The solar cell module 1 according to the first embodiment has a translucent solar cell string 10 in which a plurality of crystalline solar cell cells 11 which are photoelectric conversion units are electrically connected by a connection wiring 21. A seal that seals the light receiving surface side protective member 31 that protects the light receiving surface side of the solar cell string 10, the back surface side protective member 32 that protects the back surface side facing the light receiving surface of the solar cell string 10 and the solar cell string 10. A stopper 33 is provided. The solar cell string 10 is sealed sandwiched between a light receiving surface side protective member 31 arranged on the light receiving surface side of the solar cell module 1 and a back surface side protective member 32 arranged on the back surface side of the solar cell module 1. It is sealed in the material 33. Further, as shown in FIG. 1, the solar cell module 1 is surrounded by a frame 41 over the entire circumference of the outer edge portion. In the solar cell module 1, light L is incident from the light receiving surface side protective member 31 side.

The solar cell string 10 has a plurality of solar cells 11 arranged in a first direction, which is a predetermined arrangement direction, and a connection wiring 21. The first direction corresponds to the X direction in FIGS. 1 to 4. The plurality of solar cells 11 are regularly arranged on the same plane with a predetermined distance in the first direction. Then, the two solar cells 11 adjacent to each other in the first direction are electrically connected in series by the connection wiring 21. In FIG. 1, five solar cell strings 10 in which ten solar cells 11 are electrically connected in series and arranged in a second direction are further electrically connected in series to one. A long solar cell string is constructed. The second direction is a direction orthogonal to the first direction in the plane direction of the solar cell module 1, and corresponds to the Y direction in FIG.

As the solar cell 11, a single-sided power generation type crystalline solar cell can be used. The solar cell 11 is a solar cell substrate having a photoelectric conversion function, and an antireflection film made of a silicon nitride film (not shown) is formed on the light receiving surface side of the semiconductor substrate 12 having a pn junction. In the semiconductor substrate 12, an n-type impurity diffusion layer (not shown) is formed by phosphorus diffusion on the light receiving surface side of the p-type semiconductor substrate made of p-type silicon to form a pn junction. The p-type silicon may be single crystal silicon or polycrystalline silicon. Further, a semiconductor substrate using an n-type semiconductor substrate may be used instead of the p-type semiconductor substrate.

Further, a light receiving surface electrode 13 is provided on the light receiving surface of the semiconductor substrate 12. A long and slender light-receiving surface grid electrode 14 that collects light-generating carriers from the semiconductor substrate 12, and a light-receiving surface bus electrode 15 that conducts with the light-receiving surface grid electrode 14 and collects light-generating carriers from the light-receiving surface grid electrode 14. Are provided in a state of being orthogonal to each other in the plane direction of the semiconductor substrate 12. In the light receiving surface grid electrode 14, linear patterns having a line width of about 50 μm are arranged in parallel at intervals of about 1 mm to 2 mm. The light receiving surface bus electrode 15 has a width of about 1 mm to 3 mm, and about 2 to 4 electrodes are arranged in parallel per solar cell.

Further, a back surface electrode 16 is provided on the back surface of the semiconductor substrate 12. The back surface electrodes 16 include a long and slender back surface grid electrode 17 that collects light generation carriers from the semiconductor substrate 12, and a back surface bus that conducts with the back surface grid electrode 17 and collects light generation carriers from the back surface grid electrode 17. An electrode 18 is provided. The back surface grid electrode 17 and the back surface bus electrode 18 are provided so as to be orthogonal to each other in the plane direction of the semiconductor substrate 12.

The light receiving surface bus electrode 15 and the back surface bus electrode 18 are provided in parallel with each other at corresponding positions in the surface direction of the semiconductor substrate 12. The light receiving surface bus electrode 15 and the back surface bus electrode 18 are used as connection electrodes for joining the connection wiring 21 which is a connection wiring. Then, in the two adjacent solar cells 11, the light receiving surface bus electrode 15 of one solar cell 11 and the back surface bus electrode 18 of the other solar cell 11 are electrically connected in series by a connection wiring 21. Has been done.

The connection wiring 21 is the light receiving surface bus electrode 15 of the light receiving surface electrode 13 formed on the light receiving surface of one solar cell 11 in the two adjacent solar cells 11, and the one solar cell in the first direction. It is joined to the back surface bus electrode 18 of the back surface electrode 16 formed on the back surface of the other solar cell 11 adjacent to the cell 11, and the adjacent solar cell 11s are electrically connected in series in the first direction. To do. A good conductor such as copper is used as the connection wiring 21.

The light receiving surface side protective member 31 is made of a light transmissive substrate made of a translucent material. The light receiving surface side protective member 31 covers the solar cell string 10 and is arranged on the light receiving surface side of the solar cell string 10 to protect the light receiving surface side of the solar cell string 10. The light receiving surface side protective member 31 is arranged parallel to the solar cell 11 of the solar cell string 10, that is, parallel to the semiconductor substrate 12. As the material of the light receiving surface side protective member 31, for example, glass or translucent plastic is used. The details of the light receiving surface side protective member 31 will be described later.

The back side protective member 32 is arranged on the back side of the solar cell string 10 to protect the back side of the solar cell string 10. A resin back sheet made of an electrically insulating material is used as the back surface side protective member 32, and a hydrolysis-resistant polyethylene terephthalate (PET) resin sheet, an olefin resin, and a polyvinyl fluoride, which are generally used in crystalline solar cell modules, are used. A vinyl fluoride (PVF) resin sheet or a laminated resin sheet in which these are bonded can be used.

As the sealing material 33, a transparent insulating film made of a resin material or an organic material having excellent transparency, that is, light transmission and insulating properties is used. As such a material, an electrically insulating material such as ethylene-vinyl acetate (EVA) resin, polyethylene terephthalate (PET) resin, acrylic resin, polyurethane resin and silicone rubber can be used.

The frame 41 is manufactured by extrusion molding of a metal material such as aluminum, and protects the outer periphery of the solar cell module 1.

Next, the details of the light receiving surface side protective member 31 according to the first embodiment will be described. FIG. 5 is a plan view of the glass plate 51 constituting the light receiving surface side protective member 31 of the solar cell module 1 according to the first embodiment of the present invention. FIG. 6 is a perspective view when the uneven structure of the glass plate 51 constituting the light receiving surface side protective member 31 of the solar cell module 1 according to the first embodiment of the present invention is convex. FIG. 7 is an enlarged perspective view showing the uneven structure of the glass plate 51 according to the first embodiment of the present invention. FIG. 8 is an enlarged cross-sectional view showing the uneven structure of the glass plate 51 according to the first embodiment of the present invention. Although the case where the light receiving surface side protective member 31 is composed of the glass plate 51 is shown here, the light receiving surface side protective member 31 may be formed of a translucent plastic having the same structure as the glass plate 51.

In the glass plate 51, a concavo-convex structure composed of an aggregate of polygonal pyramids having a polygonal bottom surface in the surface of the glass plate 51 which is a light transmitting substrate is formed on the surface of one surface 51a which is the first surface. There is. On the other hand, the second surface of the glass plate 51, the other surface 51b facing in the opposite direction to the one surface 51a, is a flat surface.

The uneven structure formed on one surface 51a of the glass plate 51 includes a plurality of hexagonal pyramids 52 which are polygonal pyramids having a polygonal bottom surface on one surface 51a of the glass plate 51, and hexagonal pyramids 52 adjacent to each other on one surface 51a of the glass plate 51. It is composed of a flat surface portion 53 provided between the two and connected to each side of the hexagon on the bottom surface of the adjacent hexagonal pyramid 52. The hexagonal pyramid 52 is a convex portion that constitutes a concave-convex structure when the concave-convex structure of the glass plate that constitutes the light-receiving surface side protective member 31 is convex, and is a honeycomb with a gap in the surface of one surface 51a of the glass plate 51. It is formed in a state of being arranged in a shape. All hexagonal pyramids 52 have the same size and shape and are arranged in the same direction.

In the two hexagonal pyramids 52 adjacent to each other in the plane of one surface 51a, the bases of the adjacent slopes are parallel. Then, between the region between the adjacent hexagonal pyramids 52 in the plane of one surface 51a, that is, between the base of the slope of one hexagonal pyramid 52 adjacent to each other in the plane of one surface 51a and the bottom of the slope of the other hexagonal pyramid 52. Region is configured as a line-shaped flat surface portion 53. The flat surface portion 53 is a surface parallel to one surface 51a, that is, a surface parallel to the surface direction of the glass plate 51. The bottom of the slope of the hexagonal pyramid 52 is one side of the hexagonal bottom surface of the hexagonal pyramid 52.

That is, as shown in FIG. 7, the first hexagonal pyramid 52a, the second hexagonal pyramid 52b, and the two hexagonal pyramids 52 that are adjacent to each other in the plane of the one surface 51a are the base 54a of the slope of the first hexagonal pyramid 52a. The second hexagonal pyramid 52b is arranged so as to be parallel to the base 54b of the slope. The region between the base 54a of the slope of the first hexagonal pyramid 52a and the bottom 54b of the slope of the second hexagonal pyramid 52b arranged so as to face each other is a line-shaped flat surface portion 53. In the uneven structure formed on one surface 51a of the glass plate 51, the above positional relationship is established in all the hexagonal pyramids 52.

Such an uneven structure can be formed by embossing one surface 51a of the glass plate 51. In the hexagonal pyramid 52, the slope of the hexagonal pyramid 52 and the one surface 51a form an acute angle of inclination, but the intersection of each side and the one surface 51a in the hexagon on the bottom surface of the hexagonal pyramid 52 has the same inclination as the slope. Difficult to form with horns. That is, it is difficult to form the base 54a of the slope of the first hexagonal pyramid 52a adjacent to each other in the plane of the one surface 51a and the base 54b of the slope of the second hexagonal pyramid 52b so as to be exactly aligned with each other. Therefore, a flat surface portion 53 parallel to the plane direction of the glass plate 51 is formed between the base 54a of the slope of the first hexagonal pyramid 52a and the bottom 54b of the slope of the second hexagonal pyramid 52b. Therefore, in the concave portion having the uneven structure in the surface of the one surface 51a, the corner where the slope of the hexagonal pyramid 52 is in contact with the one surface 51a is rounded, and the flat surface portion 53 is formed. In addition, in FIGS. 5 to 7, in order to show the shape of the hexagonal pyramid 52, the boundary between the base of the slope of the hexagonal pyramid 52 and the flat surface portion 53 is clearly shown for convenience.

The thickness of the glass plate 51 is about 2 mm to 4 mm. The height of the unevenness in the plane of the one surface 51a, that is, the height of the hexagonal pyramid 52 from the flat surface portion 53 is about 20 μm to 100 μm. The arrangement interval 57 of the hexagonal pyramids 52 in the plane of one surface 51a is about 0.5 mm to 1.5 mm. As shown in FIGS. 5 and 7, the arrangement interval 57 of the hexagonal pyramids 52 is the length between the corresponding sides of the hexagonal pyramids 52 adjacent to each other in the in-plane direction of the one surface 51a. The size of the bottom surface of the hexagonal pyramid 52 is about 0.5 mm ² to 1.3 mm ² . The ratio of the arrangement interval 57 of the hexagonal pyramids 52 to the width 58 of the flat surface portion 53 is about 5: 1 to 20: 1. The width 58 of the flat surface portion 53 is the length of the flat surface portion 53 in the direction orthogonal to the extension direction of the flat surface portion 53 in the plane of the one surface 51a. When the ratio of the arrangement interval 57 of the hexagonal pyramids 52 to the width 58 of the flat surface portion 53 is 10: 1, the width 58 of the flat surface portion 53 is about 50 μm to 150 μm. The distance between the two opposing sides on the bottom surface of the hexagonal pyramid 52 is about 450 μm to 1350 μm. When the hexagon on the bottom surface of the hexagonal pyramid 52 is a regular hexagon, the ratio of the distance between the two opposite sides of the regular hexagon to the length of one side of the regular hexagon is √3: 1. Therefore, the length of one side of the regular hexagon on the bottom surface of the hexagonal pyramid 52 is about 260 μm to 780 μm. When the ratio of the arrangement interval 57 of the hexagonal pyramid 52 to the width 58 of the flat surface portion 53 is 10: 1, the ratio of the length of one side of the regular hexagon on the bottom surface of the hexagonal pyramid 52 to the width 58 of the flat surface portion 53 is 3, √ 3: 1.

The hexagonal pyramids 52 are formed in a staggered arrangement in the plane of one surface 51a. By arranging the hexagonal pyramids 52 in the plane of the one surface 51a in a staggered arrangement, the hexagonal pyramids 52 can be arranged at high density in the plane of the one surface 51a, and more hexagonal pyramids 52 can be spread over the one surface 51a. Is possible.

When the glass plate 51 configured in this way is used for the light receiving surface side protective member 31, the one side 51a side on which the uneven structure is formed is arranged as the light receiving surface side of the solar cell module 1. That is, in the glass plate 51 shown in FIG. 8, the upper side is the light receiving surface side of the light receiving surface side protective member 31. Further, the surface direction of the light receiving surface side protective member 31, that is, the surface direction of the glass plate 51 and the surface direction of the semiconductor substrate 12 of the solar cell 11 are parallel.

As a result, the solar cell module 1 has good light diffusion performance of the reflected light of sunlight on the surface of the light receiving surface side protective member 31, that is, the reflected light on the surface of the solar cell module 1 on the light receiving surface side, and has good protection. A dazzling function can be obtained.

As described above, the arrangement interval of the light receiving surface grid electrodes 14 in the surface of the semiconductor substrate 12 is about 1 mm to 2 mm. On the other hand, as described above, the arrangement interval of the hexagonal pyramids 52 in the plane of one surface 51a of the glass plate 51 is about 0.5 mm to 1.5 mm. The arrangement interval of the light receiving surface grid electrodes 14 is determined so that the power generation characteristics of the solar cell 11 are optimized. On the other hand, the arrangement interval of the hexagonal pyramids 52 is determined by manufacturing restrictions. That is, since the arrangement interval of the light receiving surface grid electrode 14 and the arrangement interval of the hexagonal pyramid 52 are determined independently, the arrangement intervals of the two do not always match.

FIG. 9 is a plan view showing the positional relationship between the light receiving surface grid electrode 14 of the solar cell 11 and the hexagonal cone 52 of the light receiving surface side protective member 31 in the solar cell module 1 according to the first embodiment of the present invention. is there. FIG. 10 is a plan view showing the positional relationship between the light receiving surface grid electrode 14 of the solar cell 11 and the hexagonal cone 52 of the light receiving surface side protective member 31 in the solar cell module 1 according to the first embodiment of the present invention. Yes, it is an enlarged view of the main part of FIG.

As described above, the hexagonal pyramids 52 are arranged in a staggered arrangement in the plane of the light receiving surface side protective member 31. Further, in the two hexagonal pyramids 52 adjacent to each other with the flat surface portion 53 in the plane of the light receiving surface side protective member 31, the bases of the adjacent slopes facing each other are parallel to each other. All the hexagonal pyramids 52 have the same size and shape in the plane of the light receiving surface side protective member 31, and are arranged in the same direction.

Further, in the solar cell module 1, three pairs of sides provided in parallel in the hexagon on the bottom surface of the first hexagonal pyramid 52a in a vertical view with respect to the light receiving surface side protective member 31 as viewed from the light receiving surface side protective member 31 side. Of these, the first pair of sides 55a and the light receiving surface grid electrode 14 of the solar cell 11 are at right angles. That is, in a vertical view with respect to the light receiving surface side protective member 31 viewed from the light receiving surface side protective member 31 side, the intersection angle β between the first pair of sides 55a of the first hexagonal pyramid 52a and the light receiving surface grid electrode 14 is set. It is said to be 90 °. In other words, in the vertical view with respect to the light receiving surface side protective member 31 viewed from the light receiving surface side protective member 31 side, the extension direction of the flat surface portion 53 extending in a line shape adjacent to the first pair of sides 55a and the solar cell. The extension direction of the light receiving surface grid electrode 14 of 11 is perpendicular to the extension direction.

In this case, in the third hexagonal pyramid 52c adjacent to the first hexagonal pyramid 52a, among the three pairs of sides provided in parallel in the hexagon on the bottom surface, the first pair of the first hexagonal pyramid 52a Two pairs of sides 56b, 56c that are not parallel to the side 55a and the light receiving surface grid electrode 14 intersect at 30 °. That is, in the vertical view with respect to the light receiving surface side protective member 31 seen from the light receiving surface side protective member 31, the intersection angle α between the two pairs of sides 56b and 56c of the third hexagonal pyramid 52c and the light receiving surface grid electrode 14 is 30. It is said to be °. As a result, in the solar cell module 1, the two pairs of sides 56b and 56c on the bottom surface of the third hexagonal pyramid 52c are the light receiving surface grid electrodes 14 and 10 of the solar cell 11 in the in-plane direction of the light receiving surface side protective member 31. Cross at angles greater than °.

Here, since the flat surface portion 53 is parallel to the side of the bottom surface of the adjacent third hexagonal pyramid 52c, the extension direction of the flat surface portion 53 is the in-plane direction of the light receiving surface side protective member 31 of the solar cell 11. It intersects the light receiving surface grid electrode 14 at 30 ° and intersects at an angle of 10 ° or more. That is, in the solar cell module 1, the intersection angle between the light receiving surface grid electrode 14 of the solar cell 11 and the extension direction of the two pairs of sides 56b and 56c and the adjacent flat surface portion 53 is set to 10 ° or more. Since the flat surface portion 53 is parallel to the side of the bottom surface of the adjacent hexagonal pyramid 52c, the intersection angle between the extension direction of the flat surface portion 53 and the light receiving surface grid electrode 14 is the same as the above-mentioned intersection angle α.

As a result, in the vertical view with respect to the light receiving surface side protective member 31 seen from the light receiving surface side protective member 31 side, the light receiving surface grid electrode 14 and all the sides on the bottom surface of the first hexagonal pyramid 52a are in a non-parallel state. .. Then, in the vertical view with respect to the light receiving surface side protective member 31 seen from the light receiving surface side protective member 31, the light receiving surface grid electrode 14 and all the sides on the bottom surface of all the hexagonal pyramids 52 are in a non-parallel state. As a result, in the solar cell module 1, all the light receiving surface grid electrodes 14 are formed in the hexagon on the bottom surface of the plurality of hexagonal pyramids 52 in the vertical view with respect to the light receiving surface side protective member 31 seen from the light receiving surface side protective member 31 side. It intersects either side.

Due to such a structure, in the solar cell module 1, the position of the flat surface portion 53 and the light receiving surface grid electrode 14 of the solar cell 11 in the vertical view with respect to the light receiving surface side protective member 31 seen from the light receiving surface side protective member 31 side. However, they do not overlap along the extending direction of the flat surface portion 53. That is, in the plane of the light receiving surface side protective member 31, the extending direction of the flat surface portion 53 and the light receiving surface grid electrode 14 of the solar cell 11 do not overlap in a parallel state. Therefore, in the solar cell module 1, the flat surface portion 53 and the light receiving surface grid electrode 14 overlap each other as compared with the case where the extending direction of the flat surface portion 53 and the light receiving surface grid electrode 14 of the solar cell 11 overlap each other in a parallel state. It can be shortened, and the generation of interference fringes due to the increased interference of light between the light receiving surface grid electrode 14 of the solar cell 11 and the flat surface portion 53 can be reduced.

That is, when the extension direction of the flat surface portion 53 and the light receiving surface grid electrode 14 overlap in a parallel state, the interference between the reflected light on the flat surface portion 53 and the reflected light on the light receiving surface grid electrode 14 becomes large. The generation of interference fringes due to the increased interference of light becomes remarkable.

On the other hand, in the solar cell module 1, since the extension direction of the flat surface portion 53 and the light receiving surface grid electrode 14 do not overlap in a parallel state, the overlapping length of the flat surface portion 53 and the light receiving surface grid electrode 14 can be shortened. It is possible to reduce the occurrence of interference fringes due to the increased interference of light between the light receiving surface grid electrode 14 of the solar cell 11 and the flat surface portion 53.

As a result, in the solar cell module 1, the light receiving surface grid electrode 14 of the solar cell 11 and the flat surface portion 53 of the light receiving surface side protective member 31 are overlapped, and the overlapping portion of the light receiving surface grid electrode 14 and the flat surface portion 53 is formed. It is possible to suppress the deterioration of the appearance due to the observed interference fringes. Therefore, in the solar cell module 1, it is possible to suppress deterioration of the appearance due to interference fringes caused by the light receiving surface grid electrode 14 of the solar cell 11 and the light receiving surface side protective member 31 having an uneven structure. is there.

That is, in the solar cell module 1, the hexagonal pyramid 52 has the positional relationship between the hexagonal pyramid 52 and the light receiving surface grid electrode 14 in the vertical view with respect to the light receiving surface side protective member 31 as viewed from the light receiving surface side protective member 31 side. By arranging the light receiving surface grid electrode 14 and the light receiving surface grid electrode 14, the overlap occurs only in a part of one side of the flat surface portion 53 at the place where the flat surface portion 53 and the light receiving surface grid electrode 14 overlap, so that the interference fringes observed in the overlapping portion are observed. Can be reduced. That is, by setting the positional relationship between the hexagonal pyramid 52 and the light receiving surface grid electrode 14 as described above, the interference caused by the light receiving surface grid electrode 14 of the solar cell 11 and the flat surface portion 53 of the light receiving surface side protective member 31 It is possible to suppress the deterioration of the appearance due to the fringes. Then, such an effect can be obtained on the entire surface of the light receiving surface side protective member 31.

Further, when the arrangement interval of the light receiving surface grid electrodes 14 is shorter, the sides other than the first pair of sides 55a on the bottom surface of the first hexagonal pyramid 52a receive light received from the light receiving surface side protective member 31 side. In a vertical view with respect to the surface-side protective member 31, the light-receiving surface-side protective member 31 intersects with the light-receiving surface grid electrode 14 at an angle of 10 ° or more in the in-plane direction.

It should be noted that the angle at which the extension direction of the flat surface portion 53 and the light receiving surface grid electrode 14 intersect is not necessarily a right angle in the vertical view with respect to the light receiving surface side protective member 31 seen from the light receiving surface side protective member 31 side. If the angle at which the first pair of sides 55a provided in parallel in the hexagon on the bottom surface of the first hexagonal cone 52a and the light receiving surface grid electrode 14 intersect is 70 ° to 110 °, that is, the first Assuming that the angle at which the extension direction of the flat surface portion 53 adjacent to the pair of sides 55a intersects with the light receiving surface grid electrode 14 is 70 ° to 110 °, the side of the bottom surface of the hexagonal cone 52 other than the first hexagonal cone 52a The intersection angle α between the other side that is not parallel to the first pair of sides 55a and the light receiving surface grid electrode 14 is 10 ° to 50 °, and the extension direction of the flat surface portion 53 adjacent to the other side and the light receiving. The angle of intersection with the surface grid electrode 14 is also 10 ° to 50 °.

FIG. 11 is a plan view showing the positional relationship between the light receiving surface grid electrode 14 of the solar cell 11 and the flat surface portion 53 of the light receiving surface side protective member 31 in the solar cell module 1 according to the first embodiment of the present invention. is there. The lower limit of the intersection angle θ between the extension direction of the flat surface portion 53 and the light receiving surface grid electrode 14 will be described with reference to FIG. All hexagonal pyramids 52 have the same size and shape and are arranged in the same direction. The hexagon on the bottom surface of the hexagonal pyramid 52 is a regular hexagon. Further, the extension directions of the plurality of light receiving surface grid electrodes 14 are parallel.

In a vertical view with respect to the light receiving surface side protective member 31 as seen from the light receiving surface side protective member 31, for example, a region F1 which is one of a plurality of flat surface portions 53 existing on the light receiving surface side protective member 31 and a flat surface portion 53. When the same light receiving surface grid electrode 14 intersects the region F2 adjacent to the region F1 in the extension direction of the above, interference fringes are easily visible. That is, as shown in FIG. 11, the same one light receiving surface grid electrode 14 can be tilted at an angle that does not intersect the region F1 and the region F2 that are adjacent plane portions 53 in the extension direction of the plane portion 53. preferable.

Assuming that the arrangement interval of the hexagonal pyramid 52 is X1, the length Y1 of one side of the regular hexagon on the bottom surface of the hexagonal pyramid 52 is represented by "Y1 = X1 / √3". Therefore, the distance between the region F1 and the area F2, which are the plane portions 53 adjacent to each other in the extension direction of the plane portion 53, that is, the distance Y2 between the plane portions 53 adjacent to each other in the extension direction of the plane portion 53 is "Y2 = Y1 × 2 = X1". It is represented by "× 2 / √3". Assuming that the ratio of the arrangement interval X1 of the hexagonal pyramid 52 to the width X2 of the flat surface portion 53 is R: 1, if "tan θ ≧ X2 / Y2", then the flat surface portions 53 adjacent to each other in the extension direction of the flat surface portion 53 That is, the same single light receiving surface grid electrode 14 does not intersect the adjacent regions F1 and F2 in the extending direction of the flat surface portion 53. When R = 10, θ ≧ 5 °. Further, when R = 5, θ ≧ 10 °. That is, by setting the intersection angle θ to 10 ° or more, the same single light receiving surface grid electrode 14 of the adjacent flat surface portions 53 does not intersect in the extension direction of the flat surface portion 53, so that interference fringes can be suppressed.

As shown in FIG. 10, in a vertical view with respect to the light receiving surface side protective member 31 seen from the light receiving surface side protective member 31 side, with respect to the first pair of sides 55a of the regular hexagon on the bottom surface of the first hexagonal pyramid 52a. When one light receiving surface grid electrode 14 intersects at an angle of 90 °, the other light receiving surface grid electrode 14 intersects with two pairs of sides 56b, 56c of the third hexagonal pyramid 52c at an angle of 30 °. When the angle at which one light receiving surface grid electrode 14 intersects with respect to the first pair of sides 55a of the regular hexagon on the bottom surface of the first hexagonal pyramid 52a is 80 °, the other light receiving surface grid electrode 14 is the first. It intersects the two pairs of sides 56b, 56c of the hexagonal pyramid 52c of 3 at an angle of 20 ° or 40 °. When the angle at which one light receiving surface grid electrode 14 intersects with respect to the first pair of sides 55a of the regular hexagon on the bottom surface of the first hexagonal pyramid 52a is 70 °, the other light receiving surface grid electrode 14 is the first. It intersects the two pairs of sides 56b, 56c of the hexagonal pyramid 52c of 3 at an angle of 10 ° or 50 °.

That is, as shown in FIG. 10, if the angle at which the first pair of sides 55a and the light receiving surface grid electrode 14 in the regular hexagon on the bottom surface of the first hexagonal pyramid 52a intersect is 70 ° to 110 °, the light is received. The angle at which the surface grid electrode 14 intersects the two pairs of sides 56b and 56c of the third hexagonal pyramid 52c can be 10 ° or more.

Therefore, if the angle at which the pair of sides provided in parallel in the regular hexagon on the bottom surface of one of the plurality of hexagonal pyramids 52 and the light receiving surface grid electrode 14 intersect is 70 ° to 110 °. The angle at which the light receiving surface grid electrode 14 intersects the two pairs of sides of the other hexagonal pyramid 52 that are not parallel to the pair of sides can be 10 ° or more.

Also in this case, by setting the angle at which the extension direction of the flat surface portion 53 and the light receiving surface grid electrode 14 intersect to 10 ° or more, the flat surface portion 53 is extended at the position where the flat surface portion 53 and the light receiving surface grid electrode 14 overlap. The overlap between the flat surface portion 53 and the light receiving surface grid electrode 14 can be shortened as compared with the case where the direction and the light receiving surface grid electrode 14 of the solar cell 11 overlap in a parallel state, and the light receiving surface grid of the solar cell 11 can be shortened. It is possible to reduce the occurrence of interference fringes due to the increased interference of light between the electrode 14 and the flat surface portion 53.

FIG. 12 is a diagram showing an example of a situation in which interference fringes occur in the solar cell module 1 according to the first embodiment of the present invention. FIG. 12 shows an example of a state in a vertical view with respect to the light receiving surface side protective member 31 as viewed from the light receiving surface side protective member 31 side, and for convenience, only the hexagonal pyramid 52 and the light receiving surface grid electrode 14 are shown. In FIG. 12, the position where the flat surface portion 53 and the light receiving surface grid electrode 14 overlap is shown by a thick solid line. The bottom of the hexagonal pyramid 52 is shown by a thin solid line. In terms of appearance, the dark solid line where the flat surface portion 53 and the light receiving surface grid electrode 14 overlap is emphasized and visually recognized. Therefore, as shown in FIG. 12, irregular and partial interference fringes are generated, and it is possible to suppress deterioration of the appearance due to the interference fringes.

FIG. 13 is a diagram showing another example of a situation in which interference fringes occur in the solar cell module 1 according to the first embodiment of the present invention. FIG. 13 shows a state in a vertical view with respect to the light receiving surface side protective member 31 as seen from the light receiving surface side protective member 31 side, and for convenience, only the hexagonal pyramid 52 and the light receiving surface grid electrode 14 are shown. In FIG. 13, the position where the flat surface portion 53 and the light receiving surface grid electrode 14 overlap is shown by a dark solid line. The bottom of the hexagonal pyramid 52 is shown by a thin solid line.

FIG. 13 shows how the interference fringes appear when the light receiving surface side protective member 31 is arranged rotated by 1 ° with respect to the predetermined arrangement relationship with respect to the solar cell 11 in the surface direction of the solar cell module 1. ing. When the solar cell 11 and the light receiving surface side protective member 31 are arranged to rotate in the surface direction of the solar cell module 1 with manufacturing accuracy, the occurrence of interference fringes becomes more irregular. In this case, it is possible to further suppress the deterioration of the appearance due to the interference fringes.

FIG. 10 shows the convex portion and the light receiving surface grid electrode 14 when the convex portion of the concave-convex structure is a convex portion having a quadrangular pyramid shape and when the convex portion of the concave-convex structure is a convex portion having a triangular pyramid shape. The positional relationship with and is also shown. In FIG. 10, the quadrangular pyramid-shaped convex portion 61 and the triangular pyramid-shaped convex portion 62 are shown by broken lines.

When the convex portion of the concave-convex structure is a quadrangular pyramid-shaped convex portion, and the plurality of convex portions have the same size and shape and are arranged in the same direction, the side of the bottom surface of the convex portion is the glass plate 51. Since it is arranged so as to be linearly connected over the entire surface, the flat surface portion between the adjacent convex portions corresponding to the flat surface portion 53 is also arranged so as to be linearly connected over the entire surface of the glass plate 51. Therefore, at the location where the flat surface portion 53 and the light receiving surface grid electrode 14 overlap, overlap occurs over the entire length of the linearly connected flat surface portion in the extending direction, and the overlapping portion between the flat surface portion and the light receiving surface grid electrode 14 Will be clearly observed as an interference fringe. As a result, the appearance of the appearance deteriorates remarkably due to the interference fringes observed in the overlapping portion between the flat surface portion and the light receiving surface grid electrode 14.

Even when the convex portion of the concave-convex structure is a triangular pyramid-shaped convex portion, and the plurality of convex portions have the same size and shape and are arranged in the same direction, the bottom side of the convex portion is similarly a glass plate. Since it is arranged so as to be linearly connected over the entire surface of the glass plate 51, the flat surface portion between the adjacent convex portions corresponding to the flat surface portion 53 is also arranged so as to be linearly connected over the entire surface of the glass plate 51. Therefore, at the location where the flat surface portion and the light receiving surface grid electrode 14 overlap, overlap occurs over the entire length of the linearly connected flat surface portion in the extension direction, and the overlapping portion between the flat surface portion and the light receiving surface grid electrode 14 is formed. It will be clearly observed as an interference fringe. As a result, the appearance of the appearance deteriorates remarkably due to the interference fringes observed in the overlapping portion between the flat surface portion and the light receiving surface grid electrode 14.

Next, a method of manufacturing the solar cell module 1 according to the first embodiment will be described. FIG. 14 is a flowchart showing a procedure of a manufacturing method of the solar cell module 1 according to the first embodiment of the present invention.

First, in step S10, a plurality of solar cell 11s are formed by a known technique using a p-type semiconductor substrate.

Next, in step S20, the plurality of solar cells 11 are connected to the connection wiring 21 by joining the connection wiring 21 to the light receiving surface electrode 13 of one solar cell 11 and the back electrode 16 of the one solar cell 11. Electrically connected by the solar cell string 10 is formed.

Next, in step S30, the sheet of the sealing material 33, the solar cell string 10, the sheet of the sealing material 33, and the back surface side protective member 32 are sequentially laminated on the light receiving surface side protective member 31, to form a laminated body. To. Here, the glass plate 51 described above is used as the light receiving surface side protective member 31, and one surface 51a on which the uneven structure is formed is used as the outer surface.

Next, in step S40, the laminate is attached to the laminating apparatus, and heat treatment and laminating treatment are performed at a temperature of 140 ° C. or higher and 160 ° C. or lower for about 30 minutes. As a result, each member of the laminated body is integrated via the sealing material 33, and the solar cell module 1 is obtained.

After that, the outer edge portion of the solar cell module 1 is held by the frame 41 over the entire circumference.

As described above, in the solar cell module 1 according to the first embodiment, since the concave-convex structure composed of the hexagonal pyramid 52 and the flat surface portion 53 is provided on one surface 31a on the light receiving surface side of the light receiving surface side protective member 31. , The antiglare function against the reflected light on the surface of the solar cell module 1 on the light receiving surface side can be obtained.

Further, in the solar cell module 1 according to the first embodiment, the uneven structure provided on one surface 31a of the light receiving surface side protective member 31 does not overlap the flat surface portion 53 and the light receiving surface grid electrode 14 in a parallel state. Because of the configuration, the overlapping length between the flat surface portion 53 and the light receiving surface grid electrode 14 can be shortened, and interference due to the increased interference of light between the light receiving surface grid electrode 14 and the flat surface portion 53 of the solar cell 11 can be shortened. The occurrence of fringes can be reduced. As a result, the solar cell module 1 is observed at the overlapping portion of the light receiving surface grid electrode 14 and the flat surface portion 53. It is possible to suppress deterioration of the appearance due to interference fringes caused by interference between the reflected light on the flat surface portion 53 and the reflected light on the light receiving surface grid electrode 14.

Therefore, according to the solar cell module 1, the sun capable of suppressing deterioration of the appearance due to the generation of interference fringes while maintaining the antiglare function against the reflected light on the surface of the solar cell module 1 on the light receiving surface side. A battery module is obtained.

The shape of the bottom surface of the hexagonal pyramid 52 is not limited to a regular hexagon, and may be a shape having an internal angle of 120 ° and point symmetry with respect to the center of the bottom surface.

Further, from the viewpoint of reducing the occurrence of interference fringes, it is preferable that the uneven structure is provided on the entire surface of the light receiving surface side protective member 31, but the above is partially provided in the surface of the light receiving surface side protective member 31. The above-mentioned effect can be obtained even when the uneven structure of is formed.

Embodiment 2.
FIG. 15 is a top view showing the uneven structure of the light receiving surface side protective member 31 of the solar cell module according to the second embodiment of the present invention. FIG. 16 is a plan view showing the positional relationship between the light receiving surface grid electrode 14 of the solar cell 11 and the uneven structure of the light receiving surface side protective member 31 in the solar cell module according to the second embodiment of the present invention. In addition, in FIGS. 15 and 16, the flat surface portion provided between the quadrangular pyramids, which is a convex portion in the concave-convex structure, and the slope of the quadrangular pyramid are not shown. The solar cell module according to the second embodiment has the same structure as the solar cell module 1 according to the first embodiment described above, except that the uneven structure provided on the light receiving surface side of the light receiving surface side protective member 31 is different. Have.

As shown in FIG. 15, the concave-convex structure of the light-receiving surface side protective member 31 of the solar cell module according to the second embodiment is composed of two types of quadrangular pyramids whose bottom surface has the same rhombic shape as the Penrose tile. Fills the plane with. A plane portion (not shown) is formed between the two types of quadrangular pyramids, as in the case of the first embodiment. The Penrose tile is composed of a rhombus 71 having internal angles of 72 ° and 108 ° and a rhombus 72 having internal angles of 36 ° and 144 °.

Here, the Penrose tile will be described. Penrose tiling is two types of tiles devised by British physicist Roger Penrose, and when the penrose tile is used to fill a flat surface, a periodic pattern does not appear and the penrose tile is displayed on the flat surface. It is known that it can be filled aperiodically.

In the solar cell module according to the second embodiment, as shown in FIG. 16, in the vertical view with respect to the light receiving surface side protective member 31 seen from the light receiving surface side protective member 31 side, any one of the plurality of rhombuses 71 is rhombic. One side of 71 and the light receiving surface grid electrode 14 of the solar cell 11 are orthogonal to each other. That is, as shown in FIG. 16, in the vertical view with respect to the light receiving surface side protective member 31 seen from the light receiving surface side protective member 31 side, the first side 711a of the first rhombus 711 and the light receiving surface of the solar cell 11 The grid electrode 14 is orthogonal to the grid electrode 14.

As a result, the second side 711b, which is the other side of the first rhombus 711, which is a rhombus whose one side is orthogonal to the light receiving surface grid electrode 14, and the other rhombus 71 adjacent to the first rhombus 711. The first side 712a of a second rhombus 712 and the light receiving surface grid electrode 14 can be crossed at an intersection angle of 18 °.

Here, the sides of the bottom surfaces of adjacent rhombuses are parallel. That is, since the plane portion between the adjacent first rhombus 711 and the second rhombus 712 is parallel to the side of the bottom surface of the first rhombus 711 and the second rhombus 712, the first rhombus adjacent to each other The plane portion between the 711 and the second rhombus 712 and the light receiving surface grid electrode 14 can be crossed at an intersection angle of 18 °.

As a result, the second side 711b of the first rhombus 711 and the light receiving surface grid electrode 14 can be crossed at an angle of 10 ° or more, and between the adjacent first rhombus 711 and the second rhombus 712. Since the flat surface portion of the above and the light receiving surface grid electrode 14 can be intersected at an angle of 10 ° or more, the overlap between the second side 711b of the first rhombus 711 and the light receiving surface grid electrode 14 of the flat surface portion is shortened. It is possible to reduce the interference fringes of light observed in the overlapping portion of the flat surface portion between the second side 711b and the light receiving surface grid electrode 14 of the first rhombus 711. Then, such an effect can be obtained on the entire surface of the light receiving surface side protective member 31.

Further, in the concave-convex structure of the light-receiving surface side protective member 31 of the solar cell module according to the second embodiment, since the flat surface of the light-receiving surface side protective member 31 is filled with Penrose tiling, a periodic pattern does not appear. , The interference fringes observed at the overlapping portion with the linear light receiving surface grid line 14 can be made difficult to be observed as a macroscopic pattern.

Embodiment 3.
FIG. 17 is an enlarged perspective view showing the uneven structure of the glass plate 151 according to the third embodiment of the present invention. FIG. 18 is an enlarged cross-sectional view showing the uneven structure of the glass plate 151 according to the third embodiment of the present invention. The solar cell module according to the third embodiment has the same structure as the solar cell module 1 according to the first embodiment described above, except that the uneven structure provided on the light receiving surface side of the light receiving surface side protective member 31 is different. Have. That is, in the solar cell module according to the third embodiment, a glass plate 151 is used instead of the glass plate 51 as the glass plate constituting the light receiving surface side protective member 31.

The glass plate 151 has a concavo-convex structure composed of an aggregate of polygonal pyramid-shaped recesses having a polygonal bottom surface in the surface of the glass plate 151 which is a light transmissive substrate, and is formed on the surface of one surface 151a which is the first surface. It is formed. That is, the glass plate 151 has a concave-convex structure in which the recesses are hexagonal pyramids formed on the surface of one surface 151a of the glass plate 151. On the other hand, the second surface of the glass plate 151, the other surface 151b facing the opposite direction to the one surface 151a, is a flat surface.

The uneven structure formed on one surface 151a of the glass plate 151 includes a plurality of hexagonal pyramid-shaped recesses 152 which are polygonal pyramids having a polygonal bottom surface on one surface 151a of the glass plate 151, and six adjacent surfaces 51a of the glass plate 51. It is composed of a flat surface portion 153 provided between the pyramid-shaped recesses 152 and connected to each side in a hexagon on the bottom surface of the adjacent hexagonal pyramid recess 152. The hexagonal pyramid-shaped recess 152 is a recess that constitutes a concave-convex structure when the concave-convex structure of the glass plate constituting the light-receiving surface side protective member 31 is concave, and a gap is provided in the surface of one surface 151a of the glass plate 151. It is formed in a state of being arranged in a honeycomb shape. All hexagonal pyramidal recesses 152 have the same size and shape and are arranged in the same direction.

In the two hexagonal pyramid recesses 152 adjacent to each other in the plane of one surface 151a, the bases of the adjacent slopes are parallel. Then, the area between the adjacent hexagonal pyramid recesses 152 in the plane of one surface 151a, that is, the bottom of the slope of one of the hexagonal pyramid recesses 152 adjacent to each other in the plane of one surface 151a, and the other hexagonal pyramid recess 152. The area between the slope and the bottom of the slope is configured as a linear flat surface portion 153. The flat surface portion 153 is a surface parallel to one surface 151a, that is, a surface parallel to the surface direction of the glass plate 151. The bottom of the slope of the hexagonal pyramid recess 152 is one side of the hexagonal bottom surface of the hexagonal pyramid recess 152.

In the solar cell module according to the third embodiment, the uneven structure provided on one surface 31a of the light receiving surface side protective member 31 is the same as in the case of the first embodiment, with the flat surface portion 153 and the light receiving surface grid electrode 14. Are parallel and do not overlap. That is, in the vertical view with respect to the glass plate 151, the light receiving surface grid electrode 14 and the side of the bottom surface of the polygonal pyramid-shaped recess are made non-parallel. Therefore, in the solar cell module according to the third embodiment, the overlapping length between the flat surface portion 153 and the light receiving surface grid electrode 14 can be shortened as in the case of the first embodiment, and the solar cell 11 It is possible to reduce the occurrence of interference fringes due to the increased interference of light by the light receiving surface grid electrode 14 and the flat surface portion 153.

That is, in the solar cell module according to the third embodiment, the light receiving surface grid electrode 14 and the flat surface portion 153 are generated by the overlap between the light receiving surface grid electrode 14 of the solar cell 11 and the flat surface portion 153 of the light receiving surface side protective member 31. It is possible to suppress the deterioration of the appearance due to the interference fringes observed in the overlapping portion with. Therefore, in the solar cell module 1, as in the case of the first embodiment, the appearance is caused by the interference fringes generated by the light receiving surface grid electrode 14 of the solar cell 11 and the light receiving surface side protective member 31 having an uneven structure. It is possible to suppress the deterioration of the appearance.

The configuration shown in the above-described embodiment shows an example of the content of the present invention, can be combined with another known technique, and is one of the configurations without departing from the gist of the present invention. It is also possible to omit or change the part.

1 solar cell module, 10 solar cell string, 11 solar cell, 12 semiconductor substrate, 13 light receiving surface electrode, 14 light receiving surface grid electrode, 15 light receiving surface bus electrode, 16 back electrode, 17 back grid electrode, 18 back surface bus electrode, 21 Connection wiring, 31 Light receiving surface side protection member, 31a One side, 32 Back side protection member, 33 Encapsulant, 41 Frame, 51, 151 glass plate, 51a, 151a One side, 51b, 151b Other surface, 52 Hexagonal pyramid, 52a 1st hexagonal pyramid, 52b 2nd hexagonal pyramid, 52c 3rd hexagonal pyramid, 53 plane part, 54a slope bottom, 54b slope bottom, 55a 1st pair of sides, 56b, 56c 2 pairs of sides, 57 Arrangement interval, 58 width, 61 quadrangular pyramid convex part, 62 triangular pyramid convex part, 71, 72 rhombus, 152 hexagonal pyramid concave part, 711 first rhombus, 711a first side, 711b second Side, 712 second diamond, 712a first side.

Claims (5)

A solar cell having a plurality of light receiving surface grid electrodes arranged in parallel in a plane on the light receiving surface side of a semiconductor substrate having a pn junction, and a solar cell.
A light-transmitting substrate arranged parallel to the semiconductor substrate on the light-receiving surface side of the solar cell and having an uneven structure on the surface of one surface on the light-receiving surface side.
It is a solar cell module equipped with
The convex or concave portion of the concave-convex structure is composed of an aggregate of polygonal pyramids having a polygonal bottom surface in the plane of the light-transmitting substrate.
In a vertical view with respect to the light transmitting substrate, the light receiving surface grid electrode and all sides of the bottom surface of the polygonal pyramid are in a non-parallel state.
A solar cell module featuring. The intersection angle at which the polygonal side and the light receiving surface grid electrode intersect in the plane of the light transmitting substrate is 10 ° or more.
The solar cell module according to claim 1 . The polygonal pyramid is a regular hexagonal pyramid having a regular hexagonal bottom surface on one surface of the light transmissive substrate.
The uneven structure is configured by arranging the regular hexagonal pyramids of the same size in a honeycomb shape.
The solar cell module according to claim 1 or 2 . In a vertical view with respect to the light transmitting substrate, one side of the bottom surface of the regular hexagonal pyramid is orthogonal to the light receiving surface grid electrode.
The solar cell module according to claim 3 . The bottom surface of the polygonal pyramid is composed of Penrose tiles.
The solar cell module according to claim 1 or 2 .

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